Abstract:
Disclosed are a glutamate receptor or a modified glutamate receptor as defined in the Sequence Table, a gene encoding the same and a method for effecting screening an agonist or antagonist which binds to the above glutamate receptor or the above modified glutamate receptor which comprises using the glutamate receptor or the modified glutamate receptor as defined above.

Description:
BACKGROUND OF THE INVENTION 
     This invention relates to novel proteins and genes coding the same, more specifically to protein NMDA (N-methyl-D-aspartic acid) type glutamate receptors which play a central role in nervous information transmission, modified products thereof, and genes (cDNAs) encoding them. 
     It has been suggested that glutamate receptors, which are receptors of main stimulant nervous transmitter substances in a central nervous system of a higher animal, play a central role in nervous information transmission at a synapse, and also are deeply concerned with appearance of synapse plasticity which is basically required for memory and learning and neuronal cell death caused by a disease such as cerebral ischemia and epilepsy. Thus, it is considered that clarifications of molecular structures and functions of the glutamate receptors are required to understand a transmission mechanism of nervous information in a center, a cerebral structure of higher order and the disease of a brain. 
     As in the case of receptors of acetylcholine and GABA (γ-aminobutyric acid), the glutamate receptors are roughly classified into ion channel type glutamate receptors and G protein coupled type receptors (metabolism-controlling type receptors). Receptors which can effect long-term reinforcement of synapse transmission at a CA1 region of a hippocampus of which the most advanced study has been made about synapse plasticity are two kinds of ion channel type glutamate receptors. That is, an NMDA type receptor having Ca 2+   permeability and opening depending on membrane potential and a quisqualate/kinate type receptor (or a non-NMDA type receptor). While the non-NMDA type receptor performs general synapse transmission, the NMDA type receptor performs Ca 2+  permeation when a high frequent. stimulus which induces long-term reinforcement of synapse transmission is given. The Ca 2+   permeation is inhibited by Mg 2+   depending on membrane potential. 
     Although the glutamate receptors have important physiological functions as described above, molecular biological structures thereof had not been clarified for a long term. In recent years, by using a cDNA-producing system of Xenopus oocytes, Hollmann et al. cloned cDNA of a non-NMDA type glutamate receptor (&#34;Nature&#34;, 342, pp. 643 to 648 (1989)) and Nakanishi et al. cloned cDNA of a rat-G protein coupled type glutamate receptor (&#34;Nature&#34;, 349, pp. 760 to 765 (1991)) and cDNA of a rat-NMDA type receptor (&#34;Nature&#34;, 354, pp. 31 to 37 (1991)). Other plural kinds of genes of glutamate receptors have been cloned, and the molecular biological mechanisms thereof have not yet been clarified sufficiently under the present situation. 
     SUMMARY OF THE INVENTION 
     The present inventors have paid special attention to NMDA type glutamate receptors and researched and studied them intensively, and consequently novel glutamate receptors and glutamate receptors modified by protein engineering have been obtained to accomplish the present invention. 
     That is, the characteristic features of the present invention reside in a glutamate receptor which is represented by an amino acid sequence described in Sequence ID No. 1, 2, 3 or 4 of the sequence table and a gene encoding the same, a modified glutamate receptor which is represented by an amino acid sequence described in Sequence ID No. 8 or 9 of the sequence table and a gene encoding the same, and a modified glutamate receptor which is represented by a base sequence described in Sequence ID No. 19 of the sequence table and a gene encoding the same. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The drawings relating to the present invention are explained. 
     FIGS. 1(a) and 1(b) show functional expression of ε4/ζ1 heteromeric NMDA receptor channel cDNAs in frog oocytes. Current responses are measured at -70 mV membrane potential in normal Ringer&#39;s solution. FIG. 1 (a) represent a current response to 100 μM NMDA +10 μM glycine (NMDA/Gly) of the ε4/ζ1 heteromeric channel, a current response to 10 μM L-glutamate+10 μM glycine (Glu/Gly) of the same and 1 mM Mg 2+   (Glu/Gly +Mg 2+ ) on a current response to Glu/Gly of the same, respectively. FIG. 1(b) represent effects of 500 μM D-2-amino-5-phosphonovalerate (APV) (Glu/Gly +APV) and 100 μM 7-chlorokynurenate (7 CK) (Glu/Gly +7 CK) on a current response of the ε4/ζ1 heteromeric channel to Glu/Gly, respectively. 
     FIG. 2 shows pharmacological properties of the ε4/ζ1 heteromeric NMDA receptor channel. Current responses are measured at -70 mV membrane potential in a Ba 2+  -Ringer&#39;s solution. In the figure, dose-response relationship for L-glutamate (∘) and glycine ( ) in the presences of 10 μM glycine and 10 μM L-glutamate (each point represents the mean fractional responses obtained from 4 oocytes) are shown. 
     FIG. 3 shows pharmacological properties of the ε4/ζ1 heteromeric NMDA receptor channel. Current responses are measured at -70 mV membrane potential in a Ba 2+  -Ringer&#39;s solution. In the figure, influences of APV and 7 CK on response to 4.7 μM L-glutamate +0.9 μM glycine (the concentrations of agonists were 10-folds the respective EC 50  values) are shown. 
     FIGS. 4(a) to 4(d) show a current response of the heteromeric NMDA receptor channel to 10 μM L-glutamate +10 μM L-glycine at -70 mV membrane potential in a frog standard Ringer&#39;s solution. In the figures, FIGS. 4(a), 4(b), 4(c) and 4(d) represent an ε2/ζ1 NMDA receptor channel, an ε2/ζ1-N598Q (a modified glutamate receptor shown in Sequence ID No. 9 of the sequence table) NMDA receptor channel, an ε2-N589Q (a modified glutamate receptor shown in Sequence ID No. 8 of the sequence table)/ζl NMDA receptor channel and an ε2-N589Q/ζ1-N598Q NMDA receptor channel, respectively. 
     FIGS. 5(a) to 5(d) show current-voltage relationships of wild type and mutant heteromeric channels in the presence of 1 mM Mg 2+   ( ) and in the absence thereof (∘). In the figures, FIGS. 5(a) , 5(b) , 5(c) and 5(d) represent an ε2/ζ1 NMDA receptor channel, an ε2/ζ1-N598Q NMDA receptor channel, an ε2-N589Q/ζ1 NMDA receptor channel and an ε2-N589Q/ζ1-N598Q NMDA receptor channel, respectively. 
