Abstract:
Human restrictin proteins and nucleic acid sequences encoding them are provided. Antibodies which recognize human restrictin in human brain are disclosed. In the human brain, restrictin occurs as two major polypeptides of 180 and 160 kD located in fiber tracts. These polypeptides are similar to those seen in rat brain. Surprisingly, restrictin has also been found in the peripheral nerves of rats and humans. The antibodies also detect a 170 kD polypeptide in MATRIGEL, an extracellular matrix product of rat EHS sarcoma cells widely used as a tissue culture substrate. Monoclonal antibodies to human restrictin and assays using the human restrictin protein, antibodies and DNA sequences are also provided.

Description:
FIELD OF THE INVENTION 
     The present invention relates to extracellular matrix molecules and nucleic acid sequences encoding them. 
     BACKGROUND OF THE INVENTION 
     The adherence of cells to each other and to the extracellular matrix, as well as the cellular signals transduced as a consequence of such binding, are of fundamental importance to the development and maintenance of body form and function. A number of molecules mediating cell adhesion have been identified and characterized at the molecular level both in vertebrates and in invertebrates. Many cell surface cell adhesion molecules (CAMs) are of three major types: 1) members of the immunoglobulin supergene family, which mediate calcium independent adhesion, 2) cadherins, which mediate calcium-dependent adhesion and are important structural components of adherence junctions, and 3) integrins, a family of heterodimeric proteins which can facilitate adhesion of cells both to each other and to the extracellular matrix. 
     CAMs may have multiple ligands. They can mediate adhesion by the interaction of a CAM on one cell with the identical CAM on another cell (homophilic binding), or they can mediate adhesion by interacting with different CAMs or extracellular matrix molecules (heterophilic binding). For example, contactin, a member of the immunoglobulin gene superfamily, can undergo homophilic binding or can bind heterophilically to other cell surface molecules such as the L1 antigen or to extracellular matrix molecules of the tenascin family. One extracellular matrix ligand for contactin is janusin, which is a member of the tenascin-R family. Janusin is closely related to tenascin in its patterns of epidermal growth factor, fibronectin type III and fibrinogen-like domains. In rodents, it is synthesized by oligodendrocytes and subpopulations of neurons at late developmental stages in the central nervous system. It can promote cell adhesion or anti-adhesion, depending on the neural cell type with which it interacts, promoting neurite outgrowth of some neural cell types and inhibiting neurite outgrowth from other neuronal populations. The repulsive response of neurons to janusin may be mediated by contactin. Janusin has been identified in rodents (A. Faissner. et al. 1990. J. Neurochem. 54: 1004-1015) and the rat gene has been cloned (B. Fuss, et al. 1991. Neurosci. Res. 29:299-307) and sequenced (B. Fuss, et al. 1993. J. Cell Biol. 120:1237-1249). The chicken homolog of janusin, referred to as restrictin, has also been identified and characterized (U. Norenberg, et al. 1992. Neuron 8:849-863). 
     SUMMARY OF THE INVENTION 
     Prior to the present invention, no human homolog of janusin/restrictin had been identified and it was not previously known if such a homolog existed. A human homolog of rat janusin has now been found, and the complete cDNA sequence encoding it has been determined. Antisera were prepared against a fragment of the human restrictin protein expressed in bacteria. These antibodies detect the immunogen, high molecular weight polypeptides in human brain, and cross react with several animal species. In the human brain, restrictin occurs as two major polypeptides of 180 and 160 kD located in fiber tracts. These polypeptides are similar in size to those seen in rat brain. Surprisingly, restrictin has also been found in the peripheral nerves of rats and humans. The antibodies also detect a 170 kD polypeptide in MATRIGEL, an extracellular matrix product of rat EHS sarcoma cells widely used as a tissue culture substrate. Monoclonal antibodies to human restrictin and assays using the human restrictin protein, antibodies and DNA sequences are also provided. 
