Patent application title: Methods of expressing LIM mineralization protein in non-osseous cells
William F. Mckay (Memphis, TN, US)
Scott D. Boden (Atlanta, GA, US)
Sangwook T. Yoon (Atlanta, GA, US)
IPC8 Class: AA61K4800FI
Publication date: 2010-09-23
Patent application number: 20100239545
Methods of expressing LIM mineralization protein in non-osseous mammalian
cells, such as stem cells or intervertebral disc cells (e.g., cells of
the annulus fibrosus, or cells of the nucleus pulposus) are described.
The methods involve transfecting the cells with an isolated nucleic acid
comprising a nucleotide sequence encoding a LIM mineralization protein
operably linked to a promoter. Transfection may be accomplished ex vivo
or in vivo by direct injection of virus or naked DNA, or by a nonviral
vector such as a plasmid. Expression of the LIM mineralization protein
can stimulate proteoglycan and/or collagen production in cells capable of
producing proteoglycyan and/or collagen. Methods for treating disc
disease associated with trauma or disc degeneration are also described.
1. A method of expressing a LIM mineralization protein in a non-osseous
mammalian cell, comprising: transfecting the cell with an isolated
nucleic acid comprising a nucleotide sequence encoding the LIM
mineralization protein operably linked to a promoter.
2. The method of claim 1, wherein the cell is capable of producing proteoglycan and/or collagen and wherein expression of the LIM mineralization protein stimulates proteoglycan and/or collagen synthesis in the cell.
3. The method of claim 2, wherein the isolated nucleic acid: hybridizes under standard conditions to a nucleic acid molecule complementary to the full length of SEQ.ID NO: 25; and/or hybridizes under highly stringent conditions to a nucleic acid molecule complementary to the full length of SEQ.ID NO: 26.
4. The method of claim 2, wherein the cell is a stem cell, an intervertebral disc cell, a cell of the nucleus pulposus, or a cell of the annulus fibrosus.
5. The method of claim 1, wherein the cell is transfected ex vivo.
6. The method of claim 1, wherein the cell is transfected in vivo.
7. The method of claim 2, wherein the cell is transfected in vivo by direct injection of the nucleic acid into an intervertebral disc of a mammal.
8. The method of claim 1, wherein the nucleic acid is in a vector.
9. The method of claim 8, wherein the vector is an expression vector.
10. The method of claim 9, wherein the expression vector is a plasmid.
11. The method of claim 8, wherein the vector is a virus.
12. The method of claim 11, wherein the virus is an adenovirus.
13. The method of claim 11, wherein the virus is a retrovirus.
14. The method of claim 12, wherein the adenovirus is AdHLMP-1.
15. The method of claim 1, wherein the promoter is a cytomegalovirus promoter.
16. The method according to claim 1, wherein the proteoglycan is sulfated glycosaminoglycan.
17. The method according to claim 1, wherein the LIM mineralization protein is RLMP, HLMP-1, HLMP-1s, HLMP-2, or HLMP-3.
18. The method according to claim 1, wherein the LIM mineralization protein is HLMP-1.
19. The method according to claim 1, wherein expression of the LIM mineralization protein increases the expression of one or more bone morphogenetic proteins in the cell.
20. A non-osseous mammalian cell comprising an isolated nucleic acid sequence encoding a LIM mineralization protein.
21. The non-osseous mammalian cell of claim 20, wherein the cell is a stem cell, a cell of the annulus fibrosus, a cell of the nucleus pulposus or an intervertebral disc cell.
22. The non-osseous mammalian cell of claim 20, wherein the cell is a pluripotential stem cell or a mesenchymal stem cell.
23. A method of treating intervertebral disc injury or disease in a mammal comprising: transfecting an isolated nucleic acid into a mammalian cell capable of producing proteoglycan and/or collagen; wherein the isolated nucleic acid comprises a nucleotide sequence encoding a LIM mineralization protein operably linked to a promoter and wherein expression of the LIM mineralization protein stimulates proteoglycan and/or collagen synthesis in the cell.
24. The method according to claim 23, wherein the method reverses, prevents or retards disc degeneration.
25. The method according to claim 23, wherein the disc disease is degenerative disc disease, lower back pain, disc herniation, or spinal stenosis.
26. The method according to claim 23, wherein the cell is an intervertebral disc cell and wherein the cell is transfected in vivo by direct injection of the isolated nucleic acid into an intervertebral disc of the mammal.
27. The method according to claim 23, wherein the mammalian cell is transfected ex vivo and then implanted into the mammal.
28. The method of claim 23, wherein the mammalian cell is a non-osseous mammalian cell.
29. The method of claim 27, wherein the mammalian cell is a stem cell, an intervertebral disc cell, a cell of the annulus fibrosus, or a cell of the nucleus pulposus.
30. The method of claim 27, wherein the mammalian cell is a pluripotential stem cell or a mesenchymal stem cell.
31. The method of claim 23, wherein the isolated nucleic acid is in a vector.
32. The method of claim 23, wherein the isolated nucleic acid is in an expression vector.
33. The method of claim 23, wherein the isolated nucleic acid is in a plasmid.
34. The method of claim 23, wherein the isolated nucleic acid is in a virus.
35. The method of claim 23, wherein the isolated nucleic acid is in an adenovirus.
36. The method of claim 23, wherein the isolated nucleic acid is in a retrovirus.
37. The method of claim 35, wherein the adenovirus is AdHLMP-1.
38. The method of claim 23, wherein the promoter is a cytomegalovirus promoter.
39. The method according to claim 23, wherein the LIM mineralization protein is RLMP, HLMP-1, HLMP-1s, HLMP-2, or HLMP-3.
40. The method according to claim 23, wherein the LIM mineralization protein is HLMP-1.
41. The method of claim 23, wherein the isolated nucleic acid: hybridizes under standard conditions to a nucleic acid molecule complementary to the full length of SEQ.ID NO: 25; and/or hybridizes under highly stringent conditions to a nucleic acid molecule complementary to the full length of SEQ.ID NO: 26.
42. The method of claim 27, wherein the cell is implanted into an intervertebral disc.
43. The method of claim 27, further comprising: combining the transfected cell with a carrier prior to implantation into the mammal.
44. The method of claim 43, wherein the carrier comprises a porous matrix.
45. The method of claim 44, wherein the carrier comprises a synthetic polymer or collagen matrix.
46. An intervertebral disc implant comprising: a carrier material; and a plurality of mammalian cells comprising an isolated nucleic acid sequence encoding a LIM mineralization protein; wherein the carrier material comprises a porous matrix of biocompatible material and wherein the mammalian cells are incorporated into the carrier.
47. The implant of claim 46, wherein the mammalian cells are selected from the group consisting of stem cells, cells of the annulus fibrosus, cells of the nucleus pulposus, intervertebral disc cells and combinations thereof.
48. The implant of claim 46, wherein the mammalian cells are pluripotential stem cells, mesenchymal stem cells or combinations thereof.
49. The implant of claim 46, wherein the biocompatible material comprises a synthetic polymer or a protein.
50. The implant of claim 46, wherein the biocompatible material comprises collagen.
 This application claims priority from U.S. Provisional Application
Serial No. 60/331,321 filed Nov. 14, 2001. The entirety of that
provisional application is incorporated herein by reference.
 This application is related to U.S. patent application Ser. No. 09/124,238, filed Jul. 29, 1988, now U.S. Pat. No. 6,300,127, and U.S. patent application Ser. No. 09/959,578, filed Apr. 28, 2000, pending. Each of these applications is incorporated by reference herein in its entirety.
BACKGROUND OF THE INVENTION
 1. Field of the Invention
 The field of the invention relates generally to methods for expressing LIM mineralization proteins in non-osseous cells such as intervertebral disc cells or cells of the nucleus pulposus. More specifically, the field of the invention relates to transfecting non-osseous cells such as intervertebral disc cells with a nucleic acid encoding a LIM mineralization protein.
 2. Background of the Technology
 Osteoblasts are thought to differentiate from pluripotent mesenchymal stem cells. The maturation of an osteoblast results in the secretion of an extracellular matrix which can mineralize and form bone. The regulation of this complex process is not well understood but is thought to involve a group of signaling glycoproteins known as bone morphogenetic proteins (BMPs). These proteins have been shown to be involved with embryonic dorsal-ventral patterning, limb bud development, and fracture repair in adult animals. B. L. Hogan, Genes & Develop., 10, 1580 (1996). This group of transforming growth factor-beta superfamily secreted proteins has a spectrum of activities in a variety of cell types at different stages of differentiation; differences in physiological activity between these closely related molecules have not been clarified. D. M. Kingsley, Trends Genet., 10, 16 (1994).
 To better discern the unique physiological role of different BMP signaling proteins, we recently compared the potency of BMP-6 with that of BMP-2 and BMP-4, for inducing rat calvarial osteoblast differentiation. Boden, et al., Endocrinology, 137, 3401 (1996). We studied this process in first passage (secondary) cultures of fetal rat calvaria that require BMP or glucocorticoid for initiation of differentiation. In this model of membranous bone formation, glucocorticoid (GC) or a BMP will initiate differentiation to mineralized bone nodules capable of secreting osteocalcin, the osteoblast-specific protein. This secondary culture system is distinct from primary rat osteoblast cultures which undergo spontaneous differentiation. In this secondary system, glucocorticoid resulted in a ten-fold induction of BMP-6 mRNA and protein expression which was responsible for the enhancement of osteoblast differentiation. Boden, et al., Endocrinology, 138, 2920 (1997).
 In addition to extracellular signals, such as the BMPs, intracellular signals or regulatory molecules may also play a role in the cascade of events leading to formation of new bone. One broad class of intracellular regulatory molecules are the LIM proteins, which are so named because they possess a characteristic structural motif known as the LIM domain. The LIM domain is a cysteine-rich structural motif composed of two special zinc fingers that are joined by a 2-amino acid spacer. Some proteins have only LIM domains, while others contain a variety of additional functional domains. LIM proteins form a diverse group, which includes transcription factors and cytoskeletal proteins. The primary role of LIM domains appears to be in mediating protein-protein interactions, through the formation of dimers with identical or different LIM domains, or by binding distinct proteins.
 In LIM homeodomain proteins, that is, proteins having both LIM domains and a homeodomain sequence, the LIM domains function as negative regulatory elements. LIM homeodomain proteins are involved in the control of cell lineage determination and the regulation of differentiation, although LIM-only proteins may have similar roles. LIM-only proteins are also implicated in the control of cell proliferation since several genes encoding such proteins are associated with oncogenic chromosome translocations.
 Humans and other mammalian species are prone to diseases or injuries that require the processes of bone repair and/or regeneration. For example, treatment of fractures would be improved by new treatment regimens that could stimulate the natural bone repair mechanisms, thereby reducing the time required for the fractured bone to heal. In another example, individuals afflicted with systemic bone disorders, such as osteoporosis, would benefit from treatment regimens that would results in systemic formation of new bone. Such treatment regimens would reduce the incidence of fractures arising from the loss of bone mass that is a characteristic of this disease.
 For at least these reasons, extracellular factors, such as the BMPs, have been investigated for the purpose of using them to stimulate formation of new bone in vivo. Despite the early successes achieved with BMPs and other extracellular signalling molecules, their use entails a number of disadvantages. For example, relatively large doses of purified BMPs are required to enhance the production of new bone, thereby increasing the expense of such treatment methods. Furthermore, extracellular proteins are susceptible to degradation following their introduction into a host animal. In addition, because they are typically immunogenic, the possibility of stimulating an immune response to the administered proteins is ever present.
 Due to such concerns, it would be desirable to have available treatment regimens that use an intracellular signaling molecule to induce new bone formation. Advances in the field of gene therapy now make it possible to introduce into osteogenic precursor cells, that is, cells involved in bone formation, or peripheral blood leukocytes, nucleotide fragments encoding intracellular signals that form part of the bone formation process. Gene therapy for bone formation offers a number of potential advantages: (1) lower production costs; (2) greater efficacy, compared to extracellular treatment regiments, due to the ability to achieve prolonged expression of the intracellular signal; (3) it would by-pass the possibility that treatment with extracellular signals might be hampered due to the presence of limiting numbers of receptors for those signals; (4) it permits the delivery of transfected potential osteoprogenitor cells directly to the site where localized bone formation is required; and (5) it would permit systemic bone formation, thereby providing a treatment regimen for osteoporosis and other metabolic bone diseases.
 In addition to diseases of the bone, humans and other mammalian species are also subject to intervertebral disc degeneration, which is associated with, among other things, low back pain, disc herniations, and spinal stenosis. Disc degeneration is associated with a progressive loss of proteoglycan matrix. This may cause the disc to be more susceptible to bio-mechanical injury and degeneration. Accordingly, it would be desirable to have a method of stimulating proteoglycan and/or collagen synthesis by the appropriate cells, such as, for example, cells of the nucleous pulposus, cells of the annulus fibrosus, and cells of the intervertebral disc.
SUMMARY OF THE INVENTION
 According to a first aspect of the invention, a method of expressing a LIM mineralization protein in a non-osseous mammalian cell is provided. According to this aspect of the invention, the method comprises transfecting the cell with an isolated nucleic acid comprising a nucleotide sequence encoding the LIM mineralization protein operably linked to a promoter. The cell can be a cell capable of producing proteoglycan and/or collagen such that the expression of the LIM mineralization protein stimulates proteoglycan and/or collagen synthesis in the cell. The isolated nucleic acid according to this aspect of the invention can be a nucleic acid which can hybridize under standard conditions to a nucleic acid molecule complementary to the full length of SEQ. ID NO: 25; and/or a nucleic acid molecule which can hybridize under highly stringent conditions to a nucleic acid molecule complementary to the full length of SEQ. ID NO: 26. The cell can be a stem cell, an intervertebral disc cell, a cell of the annulus fibrosus, or a cell of the nucleus pulposus.
 According to a second aspect of the invention, a non-osseous mammalian cell comprising an isolated nucleic acid sequence encoding a LIM mineralization protein is provided. According to this aspect of the invention, the cell can be a stem cell, a cell of the nucleus pulposus, a cell of the annulus fibrosus, or an intervertebral disc cell.
 According to a third aspect of the invention, a method of treating intervertebral disc injury or disease is provided. According to this aspect of the invention, the method comprises transfecting an isolated nucleic acid into a mammalian cell capable of producing proteoglycan and/or collagen. The isolated nucleic acid comprises a nucleotide sequence encoding a LIM mineralization protein operably linked to a promoter. The LIM mineralization protein stimulates proteoglycan and/or collagen synthesis in the cell.
 According to a fourth aspect of the invention, an intervertebral disc implant is provided. According to this aspect of the invention, the implant comprises a carrier material and a plurality of mammalian cells comprising an isolated nucleic acid sequence encoding a LIM mineralization protein. Also according to this aspect of the invention, the carrier material comprises a porous matrix of biocompatible material and the mammalian cells are incorporated into the carrier material.
BRIEF DESCRIPTION OF THE DRAWINGS
 The present invention may be better understood with reference to the accompanying drawings in which:
 FIG. 1 is a graph showing the production of sulfated glycosaminoglycan (sGAG) after expression of HLMP-1 by rat intervertebral disc cells transfected with different MOIs;
 FIG. 2 is a chart showing the dose response of rat intervertebral disc cells six days after infection with different MOI of AdHLMP-1;
 FIG. 3 is a chart showing the expression of Aggrecan and BMP-2 mRNA by AdHLMP-1 transfected rat intervertebral disc cells six days following transfection with an MOI of 250 virions/cell;
 FIG. 4A is a chart showing HLMP-1 mRNA expression 12 hours after infection with Ad-hLMP-1 at different MOIs;
 FIG. 4B is a chart showing the production of sGAG in medium from 3 to 6 days after infection;
 FIG. 5 is a chart showing time course changes of the production of sGAG;
 FIG. 6A is a chart showing gene response to LMP-1 over-expression in rat annulus fibrosus cells for aggrecan
 FIG. 6B is a chart showing gene response to LMP-1 over-expression in rat annulus fibrosus cells for BMP-2;
 FIG. 7 is a graph showing the time course of HLMP-1 mRNA levels in rat annulus fibrosus cells after infection with AdLMP-1 at MOI of 25;
 FIG. 8 is a chart showing changes in mRNA levels of BMPs and aggrecan in response to HLMP-1 over-expression;
 FIG. 9 is a graph showing the time course of sGAG production enhancement in response to HLMP-1 expression;
 FIG. 10 is a chart showing that the LMP-1 mediated increase in sGAG production is blocked by noggin; and
 FIG. 11 is a graph showing the effect of LMP-1 on sGAG in media after day 6 of culture in monolayer.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
 The present invention relates to the transfection of non-osseous cells with nucleic acids encoding LIM mineralization proteins. The present inventors have discovered that transfection of non-osseous cells such as intervertebral disc cells with nucleic acids encoding LIM mineralization proteins can result in the increased synthesis of proteoglycan, collagen and other intervertebral disc components and tissue. The present invention also provides a method for treating intervertebral disc disease associated with the loss of proteoglycan, collagen, or other intervertebral disc components.
 It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. TABLE-US-00001 ABBREVIATIONS AND DEFINITIONS BMP Bone Morphogenetic Protein HLMP-1 Human LMP-1, also designated as Human LIM Protein or HLMP HLMP-1s Human LMP-1 Short (truncated) protein HLMPU Human LIM Protein Unique Region LMP LIM mineralization protein MEM Minimal essential medium Trm Triamcinolone β-GlyP Beta-glycerolphosphate RACE Rapid Amplification of cDNA Ends RLMP Rat LIM mineralization protein, also designated as RLMP-l RLMPU Rat LIM Protein Unique Region RNAsin RNase inhibitor ROB Rat Osteoblast 10-4 Clone containing cDNA sequence for RLMP (SEQ ID NO: 2) UTR Untranslated Region HLMP-2 Human LMP Splice Variant 2 HLMP-3 Human LMP Splice Variant 3 MOI multiplicity of infection sGAG sulfated glycosaminoglycan AdHLMP-1 Recombinant Type 5 Adenovirus comprising nucleotide sequence encoding HLMP-1
 A LIM gene (10-4/RLMP) has been isolated from stimulated rat calvarial osteoblast cultures (SEQ. ID NO: 1, SEQ. ID NO: 2). See U.S. Pat. No. 6,300,127. This gene has been cloned, sequenced and assayed for its ability to enhance the efficacy of bone mineralization in vitro. The protein RLMP has been found to affect the mineralization of bone matrix as well as the differentiation of cells into the osteoblast lineage. Unlike other known cytokines (e.g., BMPs), RLMP is not a secreted protein, but is instead an intracellular signaling molecule. This feature has the advantage of providing intracellular signaling amplification as well as easier assessment of transfected cells. It is also suitable for more efficient and specific in vivo applications. Suitable clinical applications include enhancement of bone repair in fractures, bone defects, bone grafting, and normal homeostasis in patients presenting with osteoporosis.
 The amino acid sequence of a corresponding human protein, named human LMP-1 ("HLMPI"), has also been cloned, sequenced and deduced. See U.S. Pat. No. 6,300,127. The human protein has been found to demonstrate enhanced efficacy of bone mineralization in vitro and in vivo.
 Additionally, a truncated (short) version of HLMP-1, termed HLMP-1s, has been characterized. See U.S. Pat. No. 6,300,127. This short version resulted from a point mutation in one source of a cDNA clone, providing a stop codon which truncates the protein. HLMP-1s has been found to be fully functional when expressed in cell culture and in vivo.
 Using PCR analysis of human heart cDNA library, two alternative splice variants (referred to as HLMP-2 and HLMP-3) have been identified that differ from HLMP-1 in a region between base pairs 325 and 444 in the nucleotide sequence encoding HLMP-1. See U.S. patent application Ser. No. 09/959,578, filed Apr. 28, 2000, pending. The HLMP-2 sequence has a 119 base pair deletion and an insertion of 17 base pairs in this region. Compared to HLMP-1, the nucleotide sequence encoding HLMP-3 has no deletions, but it does have the same 17 base pairs as HLMP-2, which are inserted at position 444 in the HLMP-1 sequence.
 LMP is a pluripotent molecule, which regulates or influences a number of biological processes. The different splice variants of LMP are expected to have different biological functions in mammals. They may play a role in the growth, differentiation, and/or regeneration of various tissues. For example, some form of LMP is expressed not only in bone, but also in muscle, tendons, ligaments, spinal cord, peripheral nerves, and cartilage.
 According to one aspect, the present invention relates to a method of stimulating proteoglycan and/or collagen synthesis in a mammalian cell by providing an isolated nucleic acid comprising a nucleotide sequence encoding LIM mineralization protein operably linked to a promoter; transfecting said isolated nucleic acid sequence into a mammalian cell capable of producing proteoglycan; and expressing said nucleotide sequence encoding LIM mineralization protein, whereby proteoglycan synthesis is stimulated. The mammalian cell may be a non-osseous cell, such as an intervertebral disc cell, a cell of the annulus fibrosus, or a cell of the nucleus pulposus. Transfection may occur either ex vivo or in vivo by direct injection of virus or naked DNA, such as, for example, a plasmid. In certain embodiments, the virus is a recombinant adenovirus, preferably AdHLMP-1.
 Another embodiment of the invention comprises a non-osseous mammalian cell comprising an isolated nucleic acid sequence encoding a LIM mineralization protein. The non-osseous mammalian cell may be a stem cell (e.g., a pluripotential stem cell or a mesenchymal stem cell) or an intervertebral disc cell, preferably a cell of the nucleus pulposus or a cell of the annulus fibrosus.
 In a different aspect, the invention is directed to a method of expressing an isolated nucleotide sequence encoding LIM mineralization protein in a non-osseous mammalian cell, comprising providing an isolated nucleic acid comprising a nucleotide sequence encoding LIM mineralization protein operably linked to a promoter; transfecting said isolated nucleic acid sequence into a non-osseous mammalian cell; and expressing said nucleotide sequence encoding LIM mineralization protein. The non-osseous mammalian cell may be a stem cell or an intervertebral disc cell (e.g., a cell of the nucleus pulposus or annulus fibrosus). Transfection may occur either ex vivo or in vivo by direct injection of virus or naked DNA, such as, for example, a plasmid. The virus can be a recombinant adenovirus, preferably AdHLMP-1.
 In yet another embodiment, the invention is directed to a method of treating intervertebral disc disease by reversing, retarding or slowing disc degeneration, comprising providing an isolated nucleic acid comprising a nucleotide sequence encoding LIM mineralization protein operably linked to a promoter; transfecting said isolated nucleic acid sequence into a mammalian cell capable of producing proteoglycan; and stimulating proteoglycan synthesis in said cell by expressing said nucleotide sequence encoding LIM mineralization protein, whereby disc degeneration is reversed, halted or slowed. The disc disease may involve lower back pain, disc herniation, or spinal stenosis. The mammalian cell may be a non-osseous cell, such as a stem cell or an intervertebral disc cell (e.g., a cell of the annulus fibrosus, or a cell of the nucleus pulposus).
 Transfection may occur either ex vivo or in vivo by direct injection of virus or naked DNA, such as, for example, a plasmid. In certain embodiments, the virus is a recombinant adenovirus, preferably AdHLMP-1.
 The present invention relates to novel mammalian LIM proteins, herein designated LIM mineralization proteins, or LMPs. The invention relates more particularly to human LMP, known as HLMP or HLMP-1, or alternative splice variants of human LMP, which are known as HLMP-2 or HLMP-3. The Applicants have discovered that these proteins enhance bone mineralization in mammalian cells grown in vitro. When produced in mammals, LMP also induces bone formation in vivo.
 Ex vivo transfection of bone marrow cells, osteogenic precursor cells, peripheral blood cells, and stem cells (e.g., pluripotential stem cells or mesenchymal stem cells) with nucleic acid that encodes a LIM mineralization protein (e.g., LMP or HLMP), followed by reimplantation of the transfected cells in the donor, is suitable for treating a variety of bone-related disorders or injuries. For example, one can use this method to: augment long bone fracture repair; generate bone in segmental defects; provide a bone graft substitute for fractures; facilitate tumor reconstruction or spine fusion; and provide a local treatment (by injection) for weak or osteoporotic bone, such as in osteoporosis of the hip, vertebrae, or wrist. Transfection with LMP or HLMP-encoding nucleic acid is also useful in: the percutaneous injection of transfected marrow cells to accelerate the repair of fractured long bones; treatment of delayed union or non-unions of long bone fractures or pseudoarthrosis of spine fusions; and for inducing new bone formation in avascular necrosis of the hip or knee.
 In addition to ex vivo methods of gene therapy, transfection of a recombinant DNA vector comprising a nucleic acid sequence that encodes LMP or HLMP can be accomplished in vivo. When a DNA fragment that encodes LMP or HLMP is inserted into an appropriate viral vector, for example, an adenovirus vector, the viral construct can be injected directly into a body site were endochondral bone formation is desired. By using a direct, percutaneous injection to introduce the LMP or HLMP sequence stimulation of bone formation can be accomplished without the need for surgical intervention either to obtain bone marrow cells (to transfect ex vivo) or to reimplant them into the patient at the site where new bone is required. Alden, et al., Neurosurgical Focus (1998), have demonstrated the utility of a direct injection method of gene therapy using a cDNA that encodes BMP-2, which was cloned into an adenovirus vector.