     FIG. 6 shows the effects of Mg 2+   concentrations on the response at -70 mV membrane potential. In the figure, ◯,  ,  , □ and   represent an ε2/ζ1 NMDA receptor channel, an ε2/ζ1-N598Q NMDA receptor channel, an ε2-N589Q/ζ1 NMDA receptor channel, an ε2-N589Q/ζ1-N598Q NMDA receptor channel and an ε2/ζ1-ZAZ (a mutant glutamate receptor shown in Sequence ID No. 10 of the sequence table) NMDA receptor channel, respectively. 
     FIG. 7 shows suppression after repetitive application of 1 μM (+)-MK 801. In the figure, ◯,  ,  , □ and   represent a ε2/ζ1 NMDA receptor channel, an ε2/ζ1-N598Q MNDA receptor channel, an ε2-N589Q/ζ1 NMDA receptor channel, ε2-N589Q/ζ1-N598Q NMDA receptor channel and an ε2/ζ1-ZAZ NMDA receptor channel, respectively. 
     FIG. 8 shows the sensitivity to various concentrations of Zn 2+ . In the figure, ◯,  ,  , □ and   represent an ε2/ζ1 NMDA receptor channel, an ε2/ζ1-N598Q NMDA receptor channel, an ε2-N589Q/ζ1 NMDA receptor channel, an ε2-N589Q/ζ1-N598Q NMDA receptor channel and an ε2/ζ1-ZAZ NMDA receptor channel, respectively. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In the following, the present invention is explained in detail. 
     The glutamate receptor of the present invention has an amino acid sequence as shown in Sequence ID No. 1, 2, 3 or 4 of the sequence table. 
     The glutamate receptor shown in Sequence ID No. 1 of the sequence table (hereinafter sometimes referred to as &#34;ε1  subunit&#34;) is a protein comprising 1464 amino acids. As a gene encoding such a glutamate receptor, there may be mentioned, for example, a base sequence as shown in Sequence ID No. 5 of the sequence table. 
     The glutamate receptor shown in Sequence ID No. 2 of the sequence table (hereinafter sometimes referred to as &#34;ε2 subunit&#34;) is a protein comprising 1482 amino acids. As a gene encoding such a glutamate receptor, there may be mentioned, for example, a base sequence as shown in Sequence ID No. 6 of the sequence table. 
     The glutamate receptor shown in Sequence ID No. 3 of the sequence table (hereinafter sometimes referred to as &#34;ε3 subunit&#34;) is a protein comprising 1239 amino acids. As a gene encoding such a glutamate receptor, there may be mentioned, for example, a base sequence as shown in Sequence ID No. 7 of the sequence table. 
     The glutamate receptor shown in Sequence ID No. 4 of the sequence table (hereinafter sometimes referred to as &#34;ε4 subunit&#34;) is a protein comprising 1323 amino acids. This protein has a signal sequence, and a mature type thereof is considered to start from phenylalanine which is the 28th amino acid in Sequence ID No. 4 of the sequence table. As a gene encoding such a glutamate receptor, there may be mentioned, for example, a base sequence as shown in Sequence ID No. 16 of the sequence table. 
     The modified glutamate receptor of the present invention has an amino acid sequence as shown in Sequence ID No. 8, 9 or 10 of the sequence table. 
     The modified glutamate receptor shown in Sequence ID No. 8 of the sequence table (hereinafter sometimes referred to as &#34;ε2-N589Q&#34;) is a modified product in which asparagine which is the 589th from the N terminal end of the above ε2 subunit is replaced with glutamine. As a gene encoding such a modified product, there may be mentioned, for example, a base sequence as shown in Sequence ID No. 17 of the sequence table. 
     The modified glutamate receptor shown in Sequence ID No. 9 of the sequence table (hereinafter sometimes referred to as &#34;ζ1-N598Q&#34;) is a modified product in which asparagine which is the 598th from the N terminal end of a ζ1 subunit comprising 920 amino acids (&#34;FEBS Lett&#34;, 300 pp 39 to 45 (1992)) is replaced with glutamine. As a gene encoding such a modified product, there may be mentioned, for example, a base sequence as shown in Sequence ID No. 18 of the sequence table. 
     The modified glutamate receptor shown in Sequence ID No. 10 of the sequence table (hereinafter sometimes referred to as &#34;ζ1-ZAZ&#34;) is a modified product in which the 1726th to 1743rd base sequence of the above ζ1 subunit is changed to a base sequence as shown in Sequence ID No. 19 of the sequence table. 
     In the present invention, there may be included modified glutamate receptors in which amino acids or nucleic acids are partially removed, replaced or added within the range which does not impair activity as a glutamate receptor. 
     DNA fragments of the glutamate receptor of the present invention and the gene coding the same can be obtained by, for example, the following method. 
     First, cerebral tissues of a mammal, such as mouse, are homogenized in an aqueous solution containing guanidium thiocyanate or the like, and all RNAs are separated as precipitates by cesium chloride equilibrium density gradient centrifugation or sucrose density gradient centrifugation in accordance with the method of Chirgwin et al. (&#34;Biochemistry&#34;, 18, pp. 5294 to 5299 (1979)). 
     After separation, all RNAs are purified by extraction with phenol, precipitation with ethanol or the like, and the resulting RNAs are purified by oligo (dT) cellulose column chromatography to isolate poly (A)-containing mRNAs (poly A +   mRNAs) including mRNAs of the desired glutamate receptor, whereby an mRNA group can be obtained. 
     The mRNA group prepared as described above and, for example, primer DNA as described in &#34;FEBS Lett.&#34;, 272, pp 73 to 80 (1990) are hybridized, and by using a reverse transcriptase and T4 DNA polymerase, cDNAs with double strands are synthesized and prepared according to a conventional method. 
     Then, EcoRI linkers are added to both ends of cDNA chains. 
     The above cDNA chains are inserted into a position of EcoRI cleave site of a λ phage vector such as λgt10 to obtain a recombinant λ phage DNA group. 
     By using the recombinant λ phage DNA group obtained as described above and using an in vitro packaging kit such as commercially available Gigapack Gold (trade name, produced by Promega Co.) according to an operating manual, the so-called in vitro packaging was carried out to obtain λ phage particles having the recombinant λ phage DNAs. The λ phage particles obtained are increased by transforming host cells such as Escherichia coli according to a conventional method. 