    
    
     DESCRIPTION OF THE DRAWINGS 
     FIG. 1 illustrates the cloning process used to obtain the human restrictin cDNA sequence. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     cDNAs encoding human restrictin were cloned from human brain polyA+ RNA using the reverse transcriptase polymerase chain reaction (RT-PCR) with primers based on the rat janusin gene sequence. RT-PCR was performed on rat and human (adult and fetal, Clontech) brain polyA+ RNA using the one-step protocol described by Goblet, et al. (1989. Nucl. Acids Res. 17:2144). PolyA+RNA (1 μg) and 300 ng of each primer (see below) in 66 μl DEPC water were incubated at 65° C. for 15 min. and cooled on ice. Thirty-three μl of 3×RT-PCR reagent mix (3× PCR buffer, 150 mM KCl, 30 mM Tris-HCl pH 8.3, 4.5 mM MgCl 2 , 0.3% gelatin, 500 μM dNTPs, 200 U M-MLV reverse transcriptase, 4 U rRNAsin (Promega, Madison, Wis.), 2.5 U AMPLITAQ (Perkin-Elmer Cetus, Norwalk, Conn.) was added and the reaction was incubated at 37° C. for 30 min. The amplification reaction (94° C. for 1 min., 50° C. for 2 min., and 72° C. for 2 min.) was repeated for 40 cycles. The primer pair for amplification was as follows: 
     
         ______________________________________5&#39;-ACTGACAGATCTAGAGCC             SEQ ID NO:1 (corresponding to             nucleotides 2375-2392 in rat)5&#39;-GGTGGTCGATAGGATACT             SEQ ID NO:2 (corresponding to             nucleotides 2856-2839 in rat)______________________________________ 
    
     A major 480 bp amplification product was obtained from rat RNA, which was subcloned and sequenced, confirming that this product corresponded to rat janusin. A minor 290 bp product was also obtained in rat. An amplification product of the appropriate size (480 bp) was also generated from human adult brain RNA. This product was subcloned and sequenced directly (Mihovilovic, 1989). Amplification of fetal RNA produced only a 290 bp amplification product which was subsequently found not to be human restrictin. 
     The 480 bp human amplification product (206/207N) was used as a probe on Northern blots of multiple regions of human brain (Clontech). The radiolabeled probe was prepared using a random primer labeling kit (BRL, Gaithersburg, Md.) with purification over NICK columns (Pharmacia, Piscataway, N.J.). Blots were reprobed with a human beta-actin probe (Clontech) to determine the relative amounts and integrity of RNA in each sample. The probe hybridized to a single approximately 12 Kb nucleic acid sequence in amygdala, caudate nucleus, corpus collusum, hippocampus, hypothalamus, substantia nigra, subthalamic nuclei and thalamus. The restrictin cDNA clones described below were also used as probes on northern blots of human fetal tissues. The approximately 12 Kb restrictin mRNA seen in adult brain was also detected in fetal brain, but was absent from fetal heart, lung, liver and kidney. This illustrates the tissue specificity of restrictin. 
     Two commercially available lambda human cDNA libraries were screened as recommended by the manufacturer using 206/207N as a probe to identify additional clones for determination of the sequence of the full-length human restrictin gene (FIG. 1). Initial screening with 206/207N identified cDNA clones 6-1 and 6-2. A second hybridization screening using a probe from the 5&#39; end of clone 6-1, as illustrated in FIG. 1, produced cDNA clones 12 and 15. The upstream end of clone 12 was used in a third library screen to isolate clone 20. Together, these clones encode the entire protein coding region of human restrictin (FIG. 1) The lambda cDNA inserts of these clones were either 1) PCR amplified using lambda gt10 EcoRI forward and reverse primers for direct sequencing as described above (Mihovilovic, 1989), or 2) subcloned into pBLUESCRIPT (SK+) (Stratagene, La Jolla, Calif.) for sequencing by dye-termination or dye-labeled primer methods (Applied Biosystems, Model 373A, Foster City, Calif.). Sequencing primers were synthesized on an Applied Biosystems (ABI) Model 380B DNA synthesizer and purified using OPC cartridges (ABI). Sequence alignments, translations, and feature location were performed using IG-Suite software (lntelligenetics, Mountain View, Calif.). In this manner, the entire 4,724 bp human restrictin cDNA coding sequence was determined by sequencing both strands of the cDNAs (SEQ ID NO:3). The sequence of the full-length restrictin protein (1358 amino acids, SEQ ID NO:4) was deduced from the cDNA sequence. The human restrictin protein shows structural similarity to other members of the tenascin-R family. In particular, human restrictin, like its homologs from rat and chicken, comprises a short amino terminal region followed by heptad repeats, epidermal growth factor-like repeats, nine fibronectin type III repeats and a carboxyl-terminal region homologous to the globular domain of fibrinogen. There is no evidence for a hydrophobic membrane spanning region, consistent with restrictin being a secreted, extracellular matrix molecule. The human sequence obtained is highly homologous to the rat and chicken sequences at both the DNA (88 and 76%, respectively, within the protein coding region) and at the amino acid level (93 and 72%, respectively). 