 It is also possible to carry out in vivo gene therapy by directly injecting into an appropriate body site, a naked, that is, unencapsulated, recombinant plasmid comprising a nucleic acid sequence that encodes HLMP. In this embodiment of the invention, transfection occurs when the naked plasmid DNA is taken up, or internalized, by the appropriate target cells, which have been described. As in the case of in vivo gene therapy using a viral construct, direct injection of naked plasmid DNA offers the advantage that little or no surgical intervention is required. Direct gene therapy, using naked plasmid DNA that encodes the endothelial cell mitogen VEGF (vascular endothelial growth factor), has been successfully demonstrated in human patients. Baumgartner, et al., Circulation, 97, 12, 1114-1123 (1998).
 For intervertebral disc applications, ex vivo transfection may be accomplished by harvesting cells from an intervertebral disc, transfecting the cells with nucleic acid encoding LMP in vitro, followed by introduction of the cells into an intervertebral disc. The cells may be harvested from or introduced back into the intervertebral disc using any means known to those of skill in the art, such as, for example, any surgical techniques appropriate for use on the spine. In one embodiment, the cells are introduced into the intervertebral disc by injection.
 Also according to the invention, stem cells (e.g., pluripotential stem cells or mesenchymal stem cells) can be transfected with nucleic acid encoding a LIM Mineralization Protein ex vivo and introduced into the intervertebral disc (e.g., by injection).
 The cells transfected ex vivo can also be combined with a carrier to form an intervertebral disc implant. The carrier comprising the transfected cells can then be implanted into the intervertebral disc of a subject. Suitable carrier materials are disclosed in Helm, et al., "Bone Graft Substitutes for the Promotion of Spinal Arthrodesis", Neurosurg Focus, Vol. 10 (4): April 2001. The carrier preferably comprises a biocompatible porous matrix such as a demineralized bone matrix (DBM), a biocompatible synthetic polymer matrix or a protein matrix. Suitable proteins include extracellular matrix proteins such as collagen. The cells transfected with the LMP ex vivo can be incorporated into the carrier (i.e., into the pores of the porous matrix) prior to implantation.
 Similarly, for intervertebral disc applications where the cells are transfected in vivo, the DNA may be introduced into the intevertebral disc using any suitable method known to those of skill in the art. In one embodiment, the nucleic acid is directly injected into the intervertebral space.
 By using an adenovirus vector to deliver LMP into osteogenic cells, transient expression of LMP is achieved. This occurs because adenovirus does not incorporate into the genome of target cells that are transfected. Transient expression of LMP, that is, expression that occurs during the lifetime of the transfected target cells, is sufficient to achieve the objects of the invention. Stable expression of LMP, however, can occur when a vector that incorporates into the genome of the target cell is used as a delivery vehicle. Retrovirus-based vectors, for example, are suitable for this purpose.
 Stable expression of LMP is particularly useful for treating various systemic bone-related disorders, such as osteoporosis and osteogenesis imperfecta. For this embodiment of the invention, in addition to using a vector that integrates into the genome of the target cell to deliver an LMP-encoding nucleotide sequence into target cells, LMP expression can be placed under the control of a regulatable promoter. For example, a promoter that is turned on by exposure to an exogenous inducing agent, such as tetracycline, is suitable.
 Using this approach, one can stimulate formation of new bone on a systemic basis by administering an effective amount of the exogenous inducing agent. Once a sufficient quantity of bone mass is achieved, administration of the exogenous inducing agent can be discontinued. This process may be repeated as needed to replace bone mass lost, for example, as a consequence of osteoporosis. Antibodies specific for HLMP are particularly suitable for use in methods for assaying the osteoinductive, that is, bone-forming, potential of patient cells. In this way one can identify patients at risk for slow or poor healing of bone repair. Also, HLMP-specific antibodies are suitable for use in marker assays to identify risk factors in bone degenerative diseases, such as, for example, osteoporosis.
 Following well known and conventional methods, the genes of the present invention are prepared by ligation of nucleic acid segments that encode LMP to other nucleic acid sequences, such as cloning and/or expression vectors. Methods needed to construct and analyze these recombinant vectors, for example, restriction endonuclease digests, cloning protocols, mutagenesis, organic synthesis of oligonucleotides and DNA sequencing, have been described. For DNA sequencing DNA, the dieoxyterminator method is the preferred.
 Many treatises on recombinant DNA methods have been published, including Sambrook, et al., Molecular Cloning: A Laboratory Manual, 2nd edition, Cold Spring Harbor Press, (1988), Davis. et al., Basic Methods in Molecular Biology, Elsevier (1986), and Ausubel, et al., Current Protocols in Molecular Biology, Wiley Interscience (1988). These reference manuals are specifically incorporated by reference herein.
 Primer-directed amplification of DNA or cDNA is a common step in the expression of the genes of this invention. It is typically performed by the polymerase chain reaction (PCR). PCR is described in U.S. Pat. No. 4,800,159 to Mullis, et al. and other published sources. The basic principle of PCR is the exponential replication of a DNA sequence by successive cycles of primer extension. The extension products of one primer, when hybridized to another primer, becomes a template for the synthesis of another nucleic acid molecule. The primer-template complexes act as substrate for DNA polymerase, which in performing its replication function, extends the primers. The conventional enzyme for PCR applications is the thermostable DNA polymerase isolated from Thermus aquaticus, or Taq DNA polymerase.
 Numerous variations of the basic PCR method exist, and a particular procedure of choice in any given step needed to construct the recombinant vectors of this invention is readily performed by a skilled artisan. For example, to measure cellular expression of 10-4/RLMP, RNA is extracted and reverse transcribed under standard and well known procedures. The resulting cDNA is then analyzed for the appropriate mRNA sequence by PCR.
 The gene encoding the LIM mineralization protein is expressed in an expression vector in a recombinant expression system. Of course, the constructed sequence need not be the same as the original, or its complimentary sequence, but instead may be any sequence determined by the degeneracy of the DNA code that nonetheless expresses an LMP having bone forming activity. Conservative amino acid substitutions, or other modifications, such as the occurrence of an amino-terminal methionine residue, may also be employed.
 A ribosome binding site active in the host expression system of choice is ligated to the 5' end of the chimeric LMP coding sequence, forming a synthetic gene. The synthetic gene can be inserted into any one of a large variety of vectors for expression by ligating to an appropriately linearized plasmid. A regulatable promoter, for example, the E. coli lac promoter, is also suitable for the expression of the chimeric coding sequences. Other suitable regulatable promoters include trp, tac, recA, T7 and lambda promoters.
 DNA encoding LMP is transfected into recipient cells by one of several standard published procedures, for example, calcium phosphate precipitation, DEAE-Dextran, electroporation or protoplast fusion, to form stable transformants. Calcium phosphate precipitation is preferred, particularly when performed as follows.
 DNAs are coprecipitated with calcium phosphate according to the method of Graham and Van Der, Virology, 52, 456 (1973), before transfer into cells. An aliquot of 40-50 μg of DNA, with salmon sperm or calf thymus DNA as a carrier, is used for 0.5×106 cells plated on a 100 mm dish. The DNA is mixed with 0.5 ml of 2× Hepes solution (280 mM NaCl, 50 mM Hepes and 1.5 mM Na2HPO4, pH 7.0), to which an equal volume of 2× CaCl2 (250 mM CaCl2 and 10 mM Hepes, pH 7.0) is added. A white granular precipitate, appearing after 30-40 minutes, is evenly distributed dropwise on the cells, which are allowed to incubate for 4-16 hours at 37° C. The medium is removed and the cells shocked with 15% glycerol in PBS for 3 minutes. After removing the glycerol, the cells are fed with Dulbecco's Minimal Essential Medium (DMEM) containing 10% fetal bovine serum.
 DNA can also be transfected using: the DEAE-Dextran methods of Kimura, et al., Virology, 49:394 (1972) and Sompayrac et al., Proc. Natl. Acad. Sci. USA, 78, 7575 (1981); the electroporation method of Potter, Proc. Natl. Acad. Sci. USA, 81, 7161 (1984); and the protoplast fusion method of Sandri-Goddin et al., Molec. Cell. Biol., 1, 743 (1981).
 Phosphoramidite chemistry in solid phase is the preferred method for the organic synthesis of oligodeoxynucleotides and polydeoxynucleotides. In addition, many other organic synthesis methods are available. Those methods are readily adapted by those skilled in the art to the particular sequences of the invention.
 The present invention also includes nucleic acid molecules that hybridize under standard conditions to any of the nucleic acid sequences encoding the LIM mineralization proteins of the invention. "Standard hybridization conditions" will vary with the size of the probe, the background and the concentration of the nucleic acid reagents, as well as the type of hybridization, for example, in situ, Southern blot, or hybrization of DNA-RNA hybrids (Northern blot). The determination of "standard hybridization conditions" is within the level of skill in the art. For example, see U.S. Pat. No. 5,580,775 to Fremeau, et al., herein incorporated by reference for this purpose. See also, Southern, J. Mol. Biol., 98:503 (1975), Alwine, et al., Meth. Enzymol., 68:220 (1979), and Sambrook, et al., Molecular Cloning: A Laboratory Manual, 2nd edition, Cold Spring Harbor Press, 7.19-7.50 (1989).
 One preferred set of standard hybrization conditions involves a blot that is prehybridized at 42° C. for 2 hours in 50% formamide, 5×SSPE (150 nM NaCl, 10 mM Na H2PO4 [pH 7.4], 1 mM EDTA [pH 8.0])l 5× Denhardt's solution (20 mg Ficoll, 20 mg polyvinylpyrrolidone and 20 mg BSA per 100 ml water), 10% dextran sulphate, 1% SDS and 100 μg/ml salmon sperm DNA. A 32P-labeled cDNA probe is added, and hybridization is continued for 14 hours. Afterward, the blot is washed twice with 2×SSPE, 0.1% SDS for 20 minutes at 22° C., followed by a 1 hour wash at 65° C. in 0.1×SSPE, 0.1% SDS. The blot is then dried and exposed to x-ray film for 5 days in the presence of an intensifying screen.
 Under "highly stringent conditions," a probe will hybridize to its target sequence if those two sequences are substantially identical. As in the case of standard hybridization conditions, one of skill in the art can, given the level of skill in the art and the nature of the particular experiment, determine the conditions under which only susbstantially identical sequences will hybridize.
 According to one aspect of the present invention, an isolated nucleic acid molecule comprising a nucleic acid sequence encoding a LIM mineralization protein is provided. The nucleic acid molecule according to the invention can be a molecule which hybridizes under standard conditions to a nucleic acid molecule complementary to the full length of SEQ. ID NO: 25 and/or which hybridizes under highly stringent conditions to a nucleic acid molecule complementary to the full length of SEQ. ID NO: 26. More specifically, the isolated nucleic acid molecule according to the invention can encode HLMP-1, HLMP-1s, RLMP, HLMP-2, or HLMP-3.
 Another aspect of the invention includes the proteins encoded by the nucleic acid sequences. In still another embodiment, the invention relates to the identification of such proteins based on anti-LMP antibodies. In this embodiment, protein samples are prepared for Western blot analysis by lysing cells and separating the proteins by SDS-PAGE. The proteins are transferred to nitrocellulose by electrobloffing as described by Ausubel, et al., Current Protocols in Molecular Biology, John Wiley and Sons (1987). After blocking the filter with instant nonfat dry milk (1 gm in 100 ml PBS), anti-LMP antibody is added to the filter and incubated for 1 hour at room temperature. The filter is washed thoroughly with phosphate buffered saline (PBS) and incubated with horseradish peroxidase (HRPO)-antibody conjugate for 1 hour at room temperature. The filter is again washed thoroughly with PBS and the antigen bands are identified by adding diaminobenzidine (DAB).
 Monospecific antibodies are the reagent of choice in the present invention, and are specifically used to analyze patient cells for specific characteristics associated with the expression of LMP. "Monospecific antibody" as used herein is defined as a single antibody species or multiple antibody species with homogenous binding characteristics for LMP. "Homogeneous binding" as used herein refers to the ability of the antibody species to bind to a specific antigen or epitope, such as those associated with LMP, as described above. Monospecific antibodies to LMP are purified from mammalian antisera containing antibodies reactive against LMP or are prepared as monoclonal antibodies reactive with LMP using the technique of Kohler and Milstein. Kohler et al., Nature, 256, 495-497 (1975). The LMP specific antibodies are raised by immunizing animals such as, for example, mice, rats, guinea pigs, rabbits, goats or horses, with an appropriate concentration of LMP either with or without an immune adjuvant.
 In this process, pre-immune serum is collected prior to the first immunization. Each animal receives between about 0.1 mg and about 1000 mg of LMP associated with an acceptable immune adjuvant, if desired. Such acceptable adjuvants include, but are not limited to, Freund's complete, Freund's incomplete, alum-precipitate, water in oil emulsion containing Corynebacterium parvum and tRNA adjuvants. The initial immunization consists of LMP in, preferably, Freund's complete adjuvant injected at multiple sites either subcutaneously (SC), intraperitoneally (IP) or both. Each animal is bled at regular intervals, preferably weekly, to determine antibody titer. The animals may or may not receive booster injections following the initial immunization. Those animals receiving booster injections are generally given an equal amount of the antigen in Freund's incomplete adjuvant by the same route. Booster injections are given at about three week intervals until maximal titers are obtained. At about 7 days after each booster immunization or about weekly after a single immunization, the animals are bled, the serum collected, and aliquots are stored at about -20° C.
 Monoclonal antibodies (mAb) reactive with LMP are prepared by immunizing inbred mice, preferably Balb/c mice, with LMP. The mice are immunized by the IP or SC route with about 0.1 mg to about 10 mg, preferably about 1 mg, of LMP in about 0.5 ml buffer or saline incorporated in an equal volume of an acceptable adjuvant, as discussed above. Freund's complete adjuvant is preferred. The mice receive an initial immunization on day 0 and are rested for about 3-30 weeks. Immunized mice are given one or more booster immunizations of about 0.1 to about 10 mg of LMP in a buffer solution such as phosphate buffered saline by the intravenous (IV) route. Lymphocytes from antibody-positive mice, preferably splenic lymphocytes, are obtained by removing the spleens from immunized mice by standard procedures known in the art. Hybridoma cells are produced by mixing the splenic lymphocytes with an appropriate fusion partner, preferably myeloma cells, under conditions which will allow the formation of stable hybridomas. Fusion partners may include, but are not limited to: mouse myelomas P3/NS1/Ag 4-1; MPC-11; S-194 and Sp 2/0, with Sp 2/0 being preferred. The antibody producing cells and myeloma cells are fused in polyethylene glycol, about 1,000 mol. wt., at concentrations from about 30% to about 50%. Fused hybridoma cells are selected by growth in hypoxanthine, thymidine and aminopterin in supplemented Dulbecco's Modified Eagles Medium (DMEM) by procedures known in the art. Supernatant fluids are collected from growth positive wells on about days 14, 18, and 21, and are screened for antibody production by an immunoassay such as solid phase immunoradioassay (SPIRA) using LMP as the antigen. The culture fluids are also tested in the Ouchterlony precipitation assay to determine the isotype of the mAb. Hybridoma cells from antibody positive wells are cloned by a technique such as the soft agar technique of MacPherson, "Soft Agar Techniques: Tissue Culture Methods and Applications", Kruse and Paterson (eds.), Academic Press (1973). See, also, Harlow, et al., Antibodies: A Laboratory Manual, Cold Spring Laboratory (1988).
 Monoclonal antibodies may also be produced in vivo by injection of pristane-primed Balb/c mice, approximately 0.5 ml per mouse, with about 2×106 to about 6×106 hybridoma cells about 4 days after priming. Ascites fluid is collected at approximately 8-12 days after cell transfer and the monoclonal antibodies are purified by techniques known in the art.
 In vitro production in anti-LMP mAb is carried out by growing the hydridoma cell line in DMEM containing about 2% fetal calf serum to obtain sufficient quantities of the specific mAb. The mAb are purified by techniques known in the art.
 Antibody titers of ascites or hybridoma culture fluids are determined by various serological or immunological assays, which include, but are not limited to, precipitation, passive agglutination, enzyme-linked immunosorbent antibody (ELISA) technique and radioimmunoassay (RIA) techniques. Similar assays are used to detect the presence of the LMP in body fluids or tissue and cell extracts.
 It is readily apparent to those skilled in the art that the above described methods for producing monospecific antibodies may be utilized to produce antibodies specific for polypeptide fragments of LMP, full-length nascent LMP polypeptide, or variants or alleles thereof.
 In another embodiment, the invention is directed to alternative splice variants of HLMP-1. PCR analysis of human heart cDNA revealed mRNA for two HLMP alternative splice variants, named HLMP-2 and HLMP-3, that differ from HLMP-1 in a region between base pairs 325 and 444 in the HLMP-1 sequence. The HLMP-2 sequence has a 119 base pair deletion and an insertion of 17 base pairs in this region. These changes preserve the reading frame, resulting in a 423 amino acid protein, which compared to HLMP-1, has a net loss of 34 amino acids (40 amino acids deleted plus 6 inserted amino acids). HLMP-2 contains the c-terminal LIM domains that are present in HLMP-1.
 Compared to HLMP-1, HLMP-3 has no deletions, but it does have the same 17 base pair insertion at position 444. This insertion shifts the reading frame, causing a stop codon at base pairs 459-461. As a result, HLMP-3 encodes a protein of 153 amino acids. This protein lacks the c-terminal LIM domains that are present in HLMP-1 and HLMP-2. The predicted size of the proteins encoded by HLMP-2 and HLMP-3 was confirmed by western blot analysis.
 PCR analysis of the tissue distribution of the three splice variants revealed that they are differentially expressed, with specific isoforms predominating in different tissues. HLMP-1 is apparently the predominant form expressed in leukocytes, spleen, lung, placenta, and fetal liver. HLMP-2 appears to be the predominant isoform in skeletal muscle, bone marrow, and heart tissue. HLMP-3, however, was not the predominant isoform in any tissue examined.
 Over-expression of HLMP-3 in secondary rat osteoblast cultures induced bone nodule formation (287±56) similar to the effect seen for glucicorticoid (272±7) and HLMP-1 (232±200). Since HLMP-3 lacks the C-terminal LIM domains, there regions are not required for osteoinductive activity.
 Over-expression of HLMP-2, however, did not induce nodule formation (11±3). These data suggest that the amino acids encoded by the deleted 119 base pairs are necessary for osteoinduction. The data also suggest that the distribution of HLMP splice variants may be important for tissue-specific function. Surprisingly, we have shown that HLMP-2 inhibits steroid-induced osteoblast formation in secondary rat osteoblast cultures. Therefore, HLMP-2 may have therapeutic utility in clinical situations where bone formation is not desirable.
 On Jul. 22, 1997, a sample of 10-4/RLMP in a vector designated pCMV2/RLMP (which is vector pRc/CMV2 with insert 10-4 clone/RLMP) was deposited with the American Type Culture Collection (ATCC), 12301 Parklawn Drive, Rockville, Md. 20852. The culture accession number for that deposit is 209153. On Mar. 19, 1998, a sample of the vector pHis-A with insert HLPM-1s was deposited at the American Type Culture Collection ("ATCC"). The culture accession number for that deposit is 209698. On Apr. 14, 2000, samples of plasmids pHAhLMP-2 (vector pHisA with cDNA insert derived from human heart muscle cDNA with HLMP-2) and pHAhLMP-3 (vector pHisA with cDNA insert derived from human heart muscle cDNA with HLMP-3) were deposited with the ATCC, 10801 University Blvd., Manassas, Va., 20110-2209, USA, under the conditions of the Budapest treaty. The accession numbers for these deposits are PTA-1698 and PTA-1699, respectively. These deposits, as required by the Budapest Treaty, will be maintained in the ATCC for at least 30 years and will be made available to the public upon the grant of a patent disclosing them. It should be understood that the availability of a deposit does not constitute a license to practice the subject invention in derogation of patent rights granted by government action.
 In assessing the nucleic acids, proteins, or antibodies of the invention, enzyme assays, protein purification, and other conventional biochemical methods are employed. DNA and RNA are analyzed by Southern blotting and Northern blotting techniques, respectively. Typically, the samples analyzed are size fractionated by gel electrophoresis. The DNA or RNA in the gels are then transferred to nitrocellulose or nylon membranes. The blots, which are replicas of sample patterns in the gels, were then hybridized with probes. Typically, the probes are radio-labeled, preferably with 32P, although one could label the probes with other signal-generating molecules known to those in the art. Specific bands of interest can then be visualized by detection systems, such as autoradiography.
 For purposes of illustrating preferred embodiments of the present invention, the following, non-limiting examples are included. These results demonstrate the feasibility of inducing or enhancing the formation of bone using the LIM mineralization proteins of the invention, and the isolated nucleic acid molecules encoding those proteins.
Calvarial Cell Culture
 Rat calvarial cells, also known as rat osteoblasts ("ROB"), were obtained from 20-day pre-parturition rats as previously described. Boden. et al., Endocrinology, 137, 8, 3401-3407 (1996). Primary cultures were grown to confluence (7 days), trypsinized, and passed into 6-well plates (1×105 cells/35 mm well) as first subculture cells. The subculture cells, which were confluent at day 0, were grown for an additional 7 days. Beginning on day 0, media were changed and treatments (Trm and/or BMPs) were applied, under a laminar flow hood, every 3 or 4 days. The standard culture protocol was as follows: days 1-7, MEM, 10% FBS, 50 μg/ml ascorbic acid, ±stimulus; days 8-14, BGJb medium, 10% FBS, 5 mM β-GlyP (as a source of inorganic phosphate to permit mineralization). Endpoint analysis of bone nodule formation and osteocalcin secretion was performed at day 14. The dose of BMP was chosen as 50 ng/ml based on pilot experiments in this system that demonstrated a mid-range effect on the dose-response curve for all BMPs studied.
Antisense Treatment and Cell Culture
 To explore the potential functional role of LMP-1 during membranous bone formation, we synthesized an antisense oligonucleotide to block LMP-1 mRNA translation and treated secondary osteoblast cultures that were undergoing differentiation initiated by glucocorticoid. Inhibition of RLMP expression was accomplished with a highly specific antisense oligonucleotide (having no significant homologies to known rat sequences) corresponding to a 25 bp sequence spanning the putative translational start site (SEQ. ID NO: 42). Control cultures either did not receive oligonucleotide or they received sense oligonucleotide. Experiments were performed in the presence (preincubation) and absence of lipofectamine. Briefly, 22 μg of sense or antisense RLMP oligonucleotide was incubated in MEM for 45 minutes at room temperature. Following that incubation, either more MEM or pre-incubated lipofectamine/MEM (7% v/v; incubated 45 minutes at room temperature) was added to achieve an oligonucleotide concentration of 0.2 μM. The resulting mixture was incubated for 15 minutes at room temperature. Oligonucleotide mixtures were then mixed with the appropriate medium, that is, MEM/Ascorbate/±Trm, to achieve a final oligonucleotide concentration of 0.1 μM.
 Cells were incubated with the appropriate medium (±stimulus) in the presence or absence of the appropriate oligonucleotides. Cultures originally incubated with lipofectamine were re-fed after 4 hours of incubation (37° C.; 5% CO2) with media containing neither lipofectamine nor oligonucleotide. All cultures, especially cultures receiving oligonucleotide, were re-fed every 24 hours to maintain oligonucleotide levels.
 LMP-1 antisense oligonucleotide inhibited mineralized nodule formation and osteocalcin secretion in a dose-dependent manner, similar to the effect of BMP-6 oligonucleotide. The LMP-1 antisense block in osteoblast differentiation could not be rescued by addition of exogenous BMP-6, while the BMP-6 antisense oligonucleotide inhibition was reversed with addition of BMP-6. This experiment further confirmed the upstream position of LMP-1 relative to BMP-6 in the osteoblast differentiation pathway. LMP-1 antisense oligonucleotide also inhibited spontaneous osteoblast differentiation in primary rat osteoblast cultures.
Quantitation of Mineralized Bone Nodule Formation
 Cultures of ROBs prepared according to Examples 1 and 2 were fixed overnight in 70% ethanol and stained with von Kossa silver stain. A semi-automated computerized video image analysis system was used to quantitate nodule count and nodule area in each well. Boden. et al., Endocrinology, 137, 8, 3401-3407 (1996). These values were then divided to calculate the area per nodule values. This automated process was validated against a manual counting technique and demonstrated a correlation coefficient of 0.92 (p<0.000001). All data are expressed as the mean±standard error of the mean (S.E.M.) calculated from 5 or 6 wells at each condition. Each experiment was confirmed at least twice using cells from different calvarial preparations.
Quantitation of Osteocalcin Secretion
 Osteocalcin levels in the culture media were measured using a competitive radioimmunoassay with a monospecific polygonal antibody (Pab) raised in our laboratory against the C-terminal nonapeptide of rat osteocalcin as described in Nanes. et al., Endocrinology, 127:588 (1990). Briefly, 1 μg of nonapeptide was iodinated with 1 mCi 125I-Na by the lactoperoxidase method. Tubes containing 200 gl of assay buffer (0.02 M sodium phosphate, 1 mM EDTA, 0.001% thimerosal, 0.025% BSA) received media taken from cell cultures or osteocalcin standards (0-12,000 fmole) at 100 gl/tube in assay buffer. The Pab (1:40,000; 100 μl) was then added, followed by the iodinated peptide (12,000 cpm; 100 μl). Samples tested for non-specific binding were prepared similarly but contained no antibody.
 Bound and free PAbs were separated by the addition of 700 μl goat antirabbit IgG, followed by incubation for 18 hours at 4° C. After samples were centrifuged at 1200 rpm for 45 minutes, the supernatants were decanted and the precipitates counted in a gamma counter. Osteocalcin values were reported in fmole/100 μl, which was then converted to pmole/ml medium (3-day production) by dividing those values by 100. Values were expressed as the mean±S.E.M. of triplicate determinations for 5-6 wells for each condition. Each experiment was confirmed at least two times using cells from different calvarial preparations.