     The clone group obtained is taken and collected on a nylon film or a nitrocellulose film such as Gene Screening Plus (trade name, produced by Du Pont), and protein is removed in the presence of an alkali. The λ phage DNAs including cDNAs are hybridized with a  32  P-labeled probe prepared from fragments of cDNA of a mouse glutamate receptor which has been already cloned (&#34;FEBS Lett.&#34;, 272, pp. 73 to 80 (1990)) and a DNA group of these cDNA clones, whereby clones having extremely high possibility of coding the desired glutamate receptor can be narrowed down to several clones. 
     The modified products are prepared by modifying the respective natural substances of the ε2 subunit and the ζ1 subunit by protein engineering or gene technology. Such a modification method is not particularly limited, and may be carried out specifically by the 2-step polymerase chain reaction (PCR) method by using a suitable synthetic oligonucleotide and DNA fragments derived from a plasmid of pBKSAε2 (&#34;Nature&#34;, 358, pp. 36 to 41 (1992)) or pBKSAζ1 (&#34;FEBS Lett.&#34;, 300, pp. 39 to 45 (1992)). 
     For these clones, activity test is conducted by using translation of Xenopus oocytes to obtain cDNA clones encoding the desired glutamate receptor. 
     The cDNA obtained as described above can be expressed in, for example, transient in vitro protein translation, specifically translation in Xenopus oocytes as described in &#34;Nature&#34;, 329, pp. 836 to 838 (1987), or in a host such as a CHO cell transformed by a plasmid for expressing a protein prepared by connecting such a cDNA to downstream of a promoter of a expression plasmid for animal cells. Then, according to a conventional method, the expressed protein is collected to obtain the glutamate receptor of the present invention. 
     EXAMPLES 
     The present invention is described in detail by referring to Examples, but it is not intended that the present invention be limited by these Examples. 
     Example 1 
     First, a cerebellum of ICR mouse was homogenized in an aqueous solution of guanidium thiocyanate, and then extracted, separated and purified according to the method of Chirgwin et al. (&#34;Biochemistry&#34;, 18, PP. 5294 to 5299 (1979)), and subjected to oligo (dT)-cellulose column chromatography according to the method of Aviv et al. (&#34;Proc. Natl. Acad. Sci. USA&#34;, 69, pp. 1408 to 1412 (1972)) to isolate poly (A)-containing mRNAs (poly A +   mRNAs) containing mRNAs of an NMDA type glutamate receptor. 
     By using a cDNA synthesizing kit produced by Bethesda Research Laboratories Co., cDNAs having double strand were prepared from the poly A +  mRNAs. Both ends of the cDNAs were blunt-ended with T4 DNA polymerase, and the cDNAs were methylated by using an EcoRI-methylase. Then, EcoRI linkers were added to both ends of the cDNAs by ligase to prepare cDNA fragments having an EcoRI restriction site at both ends by digestion with an EcoRI restriction enzyme. 
     The cDNAs obtained as described above were subjected to 1.5% agarose gel electrophoresis to select and collect cDNAs having a size of 0.5 Kb or more. 
     The obtained cDNA fragments having a size of 0.5 Kb or more were linked to λgt10 phage DNAs by ligase, and the cDNAs were inserted into an EcoRI cleaved site of λgt10 to constitute a λgt10 cDNA library according to a conventional method. By using the λgt10 cDNA library obtained and using an in vitro packaging kit Gigapack Gold (trade name, produced by Promega Co.) according to an operating manual, in vitro packaging was carried out to obtain λ phage particles having recombinant λ phage DNAs. The λ phage particles obtained were cultivated by transforming Escherichia coli of host cells according to a conventional method. 
     The clone group obtained was taken and collected on a nylon film or Gene Screening Plus (trade name, produced by Du Pont), and protein was removed in the presence of an alkali. Then, screening of the cDNA library was carried out. BamHI DNA fragments (1348 to 1946) and HincII DNA fragments (1279 to 2239) (previously cloned cDNA fragments of mouse glutamate receptors) of a pKCR30 plasmid (&#34;FEBS Lett.&#34;, 272, pp. 73 to 80 (1990)) were labeled with  32  p to prepare probes and the plaque hybridization was done in the presence of 30 % formaldehyde at 37° C. 
     According to the method described above, some cDNA clones encoding the novel glutamate receptor were obtained. Among them, cDNA fragments from a recombinant phage λ A19 having the ε1 subunit cDNAs which was considered to be a subunit of the NMDA type glutamate receptor ion channel were subcloned at an EcORI site of pBluescript IISK (-) plasmid (trade name) produced by Stratagene Co. to obtain a pGRA19 plasmid. By using the A19 cDNA fragments and other cDNA fragments (AT11) obtained by the same method as that of A19 cDNA fragments as probes, screening was carried out in the presence of 30% formamide at 45° C. to obtain ε1 subunit cDNA clones. The cDNA-inserted fragments obtained from the total 7 recombinant phages were inserted into an EcoRI site of a pBKSA plasmid, a plasmid obtained by inserting: 
     5&#39;-CCAGGTGCA-3&#39; 
     3&#39;-ACGTGGTCC-5&#39;(Sequence ID No. 11 in the sequence table) into a PstI site of pBluescript IIKS (+) (trade name, produced by Stratagene Co.) in the same direction as that of a T3 promoter) to prepare plasmids pAT4, pAT11, pAT12, pAT19, pAT20, pAT201 and pAT202. 
     All base sequences of A19 (the -327th to 3181st of base pair) and AT19 (the 2859th to 5470th of base pair) were determined according to the dideoxy chain termination method of Sanger et al. (&#34;Proc. Natl. Acad. Sci. USA&#34;, 74, pp. 5463 to 5467 (1977)). Base pair numbers were given from the 5&#39; end to the 3&#39; end, and negative numbers were given to base pairs before a codon corresponding to the amino terminal end of the ε1 subunit. The partial DNA base sequences: base sequences of clone AT4 (the 2550th to 3432nd of base pair), ATll (the 2550th to 3622nd of base pair), AT12 (the 2404th to 3622nd of base pair), AT20 (the 2550th to 3177th of base pair), AT201 (the 3526th to 4401st of base pair) and AT202 (the 3409th to 4371 st of base pair) were completely the same with the corresponding base sequences of A19 and AT19. The base sequences and the amino acid sequences were analyzed by GENETYX Software (SDC). As a result, the amino acid sequence of the ε1 subunit was a sequence shown in Sequence ID No. 1 of the sequence table, and the base sequence encoding the ε1 subunit was a sequence shown in Sequence ID No. 5 of the sequence table. 