     SEQ ID NO:3, a fragment of SEQ ID NO:3, or an equivalent nucleic acid molecule which employs degenerate codons to encode the amino acid sequence of SEQ ID NO:4 or a fragment thereof, may be cloned into an expression vector as is known in the art to produce recombinant human restrictin in transformed or transfected host cells. Recombinant human restrictin and recombinant human restrictin fragments provide a convenient source of these molecules for immunization, immunoassays, and use in tissue culture growth substrates. To generate antisera to human restrictin, the 206/207N fragment (nucleotides 2686-3165 of SEQ ID NO:3 with EcoRI cloning sites at both the 5&#39; and 3+ ends) was subcloned into the EcoRI site of pGEX-3X (Pharmacia), producing a recombinant human restrictin-glutathione-S-transferase (GST) fusion protein for immunization. After transformation of E. coli, expression of the fusion protein was induced with IPTG and the soluble material was purified over a glutathione-S Sepharose affinity column. The purified material was used to immunize rabbits using standard methods. Sera were collected and assayed by immunoblotting against the immunogen and against the 206/207N protein fragment, expressed by subcloning into the pATH expression system (New England BioLabs). The anti-fusion protein antisera recognized both of these antigens on Western blots, but anti-chicken restrictin did not, indicating immunological differences between the human and chicken restrictin proteins. 
     To verify the reactivity of the antisera against human proteins, adult brain membranes were prepared and extracted. In brief, postsmortem human brain was Dounce homogenized into 0.32M sucrose, 5 mM EDTA, 20 mM Tris-HCl (pH 8) containing 1 mM PMSF, 0.5 mM p-chloromercuriphenylsulfonic acid and 5 μg/ml of aprotinin and leupeptin as protease inhibitors. After centrifugation at 500×g for 30 min. to remove nuclei and cellular debris, the supernatant was centrifuged at 80,000×g to collect the membrane fraction, which was then extracted with I% sodium deoxycholate in homogenization buffer for 1.5 hr. at 4° C. The detergent extract was clarified by centrifugation at 100,000×g and used subsequently for either SDS-PAGE directly or for further purification of a protein fraction bearing the HNK-1 epitope, which may be involved in binding cell adhesion molecules. HNK-I brain fractions were immunoaffinity enriched on anti-Leu7 (Becton Dickinson) coupled to Sepharose. Immunoblotting was performed using a PROTOBLOT AP system (Promega) as recommended by the manufacturer with an alkaline phosphatase-conjugated anti-rabbit IgG as the secondary antibody and color development using NBT/BCIP. In Western blots, the anti-fusion protein antisera routinely detected two bands of approximately 180 and 160 kD in human brain and in HNK-1 enriched fractions. These bands were apparently enriched in the latter. The reactivity of the antisera was inhibited in a concentration dependent manner by addition of the GST fusion protein, but not by addition of GST, indicating a specific immune reaction to the human restrictin fragment. Western blots of rat, mouse, cow, pig and chicken brain extracts demonstrated similar sized bands (180 kD and 160 kD) in all cases. There were, however, slight mobility shifts, possibly due to species variation in amino acid sequence or to differential glycosylation. MATRIGEL (Collaborative Biomedical Products), an extracellular matrix substrate derived from rat EHS sarcoma cells as an in vitro tissue culture growth substrate, was also reactive with the antiserum, revealing a 170 kD polypeptide. 
     For immunohistological studies, frozen human or rat tissues were sectioned and fixed using acetone or 4% paraformaldehyde. Staining was performed using the VECTA-STAIN ELITE ABC system (Vector Laboratories) as recommended. Primary anti-fusion protein antisera were used at a 1:1000 dilution. Paraffin sections were treated using the microwave antigen retrieval system (U.S. Pat. No. 5,244,787) before staining. The antisera were reactive with frozen sections of human peripheral nerve (peripheral nervous system), rat hippocampus (central nervous system) and human cerebellum (central nervous system) and with paraffin section human pons (central nervous system). In all cases, there were areas of clear positivity as well as areas that were clearly negative. For example, in the peripheral nerve experiments, the surrounding, non-neuronal tissue was unstained, and in the central nervous system, there were clearly unstained cells in all areas examined. 
     Antibodies according to the invention which recognize human restrictin are useful in methods for detecting the protein in immunoassay systems. Polyclonal antisera raised to human restrictin or to protein fragment of human restrictin may be used to detect the restrictin protein in immunoassay methods involving binding between the protein or fragment and the antibodies, e.g., ELISAs and immunoblots. These conventional immunoassay methods can be readily adapted to employ the antibodies and restrictin protein disclosed herein. Alternatively, monoclonal antibodies which recognize the human restrictin protein of the invention may be prepared using methods known in the art, such as that of Kohler and Milstein (1975. Nature 256:495) and used in immunoassays. The spleen cells of mice immunized with the human restrictin protein or a fragment thereof are fused with murine myeloma cells and the resulting hybridomas are screened against the immunogen to select those producing the desired anti-restrictin monoclonal antibody. In general, binding between protein and antibody in an immunoassay is detected by inclusion of a detectable label in the reaction which generates a signal. The detectable label is usually conjugated to the antibody or protein and may be directly detectable (e.g., a dye, radioisotope or fluorochrome) or rendered detectable after further chemical reaction (e.g., an enzyme which reacts to produce a colored product, or biotin which may be bound to labeled avidin). 