Effect of Trm and RLMP on Mineralization In Vitro
 There was little apparent effect of either the sense or antisense oligonucleotides on the overall production of bone nodules in the non-stimulated cell culture system. When ROBs were stimulated with Trm, however, the antisense oligonucleotide to RLMP inhibited mineralization of nodules by>95%. The addition of exogenous BMP-6 to the oligonucleotide-treated cultures did not rescue the mineralization of RLMP-antisense-treated nodules.
 Osteocalcin has long been synonymous with bone mineralization, and osteocalcin levels have been correlated with nodule production and mineralization. The RLMP-antisense oligonucleotide significantly decreases osteocalcin production, but the nodule count in antisense-treated cultures does not change significantly. In this case, the addition of exogenous BMP-6 only rescued the production of osteocalcin in RLMP-antisense-treated cultures by 10-15%. This suggests that the action of RLMP is downstream of, and more specific than, BMP-6.
Harvest and Purification of RNA
 Cellular RNA from duplicate wells of ROBs (prepared according to Examples 1 and 2 in 6-well culture dishes) was harvested using 4M guanidine isothiocyanate (GIT) solution to yield statistical triplicates. Briefly, culture supernatant was aspirated from the wells, which were then overlayed with 0.6 ml of GIT solution per duplicate well harvest. After adding the GIT solution, the plates were swirled for 5-10 seconds (being as consistent as possible). Samples were saved at -70° C. for up to 7 days before further processing.
 RNA was purified by a slight modification of standard methods according to Sambrook, et al. Molecular Cloning: a Laboratory Manual, Chapter 7.19, 2nd Edition, Cold Spring Harbor Press (1989). Briefly, thawed samples received 60 μl 2.0 M sodium acetate (pH 4.0), 550 μl phenol (water saturated) and 150 μl chloroform:isoamyl alcohol (49:1). After vortexing, the samples were centrifuged (10000×g; 20 minutes; 4° C.), the aqueous phase transferred to a fresh tube, 600 μl isopropanol was added and the RNA precipitated overnight at -20° C.
 Following the overnight incubation, the samples were centrifuged (10000×g; 20 minutes) and the supernatant was aspirated gently. The pellets were resuspended in 400 μl DEPC-treated water, extracted once with phenol:chloroform (1:1), extracted with chloroform:isoamyl alcohol (24:1) and precipitated overnight at -20° C. after addition of 40 μl sodium acetate (3.0 M; pH 5.2) and 1.0 ml absolute ethanol. To recover the cellular RNA, the samples were centrifuged (10000×g; 20 min), washed once with 70% ethanol, air dried for 5-10 minutes and resuspended in 20 μl of DEPC-treated water. RNA concentrations were calculated from optical densities that were determined with a spectrophotometer.
Reverse Transcription-Polymerase Chain Reaction 25
 Heated total RNA (5 μg in 10.5 μl total volume DEPC-H2O at 65° C. for 5 minutes) was added to tubes containing 4 μl 5× MMLV-RT buffer, 2 μl dNTPs, 2 μl dT17 primer (10 pmol/ml), 0.5 μl RNAsin (40 U/ml) and 1 μl MMLV-RT (200 units/μl). The samples were incubated at 37° C for 1 hour, then at 95° C. for 5 minutes to inactivate the MMLV-RT. The samples were diluted by addition of 80 μl of water.
 Reverse-transcribed samples (5 μ) were subjected to polymerase-chain reaction using standard methodologies (50 μl total volume). Briefly, samples were added to tubes containing water and appropriate amounts of PCR buffer, 25 mM MgCl2, dNTPs, forward and reverse primers for glyceraldehyde 3-phosphate dehydrogenase (GAP, a housekeeping gene) and/or BMP-6, 32P-dCTP, and Taq polymerase. Unless otherwise noted, primers were standardized to run consistently at 22 cycles (94° C., 30''; 58° C., 30''; 72° C., 20'').
Quantitation of RT-PCR Products by Polyacrylamide Gel Electrophoresis (PAGE) and PhosphorImager Analysis
 RT-PCR products received 5 μl/tube loading dye, were mixed, heated at 65° C. for 10 min and centrifuiged. Ten μl of each reaction was subjected to PAGE (12% polyacrylamide:bis; 15 V/well; constant current) under standard conditions. Gels were then incubated in gel preserving buffer (10% v/v glycerol, 7% v/v acetic acid, 40% v/v methanol, 43% deionized water) for 30 minutes, dried (80° C.) in vacuo for 1-2 hours and developed with an electronically-enhanced phosphoresence imaging system for 6-24 hours. Visualized bands were analyzed. Counts per band were plotted graphically.
Differential Display PCR
 RNA was extracted from cells stimulated with glucocorticoid (Trm, 1 nM). Heated, DNase-treated total RNA (5 μg in 10.5 μl total volume in DEPC-H2O at 65° C. for 5 minutes) was reverse transcribed as described in Example 7, but H-T11 M (SEQ. ID. NO: 4) was used as the MMLV-RT primer. The resulting cDNAs were PCR-amplified as described above, but with various commercial primer sets (for example, H-T11G (SEQ. ID NO: 4) and H-AP-10 (SEQ. ID NO: 5); GenHunter Corp, Nashville, Tenn.). Radio-labeled PCR products were fractionated by gel electrophoresis on a DNA sequencing gel. After electrophoresis, the resulting gels were dried in vacuo and autoradiographs were exposed overnight. Bands representing differentially-expressed cDNAs were excised from the gel and reamplified by PCR using the method of Conner. et al., Proc. Natl. Acad. Sci. USA, 88, 278 (1983). The products of PCR reamplification were cloned into the vector PCR-11 (TA cloning kit; InVitrogen, Carlsbad, Calif.).
Screening of a UMR 106 Rat Osteosarcoma Cell cDNA Library
 A UMR 106 library (2.5×1010 pfu/ml) was plated at 5×104 pfu/ml onto agar plates (LB bottom agar) and the plates were incubated overnight at 37° C. Filter membranes were overlaid onto plates for two minutes. Once removed, the filters were denatured, rinsed, dried and UV cross-linked. The filters were then incubated in pre-hyridization buffer (2× PIPES [pH 6.5], 5% formamide, 1% SDS and 100 μg/ml denatured salmon sperm DNA) for 2 h at 42° C. A 260 base-pair radio-labeled probe (SEQ. ID NO: 3; 32P labeled by random priming) was added to the entire hybridization mix/filters, followed by hybridization for 18 hours at 42° C. The membranes were washed once at room temperature (10 min, 1×SSC, 0.1% SDS) and three times at 55° C. (15 min, 0.1×SSC, 0.1% SDS).
 After they were washed, the membranes were analyzed by autoradiography as described above. Positive clones were plaque purified. The procedure was repeated with a second filter for four minutes to minimize spurious positives. Plaque-purified clones were rescued as lambda SK(-) phagemids. Cloned cDNAs were sequenced as described below.
Sequencing of Clones
 Cloned cDNA inserts were sequenced by standard methods. Ausubel, et al., Current Protocols in Molecular Biology, Wiley Interscience (1988). Briefly, appropriate concentrations of termination mixture, template and reaction mixture were subjected to an appropriate cycling protocol (95° C., 30 s; 68° C., 30 s; 72° C., 60 s;×25). Stop mixture was added to terminate the sequencing reactions. After heating at 92° C. for 3 minutes, the samples were loaded onto a denaturing 6% polyacrylamide sequencing gel (29:1 acrylamide:bisacrylamide). Samples were electrophoresed for about 4 hours at 60 volts, constant current. After electrophoresis, the gels were dried in vacuo and autoradiographed.
 The autoradiographs were analyzed manually. The resulting sequences were screened against the databases maintained by the National Center for Biotechnology Information (NIH, Bethesda, Md; hftp://www.ncbi.nlm.nih.gov/) using the BLASTN program set with default parameters. Based on the sequence data, new sequencing primers were prepared and the process was repeated until the entire gene had been sequenced. All sequences were confirmed a minimum of three times in both orientations.
 Nucleotide and amino acid sequences were also analyzed using the PCGENE software package (version 16.0). Percent homology values for nucleotide sequences were calculated by the program NALIGN, using the following parameters: weight of non-matching nucleotides, 10; weight of non-matching gaps, 10; maximum number of nucleotides considered, 50; and minimum number of nucleotides considered, 50.
 For amino acid sequences, percent homology values were calculated using PALIGN. A value of 10 was selected for both the open gap cost and the unit gap cost.
Cloning of RLMP cDNA
 The differential display PCR amplification products described in Example 9 contained a major band of approximately 260 base pairs. This sequence was used to screen a rat osteosarcoma (UMR 106) cDNA library. Positive clones were subjected to nested primer analysis to obtain the primer sequences necessary for amplifying the full length cDNA. (SEQ. ID NOs: 11, 12, 29, 30 and 31). One of those positive clones selected for further study was designated clone 10-4.
 Sequence analysis of the full-length cDNA in clone 10-4, determined by nested primer analysis, showed that clone 10-4 contained the original 260 base-pair fragment identified by differential display PCR. Clone 10-4 (1696 base pairs; SEQ ID NO: 2) contains an open reading frame of 1371 base pairs encoding a protein having 457 amino acids (SEQ. ID NO: 1). The termination codon, TGA, occurs at nucleotides 1444-1446. The polyadenylation signal at nucleotides 1675-1680, and adjacent poly(A)+tail, was present in the 3' noncoding region. There were two potential N-glycosylation sites, Asn-Lys-Thr and Asn-Arg-Thr, at amino acid positions 113-116 and 257-259 in SEQ. ID NO: 1, respectively. Two potential cAMP- and cGMP-dependent protein kinase phosphorylation sites, Ser and Thr, were found at amino acid positions 191 and 349, respectively. There were five potential protein kinase C phosphorylation sites, Ser or Thr, at amino acid positions 3, 115, 166, 219, 442. One potential ATP/GTP binding site motif A (P-loop), Gly-Gly-Ser-Asn-Asn-Gly-Lys-Thr, was determined at amino acid positions 272-279.
 In addition, two highly conserved putative LIM domains were found at amino acid positions 341-391 and 400-451. The putative LIM domains in this newly identified rat cDNA clone showed considerable homology with the LIM domains of other known LIM proteins. However, the overall homology with other rat LIM proteins was less than 25%. RLMP (also designated 10-4) has 78.5% amino acid homology to the human enigma protein (see U.S. Pat. No. 5,504,192), but only 24.5% and 22.7% amino acid homology to its closest rat homologs, CLP-36 and RIT-18, respectively.
Northern Blot Analysis of RLMP Expression
 Thirty μg of total RNA from ROBs, prepared according to Examples 1 and 2, was size fractionated by formaldehyde gel electrophoresis in 1% agarose flatbed gels and osmotically transblotted to nylon membranes. The blot was probed with a 600 base pair EcoR1 fragment of full-length 10-4 cDNA labeled with 32P-dCTP by random priming.
 Northern blot analysis showed a 1.7 kb mRNA species that hybridized with the RLMP probe. RLMP mRNA was up-regulated approximately 3.7-fold in ROBs after 24 hours exposure to BMP-6. No up-regulation of RMLP expression was seen in BMP-2 or BMP-4-stimulated ROBs at 24 hours.
 For each reported nodule/osteocalcin result, data from 5-6 wells from a representative experiment were used to calculate the mean±S.E.M. Graphs may be shown with data normalized to the maximum value for each parameter to allow simultaneous graphing of nodule counts, mineralized areas and osteocalcin.
 For each reported RT-PCR, RNase protection assay or Western blot analysis, data from triplicate samples of representative experiments, were used to determine the mean±S.E.M. Graphs may be shown normalized to either day 0 or negative controls and expressed as fold-increase above control values.
 Statistical significance was evaluated using a one-way analysis of variance with post-hoc multiple comparison corrections of Bonferroni as appropriate. D. V. Huntsberger, "The Analysis of Variance", Elements of Statistical Variance, P. Billingsley (ed.), Allyn & Bacon Inc., Boston, Mass., 298-330 (1977) and SigmaStat, Jandel Scientific, Corte Madera, Calif. Alpha levels for significance were defined as p<0.05.
Detection of Rat LIM Mineralization Protein by Western Blot Analysis
 Polyclonal antibodies were prepared according to the methods of England, et al., Biochim.Biophys. Acta, 623, 171 (1980) and Timmer, et al., J. Biol. Chem., 268, 24863 (1993).
 HeLa cells were transfected with pCMV2/RLMP. Protein was harvested from the transfected cells according to the method of Hair, et al., Leukemia Research, 20, 1 (1996). Western Blot Analysis of native RLMP was performed as described by Towbin, et al., Proc. Natl. Acad. Sci. USA, 76:4350 (1979).
Synthesis of the Rat LMP-Unique (RLMPU) Derived Human PCR Product
 Based on the sequence of the rat LMP-1 cDNA, forward and reverse PCR primers (SEQ. ID NOS: 15 and 16) were synthesized and a unique 223 base-pair sequence was PCR amplified from the rat LMP-1 cDNA. A similar PCR product was isolated from human MG63 osteosarcoma cell cDNA with the same PCR primers.
 RNA was harvested from MG63 osteosarcoma cells grown in T-75 flasks. Culture supernatant was removed by aspiration and the flasks were overlayed with 3.0 ml of GIT solution per duplicate, swirled for 5-10 seconds, and the resulting solution was transferred to 1.5 ml eppendorf tubes (6 tubes with 0.6 ml/tube). RNA was purified by a slight modification of standard methods, for example, see Sambrook, et al., Molecular Cloning: A Laboratory Manual, Chapter 7, page 19, Cold Spring Harbor Laboratory Press (1989) and Boden, et al., Endocrinology, 138, 2820-2828 (1997). Briefly, the 0.6 ml samples received 60 μl 2.0 M sodium acetate (pH 4.0), 550 μl water saturated phenol and 150 μl chloroform:isoamyl alcohol (49:1). After addition of those reagents, the samples were vortexed, centrifuged (10000×g; 20 min; 4C) and the aqueous phase transferred to a fresh tube. Isopropanol (600, μl) was added and the RNA was precipitated overnight at -20° C. The samples were centrifuged (10000×g; 20 minutes) and the supernatant was aspirated gently. The pellets were resuspended in 400 μl of DEPC-treated water, extracted once with phenol:chloroform (1:1), extracted with chloroform:isoamyl alcohol (24:1) and precipitated overnight at -20° C. in 40 μl sodium acetate (3.0 M; pH 5.2) and 1.0 ml absolute ethanol. After precipitation, the samples were centrifuged (10000×g; 20 min), washed once with 70% ethanol, air dried for 5-10 minutes and resuspended in 20 μl of DEPC-treated water. RNA concentrations were derived from optical densities.
 Total RNA (5 μg in 10.5 μl total volume in DEPC-H2O) was heated at 65° C. for 5 minutes, and then added to tubes containing 4 μl 5× MMLV-RT buffer, 2 μl dNTPS, 2, μl dT17 primer (10 pmol/ml), 0.5 μl RNA sin (40 U/ml) and 1 μl MMLV-RT (200 units/μl). The reactions were incubated at 37° C. for 1 hour. Afterward, the MMLV-RT was inactivated by heating at 95° C. for 5 minutes. The samples were diluted by addition of 80 μl water.
 Transcribed samples (5 μl) were subjected to polymerase-chain reaction using standard methodologies (50 μl total volume). Boden, et al., Endocrinology, 138, 2820-2828 (1997); Ausubel, et al., "Quantitation of Rare DNAs by the Polymerase Chain Reaction", Current Protocols in Molecular Biology, Chapter 15.31-1, Wiley & Sons, Trenton, N.J. (1990). Briefly, samples were added to tubes containing water and appropriate amounts of PCR buffer (25 mM MgCl2, dNTPs, forward and reverse primers (for RLMPU; SEQ. ID NOS: 15 and 16), 32P-dCTP, and DNA polymerase. Primers were designed to run consistently at 22 cycles for radioactive band detection and 33 cycles for amplification of PCR product for use as a screening probe (94° C., 30 sec, 58° C., 30 sec; 72° C., 20 sec).
 Sequencing of the agarose gel-purified MG63 osteosarcoma-derived PCR product gave a sequence more than 95% homologous to the RLMPU PCR product. That sequence is designated HLMP unique region (HLMPU; SEQ. ID NO: 6).
Screening of Reverse-Transcriptase-Derived MG63 cDNA
 Screening was performed with PCR using specific primers (SEQ. ID NOS:16 and 17) as described in Example 7. A 717 base-pair MG63 PCR product was agarose gel purified and sequenced with the given primers (SEQ. ID NOs: 12, 15, 16, 17, 18, 27 and 28). Sequences were confirmed a minimum of two times in both directions. The MG63 sequences were aligned against each other and then against the full-length rat LMP cDNA sequence to obtain a partial human LMP cDNA sequence (SEQ. ID NO: 7).
Screening of a Human Heart cDNA Library
 Based on Northern blot experiments, it was determined that LMP-1 is expressed at different levels by several different tissues, including human heart muscle. A human heart cDNA library was therefore examined. The library was plated at 5×104 pfu/ml onto agar plates (LB bottom agar) and plates were grown overnight at 37° C. Filter membranes were overlaid onto the plates for two minutes. Afterward, the filters denatured, rinsed, dried, UV cross-linked and incubated in pre-hyridization buffer (2× PIPES [pH 6.5]; 5% formamide, 1% SDS, 100 g/ml denatured salmon sperm DNA) for 2 h at 42° C. A radio-labeled, LMP-unique, 223 base-pair probe (32P, random primer labeling; SEQ ID NO: 6) was added and hybridized for 18 h at 42° C. Following hybridization, the membranes were washed once at room temperature (10 min, 1×SSC, 0.1% SDS) and three times at 55° C. (15 min, 0.1×SSC, 0.1% SDS). Double-positive plaque-purified heart library clones, identified by autoradiography, were rescued as lambda phagemids according to the manufacturers' protocols (Stratagene, La Jolla, Calif.).
 Restriction digests of positive clones yielded cDNA inserts of varying sizes. Inserts greater than 600 base-pairs in length were selected for initial screening by sequencing. Those inserts were sequenced by standard methods as described in Example 11.
 One clone, number 7, was also subjected to automated sequence analysis using primers corresponding to SEQ. ID NOS: 11-14, 16 and 27. The sequences obtained by these methods were routinely 97-100% homologous. Clone 7 (Partial Human LMP-1 cDNA from a heart library; SEQ. ID NO: 8) contained a sequence that was more than 87% homologous to the rat LMP cDNA sequence in the translated region.
Determination of Full-Length Human LMP-1 cDNA
 Overlapping regions of the MG63 human osteosarcoma cell cDNA sequence and the human heart cDNA clone 7 sequence were used to align those two sequences and derive a complete human cDNA sequence of 1644 base-pairs. NALIGN, a program in the PCGENE software package, was used to align the two sequences. The overlapping regions of the two sequences constituted approximately 360 base-pairs having complete homology except for a single nucleotide substitution at nucleotide 672 in the MG63 cDNA (SEQ. ID NO: 7) with clone 7 having an "A" instead of a "G" at the corresponding nucleotide 516 (SEQ. ID NO: 8).
 The two aligned sequences were joined using SEQIN, another subprogram of PCGENE, using the "G" substitution of the MG63 osteosarcoma cDNA clone. The resulting sequence is shown in SEQ. ID NO: 9. Alignment of the novel human-derived sequence with the rat LMP-1 cDNA was accomplished with NALIGN. The full-length human LMP-1 cDNA sequence (SEQ. ID NO: 9) is 87.3% homologous to the translated portion of rat LMP-1 cDNA sequence.
Determination of Amino Acid Sequence of Human LMP-1
 The putative amino acid sequence of human LMP-1 was determined with the PCGENE subprogram TRANSL. The open reading frame in SEQ. ID NO: 9 encodes a protein comprising 457 amino acids (SEQ. ID NO: 10). Using the PCGENE subprogram Palign, the human LMP-1 amino acid sequence was found to be 94.1% homologous to the rat LMP-1 amino acid sequence.
Determination of the 5 Prime Untranslated Region of the Human LMP cDNA
 MG63 5' cDNA was amplified by nested RT-PCR of MG63 total RNA using a 5' rapid amplification of cDNA ends (5' RACE) protocol. This method included first strand cDNA synthesis using a lock-docking oligo (dT) primer with two degenerate nucleotide positions at the 3' end (Chenchik. et al., CLONTECHniques , X:5 (1995); Borson, et al., PC Methods Applic., 2, 144 (1993)). Second-strand synthesis is performed according to the method of Gubler, et al., Gene, 2, 263 (1983), with a cocktail of Escherichia coli DNA polymerase 1, RNase H, and E. coli DNA ligase. After creation of blunt ends with T4 DNA polymerase, double-stranded cDNA was ligated to the fragment (5'-CTAATACGACTCACTATAGGGCTCGAGCGGCCGCCCGGGCAGGT-3') (SEQ. ID NO: 19). Prior to RACE, the adaptor-ligated cDNA was diluted to a concentration suitable for Marathon RACE reactions (1:50). Adaptor-ligated double-stranded cDNA was then ready to be specifically cloned.
 First-round PCR was performed with the adaptor-specific oligonucleotide, 5'-CCATCCTAATACGACTCACTATAGGGC-3' (AP1) (SEQ. ID NO: 20) as sense primer and a Gene Specific Primer (GSP) from the unique region described in Example 16 (HLMPU). The second round of PCR was performed using a nested primers GSP1-HLMPU (antisense/reverse primer) (SEQ. ID NO: 23) and GSP2-HLMPUF (SEQ. ID NO: 24) (see Example 16; sense/forward primer). PCR was performed using a commercial kit (Advantage cDNA PCR core kit; CloneTech Laboratories Inc., Palo Alto, Calif.) that utilizes an antibody-mediated, but otherwise standard, hot-start protocol. PCR conditions for MG63 cDNA included an initial hot-start denaturation (94° C., 60 sec) followed by: 94° C., 30 sec; 60° C., 30 sec; 68° C., 4 min; 30 cycles. The firstround PCR product was approximately 750 base-pairs in length whereas the nested PCR product was approximately 230 base-pairs. The first-round PCR product was cloned into linearized pCR 2.1 vector (3.9 Kb). The inserts were sequenced in both directions using M13 Forward and Reverse primers (SEQ. ID NO: 11; SEQ. ID NO: 12).
Determination of Full-Length Human LMP-1 cDNA with 5 Prime UTR
 Overlapping MG63 human osteosarcoma cell cDNA 5'-UTR sequence (SEQ. ID NO: 21), MG63 717 base-pair sequence (Example 17; SEQ. ID NO: 8) and human heart cDNA clone 7 sequence (Example 18) were aligned to derive a novel human cDNA sequence of 1704 base-pairs (SEQ. ID NO: 22). The alignment was accomplished with NALIGN, (both PCGENE and Omiga 1.0; Intelligenetics). Over-lapping sequences constituted nearly the entire 717 base-pair region (Example 17) with 100% homology. Joining of the aligned sequences was accomplished with SEQIN.
Construction of LIM Protein Expression Vector
 The construction of pHIS-5ATG LMP-1s expression vector was carried out with the sequences described in Examples 17 and 18. The 717 base-pair clone (Example 17; SEQ. ID NO: 7) was digested with ClaI and EcoRV. A small fragment (˜250 base-pairs) was gel purified. Clone 7 (Example 18; SEQ. ID NO: 8) was digested with ClaI and XbaI and a 1400 base-pair fragment was gel purified. The isolated 250 base-pair and 1400 base-pair restriction fragments were ligated to form a fragment of ˜1650 base-pairs.
 Due to the single nucleotide substitution in Clone 7 (relative to the 717 base-pair PCR sequence and the original rat sequence) a stop codon at translated base-pair 672 resulted. Because of this stop codon, a truncated (short) protein was encoded, hence the name LMP-1s. This was the construct used in the expression vector (SEQ. ID NO: 32). The full length cDNA sequence with 5' UTR (SEQ. ID NO: 33) was created by alignment of SEQ. ID NO: 32 with the 5' RACE sequence (SEQ. ID NO: 21). The amino acid sequence of LMP-1s (SEQ. ID NO: 34) was then deduced as a 223 amino acid protein and confirmed by Western blot (as in Example 15) to run at the predicted molecular weight of ˜23.7 kD.
 The pHis-ATG vector (InVitrogen, Carlsbad, Calif.) was digested with EcoRV and XbaI. The vector was recovered and the 650 base-pair restriction fragment was then ligated into the linearized pHis-ATG. The ligated product was cloned and amplified. The pHis-ATG-LMP-1s Expression vector, also designated pHIS-A with insert HLMP-1s, was purified by standard methods.
Induction of Bone Nodule Formation and Mineralization In vitro with LMP Expression Vector
 Rat Calvarial cells were isolated and grown in secondary culture according to Example 1. Cultures were either unstimulated or stimulated with glucocorticoid (GC) as described in Example 1. A modification of the Superfect Reagent (Qiagen, Valencia, Calif.) transfection protocol was used to transfect 3 μg/well of each vector into secondary rat calvarial osteoblast cultures according to Example 25.
 Mineralized nodules were visualized by Von Kossa staining, as described in Example 3. Human LMP-1s gene product over expression alone induced bone nodule formation (˜203 nodules/well) in vitro. Levels of nodules were approximately 50% of those induced by the GC positive control (˜412 nodules/well). Other positive controls included the pHisA-LMP-Rat expression vector (˜152 nodules/well) and the pCMV2/LMP-Rat-Fwd Expression vector (˜206 nodules/well), whereas the negative controls included the pCMV2/LMP-Rat-Rev. expression vector (˜2 nodules/well) and untreated (NT) plates (˜4 nodules/well). These data demonstrate that the human cDNA was at least as osteoinductive as the rat cDNA. The effect was less than that observed with GC stimulation, most likely due to sub-optimal doses of Expression vector.