     The ends of EcoRI DNA fragments with a size of 3.5 Kb derived from the pGRA19 plasmid were bluntended by using T4 DNA polymerase and inserted into a SmaI site of a pSP64AX plasmid (&#34;FEBS Lett.&#34;, 259, pp. 37 to 42 (1989)) in the same direction with respect to an SP6 promoter to obtain a pSPA19 plasmid. SalI/HindIII DNA fragments with a size of 3.0 Kb derived from the pSPA19 plasmid, HindIII/NcoI DNA fragments with a size of 0.36 Kb derived from the same and NcoI/SalI DNA fragments with a size of 5.4 Kb derived from the pAT19 plasmid were linked by ligase to prepare a pBKSA ε1. 
     Then, by using the pBKSA ε1 cut by NotI as a template and using T3 RNA polymerase produced by BRL Co., ε1-specific mRNAs were synthesized in vitro. Transcription was carried out in a solution containing ATP, TTP and CTP at a concentration of 0.5 mM, respectively and 0.1 mM GTP in the presence of 0.5 mM dinucleotide 7mGpppG having a cap structure (in which 2 Gs were linked at 5&#39; and 7-site of one guanine was methylated, produced by P-L Biochemicals Co.). One or both of ε1 subunit-specific mRNAs and ζ1.NMDA type glutamate receptor subunit-specific mRNAs (mRNAs derived from mice, coding an amino acid sequence different in the 213rd (Glu→Asp) and the 460th (Ile→Val) from the N terminal end from the amino acid sequence which is coded by cDNA.-NMDA R1 of a rat-NMDA type glutamate receptor cloned by Nakanishi et al. (&#34;Nature&#34;, 354, pp. 31 to 37 (1991))) were injected into Xenopus oocytes. 
     The oocytes used were obtained from mature female Xenopus and separated into one oocyte in a Barth medium by using sharp tweezers and scissors. The concentration of the mRNAs was 0.1 μg/μl and 10 μl thereof was injected into about 100 oocytes in an amount of 50 to 100 nl per one oocyte. The mRNAs were injected under a microscope by using a capillary and a micromanipulator. After the injection, the oocytes were incubated at 19° C. for one day in a Barth medium containing 0.1 mg/ml of gentamicin (&#34;The Control of Gene Expression in Animal Development, Clarendon, Oxford (1974)). Then, the oocytes were allowed to stand in 1 mg/ml of collagenase at room temperature for 1 hour, and then extracellular skins were removed under a microscope by using sharp tweezers. These oocytes were returned to the Barth medium containing 0.1 mg/ml of gentamicin, incubated again at 19° C. for one day and then used for an electrophysiological test. 
     The electrophysiological test was carried out by a conventional micropipet voltage clamp method. Oocytes generally have a membrane potential of about -30 to -40 mV. First, while a frog standard Ringer&#39;s solution (115 mM NaCl, 2.5 mM KCl, 1.8 mM CaCl 2  and 10 mM HEPES-NaOH (pH: 7.2)) was flown in a chamber, 2 glass microelectrodes charged with 3M KCl were stuck in the oocytes, and the membrane potential was fixed to -70 mV. In these oocytes, an agonist (NMDA) is linked to a glutamate receptor expressed on a cell membrane and an ion channel is opened, the oocytes have an action of returning membrane potential to an original value, whereby inflow and outflow of ions are caused. In the present experiment system, flow of these ions were detected, and opening and closing of the ion channel were observed. 
     The ε1 subunit-specific mRNAs synthesized from the cloned cDNAs in vitro were injected into the Xenopus oocytes. The injected oocytes did not show any reaction to 10 μM L-glutamate and 100 μM NMDA even in the presence of 10 μM glycine which was an essential activating factor of the NMDA type receptor channel. However, when the ε1 subunit-specific mRNAs and the ζ1.NMDA type receptor subunit-specific mRNAs were injected simultaneously, significant reaction was observed. In a frog standard Ringer&#39;s solution, the inward current at a membrane potential of -70 mV was 364±62 nA (average±standard deviation, n=7) with respect to 10 μM L-glutamate and 10 μM glycine and 175±30 nA (n=7) with respect to 100 μM NMDA and 10 μM glycine. The current amplitude was extremely larger than that of the case where only the ζ1.NMDA type receptor subunit-specific mRNAs were injected to the oocytes (8±2 nA (n= 7) with respect to 10 μM L-glutamate and 10 μM glycine and 6±1 nA (n=7) with respect to 100 μM NMDA and 10 μM glycine). In a Ba 2+   Ringer&#39;s solution (in which Ca 2+   in the standard Ringer&#39;s solution described above was replaced, with Ba 2+ ), the current amplitudes with respect to 10 μM L-glutamate and 10 μM glycine, and 100 μM NMDA and 10 μM glycine were 84±4 nA and 57±3 nA (n=7), respectively, when the ε1 and ζ1 subunits were expressed at the same time, and 2±0.4 nA and 1±0.2 nA (n=7), respectively, when only the ζ1 subunit was expressed. From the results described above, it was concluded that the ε1 protein was a subunit of the NMDA type glutamate receptor ion channel. 
     Example 2 
     Using the 1388 base pair KpnI/HindIII DNA fragments derived from the pGRA 19 plasmid obtained in Example 1 as probes, the mouse brain cDNA library obtained from λgt10 in Example 1 was screened under mild conditions to obtain ε2 subunit cDNA clone U9 and two ε3 subunits, cDNA clone U20 and He49. The cDNA fragments were inserted into the EcoRI site of pBluescript IISK (-) (Stratagene) to obtain pGRU9, pGRU20 and pGRHe49 plasmids. By using 445 base pair DraIII/EcoRI derived from pGRU9 plasmid, 2847 base pair HindIII/EcoRI fragments, 1615 base pair EcoRI fragments derived from pGRHe49 and 314 base pair HindIII/EcoRI fragments derived from pGRUN3 as probes, screening was performed under severe conditions to isolate further some clones (as the ε2 subunit cDNA clones, U4, U2, U7, U8, U11, U16, U17 and U22, and as the ε3 subunit cDNA clones, UN6, UN3 and UT5). These inserted cDNAs in recombinant phage were inserted into the EcoRI site of the aforesaid pBSKA plasmid. 