     Polyclonal and monoclonal antibodies according to the invention may also be used to purify human restrictin from tissues, or to purify restrictin from the tissues of a cross-reacting species by immunoaffinity purification methods, e.g., immunoaffinity chromatography. This provides a source of natural restrictin for use in immunoassays, as an immunogen, or in tissue culture systems to promote or inhibit neurite outgrowth. 
     Oligonucleotides derived from the nucleotide sequences encoding human restrictin are useful in nucleic acid hybridization assays for detection of related restrictin nucleotide sequences. They may also be used as primers for amplification of restrictin target sequences. Oligonucleotide probes for hybridization according to the invention may comprise the complete coding sequence of the human restrictin cDNA or a portion thereof, such as nucleotides 2686-3165 of SEQ ID NO:3. Primers are generally short portions of the nucleotide sequence which specifically hybridize to restrictin nucleotide sequences, allowing specific amplification. One skilled in the art will further recognize that oligonucleotide probes and primers may also be designed which comprise all or a portion of a sequence which is complementary to SEQ ID NO:3. Detection of nucleic acids by hybridization to a probe is known in the art. Such methods as Southern blotting, Northern blotting, dot blotting, nucleic acid amplification methods and the like may be readily adapted to detection of nucleotide sequences containing all or part of the human restrictin coding sequence, or to detection of all or part of the restrictin coding sequence of a cross-reacting species. This is done using the nucleotide sequence given in SEQ ID NO:3 to design appropriate probes and primers. For purposes of the present invention, the terms &#34;encoding&#34; and &#34;coding for&#34; are intended to include nucleic acids which comprise sequences which can be transcribed and/or translated to produce restrictin, or a fragment thereof, including degenerate nucleotide sequences. It will also be understood that probes and primers derived from the disclosed nucleotide sequences may also be used to detect fragments of restrictin coding sequences. Hybridization of the probe or amplification by the primers may be detected by means of a directly or indirectly detectable label associated with the probe or primer, i.e., incorporated into the probe or conjugated to it. In general, the same labels useful for labeling antibodies and antigens may be used to label oligonucleotides. In addition, it is within the ordinary skill in the art, given the nucleotide sequence of SEQ ID NO:3. to derive the complementary nucleotide sequence, which may also be used to prepare probes and primers and which may be detected by use of probes and primers. Further, the present disclosure of SEQ ID NO:3 allows derivation of RNA sequences which are complementary to SEQ ID NO:3 or to the complement of SEQ ID NO:3. Such equivalent RNA sequences may be detected by hybridization or amplification as well. 
     The reagents for performing these immunoassays, hybridization assays, and nucleic acid amplification may be conveniently packaged together for sale or use in the form of a kit. A kit for immunoassay may contain an antibody which recognizes and binds to restrictin. The antibody may be labeled, or a second antibody carrying the label may be included for detection of binding. Optionally, any reagent required for performing the assay and detecting the label may be included. A kit for hybridization assays or amplification may contain oligonucleotide probes or primers which hybridize to one or more nucleotide sequences contained in SEQ ID NO:3. The probes or primers may be conjugated to a detectable label for detection. Optionally, the hybridization or amplification kit may contain any reagents required for performing the hybridization or amplification and detecting the label. 
     The foregoing disclosure is intended to illustrate the invention and is not to be construed as limiting its scope as defined by the appended claims. Upon reading the present disclosure, certain equivalents and variations will be apparent to one skilled in the art without exercise of inventive skill. Such equivalents and variations are intended to be included within the scope of the invention. 