LMP-Induced Cell Differentiation In Vitro and In Vivo
 The rat LMP cDNA in clone 10-4 (see Example 12) was excised from the vector by double-digesting the clone with NotI and ApaI overnight at 37° C. Vector pCMV2 MCS (InVitrogen, Carlsbad, Calif.) was digested with the same restriction enzymes. Both the linear cDNA fragment from clone 10-4 and pCMV2 were gel purified, extracted and ligated with T4 ligase. The ligated DNA was gel purified, extracted and used to transform E. coli JM109 cells for amplification. Positive agar colonies were picked, digested with NotI and ApaI and the restriction digests were examined by gel electrophoresis. Stock cultures were prepared of positive clones.
 A reverse vector was prepared in analogous fashion except that the restriction enzymes used were XbaI and HindIII. Because these restriction enzymes were used, the LMP cDNA fragment from clone 10-4 was inserted into pRc/CMV2 in the reverse (that is, non-translatable) orientation. The recombinant vector produced is designated pCMV2/RLMP.
 An appropriate volume of pCMV10-4 (60 nM final concentration is optimal [3 μg]; for this experiment a range of 0-600 nM/well [0-30 μg/well] final concentration is preferred) was resuspended in Minimal Eagle Media (MEM) to 450 μl final volume and vortexed for 10 seconds. Superfect was added (7.5 μl/ml final solution), the solution was vortexed for 10 seconds and then incubated at room temperature for 10 minutes. Following this incubation, MEM supplemented with 10% FBS (1 ml/well; 6 ml/plate) was added and mixed by pipetting.
 The resulting solution was then promptly pipetted (1 ml/well) onto washed ROB cultures. The cultures were incubated for 2 hours at 37° C. in a humidified atmosphere containing 5% CO2. Afterward, the cells were gently washed once with sterile PBS and the appropriate normal incubation medium was added.
 Results demonstrated significant bone nodule formation in all rat cell cultures which were induced with pCMV10-4. For example, pCMV10-4 transfected cells produced 429 nodules/well. Positive control cultures, which were exposed to Trm, produced 460 nodules/well. In contrast, negative controls, which received no treatment, produced 1 nodule/well. Similarly, when cultures were transfected with pCMV10-4 (reverse), no nodules were observed.
 For demonstrating de novo bone formation in vivo, marrow was aspirated from the hind limbs of 4-5 week old normal rats (mu/+; heterozygous for recessive athymic condition). The aspirated marrow cells were washed in alpha MEM, centrifuged, and RBCs were lysed by resuspending the pellet in 0.83% NH4Cl in 10 mM Tris (pH 7.4). The remaining marrow cells were washed 3× with MEM and transfected for 2 hours with 9 μg of pCMV-LMP-1s (forward or reverse orientation) per 3×106 cells. The transfected cells were then washed 2× with MEM and resuspended at a concentration of 3×107 cells/ml.
 The cell suspension (100 μl) was applied via sterile pipette to a sterile 2×5 mm type I bovine collagen disc (Sulzer Orthopaedics, Wheat Ridge, Colo.). The discs were surgically implanted subcutaneously on the skull, chest, abdomen or dorsal spine of 4-5 week old athymic rats (rnu/rnu). The animals were scarified at 3-4 weeks, at which time the discs or surgical areas were excised and fixed in 70% ethanol. The fixed specimens were analyzed by radiography and undecalcified histologic examination was performed on 5 μm thick sections stained with Goldner Trichrome. Experiments were also performed using devitalized (guanidine extracted) demineralized bone matrix (Osteotech, Shrewsbury, N.J.) in place of collagen discs.
 Radiography revealed a high level of mineralized bone formation that conformed to the form of the original collagen disc containing LMP-1s transfected marrow cells. No mineralized bone formation was observed in the negative control (cells transfected with a reverse-oriented version of the LMP-1s cDNA that did not code for a translated protein), and absorption of the carrier appeared to be well underway.
 Histology revealed new bone trabeculae lined with osteoblasts in the LMP-1s transfected implants. No bone was seen along with partial resorption of the carrier in the negative controls.
 Radiography of a further experiment in which 18 sets (9 negative control pCMV-LMP-REV & 9 experimental pCMV-LMP-1s) of implants were added to sites alternating between lumbar and thoracic spine in athymic rats demonstrated 0/9 negative control implants exhibiting bone formation (spine fusion) between vertebrae. All nine of the pCMV-LMP-1s treated implants exhibited solid bone fusions between vertebrae.
The Synthesis of pHIS-5' ATG LMP-1s Expression Vector from the Sequences Demonstrated in Examples 2 and 3
 The 717 base-pair clone (Example 17) was digested with ClaI and EcoRV (New England Biologicals, city, MA). A small fragment (˜250 base pairs) was gel purified. Clone No. 7 (Example 18) was digested with ClaI and XbaI. A 1400 base-pair fragment was gel purified from that digest. The isolated 250 base-pair and 1400 base-pair cDNA fragments were ligated by standard methods to form a fragment of ˜1650 bp. The pHis-A vector (InVitrogen) was digested with EcoRV and XbaI. The linearized vector was recovered and ligated to the chimeric 1650 base-pair cDNA fragment. The ligated product was cloned and amplified by standard methods, and the phis-A-5' ATG LMP-1s expression vector, also denominated as the vector pHis-A with insert HLMP-1s, was deposited at the ATCC as previously described.
The Induction of Bone Nodule Formation and Mineralization In Vitro With pHis-5' ATG LMP-1s Expression Vector
 Rat calvarial cells were isolated and grown in secondary culture according to Example 1. Cultures were either unstimulated or stimulated with glucocorticoid (GC) according to Example 1. The cultures were transfected with 3 μg of recombinant pHis-A vector DNA/well as described in Example 25. Mineralized nodules were visualized by Von Kossa staining according to Example 3.
 Human LMP-1s gene product overexpression alone (i.e., without GC stimulation) induced significant bone nodule formation (˜203 nodules/well) in vitro. This is approximately 50% of the amount of nodules produced by cells lo exposed to the GC positive control (˜412 nodules/well). Similar results were obtained with cultures transfected with pHisA-LMP-Rat Expression vector (˜152 nodules/well) and pCMV2/LMP-Rat-Fwd (˜206 nodules/well). In contrast, the negative control pCMV2/LMP-Rat-Rev yielded (˜2 nodules/well), while approximately 4 nodules/well were seen in the untreated plates. These data demonstrate that the human LMP-1 cDNA was at least as osteoinductive as the rat LMP-1 cDNA in this model system. The effect in this experiment was less than that observed with GC stimulation; but in some the effect was comparable.
LMP Induces Secretion of a Soluble Osteoinductive Factor
 Overexpression of RLMP-1 or HLMP-1s in rat calvarial osteoblast cultures as described in Example 24 resulted in significantly greater nodule formation than was observed in the negative control. To study the mechanism of action of LIM mineralization protein conditioned medium was harvested at different time points, concentrated to 10×, sterile filtered, diluted to its original concentration in medium containing fresh serum, and applied for four days to untransfected cells.
 Conditioned media harvested from cells transfected with RLMP-1 or HLMP-1s at day 4 was approximately as effective in inducing nodule formation as direct overexpression of RLMP-1 in transfected cells. Conditioned media from cells transfected with RLMP-1 or HLMP-1 in the reverse orientation had no apparent effect on nodule formation. Nor did.conditioned media harvested from LMP-1 transfected cultures before day 4 induce nodule formation. These data suggest that expression of LMP-1 caused the synthesis and/or secretion of a soluble factor, which did not appear in culture medium in effective amounts until 4 days post transfection.
 Since overexpression of rLMP-1 resulted in the secretion of an osteoinductive factor into the medium, Western blot analysis was used to determine if LMP-1 protein was present in the medium. The presence of RLMP-1 protein was assessed using antibody specific for LMP-1 (QDPDEE) and detected by conventional means. LMP-1 protein was found only in the cell layer of the culture and not detected in the medium.
 Partial purification of the osteoinductive soluble factor was accomplished by standard 25% and 100% ammonium sulfate cuts followed by DE-52 anion exchange batch chromatography (100 mM or 500 mM NACl). All activity was observed in the high ammonium sulfate, high NaCl fractions. Such localization is consistent with the possibility of a single factor being responsible for conditioning the medium.
Gene Therapy in Lumbar Spine Fusion Mediated by Low Dose Adenovirus
 This study determined the optimal dose of adenoviral delivery of the LMP-1 cDNA (SEQ. ID NO: 2) to promote spine fusion in normal, that is, immune competent, rabbits.
 A replication-deficient human recombinant adenovirus was constructed with the LMP-1 cDNA (SEQ. ID NO: 2) driven by a CMV promoter using the Adeno-Quest® Kit (Quantum Biotechnologies, Inc., Montreal). A commercially available (Quantum Biotechnologies, Inc., Montreal) recombinant adenovirus containing the beta-galactosidase gene was used as a control.
 Initially, an in vitro dose response experiment was performed to determine the optimal concentration of adenovirus-delivered LMP-1 ("AdV-LMP-1") to induce bone differentiation in rat calvarial osteoblast cultures using a 60-minute transduction with a multiplicity of infection ("MOI") of 0.025, 0.25, 2.5, or 25 plaque-forming units (pfu) of virus per cell. Positive control cultures were differentiated by a 7-day exposure to 109 M glucocorticoid ("GC"). Negative control cultures were left untreated. On day 14, the number of mineralized bone nodules was counted after von Kossa staining of the cultures, and the level of osteocalcin secreted into the medium (pmol/mL) was measured by radioimmunoassay (mean±SEM).
 The results of this experiment are shown in Table 1. Essentially no spontaneous nodules formed in the untreated negative control cultures. The data show that a MOI equal to 0.25 pfu/cell is most effective for osteoinducing bone nodules, achieving a level comparable to the positive control (GC). Lower and higher doses of adenovirus were less effective. TABLE-US-00002 TABLE I Neg. Adv-LMP-1 Dose (MOI) Outcome Ctrl. GC 0.025 0.25 2.5 25 Bone 0.5 ± 0.2 188 ± 35 79.8 ± 13 145.1 ± 13 26.4 ± 15 87.6 ± 2 Nodules Osteocalcin 1.0 ± .1 57.8 ± 9 28.6 ± 11 22.8 ± 1 18.3 ± 3 26.0 ± 2
 In vivo experiments were then performed to determine if the optimal in vitro dose was capable of promoting intertransverse process spine fusions in skeletally mature New Zealand white rabbits. Nine rabbits were anesthetized and 3 cc of bone marrow was aspirated from the distal femur through the intercondylar notch using an 18 gauge needle. The buffy coat was then isolated, a 10-minute transduction with AdV-LMP-1 was performed, and the cells were returned to the operating room for implantation. Single level posterolateral lumbar spine arthrodesis was performed with decortication of transverse processes and insertion of carrier (either rabbit devitalized bone matrix or a collagen sponge) containing 8-15 million autologous nucleated buffy coat cells transduced with either AdV-LMP-1 (MOI=0.4) or AdV-BGal (MOI=0.4). Rabbits were euthanized after 5 weeks and spine fusions were assessed by manual palpation, plain x-rays, CT scans, and undecalcified histology.
 The spine fusion sites that received AdV-LMP-1 induced solid, continuous spine fusion masses in all nine rabbits. In contrast, the sites receiving AdV-BGal, or a lower dose of AdV-LMP-1 (MOI=0.04) made little or no bone and resulted in spine fusion at a rate comparable to the carrier alone (<40%). These results were consistent as evaluated by manual palpation, CT scan, and histology. Plain radiographs, however, sometimes overestimated the amount of bone that was present, especially in the control sites. LMP-1 cDNA delivery and bone induction was successful with both of the carrier materials tested. There was no evidence of systemic or local immune response to the adenovirus vector.
 These data demonstrate consistent bone induction in a previously validated rabbit spine fusion model which is quite challenging. Furthermore, the protocol of using autogenous bone marrow cells with intraoperative ex vivo gene transduction (10 minutes) is a more clinically feasible procedure than other methods that call for overnight transduction or cell expansion for weeks in culture. In addition, the most effective dose of recombinant adenovirus (MOI=0.25) was substantially lower than doses reported in other gene therapy applications (MOI 40-500). We believe this is due to the fact that LMP-1 is an intracellular signaling molecule and may have powerful signal amplification cascades. Moreover, the observation that the same concentration of AdV-LMP-1 that induced bone in cell culture was effective in vivo was also surprising given the usual required increase in dose of other growth factors when translating from cell culture to animal experiments. Taken together, these observations indicate that local gene therapy using adenovirus to deliver the LMP-1 cDNA is possible and the low dose required will likely minimize the negative effects of immune response to the adenovirus vector.
Use of Peripheral Venous Blood Nucleated Cells (Buffy Coat) for Gene Therapy With LMP-1 cDNA to Make Bone
 In four rabbits we performed spine fusion surgery as above (Example 29) except the transduced cells were the buffy coat from venous blood rather than bone marrow. These cells were transfected with Adeno-LMP or pHIS-LMP plasmid and had equivalent successful results as when bone marrow cells were used. This discovery of using ordinary venous blood cells for gene delivery makes gene therapy more feasible clinically since it avoids painful marrow harvest under general anesthesia and yields two times more cells per mL of starting material.
Isolation of Human LMP-1 Splice Variants
 Intron/Exon mRNA transcript splice variants are a relatively common regulatory mechanism in signal-transduction and cellular/tissue development. Splice variants of various genes have been shown to alter protein-protein, protein-DNA, protein-RNA, and protein-substrate interactions. Splice variants may also control tissue specificity for gene expression allowing different forms (and therefore functions) to be expressed in various tissues. Splice variants are a common regulatory phenomenon in cells. It is possible that the LMP splice variants may result in effects in other tissues such as nerve regeneration, muscle regeneration, or development of other tissues.
 To screen a human heart cDNA library for splice variants of the HLMP-1 sequence, a pair of PCR primer corresponding to sections of SEQ. ID NO: 22 was prepared. The forward PCR primer, which was synthesized using standard techniques, corresponds to nucleotides 35-54 of SEQ. ID NO: 22. It has the following sequence:  5' GAGCCGGCATCATGGATTCC 3' (SEQ. ID NO: 35)
 The reverse PCR primer, which is the reverse complement of nucleotides 820-839 in SEQ. ID NO: 22, has the following sequence:  5' GCTGCCTGCACAATGGAGGT 3' (SEQ. ID NO: 36)
 The forward and reverse PCR primers were used to screen human heart cDNA (ClonTech, Cat No. 7404-1) for sequences similar to HLMP-1 by standard techniques, using a cycling protocol of 94° C. for 30 seconds, 64° C. for 30 seconds, and 72° C. for 1 minute, repeated 30 times and followed by a 10 minute incubation at 72° C. The amplification cDNA sequences were gel-purified and submitted to the Emory DNA Sequence Core Facility for sequencing. The clones were sequenced using standard techniques and the sequences were examined with PCGENE (intelligenetics; Programs SEQUIN and NALIGN) to determine homology to SEQ. ID NO: 22. Two homologous nucleotide sequences with putative alternative splice sites compared to SEQ. ID NO: 22 were then translated to their respective protein products with Intelligenetic's program TRANSL.
 One of these two novel human cDNA sequences (SEQ. ID NO: 37) comprises 1456 bp: TABLE-US-00003 CGACGCAGAG CAGCGCCCTG GCCGGGCCAA GCAGGAGCCG GCATCATGGA TTCCTTCAAG 60 GTAGTGCTGG AGGGGCCAGC ACCTTGGGGC TTCCGGCTGC AAGGGGGCAA GGACTTCAAT 120 GTGCCCCTCT CCATTTCCCG GCTCACTCCT GGGGGCAAAG CGGCGCAGGC CGGAGTGGCC 180 GTGGGTGACT GGGTGCTGAG CATCGATGGC GAGAATGCGG GTAGCCTCAC ACACATCGAA 240 GCTCAGAACA AGATCCGGGC CTGCGGGGAG CGCCTCAGCC TGGGCCTCAG CAGGGCCCAG 300 x x CCGGTTCAGA GCAAACCGCA GAAGGTGCAG ACCCCTGACA AACAGCCGCT CCGACCGCTG 360 GTCCCAGATG CCAGCAAGCA GCGGCTGATG GAGAACACAG AGGACTGGCG GCCGCGGCCG 420 GGGACAGGCC AGTCGCGTTC CTTCCGCATC CTTGCCCACC TCACAGGCAC CGAGTTCATG 480 CAAGACCCGG ATGAGGAGCA CCTGAAGAAA TCAAGCCAGG TGCCCAGGAC AGAAGCCCCA 540 GCCCCAGCCT CATCTACACC CCAGGAGCCC TGGCCTGGCC CTACCGCCCC CAGCCCTACC 600 AGCCGCCCGC CCTGGGCTGT GGACCCTGCG TTTGCCGAGC GCTATGCCCC GGACAAAACG 660 AGCACAGTGC TGACCCGGCA CAGCCAGCCG GCCACGCCCA CGCCGCTGCA GAGCCGCACC 720 TCCATTGTGC AGGCAGCTGC CGGAGGGGTG CCAGGAGGGG GCAGCAACAA CGGCAAGACT 780 CCCGTGTGTC ACCAGTGCCA CAAGGTCATC CGGGGCCGCT ACCTGGTGGC GTTGGGCCAC 840 GCGTACCACC CGGAGGAGTT TGTGTGTAGC CAGTGTGGGA AGGTCCTGGA AGAGGGTGGC 900 TTCTTTGAGG AGAAGGGCGC CATCTTCTGC CCACCATGCT ATGACGTGCG CTATGCACCC 960 AGCTGTGCCA AGTGCAAGAA GAAGATTACA GGCGAGATCA TGCACGCCCT GAAGATGACC 1020 TGGCACGTGC ACTGCTTTAC CTGTGCTGCC TGCAAGACGC CCATCCGGAA CAGGGCCTTC 1080 TACATGGAGG AGGGCGTGCC CTATTGCGAG CGAGACTATG AGAAGATGTT TGGCACGAAA 1140 TGCCATGGCT GTGACTTCAA GATCGACGCT GGGGACCGCT TCCTGGAGGC CCTGGGCTTC 1200 AGCTGGCATG ACACCTGCTT CGTCTGTGCG ATATGTCAGA TCAACCTGGA AGGAAAGACC 1260 TTCTACTCCA AGAAGGACAG GCCTCTCTGC AAGAGCCATG CCTTCTCTCA TGTGTGAGCC 1320 CCTTCTGCCC ACAGCTGCCG CGGTGGCCCC TAGCCTGAGG GGCCTGGAGT CGTGGCCCTG 1380 CATTTCTGGG TAGGGCTGGC AATGGTTGCC TTAACCCTGG CTCCTGGCCC GACCCTGGGC 1440 TCCCGGGCCC TGCCCA 1456
 Reading frame shifts caused by the deletion of a 119 bp fragment (between X) and the addition of a 17 bp fragment (underlined) results in a truncated gene product having the following derived amino acid sequence (SEQ. ID NO: 38): TABLE-US-00004 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arq Ala Gln Pro Val Gln Asn Lys Pro Gln Lys Val Gln Thr 85 90 95 Pro Asp Lys Gln Pro Leu Arg Pro Leu Val Pro Asp Ala Ser Lys Gln 100 105 110 Arg Leu Met Glu Asn Thr Glu Asp Trp Arg Pro Arg Pro Gly Thr Gly 115 120 125 Gln Ser Arg Ser Phe Arg Ile Leu Ala His Leu Thr Gly Thr Glu Phe 130 135 140 Met Gln Asp Pro Asp Glu Glu His Leu Lys Lys Ser Ser Gln Val Pro 145 150 155 160 Arg Thr Glu Ala Pro Ala Pro Ala Ser Ser Thr Pro Gln Glu Pro Trp 165 170 175 Pro Gly Pro Thr Ala Pro Ser Pro Thr Ser Arg Pro Pro Trp Ala Val 180 185 190 Asp Pro Ala Phe Ala Glu Arg Tyr Ala Pro Asp Lys Thr Ser Thr Val 195 200 205 Leu Thr Arg His Ser Gln Pro Ala Thr Pro Thr Pro Leu Gln Ser Arg 210 215 220 Thr Ser Ile Val Gln Ala Ala Ala Gly Gly Val Pro Gly Gly Gly Ser 225 230 235 240 Asn Asn Gly Lys Thr Pro Val Cys His Gln Cys His Gln Val Ile Arg 245 250 255 Ala Arg Tyr Leu Val Ala Leu Gly His Ala Tyr His Pro Glu Glu Phe 260 265 270 Val Cys Ser Gln Cys Gly Lys Val Leu Glu Glu Gly Gly Phe Phe Glu 275 280 285 Glu Lys Gly Ala Ile Phe Cys Pro Pro Cys Tyr Asp Val Arg Tyr Ala 290 295 300 Pro Ser Cys Ala Lys Cys Lys Lys Lys Ile Thr Gly Glu Ile Met His 305 310 315 320 Ala Leu Lys Met Thr Trp His Val Leu Cys Phe Thr Cys Ala Ala Cys 325 330 335 Lys Thr Pro Ile Arg Asn Arg Ala Phe Tyr Met Glu Glu Gly Val Pro 340 345 350 Tyr Cys Glu Arg Asp Tyr Glu Lys Met Phe Gly Thr Lys Cys Gln Trp 355 360 365 Cys Asp Phe Lys Ile Asp Ala Gly Asp Arg Phe Leu Glu Ala Leu Gly 370 375 380 Phe Ser Trp His Asp Thr Cys Phe Val Cys Ala Ile Cys Gln Ile Asn 385 390 395 400 Leu Glu Gly Lys Thr Phe Tyr Ser Lys Lys Asp Arg Pro Leu Cys Lys 405 410 415 Ser His Ala Phe Ser His Val 420
 This 423 amino acid protein demonstrates 100% homology to the protein shown in SEQ. ID NO. 10, except for the sequence in the highlighted area (amino acids 94-99), which are due to the nucleotide changes depicted above.
 The second novel human heart cDNA sequence (SEQ. ID NO: 39) comprises 1575 bp: TABLE-US-00005 CGACGCAGAG CAGCGCCCTG GCCGGGCCAA GCAGGAGCCG GCATCATGGA TTCCTTCAAG 60 GTAGTGCTGG AGGGGCCAGC ACCTTGGGGC TTCCGGCTGC AAGGGGGCAA GGACTTCAAT 120 GTGCCCCTCT CCATTTCCCG GCTCACTCCT GGGGGCAAAG CGGCGCAGGC CGGAGTGGCC 180 GTGGGTGACT GGGTGCTGAG CATCGATGGC GAGAATGCGG GTAGCCTCAC ACACATCGAA 240 GCTCAGAACA AGATCCGGGC CTGCGGGGAG CGCCTCAGCC TGGGCCTCAG CAGGGCCCAG 300 CCGGTTCAGA GCAAACCGCA GAAGGCCTCC GCCCCCGCCG CGGACCCTCC GCGGTACACC 360 TTTGCACCCA GCGTCTCCCT CAACAAGACG GCCCGGCCCT TTGGGGCGCC CCCGCCCGCT 420 GACAGCGCCC CGCAACAGAA TGGGTGCAGA CCCCTGACAA ACAGCCGCTC CGACCGCTGG 480 TCCCAGATGC CAGCAAGCAG CGGCTGATGG AGAACACAGA GGACTGGCGG CCGCGGCCGG 540 GGACAGGCCA GTCGCGTTCC TTCCGCATCC TTGCCCACCT CACAGGCACC GAGTTCATGC 600 AAGACCCGGA TGAGGAGCAC CTGAAGAAAT CAAGCCAGGT GCCCAGGACA GAAGCCCCAG 660 CCCCAGCCTC ATCTACACCC CAGGAGCCCT GGCCTGGCCC TACCGCCCCC AGCCCTACCA 720 GCCGCCCGCC CTGGGCTGTG GACCCTGCGT TTGCCGAGCG CTATGCCCCG GACAAAACGA 780 GCACAGTGCT GACCCGGCAC AGCCAGCCGG CCACGCCCAC GCCGCTGCAG AGCCGCACCT 840 CCATTGTGCA GGCAGCTGCC GGAGGGGTGC CAGGAGGGGG CAGCAACAAC GGCAAGACTC 900 CCGTGTGTCA CCAGTGCCAC AAGGTCATCC GGGGCCGCTA CCTGGTGGCG TTGGGCCACG 960 CGTACCACCC GGAGGAGTTT GTGTGTAGCC AGTGTGGGAA GGTCCTGGAA GAGGGTGGCT 1020 TCTTTGAGGA GAAGGGCGCC ATCTTCTGCC CACCATGCTA TGACGTGCGC TATGCACCCA 1080 GCTGTGCCAA GTGCAAGAAG AAGATTACAG GCGAGATCAT GCACGCCCTG AAGATGACCT 1140 GGCACGTGCA CTGCTTTACC TGTGCTGCCT GCAAGACGCC CATCCGGAAC AGGGCCTTCT 1200 ACATGGAGGA GGGCGTGCCC TATTGCGAGC GAGACTATGA GAAGATGTTT GGCACGAAAT 1260 GCCATGGCTG TGACTTCAAG ATCGACGCTG GGGACCGCTT CCTGGAGGCC CTGGGCTTCA 1320 GCTGGCATGA CACCTGCTTC GTCTGTGCGA TATGTCAGAT CAACCTGGAA GGAAAGACCT 1380 TCTACTCCAA GAAGGACAGG CCTCTCTGCA AGAGCCATGC CTTCTCTCAT GTGTGAGCCC 1440 CTTCTGCCCA CAGCTGCCGC GGTGGCCCCT AGCCTGAGGG GCCTGGAGTC GTGGCCCTGC 1500 ATTTCTGGGT AGGGCTGGCA ATGGTTGCCT TAACCCTGGC TCCTGGCCCG AGCCTGGGCT 1560 CCCGGGCCCT GCCCA 1575
 Reading frame shifts caused by the addition of a 17 bp fragment (bolded, italicized and underlined) results in an early translation stop codon at position 565-567 (underlined).