     All base sequences of the ε2 subunit cDNA clones U9 (the -417th to 3218th base pair) and U4 (the 1117th to 4454th base pair) were determined according to the dideoxy chain termination method as described above. Base sequences of clones U2 (the 4319th to 4396th base pair), U7 (the -417th to 3616th base pair), U8 (the 4319th to 4396th base pair), U11 (the 4319th to 4396th base pair), U16 (the -205th to -57th base pair), U17 (the -205th to -57th base pair) and U22 (the 1449th to 4365th base pair) were completely coincident with the corresponding base sequences of U9 and U4. 
     In the ε3 subunit cDNA clones UN6 (the -232nd to 3283th base pair), He49 (the -101st to 1504th base pair), . UN3 (the 52nd to 4039th base pair), U20 (the 347th to 2016th base pair) and UT5 (the 2487th to 4071st base pair), base sequences were completely identical therewith except for the 711st (T or C), 1485th (A or G), 1494th (A or G) and 2721st (T or C) . Base pair numbers were started from a codon coding an amino terminal end amino acid of a mature type subunits and given a direction from the 5&#39; end to the 3&#39; end. The base sequences and the amino acid sequences were analyzed by GENETYX Software. As a result, the amino acid sequence of the mature type ε2 subunit was a sequence shown in Sequence ID No. 2 of the sequence table, and the base sequence coding the ε2 subunit was a sequence shown in Sequence ID No. 6 of the sequence table. Also, the amino acid sequence of the mature type ε3 subunit was a sequence shown in Sequence ID No. 3 of the sequence table, and the base sequence coding the ε2 subunit was a sequence shown in Sequence ID No. 7 of the sequence table. 
     EcoRI/PvuI DNA fragments with a size of 3.5 Kb derived from the pGRU9 and PvuI/EcoRI DNA fragments with a size of 1.6 Kb derived from the pGRU4 (U4 clone derivative) were linked to EcoRI DNA fragments with a size of 3.0 Kb derived from the pBKSA by ligase to obtain pBKSA ε2 plasmids. SalI DNA fragments with a size of 864 bp derived from the pGRUN6 (UN6 clone derivative) and SalI DNA fragments having a size of 6.4 Kb derived from the pGRUN3 (UN3 clone derivative) were linked by ligase to obtain pBKSA ε3. 
     Then, by using the pBKSA ε2 cut by NotI and the pBKSA ε3 cut by XbaI as molds and using T3 RNA polymerase produced by BRL Co., ε2-specific mRNAs and ε3-specific mRNAs were synthesized in vitro. Transcription was carried out in the same manner as in Example 1. 
     The εl (not more than 22 ng/egg) subunit-specific mRNAs obtained in Example 1, the ε2 (not more than 19 ng/egg) subunit-specific mRNAs, the ε3 (not more than 16 ng/egg) subunit-specific mRNAs and ξ1 (not more than 13 ng/egg) NMDA type glutamate receptor subunit-specific mRNAs described above were used singly or in combination, they were injected into the Xenopus oocytes in the same manner as in Example 1. 10 μl of the mRNA aqueous solution was injected into about 100 oocytes in an amount of 50 to 100 nl per one oocyte. The oocytes after the injection were treated in the same manner as in Example 1 and then used for an electrophysiological test. 
     The ε2 or ε3 subunit-specific mRNAs synthesized from the cloned cDNAs in vitro were injected into the Xenopus oocytes with the ξ1 subunit-specific mRNAs. In a frog standard Ringer&#39;s solution, the inward current of ε2 and ξ1 subunits expressing oocytes at a membrane potential of -70 mV was 667±187 nA (average±standard deviation) with respect to 10 μM L-glutamate and 10 μM glycine and 546±172 nA (N=5) with respect to 100 μM NMDA and 10 μM glycine, and in ε3 and ξ1 subunits expressing oocytes, it was 191±67 nA with respect to 10 μM L-glutamate and 10 μM glycine and 89±22 nA (n=7) with respect to 100 μM NMDA and 10 μM glycine. The current amplitude was extremely larger than that of the case where only the ζ1.NMDA type receptor subunit-specific mRNAs were injected to the oocytes (11±l nA, n=12, with respect to 10 μM L-glutamate and 10 μM glycine and 9±2 nA, n=7, with respect to 100 μM NMDA and 10 μM glycine). No response was observed in the oocytes to which the ε2 or ε3 subunit-specific mRNAs were injected singly (&lt;1 nA). In the oocytes in which the ε2 and ε1 subunits, or the ε3 and ξ1 subunits were expressed, responses to 100 μM kainate and to 100 μM AMPA were less than the measurement limit. 
     The ε2/ξl heteromeric channel showed a response to 10 μM L-glutamate and 10 μM glycine and to 100 μM L-aspartic acid alone. On the other hand, the ε3/ξ1 heteromeric channel showed a response only to 10 μM glycine. The response to 10 μM L-glutamate or 10 μM glycine alone disappeared by 100 μM of D-2-amino-5-phosphonovalerate (APV) which is a specific competitive antagonist of the NMDA receptors and 30 μM 7-chlorokynurenate (7 CK) which had been reported as a competitive antagonist to glycine control site of the NMDA receptors. The response to 10 μM L-glutamate and 10 μM glycine can be suppressed by these competitive antagonists, non-competitive antagonists, 100 μM Mg 2+ , 100 μM Zn 2+ , or 1 μM (+)-MK-801 (an open channel blocker of the NMDA type receptor channel). The effect of the channel blocker to the ε 3/ξ1 channel is weaker than those to the ε1/ξ1 and ε2/ξ1 channels. The ε2/ξ1 and ε3/ξ1 channels each showed an inward current in a Na +   and K +  -free Ringer&#39;s solution containing 20 mM Ca 2+   (Ca 2+  -Ringer&#39;s solution), but in a control Na +   and K +  -free Ringer&#39;s solution, a slightly outward current could be observed. This shows that the heteromeric channels permeate Ca 2+ . According to the above, it can be concluded that ε2 and ε3 proteins are subunits of the NMDA receptor channels. 