     
         __________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 4(2) INFORMATION FOR SEQ ID NO:1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 18 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:ACTGACAGATCTAGAGCC18(2) INFORMATION FOR SEQ ID NO:2:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 18 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(xi) SEQUENCE DESCRIPTION: SEQ ID NO:2:GGTGGTCGATAGGATACT18(2) INFORMATION FOR SEQ ID NO:3:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 4724 base pairs(B) TYPE: nucleic acid(C) STRANDEDNESS: double(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(xi) SEQUENCE DESCRIPTION: SEQ ID NO:3:GAATTCCGGGAGAAGGGGGTCCTCTCTGACCCAAGGAATTACCACTAGTGGAGTGAAGCC60ACCTGACTTTTTGATCTTATTTTGGTTGCCTCCTCATTCTCCTTCCACCCGTAGCCCTGA120CAGCTTGGGTTTCATTTCTTTCGTGGAGCCTTGTCTCTTCCTCCCAGAATAGGAGGAAGG180GAAGAGAAGGGAAAGAGGAGGGCTCTCTAGGTGAGCGCATCAGCTGGCTCCAGCCTGAGC240AAGCAAGAATTTTCTTCCCAGGAAGCTCCTCTCGCTCCCCGGCCGCCCACCCCCAGCCTG300GGTGGCTGTATCGTTTTAACTGCATAGAGGGCAGGTCTCTTTTGGAATTAGGATTAAAGA360AAGTGCAGTAAAGAGAAAGCATCGAAGACACCATCACAAAAGATTCCCACAACTCCATGC420TGTGTGCTGCAGGCTGGTCCTGAACCCAGATCTCTGGCTGAGAGGATGGGGGCAGATGGG480GAAACAGTGGTTCTGAAGAACATGCTCATTGGCGTCAACCTGATCCTTCTGGGCTCCATG540ATCAAGCCTTCAGAGTGTCAGCTGGAGGTCACCACAGAAAGGGTCCAGAGACAGTCAGTG600GAGGAGGAGGGAGGCATTGCCAACTACAACACGTCCAGCAAAGAGCAGCCTGTGGTCTTC660AACCACGTGTACAACATTAACGTGCCCTTGGACAACCTCTGCTCCTCAGGGCTAGAGGCC720TCTGCTGAGCAGGAGGTGAGTGCAGAAGACGAGACTCTGGCAGAGTACATGGGCCAGACC780TCAGACCACGAGAGCCAGGTCACCTTTACACACAGGATCAACTTCCCCAAAAAGGCCTGT840CCATGTTCCAGTTCAGCCCAGGTGCTGCAGGAGCTGCTGAGCCGGATCGAGATGCTGGAG900AGGGAGGTGTCGGTGCTGCGAGACCAGTGCAACGCCAACTGCTGCCAAGAAAGTGCTGCC960ACAGGACAACTGGACTATATCCCTCACTGCAGTGGCCACGGCAACTTTAGCTTTGAGTCC1020TGTGGCTGCATCTGCAACGAAGGCTGGTTTGGCAAGAATTGCTCGGAGCCCTACTGCCCG1080CTGGGTTGCTCCAGCCGGGGGGTGTGTGTGGATGGCCAGTGCATCTGTGACAGCGAGTAC1140AGCGGGGATGACTGTTCCGAACTCCGGTGCCCAACAGACTGCAGCTCCCGGGGGCTCTGC1200GTGGACGGGGAGTGTGTCTGTGAAGAGCCCTACACTGGCGAGGACTGCAGGGAACTGAGG1260TGCCCTGGGGACTGTTCGGGGAAGGGGAGATGTGCCACCGGTACCTGTTTATGCGAGGAG1320GGCTACGTTGGTGAGGACTGCGGCCAGCGGCAGTGTCTGAATGCCTGCAGTGGGCGAGGA1380CAATGTGAGGAGGGGCTCTGCGTCTGTGAAGAGGGCTACCAGGGCCCTGACTGCTCAGCA1440GTTGCCCCTCCAGAGGACTTGCGAGTGGCTGGTATCAGCGACAGGTCCATTGAGCTGGAA1500TGGGACGGGCCGATGGCAGTGACGGAATATGTGATCTCTTACCAGCCGACGGCCCTGGGG1560GGCCTCCAGCTCCAGCAGCGGGTGCCTGGAGATTGGAGTGGTGTCACCATCACGGAGCTG1620GAGCCAGGTCTCACCTACAACATCAGCGTCTACGCTGTCATTAGCAACATCCTCAGCCTT1680CCCATCACTGCCAAGGTGGCCACCCATCTCTCCACTCCTCAAGGGCTACAATTTAAGACG1740ATCACAGAGACCACCGTGGAGGTGCAGTGGGAGCCCTTCTCATTTTCCTTCGATGGGTGG1800GAAATCAGCTTCATTCCAAAGAACAATGAAGGGGGAGTGATTGCTCAGGTCCCCAGCGAT1860GTTACGTCCTTTAACCAGACAGGACTAAAGCCTGGGGAGGAATACATTGTCAATGTGGTG1920GCTCTGAAAGAACAGGCCCGCAGCCCCCCTACCTCGGCCAGCGTCTCCACAGTCATTGAC1980GGCCCCACGCAGATCCTGGTTCGCGATGTCTCGGACACTGTGGCTTTTGTGGAGTGGATT2040CCCCCTCGAGCCAAAGTCGATTTCATTCTTTTGAAATATGGCCTGGTGGGCGGGGAAGGT2100GGGAGGACCACCTTCCGGCTGCAGCCTCCCCTGAGCCAATACTCAGTGCAGGCCCTGCGG2160CCTGGCTCCCGATACGAGGTGTCAGTCAGTGCCGTCCGAGGGACCAACGAGAGCGATTCT2220GCCACCACTCAGTTCACAACAGAGATCGATGCCCCCAAGAACTTGCGAGTTGGTTCTCGC2280ACAGCAACCAGCCTTGACCTCGAGTGGGATAACAGTGAAGCCGAAGTTCAGGAGTACAAG2340GTTGTGTACAGCACCCTGGCGGGTGAGCAATATCATGAGGTACTGGTCCCCAAGGGCATT2400GGTCCAACCACCAGGGCCACCCTGACAGATCTGGTACCTGGCACTGAGTATGGAGTTGGA2460ATATCTGCCGTCATGAACTCACAGCAAAGCGTGCCAGCCACCATGAATGCCAGGACTGAA2520CTTGACAGTCCCCGAGACCTCATGGTGACAGCCTCCTCAGAGACCTCCATCTCCCTCATC2580TGGACCAAGGCCAGTGGCCCCATTGACCACTACCGAATTACCTTTACCCCATCCTCTGGG2640ATTGCCTCAGAAGTCACCGTACCCAAGGACAGGACCTCATACACACTAACAGATCTAGAG2700CCTGGGGCAGAGTACATCATTTCCGTCACTGCTGAGAGGGGTCGGCAGCAGAGCTTGGAG2760TCCACTGTGGATGCTTTCACAGGCTTCCGTCCCATCTCTCATCTGCACTTTTCTCATGTG2820ACCTCCTCCAGTGTGAACATCACTTGGAGTGATCCATCTCCCCCAGCAGACAGACTCATT2880CTTAACTACAGCCCCAGGGATGAGGAGGAAGAGATGATGGAGGTCTCCCTGGATGCCACC2940AAGAGGCATGCTGTCCTGATGGGCCTGCAACCAGCCACAGAGTATATTGTGAACCTTGTG3000GCTGTCCATGGCACAGTGACCTCTGAGCCCATTGTGGGCTCCATCACCACAGGAATTGAT3060CCCCCAAAAGACATCACAATTAGCAATGTGACCAAGGACTCAGTGATGGTCTCCTGGAGC3120CCTCCTGTTGCATCTTTCGATTACTACCGAGTATCATATCGACCCACCCAAGTGGGACGA3180CTAGACAGCTCAGTGGTGCCCAACACTGTGACAGAATTCACCATCACCAGACTGAACCCA3240GCTACCGAATACGAAATCAGCCTCAACAGCGTGCGGGGCAGGGAGGAAAGCGAGCGCATC3300TGTACTCTTGTGCACACAGCCATGGACAACCCTGTGGATCTGATTGCTACCAATATCACT3360CCAACAGAAGCCCTGCTGCAGTGGAAGGCACCAGTGGGTGAGGTGGAGAACTACGTCATT3420GTTCTTACACACTTTGCAGTCGCTGGAGAGACCATCCTTGTTGACGGAGTCAGTGAGGAA3480TTTCGGCTTGTTGACCTGCTTCCTAGCACCCACTATACTGCCACCATGTATGCCACCAAT3540GGACCTCTCACCAGTGGCACCATCAGCACCAACTTTTCTACTCTCCTGGACCCTCCGGCA3600AACCTGACAGCCAGTGAAGTCACCAGACAAAGTGCCCTGATCTCCTGGCAGCCTCCCAGG3660GCAGAGATTGAAAATTATGTCTTGACCTACAAATCCACCGACGGAAGCCGCAAGGAGCTG3720ATTGTGGATGCAGAAGACACCTGGATTCGACTGGAGGGCCTGTTGGAGAACACAGACTAC3780ACGGTGCTCCTGCAGGCAACACAGGACACCACGTGGAGCAGCATCACCTCCACCGCTTTC3840ACCACAGGAGGCCGGGTGTTCCCTCATCCCCAAGACTGTGCCCAGCATTTGATGAATGGA3900GACACTTTGAGTGGGGTTTACCCCATCTTCCTCAATGGGGAGCTGAGCCAGAAATTACAA3960GTGTACTGTGATATGACCACCGACGGGGGCGGCTGGATTGTATTCCAGAGGCGGCAGAAT4020GGCCAAACTGATTTTTTCCGGAAATGGGCTGATTACCGTGTTGGCTTCGGGAACGTGGAG4080GATGAGTTCTGGCTGGGGCTGGACAATATACACAGGATCACATCCCAGGGCCGCTATGAG4140CTGCGCGTGGACATGCGGGATGGCCAGGAGGCCGCCTTCGCCTCCTACGACAGGTTCTCT4200GTCGAGGACAGCAGAAACCTGTACAAACTCCGCATAGGAAGCTACAACGGCACTGCGGGG4260GACTCCCTCAGCTATCATCAAGGACGCCCTTTCTCCACAGAGGATAGAGACAATGATGTT4320GCAGTGACTAACTGTGCCATGTCGTACAAGGGAGCATGGTGGTATAAGAACTGCCACCGG4380ACCAACCTCAATGGGAAGTACGGGGAGTCCAGGCACAGTCAGGGCATCAACTGGTACCAT4440TGGAAAGGCCATGAGTTCTCCATCCCCTTTGTGGAAATGAAGATGCGCCCCTACAACCAC4500CGTCTCATGGCAGGGAGAAAACGGCAGTCCTTACAGTTCTGAGCAGTGGGCGGCTGCAAG4560CCAACCAATATTTTCTGTCATTTGTTTGTATTTTATAATATGAAACAAGGGGGGAGGGTA4620ATAGCAATGTTTTTTGCAACATATTAAGAGTATGTNAAGGAAGCAGGGATGTCGCAGGAA4680TCCGCTGGCTAACATCTGCTCTNGGTTTCTGCTGNCCTGGAGGC4724(2) INFORMATION