 The derived amino acid sequence (SEQ. ID NO: 40) consists of 153 amino acids: TABLE-US-00006 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arg Ala Gln Pro Val Gln Ser Lys Pro Gln Lys Ala Ser Ala 85 90 95 Pro Ala Ala Asp Pro Pro Arg Tyr Thr Phe Ala Pro Ser Val Ser Leu 100 105 110 Asn Lys Thr Ala Arg Pro Phe Gly Ala Pro Pro Pro Ala Asp Ser Ala 115 120 125 Pro Gln Gln Asn Gly Cys Arg Pro Leu Thr Asn Ser Arg Ser Asp Arg 130 135 140 Trp Ser Gln Met Pro Ala Ser Ser Gly 145 150
 This protein demonstrates 100% homology to SEQ. ID NO: 10 until amino acid 94, where the addition of the 17 bp fragment depicted in the nucleotide sequence results in a frame shift. Over amino acids 94-153, the protein is not homologous to SEQ. ID NO: 10. Amino acids 154-457 in SEQ. ID NO: 10 are not present due to the early stop codon depicted in nucleotide sequence.
Genomic HLMP-1 Nucleotide Sequence
 Applicants have identified the genomic DNA sequence encoding HLMP-1, including putative regulatory elements associated with HLMP-1 expression. The entire genomic sequence is shown in SEQ. ID. NO: 41. This sequence was derived from AC023788 (clone RP11-564G9), Genome Sequencing Center, Washington University School of Medicine, St. Louis, Mo.
 The putative promoter region for HLMP-1 spans nucleotides 2,660-8,733 in SEQ. ID NO: 41. This region comprises, among other things, at least ten potential glucocorticoid response elements ("GREs") (nucleotides 6148-6153, 6226-6231, 6247-6252, 6336-6341, 6510-6515, 6552-6557, 6727-6732, 6752-6757, 7738-7743, and 8255-8260), twelve potential Sma-2 homologues to Mothers against Drosophilla decapentaplegic ("SMAD") binding element sites (nucleotides 3569-3575, 4552-4558, 4582-4588, 5226-5232, 6228-6234, 6649-6655, 6725-6731, 6930-6936, 7379-7384, 7738-7742, 8073-8079, and 8378-8384), and three TATA boxes (nucleotides 5910-5913, 6932-6935, and 7380-7383). The three TATA boxes, all of the GREs, and eight of the SMAD binding elements ("SBEs") are grouped in the region spanning nucleotides 5,841-8,733 in SEQ. ID NO: 41. These regulatory elements can be used, for example, to regulate expression of exogenous nucleotide sequences encoding proteins involved in the process of bone formation. This would permit systemic administration of therapeutic factors or genes relating to bone formation and repair, as well as factors or genes associated with tissue differentiation and development.
 In addition to the putative regulatory elements, 13 exons corresponding to the nucleotide sequence encoding HLMP-1 have been identified. These exons span the following nucleotides in SEQ. ID NO: 41: TABLE-US-00007 Exon 1 8733-8767 Exon 2 9790-9895 Exon 3 13635-13787 Exon 4 13877-13907 Exon 5 14387-14502 Exon 6 15161-15297 Exon 7 15401-15437 Exon 8 16483-16545 Exon 9 16689-16923 Exon 10 18068-18248 Exon 11 22117-22240 Exon 12 22323-22440 Exon 13 22575-22911
 In HLMP-2 there is another exon (Exon 5A), which spans nucleotides 14887-14904.
Expression of HLMP-1 in Intervertebral Disc Cells
 LIM mineralization protein-1 (LMP-1) is an intracellular protein that can direct cellular differentiation in osseous and non-osseous tissues. This example demonstrates that expressing human LMP-1 ("HLMP-1") in intervertebral disc cells increases proteoglycan synthesis and promotes a more chondrocytic phenotype. In addition, the effect of HLMP-1 expression on cellular gene expression was demonstrated by measuring Aggrecan and BMP-2 gene expression. Lumbar intervertebral disc cells were harvested from Sprague-Dawley rats by gentle enzymatic digestion and cultured in monolayer in DMEM/F12 supplemented with 10% FBS. These cells were then split into 6 well plates at approximately 200,000 cells per well and cultured for about 6 days until the cells reached approximately 300,000 cells per well. The culture media was changed to 1% FBS DMEM/F12 and this was considered Day 0.
 Replication deficient Type 5 adenovirus comprising a HLMP-1 cDNA operably linked to a cytomegalovirus ("CMV") promoter has been previously described, for example, in U.S. Pat. No. 6,300,127. The negative control adenovirus was identical except the HLMP-1 cDNA was replaced by LacZ cDNA. For a positive control, uninfected cultures were incubated in the continuous presence of BMP-2 at a concentration of 100 nanograms/milliliter.
 On Day 0, the cultures were infected with adenovirus for 30 minutes at 37° C. in 300 microliters of media containing 1% FBS. Fluorescence Activated Cell Sorter ("FACS") analysis of cells treated with adenovirus containing the green fluorescent protein ("GFP") gene ("AdGFP") was performed to determine the optimal dose range for expression of transgene. The cells were treated with adenovirus containing the human LMP-1 cDNA (AdHLMP-1) (at MOIs of 0, 100, 300, 1000, or 3000) or with adenovirus containing the LacZ marker gene (AdLacZ MOI of 1000) (negative control). The culture media was changed at day 3 and day 6 after infection.
 Proteoglycan production was estimated by measuring the sulfated glycosaminoglycans (sGAG) present in the culture media (at day 0, 3, and 6) using a di-methyl-methylene blue ("DMMB") calorimetric assay.
 For quantification of Aggrecan and BMP-2 mRNA, cells were harvested at day 6 and the mRNA extracted by the Trizol technique. The mRNA was converted to cDNA using reverse-transcriptase and used for real-time PCR, which allowed the relative abundance of Aggrecan and BMP-2 message to be determined. Real time primers were designed and tested for Aggrecan and BMP-2 in previous experiments. The Cybergreen technique was used. Standardization curves were used to quantitate mRNA abundance.
 For transfected cells, cell morphology was documented with a light microscope. Cells became more rounded with AdHLMP-1 (MOI 1000) treatment, but not with AdLacZ treatment. AdLacZ infection did not significantly change cell morphology.
 FACS analysis of rat disc cells infected with ADGFP at MOI of 1000 showed the highest percentage cells infected (45%).
 There was a dose dependent increase between sGAG production and AdhLMP-1 MOI. These data are seen in FIG. 1, which shows the production of sGAG after over-expressing HLMP-1 at different MOIs in rat disc cells in monolayer cultures. The results have been normalized to day 0 untreated cells. Error bars represent the standard error of the mean. As shown in FIG. 1, the sGAG production observed at day 3 was relatively minor, indicating a lag time between transfection and cellular production of GAG. Treatment with AdLacZ did not significantly change the sGAG production. As also shown in FIG. 1, the optimal dose of AdhLMP-1 was at a MOI of 1000, resulting in a 260% enhancement of sGAG production over the untreated controls at day 6. Higher or lower doses of AdhLMP-1 lead to a diminished response.
 The effect of AdhLMP-1 dosage (MOI) on sGAG production is further illustrated in FIG. 2. FIG. 2 is a chart showing rat disc sGAG levels at day 6 after treatment with AdhLMP-1 at different MOIs. As can be seen from FIG. 2, the optimal dose of AdhLMP-1 was at a MOI of 1000.
 Aggrecan and BMP-2 mRNA production is seen in FIG. 3. This figure demonstrates the increase in Aggrecan and BMP-2 mRNA after over-expression of HLMP-1. Real-time PCR of mRNA extracted from rat disc cells at day 6 was performed comparing the no-treatment ("NT") cells with cells treated with ADhLMP-1 at a MOI of 250. The data in FIG. 3 are represented as a percentage increase over the untreated sample. As illustrated in FIG. 3, a significant increase in Aggrecan and BMP-2 mRNA was noted following AdhLMP-1 treatment. The increase in BMP-2 expression suggests that BMP-2 is a down-stream gene that mediates HLMP-1 stimulation of proteoglycan synthesis.
 These data demonstrate that transfection with AdhLMP-1 is effective in increasing proteoglycan synthesis of intervertebral disc cells. The dose of virus leading to the highest transgene expression (MOI 1000) also leads to the highest induction of sGAG, suggesting a correlation between HLMP-1 expression and sGAG induction. These data indicate that HLMP-1 gene therapy is a method of increasing proteoglycan synthesis in the intervertebral disc, and that HLMP-1 is a agent for treating disc disease.
 FIG. 4A is a chart showing HLMP-1 mRNA expression 12 hours after infection with Ad-hLMP-1 at different MOIs. In FIG. 4A, exogenous LMP-1 expression was induced with different doses (MOI) of the Ad-hLMP-1 virus and quantitated with realtime PCR. The data is normalized to HLMP-1 mRNA levels from Ad-LMP-1 MOI 5 for comparison purposes. No HLMP-1 was detected in negative control groups, the no-treatment ("NT") or Ad-LacZ treatment ("LacZ"). HLMP-1 mRNA levels in a dose dependent fashion to reach a plateau of approximately 8 fold with a MOI of 25 and 50.
 FIG. 4B is a chart showing the production of sGAG in medium from 3 to 6 days after infection. DMMB assay was used to quantitate total sGAG production between days 3 to 6 after infection. The data in FIG. 4B is normalized to the control (i.e., no treatment) group. As can be seen from FIG. 4B, there was a dose dependent increase in sGAG. with the peak of approximately three fold increase above control reached with a MOI of 25 and 50. The negative control, Ad-LacZ at a MOI of 25, lead to no increase in sGAG. In FIG. 4B, each result is expressed as mean with SD for three samples.
 FIG. 5 is a chart showing time course changes of the production of sGAG. As can be seen from FIG. 5, on day 3 sGAG production increased significantly at a MOI of 25 and 50. On day 6 there was a dose dependent increase in sGAG production in response to AdLMP-1. The plateau level of sGAG increase was achieved at a MOI of 25. As can also be seen from FIG. 5, treatment with AdLacZ ("LacZ") did not significantly change the sGAG production. Each result is expressed as mean with SD for six to nine samples. In FIG. 5, "**" indicates data points for which the P value is <0.01 versus the untreated control.
 FIGS. 6A and 6B are charts showing gene response to LMP-1 over-expression in rat annulus fibrosus cells for aggrecan and BMP-2, respectively. Quantitative realtime PCR was performed on day 3 after infection with Ad-LMP-1 ("LMP-1") at a MOI of 25. As can be seen from FIGS. 6A and 6B, the gene expression of aggrecan and BMP-2 increased significantly after infection with Ad-LMP-1 compared to the untreated control ("NT"). Further, treatment with AdLacZ ("LacZ") at a MOI of 25 did not significantly change the gene expression of either aggrecan or BMP-2 compared to the untreated control. In FIGS. 6A and 6B, each result is expressed as mean with SD for six samples. In FIGS. 6A and 6B, "**" indicates data points for which the P value is P<0.01.
 FIG. 7 is a graph showing the time course of HLMP-1 mRNA levels in rat annulus fibrosus cells after infection with AdLMP-1 at a MOI of 25. The data is expressed as a fold increase above a MOI of 5 of AdLMP-1 after standardization using 18S and replication coefficient of over-expression LMP-1 primer. As can be seen from FIG. 7, HLMP-1 mRNA was upregulated significantly as early as 12 hours after infection. Further, there was a marked increase of expression levels between day 1 and day 3. Each result in FIG. 7 is expressed as mean with SD for six samples.
 FIG. 8 is a chart showing changes in mRNA levels of BMPs and aggrecan in response to HLMP-1 over-expression. The mRNA levels of BMP-2, BMP-4, BMP-6, BMP7, and aggrecan were determined with realtime-PCR at different time points after infection with Ad-hLMP-1 at a MOI of 25. As can be seen from FIG. 8, BMP-2 mRNA was upregulated significantly as early as 12 hours after infection with AdLMP-1. On the other hand, Aggrecan mRNA was not upregulated until 3 day after infection. Each result is expressed as mean with SD for six samples. In FIG. 8, "**" indicates data points for which the P value is <0.01 for infection with AdLMP-1 versus an untreated control.
 FIG. 9 is a graph showing the time course of sGAG production enhancement in response to HLMP-1 expression. For the data in FIG. 9, rat annulus cells were infected with Ad-hLMP-1 at a MOI of 25. The media was changed every three days after infection and assayed for sGAG with the DMMB assay. This data shows that sGAG production reaches a plateau at day 6 and is substantially maintained at day 9.
 FIG. 10 is a chart showing the effect of noggin (a BMP antagonist) on LMP-1 mediated increase in sGAG production. As seen in FIG. 10, infection of rat annulus cells with Ad-LMP-1 at a MOI of 25 led to a three fold increase in sGAG produced between day 3 and day 6. This increase was blocked by the addition of noggin (a BMP antagonist) at concentration of 3200 ng/ml and 800 ng/m. As shown in FIG. 10, however, noggin did not significantly alter sGAG production in uninfected cells. As can also be seen in FIG. 10, stimulation with rhBMP-2 at 100 ng/ml led to a 3 fold increase in sGAG production between day 3 and day 6 after addition of BMP-2. Noggin at 800 ng/ml also blocked this increase.
 FIG. 11 is a chart showing the effect of LMP-1 on sGAG in media after day 6 of culture in monolayer. The data points are represented as fold increase above untreated cells. As shown in FIG. 11, LMP-1 with the CMV promoter when delivered by the AAV vector is also effective in stimulating glycosaminoglycan synthesis by rat disc cells in monolayer. TABLE-US-00008 TABLE 2 Primer Sequences for RT-PCR & Real-time PCR of SYBR Green Primer Sequence Aggrecan (forward) AGGATGGCTTCCACCAGTGC Aggrecan (reverse) TGCGTAAAAGACCTCACCCTCC BMP-2 (forward) CACAAGTCAGTGGGAGAGC BMP-2 (reverse) GCTTCCGCTGTTTGTGTTTG GAPDH (forward) ACCACAGTCCATGCCATCAC GAPDH (reverse) TCCACCACCCTGTTGCTGTA GAPDH in Table 2 denotes glyceraldehyde phosphate dehydrogenase.
 TABLE-US-00009 TABLE 3 Primer and Probe sequences for Real-time PCR of TaqMan ® Primer Sequence Overexpression AATACGACTCACTATAGGGCTCGA LMP-1 (forward) Overexpression GGAAGCCCCAAGGTGCT LMP-1 (reverse) Overexpression -FAM-AGCCGGCATCATGGATTCCTTCAA-TAMRA LMP-1 (probe)
TaqMan® Ribosomal RNA Control Reagents (Part number 4308329, Applied Biosystems, Foster City, Calif., U.S.A.) were used for the forward primer, reverse primer and probe of 18S ribosomal RNA (rRNA) gene.
 All cited publications and patents are hereby incorporated by reference in their entirety.
 While the foregoing specification teaches the principles of the present invention, with examples provided for the purpose of illustration, it will be appreciated by one skilled in the art from reading this disclosure that various changes in form and detail can be made without departing from the true scope of the invention.
42 1 457 PRT Rattus norvegicus 1 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arg Ala Gln Pro Ala Gln Ser Lys Pro Gln Lys Ala Leu Thr 85 90 95 Pro Pro Ala Asp Pro Pro Arg Tyr Thr Phe Ala Pro Ser Ala Ser Leu 100 105 110 Asn Lys Thr Ala Arg Pro Phe Gly Ala Pro Pro Pro Thr Asp Ser Ala 115 120 125 Leu Ser Gln Asn Gly Gln Leu Leu Arg Gln Leu Val Pro Asp Ala Ser 130 135 140 Lys Gln Arg Leu Met Glu Asn Thr Glu Asp Trp Arg Pro Arg Pro Gly 145 150 155 160 Thr Gly Gln Ser Arg Ser Phe Arg Ile Leu Ala His Leu Thr Gly Thr 165 170 175 Glu Phe Met Gln Asp Pro Asp Glu Glu Phe Met Lys Lys Ser Ser Gln 180 185 190 Val Pro Arg Thr Glu Ala Pro Ala Pro Ala Ser Thr Ile Pro Gln Glu 195 200 205 Ser Trp Pro Gly Pro Thr Thr Pro Ser Pro Thr Ser Arg Pro Pro Trp 210 215 220 Ala Val Asp Pro Ala Phe Ala Glu Arg Tyr Ala Pro Asp Lys Thr Ser 225 230 235 240 Thr Val Leu Thr Arg His Ser Gln Pro Ala Thr Pro Thr Pro Leu Gln 245 250 255 Asn Arg Thr Ser Ile Val Gln Ala Ala Ala Gly Gly Gly Thr Gly Gly 260 265 270 Gly Ser Asn Asn Gly Lys Thr Pro Val Cys His Gln Cys His Lys Ile 275 280 285 Ile Arg Gly Arg Tyr Leu Val Ala Leu Gly His Ala Tyr His Pro Glu 290 295 300 Glu Phe Val Cys Ser Gln Cys Gly Lys Val Leu Glu Glu Gly Gly Phe 305 310 315 320 Phe Glu Glu Lys Gly Ala Ile Phe Cys Pro Ser Cys Tyr Asp Val Arg 325 330 335 Tyr Ala Pro Ser Cys Ala Lys Cys Lys Lys Lys Ile Thr Gly Glu Ile 340 345 350 Met His Ala Leu Lys Met Thr Trp His Val Pro Cys Phe Thr Cys Ala 355 360 365 Ala Cys Lys Thr Pro Ile Arg Asn Arg Ala Phe Tyr Met Glu Glu Gly 370 375 380 Ala Pro Tyr Cys Glu Arg Asp Tyr Glu Lys Met Phe Gly Thr Lys Cys 385 390 395 400 Arg Gly Cys Asp Phe Lys Ile Asp Ala Gly Asp Arg Phe Leu Glu Ala 405 410 415 Leu Gly Phe Ser Trp His Asp Thr Cys Phe Val Cys Ala Ile Cys Gln 420 425 430 Ile Asn Leu Glu Gly Lys Thr Phe Tyr Ser Lys Lys Asp Lys Pro Leu 435 440 445 Cys Lys Ser His Ala Phe Ser His Val 450 455 2 1696 DNA Rattus norvegicus 2 gcacgaggat cccagcgcgg ctcctggagg ccgccaggca gccgcccagc cgggcattca 60 ggagcaggta ccatggattc cttcaaggta gtgctggagg gacctgcccc ttggggcttc 120 cgtctgcaag ggggcaagga cttcaacgtg cccctctcca tctctcggct cactcctgga 180 ggcaaggccg cacaggccgg tgtggccgtg ggagactggg tactgagtat cgacggtgag 240 aacgccggaa gcctcacaca cattgaagcc cagaacaaga tccgtgcctg tggggagcgc 300 ctcagcctgg gtcttagcag agcccagcct gctcagagca aaccacagaa ggccctgacc 360 cctcccgccg accccccgag gtacactttt gcaccaagcg cctccctcaa caagacggcc 420 cggcccttcg gggcaccccc acctactgac agcgccctgt cgcagaatgg acagctgctc 480 agacagctgg tccctgatgc cagcaagcag cggctgatgg agaatactga agactggcgc 540 ccgcggccag ggacaggcca gtcccgttcc ttccgcatcc ttgctcacct cacgggcaca 600 gagttcatgc aagacccgga tgaggaattc atgaagaagt caagccaggt gcccaggaca 660 gaagccccag ccccagcctc aaccataccc caggaatcct ggcctggccc caccaccccc 720 agccccacca gccgcccacc ctgggccgta gatcctgcat ttgctgagcg ctatgcccca 780 gacaaaacca gcacagtgct gacccgacac agccagccag ccacacctac gcctctgcag 840 aaccgcacct ccatagttca ggctgcagct ggagggggca caggaggagg cagcaacaat 900 ggcaagacgc