     In order to minimize effects of a secondary activated Ca 2+   dependent Cl- current on a dose-reaction curve to L-glutamate and glycine of the heteromeric NMDA receptor channel, it was examined in a Ba 2+  Ringer&#39;s solution. EC 50  values to ε1/ξ1, ε2/ξ1 and ε3/ξ1 channels were each 1.7 μM, 0.8 μM and 0.7 μM and those to glycine were each 2.1 μM, 0.3 μM and 0.2 μM. Hill coefficient value was 1.2 to 2.2. Effects of the competitive antagonist were examined with 10-fold concentration of the antagonist concentration used when examining the EC 50  values. The strength in sensitivity to APV was in the order of ε1/ξ1&gt;ε2/ξ1&gt;ε3/ξ1 and that to 7 CK was in the order of ε3/ξ1&gt;ε2/ξ1&gt;ε1/ξ1. 0.1 mM and 1 mM of Mg 2+   acted on the ε/ξ heteromeric NMDA channels voltage-dependently and repressively. However, clear difference can be found between these heteromeric channels. The ε3/ξ1 channel showed resistance to Mg 2+   inhibition, and showed activity at membrane potentials of -70 mV and -100 mV in the presence of 1 mM Mg 2+ . On the other hand, under the same conditions, the ε1/ξ1 and ε2/ξ1 channels were strongly repressed. These results suggest that functionally different NMDA receptor channels were formed according to the combination of the subunits. 
     Example 3 
     Amino acid sequences highly preserved of mouse NMDA type receptor subunits, i.e. an oligo nucleotide sense primer, 5&#39;-TGGAAT/CGGA/TATGATG/A/T/CGGG/A/T/CGA-3&#39; (sequence ID No. 14 of the sequence table) corresponding to WNGMI/MGE (sequence ID No. 12 of the sequence table) existing at an upstream end of the membrane spanning region M1 and an oligo nucleotide antisense primer, 5&#39;-GCG/A/TGCT/CAG/AG/ATTG/A/TGCG/A/T/CG/ATG/ATA-3&#39; (sequence ID No. 15 of the sequence table) corresponding to YTANLAA (sequence ID No. 13 of the sequence table) in M3 were synthesized. Polymerase chain reaction (PCR) was carried out using the double strand cDNA as a template and the above synthesized oligo nucleotides as primers. PCR was carried out 30 cycles in total in which, after incubation at 94° C. for 3 minutes in 50 μl of the reaction solution containing 10 mM of Tris-HCl (pH 8.3), 50 mM of KCl, 1.5 mM of MgCl  2 , 0.001% of gelatin, 20 ng or less of a mouse cerebrum cDNA, 2 μM of the respective primers, 200 μM of 4 kinds of deoxynucleotide triphosphate and 4 units of Taq polymerase; 94° C. for 1 minute; 50° C. for 1 minute; and 72° C. for 1.5 minutes were as one cycle. 
     After treating the PCR products by T4 DNA polymerase, they were inserted into the HincII site of pBluescript IISK (+) plasmid (Stratagene). 
     Subsequently, according to screening and base sequence determination, ε4 subunit cDNA clone was identified. The thus determined base sequence of the ε4 subunit cDNA and amino acid sequence expected therefrom were each shown in sequence ID No. 4 of the sequence table. 
     In the same manner as in Example 1 except for using a mouse cerebrum and cerebellum, cDNA library obtained from λgt10 was screened by using the ε4 subunit cDNA as a probe to obtain several clones which code the ε4 subunit. These phage-derived cDNA fragments were inserted into EcoRI site of the pBluescript IISK (-) plasmid (Stratagene) or pBKSA plasmid. 
     Base sequences of both chains of cDNA clones SE11 (from the -33rd to 2550th at the 5&#39; end upstream in Sequence ID No. 16 of the sequence table) and SE4 (from the 2515th to +83st at the 3&#39; end downstream in Sequence ID No. 16 of the sequence table) were determined according to the dideoxy chain termination method using various primers synthesized by the DNA autosysnthesizer (available from Applied Biosystem Co.). Partial base sequences of respective clones, SE1 (the -33rd of the 5&#39; upstream region to 2001st of the sequence No. ID No. 16 in the sequence table), TSEE6 (the 1716th to 2291st of the sequence No. ID No. 16 in the sequence table) and K1 (the 2013rd to +83rd of the 3&#39; down stream region of the sequence No. ID No. 16 in the sequence table) were completely identical with the sequences of the cDNA clones SE4 and SE11. The base sequences and the amino acid sequences were analyzed by GENETYX Software (SDC). 
     All coding area (the 1st to +3rd of the 3&#39; down stream region in the Sequence ID No. 16 of the sequence table, i.e. until stop codon)) of the ε4 subunit cDNA was inserted by pSP35T plasmid and PCR method according to the PCR method between the NcoI and XbaI portions of the pSP35 plasmid (Cell, 66, pp. 257 to 270 (1991)) to obtain pSPGR ε4 plasmid. 
     Then, by using the pSPGR ε4 plasmid cut by EcoRI as a template and using SP6 RNA polymerase, ε4-specific mRNAs were synthesized in vitro. Transcription was carried out in the same manner as in Example 1. 
     The ε4 subunit-specific mRNAs (not more than 16 ng/egg) synthesized in vitro from a cloned cDNA and ξ1.NMDA type glutamate receptor subunit-specific mRNAs (not more than 13 ng/egg) described above were used singly or in combination, they were injected into the Xenopus oocytes in the same manner as in Example 1. 10 μl of the mRNA aqueous solution was injected into about 100 oocytes in an amount of 50 to 100 nl per one oocyte. The oocytes after the injection were treated in the same manner as in Example 1 and then used for an electrophysiological test. 
     In a frog standard Ringer&#39;s solution, the inward current of ε4 and ξ1 subunits expressing oocytes at -70 mV membrane potential was 70±9 nA (mean±standard deviation, n=13) with respect to 10 μM L-glutamate and 10 μM glycine and 68±13 nA (n=8) with respect to 100 μM NMDA and 10 μM glycine (FIG. 1(a)). The current amplitude was extremely larger than that of the case where only the ζ1.NMDA type receptor subunit-specific mRNAs were injected to the oocytes (17±1 nA, n=10, with respect to 10 μM L-glutamate and 10 μM glycine and 13±2 nA, n=7, with respect to 100 μM NMDA and 10 μM glycine). The response of the heteromeric channel comprising the ε4/ξ1 subunit to 10 μM L-glutamate and 10 μM glycine was suppressed by 500 μM APV which is a specific competitive antagonist of the NMDA receptors or 100 μM of 7 CK which had been reported as a competitive antagonist to glycine control site of the NMDA receptors (FIG. 2 and FIG. 3). According to the above, it can be concluded that ε4 protein is a subunit of the NMDA receptor channels. 
     Since the suppressive effect of the NMDA receptor competitive antagonist to the e4 subunit was relatively small, the pharmacological characteristics of the ε4/ξ1 heteromeric channel were quantitatively examined by using a Ba 2+   Ringer&#39;s solution. The EC 50  values to L-glutamate or glycine obtained from the dose-reaction curve were 0.4 μM and 0.09 μM, respectively, and the Hill coefficients were 1.4 and 1.2, respectively (FIG. 2). 