FOR SEQ ID NO:4:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1358 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:MetGlyAlaAspGlyGluThrValValLeuLysAsnMetLeuIleGly151015ValAsnLeuIleLeuLeuGlySerMetIleLysProSerGluCysGln202530LeuGluValThrThrGluArgValGlnArgGlnSerValGluGluGlu354045GlyGlyIleAlaAsnTyrAsnThrSerSerLysGluGlnProValVal505560PheAsnHisValTyrAsnIleAsnValProLeuAspAsnLeuCysSer65707580SerGlyLeuGluAlaSerAlaGluGlnGluValSerAlaGluAspGlu859095ThrLeuAlaGluTyrMetGlyGlnThrSerAspHisGluSerGlnVal100105110ThrPheThrHisArgIleAsnPheProLysLysAlaCysProCysSer115120125SerSerAlaGlnValLeuGlnGluLeuLeuSerArgIleGluMetLeu130135140GluArgGluValSerValLeuArgAspGlnCysAsnAlaAsnCysCys145150155160GlnGluSerAlaAlaThrGlyGlnLeuAspTyrIleProHisCysSer165170175GlyHisGlyAsnPheSerPheGluSerCysGlyCysIleCysAsnGlu180185190GlyTrpPheGlyLysAsnCysSerGluProTyrCysProLeuGlyCys195200205SerSerArgGlyValCysValAspGlyGlnCysIleCysAspSerGlu210215220TyrSerGlyAspAspCysSerGluLeuArgCysProThrAspCysSer225230235240SerArgGlyLeuCysValAspGlyGluCysValCysGluGluProTyr245250255ThrGlyGluAspCysArgGluLeuArgCysProGlyAspCysSerGly260265270LysGlyArgCysAlaThrGlyThrCysLeuCysGluGluGlyTyrVal275280285GlyGluAspCysGlyGlnArgGlnCysLeuAsnAlaCysSerGlyArg290295300GlyGlnCysGluGluGlyLeuCysValCysGluGluGlyTyrGlnGly305310315320ProAspCysSerAlaValAlaProProGluAspLeuArgValAlaGly325330335IleSerAspArgSerIleGluLeuGluTrpAspGlyProMetAlaVal340345350ThrGluTyrValIleSerTyrGlnProThrAlaLeuGlyGlyLeuGln355360365LeuGlnGlnArgValProGlyAspTrpSerGlyValThrIleThrGlu370375380LeuGluProGlyLeuThrTyrAsnIleSerValTyrAlaValIleSer385390395400AsnIleLeuSerLeuProIleThrAlaLysValAlaThrHisLeuSer405410415ThrProGlnGlyLeuGlnPheLysThrIleThrGluThrThrValGlu420425430ValGlnTrpGluProPheSerPheSerPheAspGlyTrpGluIleSer435440445PheIleProLysAsnAsnGluGlyGlyValIleAlaGlnValProSer450455460AspValThrSerPheAsnGlnThrGlyLeuLysProGlyGluGluTyr465470475480IleValAsnValValAlaLeuLysGluGlnAlaArgSerProProThr485490495SerAlaSerValSerThrValIleAspGlyProThrGlnIleLeuVal500505510ArgAspValSerAspThrValAlaPheValGluTrpIleProProArg515520525AlaLysValAspPheIleLeuLeuLysTyrGlyLeuValGlyGlyGlu530535540GlyGlyArgThrThrPheArgLeuGlnProProLeuSerGlnTyrSer545550555560ValGlnAlaLeuArgProGlySerArgTyrGluValSerValSerAla565570575ValArgGlyThrAsnGluSerAspSerAlaThrThrGlnPheThrThr580585590GluIleAspAlaProLysAsnLeuArgValGlySerArgThrAlaThr595600605SerLeuAspLeuGluTrpAspAsnSerGluAlaGluValGlnGluTyr610615620LysValValTyrSerThrLeuAlaGlyGluGlnTyrHisGluValLeu625630635640ValProLysGlyIleGlyProThrThrArgAlaThrLeuThrAspLeu645650655ValProGlyThrGluTyrGlyValGlyIleSerAlaValMetAsnSer660665670GlnGlnSerValProAlaThrMetAsnAlaArgThrGluLeuAspSer675680685ProArgAspLeuMetValThrAlaSerSerGluThrSerIleSerLeu690695700IleTrpThrLysAlaSerGlyProIleAspHisTyrArgIleThrPhe705710715720ThrProSerSerGlyIleAlaSerGluValThrValProLysAspArg725730735ThrSerTyrThrLeuThrAspLeuGluProGlyAlaGluTyrIleIle740745750SerValThrAlaGluArgGlyArgGlnGlnSerLeuGluSerThrVal755760765AspAlaPheThrGlyPheArgProIleSerHisLeuHisPheSerHis770775780ValThrSerSerSerValAsnIleThrTrpSerAspProSerProPro785790795800AlaAspArgLeuIleLeuAsnTyrSerProArgAspGluGluGluGlu805810815MetMetGluValSerLeuAspAlaThrLysArgHisAlaValLeuMet820825830GlyLeuGlnProAlaThrGluTyrIleValAsnLeuValAlaValHis835840845GlyThrValThrSerGluProIleValGlySerIleThrThrGlyIle850855860AspProProLysAspIleThrIleSerAsnValThrLysAspSerVal865870875880MetValSerTrpSerProProValAlaSerPheAspTyrTyrArgVal885890895SerTyrArgProThrGlnValGlyArgLeuAspSerSerValValPro900905910AsnThrValThrGluPheThrIleThrArgLeuAsnProAlaThrGlu915920925TyrGluIleSerLeuAsnSerValArgGlyArgGluGluSerGluArg930935940IleCysThrLeuValHisThrAlaMetAspAsnProValAspLeuIle945950955960AlaThrAsnIleThrProThrGluAlaLeuLeuGlnTrpLysAlaPro965970975ValGlyGluValGluAsnTyrValIleValLeuThrHisPheAlaVal980985990AlaGlyGluThrIleLeuValAspGlyValSerGluGluPheArgLeu99510001005ValAspLeuLeuProSerThrHisTyrThrAlaThrMetTyrAlaThr101010151020AsnGlyProLeuThrSerGlyThrIleSerThrAsnPheSerThrLeu1025103010351040LeuAspProProAlaAsnLeuThrAlaSerGluValThrArgGlnSer104510501055AlaLeuIleSerTrpGlnProProArgAlaGluIleGluAsnTyrVal106010651070LeuThrTyrLysSerThrAspGlySerArgLysGluLeuIleValAsp107510801085AlaGluAspThrTrpIleArgLeuGluGlyLeuLeuGluAsnThrAsp109010951100TyrThrValLeuLeuGlnAlaThrGlnAspThrThrTrpSerSerIle1105111011151120ThrSerThrAlaPheThrThrGlyGlyArgValPheProHisProGln112511301135AspCysAlaGlnHisLeuMetAsnGlyAspThrLeuSerGlyValTyr114011451150ProIlePheLeuAsnGlyGluLeuSerGlnLysLeuGlnValTyrCys115511601165AspMetThrThrAspGlyGlyGlyTrpIleValPheGlnArgArgGln117011751180AsnGlyGlnThrAspPhePheArgLysTrpAlaAspTyrArgValGly1185119011951200PheGlyAsnValGluAspGluPheTrpLeuGlyLeuAspAsnIleHis120512101215ArgIleThrSerGlnGlyArgTyrGluLeuArgValAspMetArgAsp122012251230GlyGlnGluAlaAlaPheAlaSerTyrAspArgPheSerValGluAsp123512401245SerArgAsnLeuTyrLysLeuArgIleGlySerTyrAsnGlyThrAla125012551260GlyAspSerLeuSerTyrHisGlnGlyArgProPheSerThrGluAsp1265127012751280ArgAspAsnAspValAlaValThrAsnCysAlaMetSerTyrLysGly128512901295AlaTrpTrpTyrLysAsnCysHisArgThrAsnLeuAsnGlyLysTyr130013051310GlyGluSerArgHisSerGlnGlyIleAsnTrpTyrHisTrpLysGly131513201325HisGluPheSerIleProPheValGluMetLysMetArgProTyrAsn133013351340HisArgLeuMetAlaGlyArgLysArgGlnSerLeuGlnPhe134513501355_______________________________________________________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