ctgtatgcca ccagtgccac aagatcatcc gcggccgata cctggtagca 960 ctgggccacg cgtaccatcc tgaggaattt gtgtgcagcc agtgtgggaa ggtcctggaa 1020 gagggtggct tcttcgagga gaagggagct atcttttgcc cctcctgcta tgatgtgcgc 1080 tatgcaccca gctgtgccaa atgcaagaag aagatcactg gagagatcat gcatgcgctg 1140 aagatgacct ggcatgttcc ctgcttcacc tgtgcagcct gcaaaacccc tatccgcaac 1200 agggctttct acatggagga gggggctccc tactgcgagc gagattacga gaagatgttt 1260 ggcacaaagt gtcgcggctg tgacttcaag atcgatgccg gggaccgttt cctggaagcc 1320 ctgggtttca gctggcatga tacgtgtttt gtttgcgcaa tatgtcaaat caacttggaa 1380 ggaaagacct tctactccaa gaaggacaag cccctgtgca agagccatgc cttttcccac 1440 gtatgagcac ctcctcacac tactgccacc ctactctgcc agaagggtga taaaatgaga 1500 gagctctctc tccctcgacc tttctgggtg gggctggcag ccattgtcct agccttggct 1560 cctggccaga tcctggggct ccctcctcac agtccccttt cccacacttc ctccaccacc 1620 accaccgtca ctcacaggtg ctagcctcct agccccagtt cactctggtg tcacaataaa 1680 cctgtatgta gctgtg 1696 3 260 DNA Rattus norvegicus 3 ttctacatgg aggagggggc tccctactgc gagcgagatt acgagaagat gtttggcaca 60 aagtgtcgcg gctgtgactt caagatcgat gccggggacc gtttcctgga agccctgggt 120 ttcagctggc atgatacgtg ttttgtttgc gcaatatgtc aaatcaactt ggaaggaaag 180 accttctact ccaagaagga caagcccctg tgcaagagcc atgccttttc ccacgtatga 240 gcacctcctc acactactgc 260 4 16 DNA MMLV 4 aagctttttt tttttg 16 5 13 DNA MMLV 5 aagcttggct atg 13 6 223 DNA Homo sapiens 6 atccttgctc acctcacggg caccgagttc atgcaagacc cggatgagga gcacctgaag 60 aaatcaagcc aggtgcccag gacagaagcc ccagccccag cctcatctac accccaggag 120 ccctggcctg gccctaccgc ccccagccct accagccgcc cgccctgggc tgtggaccct 180 gcgtttgccg agcgctatgc cccagacaaa accagcacag tgc 223 7 717 DNA Homo sapiens 7 atggattcct tcaaggtagt gctggagggg ccagcacctt ggggcttccg gctgcaaggg 60 ggcaaggact tcaatgtgcc cctctccatt tcccggctca ctcctggggg caaagcggcg 120 caggccggag tggccgtggg tgactgggtg ctgagcatcg atggcgagaa tgcgggtagc 180 ctcacacaca tcgaagctca gaacaagatc cgggcctgcg gggagcgcct cagcctgggc 240 ctcagcaggg cccagccggt tcagagcaaa ccgcagaagg cctccgcccc cgccgcggac 300 cctccgcggt acacctttgc acccagcgtc tccctcaaca agacggcccg gccctttggg 360 gcgcccccgc ccgctgacag cgccccgcaa cagaatggac agccgctccg accgctggtc 420 ccagatgcca gcaagcagcg gctgatggag aacacagagg actggcggcc gcggccgggg 480 acaggccagt cgcgttcctt ccgcatcctt gcccacctca caggcaccga gttcatgcaa 540 gacccggatg aggagcacct gaagaaatca agccaggtgc ccaggacaga agccccagcc 600 ccagcctcat ctacacccca ggagccctgg cctggcccta ccgcccccag ccctaccagc 660 cgcccgccct gggctgtgga ccctgcgttt gccgagcgct atgccccgga caaaacg 717 8 1488 DNA Homo sapiens 8 atcgatggcg agaatgcggg tagcctcaca cacatcgaag ctcagaacaa gatccgggcc 60 tgcggggagc gcctcagcct gggcctcagc agggcccagc cggttcagag caaaccgcag 120 aaggcctccg cccccgccgc ggaccctccg cggtacacct ttgcacccag cgtctccctc 180 aacaagacgg cccggccctt tggggcgccc ccgcccgctg acagcgcccc gcaacagaat 240 ggacagccgc tccgaccgct ggtcccagat gccagcaagc agcggctgat ggagaacaca 300 gaggactggc ggccgcggcc ggggacaggc cagtcgcgtt ccttccgcat ccttgcccac 360 ctcacaggca ccgagttcat gcaagacccg gatgaggagc acctgaagaa atcaagccag 420 gtgcccagga cagaagcccc agccccagcc tcatctacac cccaggagcc ctggcctggc 480 cctaccgccc ccagccctac cagccgcccg ccctgagctg tggaccctgc gtttgccgag 540 cgctatgccc cggacaaaac gagcacagtg ctgacccggc acagccagcc ggccacgccc 600 acgccgctgc agagccgcac ctccattgtg caggcagctg ccggaggggt gccaggaggg 660 ggcagcaaca acggcaagac tcccgtgtgt caccagtgcc acaaggtcat ccggggccgc 720 tacctggtgg cgttgggcca cgcgtaccac ccggaggagt ttgtgtgtag ccagtgtggg 780 aaggtcctgg aagagggtgg cttctttgag gagaagggcg ccatcttctg cccaccatgc 840 tatgacgtgc gctatgcacc cagctgtgcc aagtgcaaga agaagattac aggcgagatc 900 atgcacgccc tgaagatgac ctggcacgtg cactgcttta cctgtgctgc ctgcaagacg 960 cccatccgga acagggcctt ctacatggag gagggcgtgc cctattgcga gcgagactat 1020 gagaagatgt ttggcacgaa atgccatggc tgtgacttca agatcgacgc tggggaccgc 1080 ttcctggagg ccctgggctt cagctggcat gacacctgct tcgtctgtgc gatatgtcag 1140 atcaacctgg aaggaaagac cttctactcc aagaaggaca ggcctctctg caagagccat 1200 gccttctctc atgtgtgagc cccttctgcc cacagctgcc gcggtggccc ctagcctgag 1260 gggcctggag tcgtggccct gcatttctgg gtagggctgg caatggttgc cttaaccctg 1320 gctcctggcc cgagcctggg ctcccgggcc cctgcccacc caccttatcc tcccacccca 1380 ctccctccac caccacagca caccggtgct ggccacacca gccccctttc acctccagtg 1440 ccacaataaa cctgtaccca gctgaattcc aaaaaatcca aaaaaaaa 1488 9 1644 DNA Homo sapiens 9 atggattcct tcaaggtagt gctggagggg ccagcacctt ggggcttccg gctgcaaggg 60 ggcaaggact tcaatgtgcc cctctccatt tcccggctca ctcctggggg caaagcggcg 120 caggccggag tggccgtggg tgactgggtg ctgagcatcg atggcgagaa tgcgggtagc 180 ctcacacaca tcgaagctca gaacaagatc cgggcctgcg gggagcgcct cagcctgggc 240 ctcagcaggg cccagccggt tcagagcaaa ccgcagaagg cctccgcccc cgccgcggac 300 cctccgcggt acacctttgc acccagcgtc tccctcaaca agacggcccg gccctttggg 360 gcgcccccgc ccgctgacag cgccccgcaa cagaatggac agccgctccg accgctggtc 420 ccagatgcca gcaagcagcg gctgatggag aacacagagg actggcggcc gcggccgggg 480 acaggccagt cgcgttcctt ccgcatcctt gcccacctca caggcaccga gttcatgcaa 540 gacccggatg aggagcacct gaagaaatca agccaggtgc ccaggacaga agccccagcc 600 ccagcctcat ctacacccca ggagccctgg cctggcccta ccgcccccag ccctaccagc 660 cgcccgccct gggctgtgga ccctgcgttt gccgagcgct atgccccgga caaaacgagc 720 acagtgctga cccggcacag ccagccggcc acgcccacgc cgctgcagag ccgcacctcc 780 attgtgcagg cagctgccgg aggggtgcca ggagggggca gcaacaacgg caagactccc 840 gtgtgtcacc agtgccacaa ggtcatccgg ggccgctacc tggtggcgtt gggccacgcg 900 taccacccgg aggagtttgt gtgtagccag tgtgggaagg tcctggaaga gggtggcttc 960 tttgaggaga agggcgccat cttctgccca ccatgctatg acgtgcgcta tgcacccagc 1020 tgtgccaagt gcaagaagaa gattacaggc gagatcatgc acgccctgaa gatgacctgg 1080 cacgtgcact gctttacctg tgctgcctgc aagacgccca tccggaacag ggccttctac 1140 atggaggagg gcgtgcccta ttgcgagcga gactatgaga agatgtttgg cacgaaatgc 1200 catggctgtg acttcaagat cgacgctggg gaccgcttcc tggaggccct gggcttcagc 1260 tggcatgaca cctgcttcgt ctgtgcgata tgtcagatca acctggaagg aaagaccttc 1320 tactccaaga aggacaggcc tctctgcaag agccatgcct tctctcatgt gtgagcccct 1380 tctgcccaca gctgccgcgg tggcccctag cctgaggggc ctggagtcgt ggccctgcat 1440 ttctgggtag ggctggcaat ggttgcctta accctggctc ctggcccgag cctgggctcc 1500 cgggcccctg cccacccacc ttatcctccc accccactcc ctccaccacc acagcacacc 1560 ggtgctggcc acaccagccc cctttcacct ccagtgccac aataaacctg tacccagctg 1620 aattccaaaa aatccaaaaa aaaa 1644 10 457 PRT Homo sapiens 10 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arg Ala Gln Pro Val Gln Ser Lys Pro Gln Lys Ala Ser Ala 85 90 95 Pro Ala Ala Asp Pro Pro Arg Tyr Thr Phe Ala Pro Ser Val Ser Leu 100 105 110 Asn Lys Thr Ala Arg Pro Phe Gly Ala Pro Pro Pro Ala Asp Ser Ala 115 120 125 Pro Gln Gln Asn Gly Gln Pro Leu Arg Pro Leu Val Pro Asp Ala Ser 130 135 140 Lys Gln Arg Leu Met Glu Asn Thr Glu Asp Trp Arg Pro Arg Pro Gly 145 150 155 160 Thr Gly Gln Ser Arg Ser Phe Arg Ile Leu Ala His Leu Thr Gly Thr 165 170 175 Glu Phe Met Gln Asp Pro Asp Glu Glu His Leu Lys Lys Ser Ser Gln 180 185 190 Val Pro Arg Thr Glu Ala Pro Ala Pro Ala Ser Ser Thr Pro Gln Glu 195 200 205 Pro Trp Pro Gly Pro Thr Ala Pro Ser Pro Thr Ser Arg Pro Pro Trp 210 215 220 Ala Val Asp Pro Ala Phe Ala Glu Arg Tyr Ala Pro Asp Lys Thr Ser 225 230 235 240 Thr Val Leu Thr Arg His Ser Gln Pro Ala Thr Pro Thr Pro Leu Gln 245 250 255 Ser Arg Thr Ser Ile Val Gln Ala Ala Ala Gly Gly Val Pro Gly Gly 260 265 270 Gly Ser Asn Asn Gly Lys Thr Pro Val Cys His Gln Cys His Lys Val 275 280 285 Ile Arg Gly Arg Tyr Leu Val Ala Leu Gly His Ala Tyr His Pro Glu 290 295 300 Glu Phe Val Cys Ser Gln Cys Gly Lys Val Leu Glu Glu Gly Gly Phe 305 310 315 320 Phe Glu Glu Lys Gly Ala Ile Phe Cys Pro Pro Cys Tyr Asp Val Arg 325 330 335 Tyr Ala Pro Ser Cys Ala Lys Cys Lys Lys Lys Ile Thr Gly Glu Ile 340 345 350 Met His Ala Leu Lys Met Thr Trp His Val His Cys Phe Thr Cys Ala 355 360 365 Ala Cys Lys Thr Pro Ile Arg Asn Arg Ala Phe Tyr Met Glu Glu Gly 370 375 380 Val Pro Tyr Cys Glu Arg Asp Tyr Glu Lys Met Phe Gly Thr Lys Cys 385 390 395 400 His Gly Cys Asp Phe Lys Ile Asp Ala Gly Asp Arg Phe Leu Glu Ala 405 410 415 Leu Gly Phe Ser Trp His Asp Thr Cys Phe Val Cys Ala Ile Cys Gln 420 425 430 Ile Asn Leu Glu Gly Lys Thr Phe Tyr Ser Lys Lys Asp Arg Pro Leu 435 440 445 Cys Lys Ser His Ala Phe Ser His Val 450 455 11 22 DNA Rattus norvegicus 11 gccagggttt tcccagtcac ga 22 12 22 DNA Rattus norvegicus 12 gccagggttt tcccagtcac ga 22 13 22 DNA Homo sapiens 13 tcttagcaga gcccagcctg ct 22 14 22 DNA Homo sapiens 14 gcatgaactc tgtgcccgtg ag 22 15 20 DNA Rattus norvegicus 15 atccttgctc acctcacggg 20 16 22 DNA Rattus norvegicus 16 gcactgtgct ggttttgtct gg 22 17 23 DNA Homo sapiens 17 catggattcc ttcaaggtag tgc 23 18 20 DNA Homo sapiens 18 gttttgtctg gggcagagcg 20 19 44 DNA Artificial Sequence Description of Artificial Sequence adaptor for Marathon RACE reactions 19 ctaatacgac tcactatagg gctcgagcgg ccgcccgggc aggt 44 20 27 DNA Artificial Sequence Description of Artificial Sequence PCR primer specific for Marathon RACE adaptor 20 ccatcctaat acgactcact atagggc 27 21 765 DNA Homo sapiens 21 ccgttgtttg taaaacgacg cagagcagcg ccctggccgg gccaagcagg agccggcatc 60 atggattcct tcaaggtagt gctggagggg ccagcacctt ggggcttccg gctgcaaggg 120 ggcaaggact tcaatgtgcc ctcctccatt tcccggctca cctctggggg caaggccgtg 180 caggccggag tggccgtaag tgactgggtg ctgagcatcg atggcgagaa tgcgggtagc 240 ctcacacaca tcgaagctca gaacaagatc cgggcctgcg gggagcgcct cagcctgggc 300 ctcaacaggg cccagccggt tcagaacaaa ccgcaaaagg cctccgcccc cgccgcggac 360 cctccgcggt acacctttgc accaagcgtc tccctcaaca agacggcccg gcccttgggg 420 gcgcccccgc ccgctgacag cgccccgcag cagaatggac agccgctccg accgctggtc 480 ccagatgcca gcaagcagcg gctgatggag aacacagagg actggcggcc gcggccgggg 540 acaggccagt gccgttcctt tcgcatcctt gctcacctta caggcaccga gttcatgcaa 600 gacccggatg aggagcacct gaagaaatca agccaggtgc ccaggacaga agccccagcc 660 ccagcctcat ctacacccca ggagccctgg cctggcccta ccgcccccag ccctaccagc 720 cgcccgccct gggctgtgga ccctgcgttt gccgagcgct atgcc 765 22 1689 DNA Homo sapiens 22 cgacgcagag cagcgccctg gccgggccaa gcaggagccg gcatcatgga ttccttcaag 60 gtagtgctgg aggggccagc accttggggc ttccggctgc aagggggcaa ggacttcaat 120 gtgcccctct ccatttcccg gctcactcct gggggcaaag cggcgcaggc cggagtggcc 180 gtgggtgact gggtgctgag catcgatggc gagaatgcgg gtagcctcac acacatcgaa 240 gctcagaaca agatccgggc ctgcggggag cgcctcagcc tgggcctcag cagggcccag 300 ccggttcaga gcaaaccgca gaaggcctcc gcccccgccg cggaccctcc gcggtacacc 360 tttgcaccca gcgtctccct caacaagacg gcccggccct ttggggcgcc cccgcccgct 420 gacagcgccc cgcaacagaa tggacagccg ctccgaccgc tggtcccaga tgccagcaag 480 cagcggctga tggagaacac agaggactgg cggccgcggc cggggacagg ccagtcgcgt 540 tccttccgca tccttgccca cctcacaggc accgagttca tgcaagaccc ggatgaggag 600 cacctgaaga aatcaagcca ggtgcccagg acagaagccc cagccccagc ctcatctaca 660 ccccaggagc cctggcctgg ccctaccgcc cccagcccta ccagccgccc gccctgggct 720 gtggaccctg cgtttgccga gcgctatgcc ccggacaaaa cgagcacagt gctgacccgg 780 cacagccagc cggccacgcc cacgccgctg cagagccgca cctccattgt gcaggcagct 840 gccggagggg tgccaggagg gggcagcaac aacggcaaga ctcccgtgtg tcaccagtgc 900 cacaaggtca tccggggccg ctacctggtg gcgttgggcc acgcgtacca cccggaggag 960 tttgtgtgta gccagtgtgg gaaggtcctg gaagagggtg gcttctttga ggagaagggc 1020 gccatcttct gcccaccatg ctatgacgtg cgctatgcac ccagctgtgc
caagtgcaag 1080 aagaagatta caggcgagat catgcacgcc ctgaagatga cctggcacgt gcactgcttt 1140 acctgtgctg cctgcaagac gcccatccgg aacagggcct tctacatgga ggagggcgtg 1200 ccctattgcg agcgagacta tgagaagatg tttggcacga aatgccatgg ctgtgacttc 1260 aagatcgacg ctggggaccg cttcctggag gccctgggct tcagctggca tgacacctgc 1320 ttcgtctgtg cgatatgtca gatcaacctg gaaggaaaga ccttctactc caagaaggac 1380 aggcctctct gcaagagcca tgccttctct catgtgtgag ccccttctgc ccacagctgc 1440 cgcggtggcc cctagcctga ggggcctgga gtcgtggccc tgcatttctg ggtagggctg 1500 gcaatggttg ccttaaccct ggctcctggc ccgagcctgg gctcccgggc ccctgcccac 1560 ccaccttatc ctcccacccc actccctcca ccaccacagc acaccggtgc tggccacacc 1620 agcccccttt cacctccagt gccacaataa acctgtaccc agctgaattc caaaaaatcc 1680 aaaaaaaaa 1689 23 22 DNA Homo sapiens 23 gcactgtgct cgttttgtcc gg 22 24 21 DNA Homo sapiens 24 tccttgctca cctcacgggc a 21 25 30 DNA Homo sapiens 25 tcctcatccg ggtcttgcat gaactcggtg 30 26 28 DNA Homo sapiens 26 gcccccgccc gctgacagcg ccccgcaa 28 27 24 DNA Homo sapiens 27 tccttgctca cctcacgggc accg 24 28 22 DNA Homo sapiens 28 gtaatacgac tcactatagg gc 22 29 23 DNA Rattus norvegicus 29 gcggctgatg gagaatactg aag 23 30 23 DNA Rattus norvegicus 30 atcttgtggc actggtggca tac 23 31 22 DNA Rattus norvegicus 31 tgtgtcgggt cagcactgtg ct 22 32 1620 DNA Homo sapiens 32 atggattcct tcaaggtagt gctggagggg ccagcacctt ggggcttccg gctgcaaggg 60 ggcaaggact tcaatgtgcc cctctccatt tcccggctca ctcctggggg caaagcggcg 120 caggccggag tggccgtggg tgactgggtg ctgagcatcg atggcgagaa tgcgggtagc 180 ctcacacaca tcgaagctca gaacaagatc cgggcctgcg gggagcgcct cagcctgggc 240 ctcagcaggg cccagccggt tcagagcaaa ccgcagaagg cctccgcccc cgccgcggac 300 cctccgcggt acacctttgc acccagcgtc tccctcaaca agacggcccg gccctttggg 360 gcgcccccgc ccgctgacag cgccccgcaa cagaatggac agccgctccg accgctggtc 420 ccagatgcca gcaagcagcg gctgatggag aacacagagg actggcggcc gcggccgggg 480 acaggccagt cgcgttcctt ccgcatcctt gcccacctca caggcaccga gttcatgcaa 540 gacccggatg aggagcacct gaagaaatca agccaggtgc ccaggacaga agccccagcc 600 ccagcctcat ctacacccca ggagccctgg cctggcccta ccgcccccag ccctaccagc 660 cgcccgccct gagctgtgga ccctgcgttt gccgagcgct atgccccgga caaaacgagc 720 acagtgctga cccggcacag ccagccggcc acgcccacgc cgctgcagag ccgcacctcc 780 attgtgcagg cagctgccgg aggggtgcca ggagggggca gcaacaacgg caagactccc 840 gtgtgtcacc agtgccacaa ggtcatccgg ggccgctacc tggtggcgtt gggccacgcg 900 taccacccgg aggagtttgt gtgtagccag tgtgggaagg tcctggaaga gggtggcttc 960 tttgaggaga agggcgccat cttctgccca ccatgctatg acgtgcgcta tgcacccagc 1020 tgtgccaagt gcaagaagaa gattacaggc gagatcatgc acgccctgaa gatgacctgg 1080 cacgtgcact gctttacctg tgctgcctgc aagacgccca tccggaacag ggccttctac 1140 atggaggagg gcgtgcccta ttgcgagcga gactatgaga agatgtttgg cacgaaatgc 1200 catggctgtg acttcaagat cgacgctggg gaccgcttcc tggaggccct gggcttcagc 1260 tggcatgaca cctgcttcgt ctgtgcgata tgtcagatca acctggaagg aaagaccttc 1320 tactccaaga aggacaggcc tctctgcaag agccatgcct tctctcatgt gtgagcccct 1380 tctgcccaca gctgccgcgg tggcccctag cctgaggggc ctggagtcgt ggccctgcat 1440 ttctgggtag ggctggcaat ggttgcctta accctggctc ctggcccgag cctgggctcc 1500 cgggcccctg cccacccacc ttatcctccc accccactcc ctccaccacc acagcacacc 1560 ggtgctggcc acaccagccc cctttcacct ccagtgccac aataaacctg tacccagctg 1620 33 1665 DNA Homo sapiens 33 cgacgcagag cagcgccctg gccgggccaa gcaggagccg gcatcatgga ttccttcaag 60 gtagtgctgg aggggccagc accttggggc ttccggctgc aagggggcaa ggacttcaat 120 gtgcccctct ccatttcccg gctcactcct gggggcaaag cggcgcaggc cggagtggcc 180 gtgggtgact gggtgctgag catcgatggc gagaatgcgg gtagcctcac acacatcgaa 240 gctcagaaca agatccgggc ctgcggggag cgcctcagcc tgggcctcag cagggcccag 300 ccggttcaga gcaaaccgca gaaggcctcc gcccccgccg cggaccctcc gcggtacacc 360 tttgcaccca gcgtctccct caacaagacg gcccggccct ttggggcgcc cccgcccgct 420 gacagcgccc cgcaacagaa tggacagccg ctccgaccgc tggtcccaga tgccagcaag 480 cagcggctga tggagaacac agaggactgg cggccgcggc cggggacagg ccagtcgcgt 540 tccttccgca tccttgccca cctcacaggc accgagttca tgcaagaccc ggatgaggag 600 cacctgaaga aatcaagcca ggtgcccagg acagaagccc cagccccagc ctcatctaca 660 ccccaggagc cctggcctgg ccctaccgcc cccagcccta ccagccgccc gccctgagct 720 gtggaccctg cgtttgccga gcgctatgcc ccggacaaaa cgagcacagt gctgacccgg 780 cacagccagc cggccacgcc cacgccgctg cagagccgca cctccattgt gcaggcagct 840 gccggagggg tgccaggagg gggcagcaac aacggcaaga ctcccgtgtg tcaccagtgc 900 cacaaggtca tccggggccg ctacctggtg gcgttgggcc acgcgtacca cccggaggag 960 tttgtgtgta gccagtgtgg gaaggtcctg gaagagggtg gcttctttga ggagaagggc 1020 gccatcttct gcccaccatg ctatgacgtg cgctatgcac ccagctgtgc caagtgcaag 1080 aagaagatta caggcgagat catgcacgcc ctgaagatga cctggcacgt gcactgcttt 1140 acctgtgctg cctgcaagac gcccatccgg aacagggcct tctacatgga ggagggcgtg 1200 ccctattgcg agcgagacta tgagaagatg tttggcacga aatgccatgg ctgtgacttc 1260 aagatcgacg ctggggaccg cttcctggag gccctgggct tcagctggca tgacacctgc 1320 ttcgtctgtg cgatatgtca gatcaacctg gaaggaaaga ccttctactc caagaaggac 1380 aggcctctct gcaagagcca tgccttctct catgtgtgag ccccttctgc ccacagctgc 1440 cgcggtggcc cctagcctga ggggcctgga gtcgtggccc tgcatttctg ggtagggctg 1500 gcaatggttg ccttaaccct ggctcctggc ccgagcctgg gctcccgggc ccctgcccac 1560 ccaccttatc ctcccacccc actccctcca ccaccacagc acaccggtgc tggccacacc 1620 agcccccttt cacctccagt gccacaataa acctgtaccc agctg 1665 34 223 PRT Homo sapiens 34 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arg Ala Gln Pro Val Gln Ser Lys Pro Gln Lys Ala Ser Ala 85 90 95 Pro Ala Ala Asp Pro Pro Arg Tyr Thr Phe Ala Pro Ser Val Ser Leu 100 105 110 Asn Lys Thr Ala Arg Pro Phe Gly Ala Pro Pro Pro Ala Asp Ser Ala 115 120 125 Pro Gln Gln Asn Gly Gln Pro Leu Arg Pro Leu Val Pro Asp Ala Ser 130 135 140 Lys Gln Arg Leu Met Glu Asn Thr Glu Asp Trp Arg Pro Arg Pro Gly 145 150 155 160 Thr Gly Gln Ser Arg Ser Phe Arg Ile Leu Ala His Leu Thr Gly Thr 165 170 175 Glu Phe Met Gln Asp Pro Asp Glu Glu His Leu Lys Lys Ser Ser Gln 180 185 190 Val Pro Arg Thr Glu Ala Pro Ala Pro Ala Ser Ser Thr Pro Gln Glu 195 200 205 Pro Trp Pro Gly Pro Thr Ala Pro Ser Pro Thr Ser Arg Pro Pro 210 215 220 35 20 DNA Homo sapiens 35 gagccggcat catggattcc 20 36 20 DNA Homo sapiens 36 gctgcctgca caatggaggt 20 37 1456 DNA Homo sapiens 37 cgacgcagag cagcgccctg gccgggccaa gcaggagccg gcatcatgga ttccttcaag 60 gtagtgctgg aggggccagc accttggggc ttccggctgc aagggggcaa ggacttcaat 120 gtgcccctct ccatttcccg gctcactcct gggggcaaag cggcgcaggc cggagtggcc 180 gtgggtgact gggtgctgag catcgatggc gagaatgcgg gtagcctcac acacatcgaa 240 gctcagaaca agatccgggc ctgcggggag cgcctcagcc tgggcctcag cagggcccag 300 ccggttcaga gcaaaccgca gaaggtgcag acccctgaca aacagccgct ccgaccgctg 360 gtcccagatg ccagcaagca gcggctgatg gagaacacag aggactggcg gccgcggccg 420 gggacaggcc agtcgcgttc cttccgcatc cttgcccacc tcacaggcac cgagttcatg 480 