     Apparent affinity of the ε4/ξ1 heteromeric NMDA receptor channel to an agonist was stronger than those of the ε1/ξ1, ε2/ξ1 and ε3/ξ1 heteromeric channels. The strengths in affinity to L-glutamate and glycine were in the order of ε4/ξ1&gt;ε3/ξ1&gt;ε2/ξ1. The effects of APV and 7 CK were examined by 10-fold concentration of the EC 50  value (FIG. 3). Activities of the ε4/ξ1 channel were only decreased by 31% in 100 μM APV and 34% in 3 μM 7 CK. The degree of inhibition was smaller than those of the other ε/ξ channels observed under the same conditions. The sensitivities to APV were ε1/ξ1&gt;ε2/ξ1&gt;ε3/ξ1&gt;ε4/ξ1,and those to 7 CK were ε3/ξ1&gt;ε2/ξ1&gt;ε1/ξ1=ε4/ξ1. According to the above, the ε4/ξ1 heteromeric channel was characterized that it has strong affinity to an agonist and weak sensitivity to a competitive antagonist. 
     Example 4 
     By using the mouse brain cDNA library obtained from λgt10 in Example 1, screening of the cDNA library was carried out. Then, KpnI/HindIII DNA fragments (1388 base pairs: previously cloned cDNA fragments of mouse glutamate receptors) of a pGRA19 plasmid obtained in Example 1 and mouse α1 and α2 subunit cDNAs (FEBS, Lett., 272, pp. 73 to 80 (1990)) were labeled with  32  p and plaque hybridization was done in the presence of 30 % formaldehyde at 37° C. 
     Partially specific modification was carried out by using a suitable synthesized oligo nucleotide and pBKSA ε2 obtained in Example 2 and pBKSA ξ1 (FEBS, Lett., 300, pp. 39 to 45 (1992)) plasmid-derived DNA fragments according to the two-step polymerase chain reaction (PCR) method. The resulting modified 353 base pairs Cfr101SphIand 322 base pairs FspI/BlnI DNA fragments obtained by amplifying according to the PCR were substituted for the corresponding segments of pBKSA ε2 and pBKSA ξ1, respectively. The nucleotide sequences of the constructed plasmids are different from those of the original plasmids as follows. 
     pBKSA ε2-N589Q (in the ε2 subunit described in the sequence ID No. 2 and No. 6 of the sequence table, asparagine which is an amino acid at the 589th from the N-terminal is modified to glutamine, A which is the 1765th base sequence to C and C which is the 1767th base sequence to G, respectively. The amino acid sequence and base sequence are shown in sequence ID No. 8 and No. 17 of the sequence table, respectively.) 
     pBKSA ζ1-N598Q (in the ζ1 subunit described in &#34;FEBS Lett.&#34;, 300, pp. 39 to 45 (1992), asparagine which is an amino acid at the 598th from the N-terminal is modified to glutamine, A which is the 1792nd base sequence to C and C which is the 1794th base sequence to G, respectively. The amino acid sequence and base sequence are shown in sequence ID No. 9 and No. 18 of the sequence table, respectively.) 
     pBKSA ζ1-ZAZ (in the ζ1 subunit described in &#34;FEBS Lett.&#34;, 300, pp. 39 to 45 (1992), the 1726th to 1743rd base sequence is modified to ACCAGTGACCAGTCAAAT. The amino acid sequence and base sequence are shown in sequence ID No. 10 and No. 19 of the sequence table, respectively.) 
     Next, by using the pBKSA ε2 and pBKSA ζ1 plasmids and derivatives thereof cut by suitable restriction enzymes as template and using T3 RNA polymerase produced by BRL Co., ε2, ζ1 and their derivatives-specific mRNAs were synthesized in vitro, respectively. Transcription was carried out in the same manner as in Example 1. 
     In order to examine influence on the modified ion channels, the wild type or modified ε2 (not more than 19 ng/oocyte) subunit-specific mRNAs and the wild type or modified ζ1 (not more than 13 ng/oocyte) subunit-specific mRNAs were injected singly or in combination into the Xenopus oocytes in the same manner as in Example 1. 10 μl of the mRNA aqueous solution was injected into about 100 oocytes in an amount of 50 to 100 nl per one oocyte. The oocytes after the injection were treated in the same manner as in Example 1 and then used for an electrophysiological test. 
     FIGS. 4(a) to 4(d) show a current response of the heteromeric NMDA receptor channel to 10 μM L-glutamate and 10 μM L-glycine at -70 mV membrane potential in a frog standard Ringer&#39;s solution. The wild type ε2/ζ1 NMDA receptor channel was strongly inhibited by 1 mM Mg 2+ , 100 μM Zn 2+   and 1 μM (+)-MK-801. MK-801. To the contrary, the modified ε2/ζ1-N598Q channel showed a great current response even in the presence of 1 mM Mg 2+ . However, the response was suppressed effectively by 100 μM Zn 2+   and 1 μM (+)-MK-801. Similarly, in the ε2-N589Q modified product, sensitivity to Mg 2+   inhibition was decreased without changing sensitivity to Zn 2+ . To the ε2/ζ1 and ε2/ζ1-N598Q channels, the ε2-N589Q/ζ1 channel showed a great current response after repetitive application of (+)-MK-801. The heteromeric ε2-N589Q/ζ1-N598Q channel showed strong resistance to Mg 2+   and (+)-MK-801 inhibitions, but still had sensitivity to Zn 2+ . 
     In order to minimize effects of a secondary activated Ca 2+   dependent Cl- current, influences of these modified products on Mg 2+  inhibition were measured more quantitatively in a Ba 2+   Ringer&#39;s solution. FIGS. 5(a) to 5(d) each represent current-voltage curves of the wild type and modified heteromeric channels in the presence of 1 mM Mg 2+   () and in the absence thereof (∘). As observed in the case of the NMDA type receptor channel, Mg 2+   inhibited a current response to the wild type ε2/ζ1 channel depending on voltage (FIG. 5(a). Sensitivity of the heteromeric channel to Mg 2+   was decreased greatly by modification of an asparagine residue(s) of one or both of the subunits, and the modified channel retained activity even at -100 mV membrane potential (FIGS. 5(b) to 5(d). Inhibition degrees at various Mg 2+   concentrations were compared at -70 mV membrane potential (FIG. 6). Activities of the wild type ε2/ζ1 channel and the ε2/ζ1-ZAZ channel were decreased by 50% by not more than 20 μM Mg 2+   and suppressed almost completely by not more than 1 mM Mg 2+   which is a physiological concentration. On the other hand, about 100-fold concentration of Mg 2+   was required to depress the modified ε2/ζ1-N598Q, ε2-N589Q/ζ1 and ε2-589Q/ζ1-N598Q channels. 