caagacccgg atgaggagca cctgaagaaa tcaagccagg tgcccaggac agaagcccca 540 gccccagcct catctacacc ccaggagccc tggcctggcc ctaccgcccc cagccctacc 600 agccgcccgc cctgggctgt ggaccctgcg tttgccgagc gctatgcccc ggacaaaacg 660 agcacagtgc tgacccggca cagccagccg gccacgccca cgccgctgca gagccgcacc 720 tccattgtgc aggcagctgc cggaggggtg ccaggagggg gcagcaacaa cggcaagact 780 cccgtgtgtc accagtgcca caaggtcatc cggggccgct acctggtggc gttgggccac 840 gcgtaccacc cggaggagtt tgtgtgtagc cagtgtggga aggtcctgga agagggtggc 900 ttctttgagg agaagggcgc catcttctgc ccaccatgct atgacgtgcg ctatgcaccc 960 agctgtgcca agtgcaagaa gaagattaca ggcgagatca tgcacgccct gaagatgacc 1020 tggcacgtgc actgctttac ctgtgctgcc tgcaagacgc ccatccggaa cagggccttc 1080 tacatggagg agggcgtgcc ctattgcgag cgagactatg agaagatgtt tggcacgaaa 1140 tgccatggct gtgacttcaa gatcgacgct ggggaccgct tcctggaggc cctgggcttc 1200 agctggcatg acacctgctt cgtctgtgcg atatgtcaga tcaacctgga aggaaagacc 1260 ttctactcca agaaggacag gcctctctgc aagagccatg ccttctctca tgtgtgagcc 1320 ccttctgccc acagctgccg cggtggcccc tagcctgagg ggcctggagt cgtggccctg 1380 catttctggg tagggctggc aatggttgcc ttaaccctgg ctcctggccc gagcctgggc 1440 tcccgggccc tgccca 1456 38 423 PRT Homo sapiens 38 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arg Ala Gln Pro Val Gln Asn Lys Pro Gln Lys Val Gln Thr 85 90 95 Pro Asp Lys Gln Pro Leu Arg Pro Leu Val Pro Asp Ala Ser Lys Gln 100 105 110 Arg Leu Met Glu Asn Thr Glu Asp Trp Arg Pro Arg Pro Gly Thr Gly 115 120 125 Gln Ser Arg Ser Phe Arg Ile Leu Ala His Leu Thr Gly Thr Glu Phe 130 135 140 Met Gln Asp Pro Asp Glu Glu His Leu Lys Lys Ser Ser Gln Val Pro 145 150 155 160 Arg Thr Glu Ala Pro Ala Pro Ala Ser Ser Thr Pro Gln Glu Pro Trp 165 170 175 Pro Gly Pro Thr Ala Pro Ser Pro Thr Ser Arg Pro Pro Trp Ala Val 180 185 190 Asp Pro Ala Phe Ala Glu Arg Tyr Ala Pro Asp Lys Thr Ser Thr Val 195 200 205 Leu Thr Arg His Ser Gln Pro Ala Thr Pro Thr Pro Leu Gln Ser Arg 210 215 220 Thr Ser Ile Val Gln Ala Ala Ala Gly Gly Val Pro Gly Gly Gly Ser 225 230 235 240 Asn Asn Gly Lys Thr Pro Val Cys His Gln Cys His Gln Val Ile Arg 245 250 255 Ala Arg Tyr Leu Val Ala Leu Gly His Ala Tyr His Pro Glu Glu Phe 260 265 270 Val Cys Ser Gln Cys Gly Lys Val Leu Glu Glu Gly Gly Phe Phe Glu 275 280 285 Glu Lys Gly Ala Ile Phe Cys Pro Pro Cys Tyr Asp Val Arg Tyr Ala 290 295 300 Pro Ser Cys Ala Lys Cys Lys Lys Lys Ile Thr Gly Glu Ile Met His 305 310 315 320 Ala Leu Lys Met Thr Trp His Val Leu Cys Phe Thr Cys Ala Ala Cys 325 330 335 Lys Thr Pro Ile Arg Asn Arg Ala Phe Tyr Met Glu Glu Gly Val Pro 340 345 350 Tyr Cys Glu Arg Asp Tyr Glu Lys Met Phe Gly Thr Lys Cys Gln Trp 355 360 365 Cys Asp Phe Lys Ile Asp Ala Gly Asp Arg Phe Leu Glu Ala Leu Gly 370 375 380 Phe Ser Trp His Asp Thr Cys Phe Val Cys Ala Ile Cys Gln Ile Asn 385 390 395 400 Leu Glu Gly Lys Thr Phe Tyr Ser Lys Lys Asp Arg Pro Leu Cys Lys 405 410 415 Ser His Ala Phe Ser His Val 420 39 1575 DNA Homo sapiens 39 cgacgcagag cagcgccctg gccgggccaa gcaggagccg gcatcatgga ttccttcaag 60 gtagtgctgg aggggccagc accttggggc ttccggctgc aagggggcaa ggacttcaat 120 gtgcccctct ccatttcccg gctcactcct gggggcaaag cggcgcaggc cggagtggcc 180 gtgggtgact gggtgctgag catcgatggc gagaatgcgg gtagcctcac acacatcgaa 240 gctcagaaca agatccgggc ctgcggggag cgcctcagcc tgggcctcag cagggcccag 300 ccggttcaga gcaaaccgca gaaggcctcc gcccccgccg cggaccctcc gcggtacacc 360 tttgcaccca gcgtctccct caacaagacg gcccggccct ttggggcgcc cccgcccgct 420 gacagcgccc cgcaacagaa tgggtgcaga cccctgacaa acagccgctc cgaccgctgg 480 tcccagatgc cagcaagcag cggctgatgg agaacacaga ggactggcgg ccgcggccgg 540 ggacaggcca gtcgcgttcc ttccgcatcc ttgcccacct cacaggcacc gagttcatgc 600 aagacccgga tgaggagcac ctgaagaaat caagccaggt gcccaggaca gaagccccag 660 ccccagcctc atctacaccc caggagccct ggcctggccc taccgccccc agccctacca 720 gccgcccgcc ctgggctgtg gaccctgcgt ttgccgagcg ctatgccccg gacaaaacga 780 gcacagtgct gacccggcac agccagccgg ccacgcccac gccgctgcag agccgcacct 840 ccattgtgca ggcagctgcc ggaggggtgc caggaggggg cagcaacaac ggcaagactc 900 ccgtgtgtca ccagtgccac aaggtcatcc ggggccgcta cctggtggcg ttgggccacg 960 cgtaccaccc ggaggagttt gtgtgtagcc agtgtgggaa ggtcctggaa gagggtggct 1020 tctttgagga gaagggcgcc atcttctgcc caccatgcta tgacgtgcgc tatgcaccca 1080 gctgtgccaa gtgcaagaag aagattacag gcgagatcat gcacgccctg aagatgacct 1140 ggcacgtgca ctgctttacc tgtgctgcct gcaagacgcc catccggaac agggccttct 1200 acatggagga gggcgtgccc tattgcgagc gagactatga gaagatgttt ggcacgaaat 1260 gccatggctg tgacttcaag atcgacgctg gggaccgctt cctggaggcc ctgggcttca 1320 gctggcatga cacctgcttc gtctgtgcga tatgtcagat caacctggaa ggaaagacct 1380 tctactccaa gaaggacagg cctctctgca agagccatgc cttctctcat gtgtgagccc 1440 cttctgccca cagctgccgc ggtggcccct agcctgaggg gcctggagtc gtggccctgc 1500 atttctgggt agggctggca atggttgcct taaccctggc tcctggcccg agcctgggct 1560 cccgggccct gccca 1575 40 153 PRT Homo sapiens 40 Met Asp Ser Phe Lys Val Val Leu Glu Gly Pro Ala Pro Trp Gly Phe 1 5 10 15 Arg Leu Gln Gly Gly Lys Asp Phe Asn Val Pro Leu Ser Ile Ser Arg 20 25 30 Leu Thr Pro Gly Gly Lys Ala Ala Gln Ala Gly Val Ala Val Gly Asp 35 40 45 Trp Val Leu Ser Ile Asp Gly Glu Asn Ala Gly Ser Leu Thr His Ile 50 55 60 Glu Ala Gln Asn Lys Ile Arg Ala Cys Gly Glu Arg Leu Ser Leu Gly 65 70 75 80 Leu Ser Arg Ala Gln Pro Val Gln Ser Lys Pro Gln Lys Ala Ser Ala 85 90 95 Pro Ala Ala Asp Pro Pro Arg Tyr Thr Phe Ala Pro Ser Val Ser Leu 100 105 110 Asn Lys Thr Ala Arg Pro Phe Gly Ala Pro Pro Pro Ala Asp Ser Ala 115 120 125 Pro Gln Gln Asn Gly Cys Arg Pro Leu Thr Asn Ser Arg Ser Asp Arg 130 135 140 Trp Ser Gln Met Pro Ala Ser Ser Gly 145 150 41 24740 DNA Homo sapiens unsure 1..6 a or c or g or t unsure 8101 a or c or g or t 41 nnnnnntgta ttttatcata ttttaaaaat caaaaaacaa aaggcagttg aggttaggca 60 tggaggttcg tgcctgtaat cccagcactt tgggaagccg aagcacgtgg atcacctgag 120 gtcaggagtt cgagaccagc ctgcccaata tggtaaaacc ctgtctctac taaaaataca 180 aaaaattagc caggcatggt ggtgggcacc tgtaatccca gctacttggg agactgaggc 240 aggagaatca cttaaacccg ggaggcgggc tgggcgcggt ggctcatgcc tgtaatccca 300 gcactttggg aggccgagac aggcggatca tgaggtcagg agatcgagat catcctggct 360 aacatggtga aaccccatct ctactaaaaa tacaaaaaaa attagccagg cctggtggcg 420 ggcacctgta gtcccagcta cttgggaggc tgaggcagga gaatggcgtg aacctgggag 480 gcggcgttgc agtgagccaa gatcgcgcca ctgcactcca gcctgggcga caagagtgag 540 actccatctt aaagaaaaaa aacaaacccg ggaggcggaa attgcagtca gccgagatct 600 cgccattgca ctcaagtatg ggtgacagag caagactcca tgtcaaaaaa aaaggcagtt 660 gacaggagca aggagcctgg tgaggaagct gtggcatttg acccggctgt gttgctatgg 720 gccagggtgg tgctagtaga ggagctgagt gggaaagagc acaggggaca tgctgaaggc 780 ctgggtgtgg ggatgaggca gagattgggg gcaccttgca gggtcatagc aggtggctgt 840 ggtgagatgg aggaagacac ctggggtact gctctaggct gtcagacata cagaagctgg 900 cccagccaag cccaggggct gcaagggaca tccttttgtg tccccagtga tctgcagctc 960 tcagacaccc tcaagcacag tgcctcttgc ccagcccagc actctcagtg gggagccagg 1020 tgggagaaca ggctcggaag gggacctagg cttatgcagc gagccgggca aagctggaac 1080 tggagcccag gcccctggat gccccctggc ttgtggagtt ctgggatact gaggggaggg 1140 gacagggcat gggagtgcgg tgctctcacc tttgacttga actcattccc caggggacag 1200 gggaggcctc ctcaggatcc acagatgccc agtctcccaa gaggggcctg gtccccatgg 1260 aggaaaactc catctactcc tcctggcagg aaggtaagtt ggaggacgtg caagggcagc 1320 ctcagccccc cacacccagg gctgggtctt tttgggactg acggagctgt cctggccacc 1380 tgccacagtg ggcgagtttc ccgtggtggt gcagaggact gaggccgcca cccgctgcca 1440 gctgaagggg ccggccctgc tggtgctggg cccagacgcc atccagctga gggaggccaa 1500 ggcacccagg ccctctacag ctggccctac cacttcctgc gcaagttcgg ctccgacaag 1560 gtgaggtgca ggggtgggaa agggtgaggg gctgacagcc tggaccctcc tgctaatccc 1620 cacccgtgtg ccctgtgccc agggcgtgtt ctcctttgag gccggccgtc gctgccactc 1680 gggtgagggc ctctttgcct tcagcacccc ctgtgcccct gacctgtgca gggctgtggc 1740 cggggccatc gccgccagcg ggagcggctg ccagagctga ccaggcccca gccctgcccc 1800 ctgccacggg ccacctctct gccctccctg gacacccccg gagagcttcg ggagatgcca 1860 ccaggacctg agccacccac gtccaggaaa atgcacctgg
ccgagcccgg accccagagc 1920 ctgccgctac tgctaggccc ggagcccaac gatctggcgt ccgggctcta cgcttcagtg 1980 tgcaagcgtg ccagtgggcc cccaggcaat gagcacctct atgagaacct gtgtgtgctg 2040 gaggccagcc ccacgctgca cggtggggaa cctgagccgc acgagggccc cggcagccgc 2100 agccccacaa ccagtcccat ctaccacaac ggccaggact tgagctggcc cggcccggcc 2160 aacgacagta ccctggaggc ccagtaccgg cggctgctgg agctggatca ggtggagggc 2220 acaggccgcc ctgaccctca ggcaggtttc aaggccaagc tggtgaccct gctgagtcgt 2280 gagcggagga agggcccagc cccttgtgac cggccctgaa cgcccagcag agtggtggcc 2340 agaggggaga ggtgctcccc ctgggacagg agggtgggct ggtgggcaaa cattgggccc 2400 atgcagacac acgcctgtgt ccaccctggc ctgcaggaac aaggcaggcc gcctgtggag 2460 gacctcagcc ctgccctgcc ctcctcatga atagtgtgca gactcacaga taataaagct 2520 cagagcagct cccggcaggg gcactcacgg cacacgcccc tgcccacgtt cattgcggcc 2580 aacacaagca ccctgtgccg gttccagggg cacaggtgac ctgggcctta cctgccaccc 2640 gtgggctcaa acccactgca gcagacagac gggatggaaa tcattaggac tccatgttgc 2700 tctgcacggc cgagtgacac gaagaggcag gcggagggag ctgtgaggct tacttgtcag 2760 actcaggaag gagcaacatg agggcccaac tggagacccg gaggcccgag ctgggaggag 2820 gcagtggggg cggggtgcag gtggaaggga tttcagagac accctcgtcc aaaacacttg 2880 ttccctgctg aaactccaac aatttgcaga tacttctggg aaccccaggc gtcagtctcc 2940 tcatctgtaa aggagagaga accgatgacg tatcaggcat aatccttgat gagagtttgc 3000 tgcgtgccta ctcagtgcca ggcgctgggg gacacagccg tgttcaggac agccttggtc 3060 ctgttctccg ggagccgaca ttccaggggg agagaagttt cctgaagact tccatgctgc 3120 gttccctcct ctgctcctgc tcctggcgcc atcctaggag ccagccatgc acgcaagcgt 3180 catgcctcca gggctctgac tgcccagccc ctcaccgcaa ctccacctca gctgcacaca 3240 cccttggcac atcctgaacc tcattttcat gacggacaca caatttttgc tctctcctgt 3300 ccaagcctca tcctctggcc gccacctcct tccagctcac ttcctttagt gcggccagta 3360 ccgcccctgc ctaggcatgt cgacctgcag ggaccctttt ctggctcttc gaggcctctg 3420 cccaccatcc cctctttgtt ctccatagtc ccttccccct gttctctctc gtttcatctt 3480 actggtctgg caaagtcccc ggccttgggc gagccagacc tcctcagtgc ctgcacacag 3540 ctgcccacag ccagagaaat ccatttaagc agactgcctg catccttctt aacagtgcaa 3600 ggcaggcact ccctgccaca agagaccctg ttccctagta gggcagcttt tctcctcccc 3660 agaacctcct gtctatcccc acccaatgtc tcctcacagg catattgggg aaacaggtca 3720 ggctctccca ccgtatctgc aagtgtactg gcatccatct gtcttcttcc tacccctaca 3780 gtagaaacag tgtctgtccc cagctgtgct ctgatcccgg ctcctttcac ctcagagctt 3840 ggaaaattga gctgtcccca ctctctcctg cgcccattca tcctaccagc agcttttcca 3900 gccacacgca aacatgctct gtaatttcac attttaaacc ttcccttgac ctcacattcc 3960 tcttcggcca cctctgtttc tctgttcctc ttcacagcaa aaactgttca aaagagttgt 4020 tgattacttt catttccact ttctcacccc cattctctcc tcaattaact ctccttcatc 4080 cccatgatgc cattatgtgg cttttattag agtcaccaac cttattctcc aaaacaaaag 4140 caacaaggac tttgacttct cagcagcact cagctctggt tcttgaaaca cccccgttac 4200 ttgctattcc tcctacctca taacaatctc cttcccagcc tctactgctg ccttctctga 4260 gttcttccca gggtcctagg ctcagatgta gtgtagctca accctgctac acaaagaatc 4320 tcctgaaagc ctgtaaaaat gtccatgcat gttctgtgag tgatctacca agaaaataaa 4380 aaattttaaa aatcaaatgc ccatgcctgg gcccacacgc aggggctctg atttcatcag 4440 tctggtaggt gggttctggg catccacgct cactggattt ccggatgatt gtagtatgca 4500 gcctaggctg ggaaccactg gcctcagcaa gccagtcatt ctccaggtgt cacagaccct 4560 ctaggtgcta atgaccccga aggtctgtct tcagtgcaca cctccccctg agctccagat 4620 ttaggaatcc cactgcacac gagacatctg gatgtggaaa agacatctcc agatcccatg 4680 ggtgaaaggg ggttggggga atggagactc gtgttcttcc aggatgtgtg tggacacaga 4740 atgcaaagcc tggagggatg ctagagccat agggaggaag atttcggctc acttattcat 4800 gcaagcactt cctgatgggt aaggtcttag agcaagctga ggccaagagg cgggcagtcg 4860 aggtgctgct gcaggcaccc ccactcccta cagtggcaag cccaagccca gcccttggca 4920 gctcaaatcc caggacacgc tgaaggtcac ccagagagtc aggggcatgg ctagaaccag 4980 aacccaggac tctggggacc cagcatggca tcctttcctt cattacaaat ctgagctgct 5040 ttgtttccta gggatttctg tgatattcca aggggactgt gggaaagaaa gtccttggaa 5100 accaccagga cgctagaggc ctggcctgga gcctcaggag tctcggccac cagagggcgc 5160 tgggtccttg tccaggtcca gttgctacgc aggggctgcc tgtgctggga ggctccccag 5220 gggacacaga ccagagcctt gcaccagccc aaggaatggg agcctggggt cctctctgct 5280 ggaggactgc caggaccccc aggctgccgc ctcttccttt gctcatttgc tgtttcactt 5340 tgtcaatcct tcctttcttc gtgtgttcat tcacatccac tgtgtgctgg ccctggggaa 5400 atgttagata agacacatta gctgtgtgtc ttcattgtcc taacaaagaa cacaccctgg 5460 aaagagcacc gcagagagtc cccattcccc catctccctc cacacatgga atctggagat 5520 gccttttcca catccagatg tctctggtgc tgtgggattc ttaaataaac aaacatttca 5580 tacagaatgt gagatgatgg agatgctatg gggaaaagta aagcagaggg agggcctagt 5640 gtgtgatgcg ggtgaggcat ccagggattg ctgtttcagc tgtgatcagg aaaggccctg 5700 ggaggaggcc acatctgagc agagacctaa ataaagttgg aaacctgttg ctgagatatc 5760 tggagaagtg tttcaagggc cgggcaccgg gcatggtggc tcacgcctgt aatcccagca 5820 ctttgggagg ccaaggcagg tggatcgctg gaggtcagga gtttgagagc agcctgacca 5880 acatggagaa accccatctc tactaaacat ataaaaatta tccgggcatg gtggttcatg 5940 cctgtagtcc cagctactcg ggaggttgag gcaggagaat cacttgaacg tgggaggcag 6000 aggttgcagc aagccgagat cacaccactg cactccagcc tggatgacag agcgagactc 6060 cgtctcaaaa aaaaaaaaga aaagaaaaaa gaaaaaaaaa gaaaagtgtt tcaagcaggg 6120 gaactggcaa gtggagaggc cctgaggcag aaatatgctt ggcctgctgg aggaaatgtg 6180 agtgaggagg tcagggtggc tggagtggag ggagcgagtg gtaggagtca gacccagttt 6240 attcatattc tgtaggtctt aaggacttca gttttatttt gagtgcaata tgagcccact 6300 ggaatgctaa aagctgagag tgacatggtg ctgtgattct ggctttaaaa atatcacttt 6360 ggctgcttcg tgaagactct ggaaggggca agggtgaaag cagggatgcc cgttaggaga 6420 ccgttacagg ggcgcaggca caaaatggca gtggctggga caatggtggc agcagcggtt 6480 agatgtgaac atgttgaagg tggaatttgc agaatctggg ggaggacaga agagaaagga 6540 taacttcatc gtttctgctg aaccagttgg ataaatgttg gtggcacttc ttgaagtgag 6600 gaaggagtta ggaaggtggg aaaggcacaa gtttgaattg ggccatgatg gtctgagata 6660 cctagtacag tggttcccca acctttttgg cagaagggac cgctttcatg gaagacaatt 6720 tttccacaga ctgggggtgg ggtggggatg gtttcagggt ggttcgagtg cagtacattt 6780 atcattagac tctttttttt tttttttttt tgagatagag tctcgctctg tcacccacac 6840 tggagtgcag tggagccatc ttggctcact acaacctctg ctgcccaggt tcaagtcatt 6900 ctcctgcctc agcctctcaa gtagctggga ttataggcat atgcgccacc acgcccagct 6960 aatttttgta tttttagtag agacggggtt tcaccatatt ggccaggatg gtctcgaact 7020 cctgacctca agtgatcctc ccccgcctca acctcccaaa gtgctggggt tacaggcgtg 7080 aaccactgca cccggcccat ttatcattag attctcataa ggaatgagca acctagatcc 7140 ctcgcatgca cagttcacaa tagggttcac gctcctatgg gagtctaatg ctgccgctgc 7200 actcagcttc tctggcttgc cgctgctcac cttctgctgt gcagcccagt tcctaacagg 7260 ccacaaacgg ggagttgggg acccctgatc tagtaaacat ctaggcaggg ttttggataa 7320 tggagttaga gttcctgggg agaggtcagg ctggccatga aacatgggat gcctttgcat 7380 ataggtggtg ttgaaagcca caggacagta cggggtctca gggggtgagc ataaagagag 7440 gcgacatcag atggccaagg ccagaggcag aggaggatgg gaaggagggg ccagtggggc 7500 agggggaagc tgtgaagcca gggaaaaagg gtgtttcgcg gaaaaggatc aacctggacc 7560 agtgctgccc ctaggcaggg caggatgaaa cttaaccacc acggattcca tggccccatg 7620 gcctccaggc cacaggggac cttgagaaga gagatctcag gggacgggtg cggacaagag 7680 cccgcctggc atggcttcaa gagataactg aaggaaagca agtggagacg cgataaacag 7740 acaactccct ggaggaattt tactctcgag aggagaatta aagggtagta gctggagagg 7800 gatgtggggt caagagaagg tctttaacga cgagaactct cacggcggtt tgtgcagaac 7860 agggtgggtg tgatgactgt ggatggagag gggagaactg cagcgactct gtcctaggag 7920 gaggtgatgg gccgggacca ccaagcgagt ggagggtgga cgccccttcc ctcaccccga 7980 cacccgcatg tgctcagtgt ccgtgccgcc ggccctagtg cctgggctga acgcggggcc 8040 gggactctga ggacgcctcc caggcgcgca gtccgtctgg ccaaggtgga gcgggacggc 8100 ngcttccgac ggtgcgcggg tcggctcggg gttgcaggga catccggcgt ccgctcctgc 8160 cctgttttcc tgccttcgca gagcgttgcg caactctagc tttaaacgcc cctgtccccc 8220 tcaacttgtc tcccccagcc cctctgattt acagattctg cagtccccga gggttgcgcc 8280 tacgataccg acactcgcgg cagcctgcga ggcgagtatg atcgtcccat ttttcggagt 8340 agcaaactaa ggttcagaga ctactatgtc ccaggtcggt ctggtttgaa ggtccgcttt 8400 cctctccctc cgccagcggg cggtgcgagg gactgggcga ggcagcgctt ccctaaggag 8460 gcgacccgca gccccggccc cctcccgact ccgccccgtt gcagggcccg ggtcggcgag 8520 gcctctcagc tctaagcccg acgggacttg gtgattgggc aggacggaag agctgggtgg 8580 ggctttccac cagcggagaa agtctagtgg gcgtggtcgc gacgagggcg tggcctggtg 8640 ccccgccccc gtccgcgcgc tcaaagtgga gggtggctgt gggggcgggg tcagaacact 8700 ggcggccgat cccaacgagg ctccctggag cccgacgcag agcagcgccc tggccgggcc 8760 aagcaggtat cgacgaccgc gcggggcgtc ttgggctgga ccaggcgggc gcccggggcc 8820 tgctgaggac cacaaagggc actgggggtc gtggtccagg ctgtgcttcc tcccgctggc 8880 cctggcccct gcctccgccc ccgcccccgc cttcctgccg ctaagccggc tgcggcgggg 8940 ccgattggcg cctgccggct tcctgcgccg gggccagtct aatgcatggg gcccgggcgg 9000 gggactaagg ggaaactgag tcacgtcggt gtgggagcag ttctgtgtgg gaggcaccac 9060 cccccactgg gctcggggaa ggatccccct ccaagctatg cttgagggtc ccagccccca 9120 tctgtctcca caggggccgc accccactcc cgccttcccc ttcttcagca cccaggggtc 9180 ccgccctggc tcccagcagc ctcgactggt cccggaatgg ctaggaggat ccgctgcagc 9240 cgcctccctc ccctcccctc ccctcccctc ccctcccctc ccctcccctc ccctcccctc 9300 cccctcgcgt cccaagcccc cgtgtgctcc ctccgctggc tctccgcaca gtgtcagctt 9360 acacgcctta tatagtccga gcaggctcca gccgcggcct gctgccggga cctgggggcg 9420 ggggagagga gagccggccc ctgactcacc cggaccgccc gaggctccag gctggcttgg 9480 ggggaggccg cgccagttta gtccctcggc ccacccctgg ttgcaaagaa cctcaagcct 9540 ggattcaggc acccctcacc gttccagtcc caaggggagg ggggctgctc ctgtctttcc 9600 aaagtgaggt ccgccagcca gcagcccagg ccagcctgac aaaatacctg cctcctatgg 9660 cttgggcgtg ctcaggggct gcccgtgcct gcctggcccc tgtccaaggc tggtatcctg 9720 agctggcccg gcctgcctgc ctgcccgccc accatgctgg ccactcacct tctcttctct 9780 cctctcagga gccggcatca tggattcctt caaagtagtg ctggaggggc cagcaccttg 9840 gggcttccgg ctgcaagggg gcaaggactt caatgtgccc ctctccattt cccgggtgag 9900 cctaggtttg gggagggggc tcccccagcg gtctttcggt gcttaggtct ccagagggtg 9960 atggggggag tcctaacagg agctggtcag gggccagcag gccaggagat gtctaggtcc 10020 ggagatgtag tggtacctgc ctgccacaag gactcccaat gaggtggata ctgggaggga 10080 gcacccaggc ttctccagcc ctgcactgta cccgatgctg ttctcccaag ctcctgtggc 10140 cacctctgag ggctggaggg aggctcattg tgcaggatgg gagcctaaca tttcaggagg 10200 tatctaaact tgaggtggca atgcttggag ccaggcccca ggcaggacac tgtgactata 10260 ggatttcact tcagcctcac tgccgcccag ggaatagcaa tcctcatccc gtttttccag 10320 atgagagaag aactcatgga gaggtggcgg ggctcgctca tcgagtccat ggtgaagcag 10380 ggattggaat tgaggcacag catggcgtac attttttgtg ggtagaaggg gtctctcccc 10440 agcctatgta aggacccaca tccactgttc ccattcagga tgtggtggcc tttgacccca 10500 agcagaagtg taggacaggg ctccattcta ggggcttaac ttcagcttcc aagagcctgc 10560 cctggtgtgg gtggagctgg aggctggctc ctccctgtag cagggggatt gccttataag 10620 cccaagaatg cagccccacg ctgggatggc caacagtggc tgcggtctgc agagctgaaa 10680 agggctggcc taggcctggc cccctgaacc ccactggtgg gcctctcagc tggtcaccag 10740 gctgcagctc cagctgtatg gtccagttgt gagacacaac aaattgcctg cccagagtgg 10800 gtgaggccag cctgtcggct ggcatctctg actggcctgg gggtcaggag ggggtgggga 10860 cttcctgccc ctatatccgc ctgccccgag agacccaccc aggcgccggg tgggcaggca 10920 gctgttgtca ggaagcccaa ggcaagccca gcctggaggg gcccagaggg tcgtggcctg 10980 aggaggggct caagctggag tctgtctgta ggagctgggc gtgggggtta gggtgggcag 11040 gccagcagtg ctcttctcag gggtcctttg atggcattct cctggaacct gccccgccag 11100 cagggtagtg aggcagtggt tgccctatga cacacgtccc actacatagc cctcacacag 11160 ccctgaaacc tacctgacgt cctgctccct gggaaagtgc tggcccagtg tgtctgggga 11220 gcctgaacct cagtttcttc cctgatggag atgactttca gatatggcct gttgggggca 11280 ctccgggctc cagctccctg gtcagcatcc ctggcatgtg ggcggggcca ctagctgatc 11340 ccagccctgg agttggacct gggcccacat gggtgggtga ggtgggcttt tctgagttag 11400 gccagccccc tccccctccc ctgaccccag aatggaggga ggtgggaggg gcaagggctg 11460 gctgtgggcc caggcctggg agatgaggta acgtctggga ctggggggct gggctgctca 11520 ggctgactca cccccacctc atgcagggtc cagccccctg gctttttccc tccttggttc 11580 ctctggcctt accctgcccc tggcttgagc ccctccctgc ctctctccag ccacccgccc 11640 agcgctgtct tctgctctcc tgctgccctc cccacgctct gaacacccct catcctctgt 11700 gcttcctgcc ctcctcactc tgggaaggga agccgtcccc gccccccacc ccctctccag 11760 gagccagcta gctgcacccc aagaccccca cctcgggctc agcccacagc tcccaggagc 11820 cagccctgtg ggcagggagt ggctgggcca ggtttccctt ctactgactc accatgacct 11880 tgagtaagtc acttcccctc tggggtgtca cttccccata cacagtataa ggggttgatt 11940 tagttggatt gaactaaagg tgagggagtg gctcagggtg tctccaggtg ggctgacccc 12000 tcagttgggc ccccatgctc agcagaggtg gcccacagtg gtggagcctt agggtcagag 12060 acacttcctg gctctgcctc ttactagctg ggtgacttga ggcaagttgt ttaacctctc 12120 tgtgtacatt tgcaagtgca aaatgggtaa aatcccagat tactccacaa ggttgttgga 12180 agattcagtg tcaatatgta gcatagttgg tgctcaataa actgaagcaa gtcttcttat 12240 ttagcgagtg aggaaggggc cgccgagctc tcttagcctt ctgacctcct acgcaagcaa 12300 gaggtcatgt tgagcccagc tcgcctttct tttcccagtg ctgtcaagct ctgtgcctgg 12360 ctgccctgcc ctctgacatc tctctgaaac ctcttgcctc ccctctccct gcctcagctc 12420 agtctgtgca ctgacccacc tgaggagcct cctggggcca ctggcagcct ggaccccccc 12480 agatcccccc cacccagtga aattgtcttc cagcactgcc tcacaaaagc ctacttgatg 12540 cagtgccagg cctcttgcca gatggctggg tggtccctta ggcttggacc cagtcaagct 12600 gccctgcctg tgttgctggg gctgggctag aggcctggaa ggggtttatc agggtcaccc 12660 tctcagggcc tgggagatac ccaatcccag acattaaaac tgccagtagc ccctctacct 12720 tcaaagccaa gtcctggtcc cttcccctgg cattcaaagc catcgtaagt gaactctcac 12780 ccgctaggca gcacacgcca ttctccttta ccgaggccca ccgcttcctc aaagtcattc 12840 ctgatggtct cagctcatgc tggtggcagc catttctccc agcctactgt ctctactcat 12900 tgccacagga accagggact cccagctcaa gagcctgaag gattggggtc aggggaaatt 12960 ggcagtcgag ggcttgggag tgacagccat gtatggccta cgaagtccca gctgtcaact 13020 taggtcccat tcaggcagtg ttcacaggga accgggagat aacagggcct gttcctggct 13080 ctcaaagggt cccagcagac ccctatagat ggcccccgac agggtgctgg ggggtgagag 13140 gtccataaga gcccccggtg gtttcgggga ggaagctgcc ccctgcatgg gccagagggc 13200 atatctggta ggtggagtgg cctgggcagg aggccagcag gagcctcaaa aggcaatggt 13260 cctcctgaaa cacttgggct ttagcctgag cgtggctgtt tgtggacatc atagcaattt 13320 ctggactgtg ggggagggtg gtggcggtga atagataagc atcgtgactg gggaagctca 13380 ggtgagcacc acctgaggga gagggtctgg cagtgaataa ataagcagtg tgactgggaa 13440 attgtgaagc tcaggtgagc gccaccacct cctgggttgc tttagtgtcc agcagctgcc 13500 tagaactatg ttgaatgaag agctctctgg gttctggaag tgggacagct ttgggtgggg 13560 cagtgttacc accgtcagcc tggcttgggt ctgcagggtc cagggcctcg gtcactttgc 13620 ttctctctcc acagctcact cctgggggca aagcggcgca ggccggagtg gccgtgggtg 13680 actgggtgct gagcatcgat ggcgagaatg cgggtagcct cacacacatc gaagctcaga 13740 acaagatccg ggcctgcggg gagcgcctca gcctgggcct cagcaggtat gcgggtggac 13800 atggatgggt gcgcccgcgc tggcagtggg gatccctgcg gcccggcccg ctgtcacgct 13860 ttccttctcc tccagggccc agccggttca gagcaaaccg cagaaggtac gaggctggcc 13920 gggacatccg ggcggtgggc ggtgtgggct tggacggcca ggcctgctcg ccctcctggc 13980 acattctcgg taccccaatc cctggccggg agtggagggc agaaaccgga gctaaggcgg 14040 gtctagggcc ctggagttga gccaggggct gctgcacggt cctggcacca cgcatgtccg 14100 cctgtctgtc cgcctgtctg tccgcctgct gcctcccgcc gccggcgctg cgtgctcgcc 14160 cgcactcggt cagccctcgg tcctgcgtgg actgagatcg ccactcccaa atgggcccct 14220 tgaaacctga gtcgtcctct ccccgtagcc tccaaataga tgtagggggt ggggtggggg 14280 tggggggctg gagctgccgc tgtcctctgc tgcaggcgcc ccacttccac ccaggccccc 14340 accttaccct gcccgcccgc cctgcccggc tgtgtctctg cccaggcctc cgcccccgcc 14400 gcggaccctc cgcggtacac ctttgcaccc agcgtctccc tcaacaagac ggcccggcct 14460 ttgggcgccc ccgcccgctg acagcgcccc gcagcagaat gggtacgtcg gcccctgccc 14520 gcccgcgccc acgccatcag gcccactgtg gccccacgcc cgctgcccgc tgctgctcag 14580 tctgtgctgc gccccagccc ggcggaaccg tgcggcacgc cccctggcgg ccggggtggg 14640 gctgcaggca cagggcccct cccgaggctg tggcgccttg cagggcaccg cctggggagg 14700 ggtctctgaa tgacgccgcg ccccctgctg gcggctgggg gttgggttgt ggtgtcgggc 14760 cagctgagcc ccagacactc agtgccgcct tgtccccggc tgttctgacc cctccccgtc 14820 tttcttcctc tcctgtgtct gtccctttgt ccctttatct gtctgtctgt cttatttcct 14880 tcacaggtgc agacccctga caagtcagtg agcccccctc tgcctgtgcc tttcttcttc 14940 cttttggcac tctgggtggc ggcccctccc caccctggct gccctcctct ccacttcgcc 15000 ctcctgtcct ctcacctacc cgcccagcag ggctcctggc ctcaccctta cccactccct 15060 cccatcactg taacccaaac ccacatgcac caaatcctgg gaggggctgc ccccaccgcc 15120 cacccccagt gtggggttct gagccacacc ctccccacag acagccgctc cgaccgctgg 15180 tcccagatgc cagcaagcag cggctgatgg agaacacaga ggactggcgg ccgcggccgg 15240 ggacaggcca gtcgcgttcc ttccgcatcc ttgcccacct cacaggcacc gagttcagta 15300 agtgccagcc cagggcaggg ggtactttcc tcgcccccag cccaggcgtg atccctgacc 15360 ctgtgtcttt tttggtcaat gcctgcctct gctctctcag tgcaagaccc ggatgaggag 15420 cacctgaaga aatcaaggta cagggacggg caccagcccc tctcccacct cctgcctctt 15480 ccattccagc tactgccctg tgtctactcc tgaggctccc agctggggct ctcaattctc 15540 ccttccttcc ttccttcctt ccttccttcc ttccttcctt ccttccttcc ttccttcctt 15600 cccttcctcc ttccttcctt ctttcatttc ttccctccct ccttccttcc ctcctccctc 15660 cctgcctccc ttccatctct ccttccttcc acttcttcct ccctctctct ctgcccctca 15720 gggaaaagta tgtcctggag ctgcagagcc cacgctacac ccgcctccgg gactggcacc 15780 accagcgctc tgcccacgtg ctcaacgtgc agtcgtagcc cggccctctc cagccggctg 15840 ccctctctgc ctccctcttt ctgttcctcc tgcccagggc acccccttag tgcctccagc 15900 ttctgcctac ctcacccccc ctttcgtgcc cctggcctga gcctcctgct ggcctggccc 15960 tggccgccca cctgggttca tctgacactg ccttccctct ttgccctgtg gtactgctgt 16020 ctgccaggtc tgtgctgcct tgggcatgga ataaacattc tcagccctgc ttgctctgcc 16080 tgtcttctat ctttgtggac ctggtttgca tttggggtgt gggggtgttt cgtggttcgg 16140 actgtttggg ccctgccgtc cttgttttca gtgggagggg gtacctggca aaggggccct 16200 gccctgccat cacagatggc ttcctggcat gaggggagcc ccaggagctg cctcagaagc 16260 gggagccctg cctcgtctcc cagctagaga ccgcacacca gctaactgga cattgctagg 16320 agaagctgcc cttcccatcc ctaccccagt gggacctgga atccaactcg gcagtttcca 16380 cgcccccagt catctcccgt ggggccagca ggacccaggt tggggggtgg ggccatgtca 16440 ggaagctcag ccatgcaggg ccttgaatgg cagatcttgc agccaggtgc ccaggacaga 16500 agccccagcc ccagcctcat ctacacccca ggagccctgg cctggtgaga gggagtgggc 16560 tcgggcctgg gcaagggtgg gcagcctcca ggggcatggg ggtggtgggc ttctctcagc 16620 tgcctggggc tccacccccg tcctttgggg tccctgggca cccctttaga gtcactttcc 16680 ccggcaggcc ctaccgcccc cagccctacc agccgcccgc cctgggctgt ggaccctgcg 16740 tttgccgagc gctatgcccc ggacaaaacg agcacagtgc tgacccggca cagccagccg 16800 gccacgccca cgccgctgca gagccgcacc tccattgtgc aggcagctgc cggaggggtg 16860 ccaggagggg gcagcaacaa cggcaagact cccgtgtgtc accagtgcca caaggtcatc 16920 cggtgggtgg cctgttcctg tccgaccctg gctttcccat
cctgcagccc agccccacct 16980 gtctgcccac ctgtcttgcc tcagctgcga ctggggggaa taaggattca gttctcagct 17040 ggagtaggag tagggacctg ggctgggtcc tcccattctt aatcccacgc tacctacccc 17100 agcccaccca caacaactgc tagcagcatc tgccgtggcg aaatagccga agggccaacc 17160 ataggctgaa gctgcacccc tacctttgct gctctctggg caaagagggg cctgccccct 17220 cccagcgcgt ctgcccctcc ctcctgctct ctgtctccct ctgctctcag agcatacagg 17280 cctggagcca ctccctctgt gcactgcccc gtggggccaa gcagcatcaa acacccccca 17340 gcatcagcgt gccggattct agagccttcc taattcgcag gcctggcctg ctctcatctc 17400 tgtcagctct tttttttttt tttttgaaac agagtctcac tgtgttgccc acgttggcgt 17460 gcagtggcgc gatctcggct cactgcaacc tctgcctcct gggttcaaga gattctcctg 17520 cctcagcctc ctgagtagct gggattacag gcacccgcca ccatgcctgg ctaattttgt 17580 atttttagta gagacggggt tttaccatgt tggccaggct ggtctcaaac tcctcacctc 17640 aggtgatctc aggcctgcct tggcctccca aagtgctggg actacaggtg tgagccactg 17700 tgcccagccg actctatcag ctcttgccag gtagaacagg caggccagca ggacagggca 17760 gctccagggt ttgcccaggg gcggctcagc ttttatgagg ctccagtcgt cagcccttcc 17820 tcccggggtc ctccctgctc taaagctgcc tctcctgtca ccagcagttc agtgtggcgg 17880 actggctctg taagcttcat ggctgccacg gtcacttccc aagcctgtct tctatcctat 17940 gtggaaaatg gggagaatga actgtccctc ccaaggcctc ctggtgggtg gtcagtcaac 18000 ctgaaggggg ccaagacccc cacctctctg cgtgtgctcc ctctgaccgc tctcgcctcc 18060 ctgcaggggc cgctacctgg tggcgctggg ccacgcgtac cacccggagg agtttgtgtg 18120 tagccagtgt gggaaggtcc tggaagaggg tggcttcttt gaggagaagg gcgccatctt 18180 ctgcccacca tgctatgacg tgcgctatgc acccagctgt gccaagtgca agaagaagat 18240 tacaggcgtg agtagggctg gctggcgggg aggtggtccc aagcctgtca gtgggaacga 18300 gggctgctgg gaaacccaca gtccaggtct ctccccgagt gagcctccgg gtccttacca 18360 gcgtaataaa tgggctgctg tactggcctc accctgcatt agtcaggatg ctcttaacaa 18420 atgaccatgt tcctgctcag aaaccgccca aggctgcaaa gagcaggagg accaagccag 18480 gagaagccct gggccctcct gactcccact ttgggctctc cctgccctgg tgaaatgaca 18540 gaacggccaa cttgacacgc tgaagctgct ctgtctcatg cgtcctcctc atttctggat 18600 ccagagccag ggctgccagg agtagccaga gagctctgtg tggtgatgtt catattagtg 18660 aggtttacct tgaccacgag cagtgggaaa ctcaaaataa tggtggctta tttctcatct 18720 aaaaacatcc cggggtgggt ggtctgggac tgatctggtg gacccaggct ccgccttgtt 18780 gcttgactgt tggcagcacc tgcttactta ccactcatgg tgcaagatga cacttcagcc 18840 tccgccaaaa tgctcacctt ccagccagca ggaagtcgga aggagaagaa aggggacaga 18900 gccccatggc gtccatcctt agaggatgct gccacctgaa cctctgcttt catcctgttg 18960 gtcagaaccc agtcacatga ccacacccag tggcaacgga ggctgggaaa tatagtcttt 19020 attttgggca cccatgtgtc cagcaaaact gggggttcca tcagtcggca agaacgggag 19080 agtggccgat gcagtggctg atgcttgtat cccagcactt tgggaggtcg aggtgggcag 19140 atcacctgag gtcaggagtt caagaccagc ctggccaata tggtgaaacc ctgtctctac 19200 taaaaataaa aaaattagct gggtgtgctg gcgcacctgt agtcccagct acttgggagg 19260 ctgaggcagg agaatcgctt gatcttgaga ggtggaggtt gcagtgagcc aagattgtgc 19320 cactgccttc cagcctggga gacagcaaaa aaaaaaaaaa aaaaaaaaaa aaaaagggcc 19380 aggcacggtg gctcacacct gtaatcccag cactttggga ggccgagatg ggcggatcac 19440 gaggtcagga gattgagacc atcctggcta acacggtgaa accccatctc tactaaaaat 19500 acaaaaaaat tggccgggca tggtggagta gtcccagcta ctcgggaggc tgaggcagga 19560 gaatggcgtg aacctgggag gcagagcttg cagtgagccg agatcgcgcc actgcactcc 19620 agcctgggca acagagcgag actcttgtct caaaaagaaa aaaagaaaga gaaatctgcc 19680 tcccagcctt gggctcctgc cctaccagcc cacacccctg gtagagcctc ctctcccacc 19740 agctcaaagc ccaagttcct tcactgtgac cttgtctgct cctctaaaac aggcaacacc 19800 agacagtgag aagagccagc cagacatggg cagaaaacct atttctgtga tctactggct 19860 gtgtgagcag gggctagttg ctctctctgg gcctcactga agagaagggt ggcactatgc 19920 tagggccggc acggttgcaa ggtagatgta agatggggta caggtgttgt ggagggcaga 19980 aatgcaccat ccgaaggcta catgtccccc acacttatgt cttgcttggc ccacactgtt 20040 tcattttaaa atcagtagca aacaatttaa aaaatcagaa gatttgcctg catgatgcag 20100 tggctcatgc ctgtaatccc agcactttgg gaggccaagg tgggaggatt gcttgagccc 20160 aggagttcaa gaccagcatg ggcaccatag caagacccct gtttctacaa aaaaaaaaaa 20220 attagaaaat tagccaagtg tggtggcatg cacctgtggt cccagctact tgggaggcag 20280 agggaaagtg agatctcctg ctttttattt ctttatgtat aatgataggg tcttgctctg 20340 ttgcccaggc tggagtgcag tggcatgatc actgctcact gcagccttga tctcctgggc 20400 tcagaggatc ctcccacctc agcctcccaa atagctagga ctagaggtgc ccaccagcat 20460 gctcagcaga tttttaaatc tttttgtaga gatgaggttt tgctatgttg cccaggctgg 20520 tctcgaactc ctggcctcga gcgatcctcc caccttggcc tcccaaagca ctgggattac 20580 agacgtgagc cactgcgccc agcagatttc tctttaacac ctagatttca gcctgagcca 20640 ggcaggcatt cctgaatgaa ccagtagtac tgctcccaga agaagaggtc ctcctccgtg 20700 tgacacagtc cccacttggc ccttgcaggg attggatctg ggatccctgg atttaaactc 20760 agggccatcc tcataacagc ctcacaaggc tgggattagc ttcccagttc acaagggaag 20820 aaaccaagac ttgagaaggt caaggtctgg ccagacccac acatcttgga ccctcatacc 20880 gcctcgaggc cccatgctgc cctctgcctg ctccagatgt gaatactgct ggccctggct 20940 ggccccggct ggccccgagg gtcctaggga tgaacagccc agcccaggga gagctcagcc 21000 ccttgtgcct ctgccccttc ccacctcctg cggaggccag tcgactcacc cacaaagggc 21060 caggcactgt ggggatagat cagctaacaa aacagttgat gcttcctgcc cttctgggcc 21120 ttacattttg gctggaagaa gaggggagag gcagactgta agcaataagc gcaataagta 21180 ggttgcctgg aagtaatgtt agatcacgtt acggaaaaca ggaaagagca gagcgacaag 21240 tgctggggtg cgtggtgcag ggaaggcagc tggctgctgc tggtgtggtc agagtgggcc 21300 ctcatggaga agactgcatt cgagcagaaa cttgaagggg gtgaggggtg agcctagaga 21360 tatctggggc agagcagtcc aggcagaggg gacagccggt gtcaagccca ggacaggagt 21420 gtgcctggtg tgccagtttc aggcaagagg ccagtgtgca gaggcaaggt gagaacgcaa 21480 gggagagcag tggcggagac gggtgggaac gaggtcagac ctgctggcct ccagcctctg 21540 catggggctt ggctcttgct gggagcaatg ggaagcagta cacagtttca tgcaggggga 21600 gaaggcctgt cttgggttgc aggggcacgc tgtggcagct gggatcagag agaggagctt 21660 gtaggccagt tgttatgtgg tcccacgggc cagatggcca tggcttacct cacttcaggg 21720 aggctgtgag aagcactcag aatctggatg tgccttgggg gtgggcccca ctggatttcc 21780 tggtggacct ggtgtggggt gtgagaggag ggtgtgtttg gctgcagcag acaggagaat 21840 ggagttgcca tccgcgtgat ggggatggct gtgggaggag aggtttgggg tgagggaatc 21900 aggaactgag tgctggacat ggcaagtctg aaggcgcagt ggtcgtccac tcagagacct 21960 tggagttgga gatggaggtg tgggagtcct gaacagttag atgtagtgtt taccgcgaga 22020 aggaacaggg cttgcggcca gccctcctgt gttcccgtga cccagggcag ggcaggaggg 22080 gcctgagcct gccgagtgac tgggacctcc ttccaggaga tcatgcacgc cctgaagatg 22140 acctggcacg tgcactgctt tacctgtgct gcctgcaaga cgcccatccg gaacagggcc 22200 ttctacatgg aggagggcgt gccctattgc gagcgaggta cccactggcc agtgagggtg 22260 aggagggatg gtgcatgggg caggcatgaa tccaggtcct ctttctctct gcccccattc 22320 tcagactatg agaagatgtt tggcacgaaa tgccatggct gtgacttcaa gatcgacgct 22380 ggggaccgct tcctggaggc cctgggcttc agctggcatg acacctgctt cgtctgtgcg 22440 gtgagagccc cgcccctcga actgagcccc aagcccaccg gccctctgtt cattccccag 22500 gagatgcagg agaagttggg aaggggcctc tcctgctgcc cccaacccca tgtgactggg 22560 cctttgctgt ccttagatat gtcagatcaa cctggaagga aagaccttct actccaagaa 22620 ggacaggcct ctctgcaaga gccatgcctt ctctcatgtg tgagcccctt ctgcccacag 22680 ctgccgcggt ggcccctagc ctgaggggcc tggagtcgtg gccctgcatt tctgggtagg 22740 gctggcaatg gttgccttaa ccctggctcc tggcccgagc ctggggctcc ctgggccctg 22800 ccccacccac cttatcctcc caccccactc cctccaccac cacagcacac cgatgctggc 22860 cacaccagcc ccctttcacc tccagtgcca caataaacct gtacccagct gtgtcttgtg 22920 tgcccttccc ctgtgcatcc ggaggggcag aatttgaggc acgtggcagg gtggagagta 22980 agatggtttt cttgggctgg ccatctgggt ggtcctcgtg atgcagacat ggcgggctca 23040 tggttagtgg aggaggtaca ggcgagaccc catgtgccag gcccggtgcc cacagacatg 23100 aggggagcca ctggtctggc ctggcttgga ggttagagaa gggtagttag gaagggtagt 23160 tagcatggtg gctcatgcct gtgatcccag cactttggaa ggccaaggtg ggcagatcgc 23220 ttgaggtcag gagttcgaga cctcatggcc aacacggtga aacagcgtct ctagtaaaaa 23280 tacaaaaatt agccgagtgt ggtggggcat gcctgtaatc ccagccactc aggaggctga 23340 ggcgggaaaa tcacttgaac ctgggaagtg gaggttgcag tgagctgaga tcacaccact 23400 gcgcgcgagc ctgggtggca gatggcagag cgagaccctg cttcaaaaaa aaaaaaaaaa 23460 aaaaaaaaaa gaagggtagt tgtagttggg ggtggatctg cagagatatg gtgtggaaaa 23520 cagcaatggc cacagcaaag tcctggaggg gccagctgcc gtccaaacag aagaaggcag 23580 ggctggagag ggtagccctt aggtcctggg aagccacgag tgccaggcag tagagctggg 23640 gctgtctctt gaggttaggg cagggcaagg cacagcagag tttgaaatag gtttgtgttg 23700 tattgcagaa aagaggcccc agaacactga gggagtgcag gagggaggct gggaggagga 23760 gttgcagcag ggcctagggg cgggggccag gcaagggagg ggcagagagt aatatggcag 23820 agatgggacc cagtggcagg tccgggggat gagggatgga gagaaggaca ggagcgttgc 23880 caggcatctg gcctatacca gacatgctca cgctgtctcc cgcgaacctc ctagcaacct 23940 tgcgccgttg tctgcaatca cttatttcat tttttctttt ttaactttaa ttttttttgt 24000 ttttaagaga caggatctcc ctaggttgcc cgggctggtt tcaaactcct gggctcaagc 24060 aattcttcct ccttagcccc aaagtgctgg cattacaggt gtgagccacc atgcctggcc 24120 cacttatttt ctagatgagg cacagaaaga ttgggagact tgaccaaggt cacgctgtca 24180 ttgagccatg agccagacta gaatccaggc ctgaagctgg gtgcgctgtc ccaggactgg 24240 ctggcactga gtaccatttg ccagcgagca tctctctggg aagctgactt ctgcccggta 24300 cctggaggac tgtagacctt ggtggtggcg ccgtcactct ggggcttcct gcctcccact 24360 gatgcccgca ccaccctaga gggactgtca tctctcctgt cccaagcctg gactggaaag 24420 actgaagaga agccttaagt aggccaggac agctcagtgt gccatggctg cccgtccttc 24480 agtggtccct ggcatgagga cctgcaacac atctgttagt cttctcaaca ggcccttggc 24540 ccggtcccct ttaagagacg agaagggctg ggcacggtga ctcacacctc taatcccagc 24600 actttggaag gctgaggctg gagaagggct ccagcttagg agttcaggac cagcctgggc 24660 aacatggtga gaccctgttt tgttttgttt tttgtttttt tgagatggag tcttgctctg 24720 tcgcccaggc tggagtgcag 24740 42 25 DNA Rattus norvegicus 42 gcactacctt gaaggaatcc atggt 25
Patent applications by Sangwook T. Yoon, Atlanta, GA US
Patent applications by Scott D. Boden, Atlanta, GA US
Patent applications by William F. Mckay, Memphis, TN US