     By administering 1 μM (+)-MK-801 which is an open channel blocker of the NMDA type receptor channel repeatedly, the wild type ε2/ζ1 channel was suppressed almost completely (FIG. 7). Similarly, activities of the modified ε2/ζ1-N598Q and ε2-N589Q/ζ1 channels were strongly inhibited by continuous application of (+)-MK-801. On the other hand, the modified ε2-N589Q/ζ1-N598Q channel retained high activities even after (+)-MK-801 was applied three times repeatedly. 
     Effect of Zn 2+   which had been reported to induce non-competitive inhibition to the NMDA type receptor not depending on voltage was examined. Sensitivity of the heteromeric channel to 10 μM Zn 2+  was decreased a little by modification. However, the modified channel was strongly inhibited by 100 μM Zn 2+   (FIG. 8). 
     These results suggested that the NMDA type receptor channels having different functions were formed by modification of the subunits. 
     The NMDA type glutamate receptor genes of the present invention are not only useful for clarifying nervous information transmission at a synapse, appearance of synapse plasticity which is basically required for memory and learning and neuronal cell death caused by a disease such as cerebral ischemia and epilepsy and understanding a transmission mechanism of nervous information in a center, a cerebral structure of higher order and a disease of the brain, but are also useful for therapy of genetic diseases and preparation of novel pharmaceuticals (e.g. screening of an agonist or an antagonist). 
     
         __________________________________________________________________________SEQUENCE LISTING(1) GENERAL INFORMATION:(iii) NUMBER OF SEQUENCES: 19(2) INFORMATION FOR SEQ ID NO: 1:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1464 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE: (A) ORGANISM: mouse(F) TISSUE TYPE: cerebellum(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:1: FROM 1 to 1464(xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:MetGlyArgLeuGlyTyrTrpThrLeu1 5LeuValLeuProAlaLeuLeuValTrp1015HisGlyProAlaGlnAsnAlaAlaAla2025GluLysGlyThrProAla LeuAsnIle3035AlaValLeuLeuGlyHisSerHisAsp4045ValThrGluArgGluLeuArgAsnLeu 50TrpGlyProGluGlnAlaThrGlyLeu5560ProLeuAspValAsnValValAlaLeu6570LeuMetAsnArg ThrAspProLysSer7580LeuIleThrHisValCysAspLeuMet8590SerGlyAlaArgIleHisGlyLeuV al95PheGlyAspAspThrAspGlnGluAla100105ValAlaGlnMetLeuAspPheIleSer110115SerGln ThrPheIleProIleLeuGly120125IleHisGlyGlyAlaSerMetIleMet130135AlaAspLysAspProTh rSerThrPhe140PheGlnPheGlyAlaSerIleGlnGln145150GlnAlaThrValMetLeuLysIleMet155 160GlnAspTyrAspTrpHisValPheSer165170LeuValThrThrIlePheProGlyTyr175180ArgAspPh eIleSerPheIleLysThr185ThrValAspAsnSerPheValGlyTrp190195AspMetGlnAsnValIleThrLeuAsp200 205ThrSerPheGluAspAlaLysThrGln210215ValGlnLeuLysLysIleHisSerSer220225ValIleLeuLeuTyrCysSerLysAsp230GluAlaValLeuIleLeuSerGluAla235240ArgSerLeuGlyLeuThrGlyTyrAsp 245250PhePheTrpIleValProSerLeuVal255260SerGlyAsnThrGluLeuIleProLys265 270GluPheProSerGlyLeuIleSerVal275SerTyrAspAspTrpAspTyrSerLeu280285GluAlaArgValArgAspG lyLeuGly290295IleLeuThrThrAlaAlaSerSerMet300305LeuGluLysPheSerTyrIleProGlu 310315AlaLysAlaSerCysTyrGlyGlnThr320GluLysProGluThrProLeuHisThr325330LeuHisGlnP heMetValAsnValThr335340TrpAspGlyLysAspLeuSerPheThr345350GluGluGlyTyrGlnValHisProArg 355360LeuValValIleValLeuAsnLysAsp365ArgGluTrpGluLysValGlyLysTrp370375G luAsnGlnThrLeuArgLeuArgHis380385AlaValTrpProArgTyrLysSerPhe390395SerAspCysGluProAsp AspAsnHis400405LeuSerIleValThrLeuGluGluAla410ProPheValIleValGluAspIleAsp415 420ProLeuThrGluThrCysValArgAsn425430ThrValProCysArgLysPheValLys435440IleAsnAsn SerThrAsnGluGlyMet445450AsnValLysLysCysCysLysGlyPhe455CysIleAspIleLeuLysLysLeuSer460 465ArgThrValLysPheThrTyrAspLeu470475TyrLeuValThrAsnGlyLysHisGly480485 LysLysValAsnAsnValTrpAsnGly490495MetIleGlyGluValValTyrGlnArg500AlaValMetAlaValGlySer LeuThr505510IleAsnGluGluArgSerGluValVal515520AspPheSerValProPheValGluThr525 530GlyIleSerValMetValSerArgSer535540AsnGlyThrValSerProSerAlaPhe545LeuGluProPhe SerAlaSerValTrp550555ValMetMetPheValMetLeuLeuIle560565ValSerAlaIleAlaValPheValPhe57 0575GluTyrPheSerProValGlyTyrAsn580585ArgAsnLeuAlaLysGlyLysAlaPro590His GlyProSerPheThrIleGlyLys595600AlaIleTrpLeuLeuTrpGlyLeuVal605610PheAsnAsnSerValProValGlnAsn615620ProLysGlyThrThrSerLysIleMet625630ValSerValTrpAlaPhePheAlaVal 635IlePheLeuAlaSerTyrThrAlaAsn640645LeuAlaAlaPheMetIleGlnGluGlu650655PheValAspGlnValThr GlyLeuSer660665AspLysLysPheGlnArgProHisAsp670675TyrSerProProPheArgPheGlyThr 680ValProAsnGlySerThrGluArgAsn685690IleArgAsnAsnTyrProTyrMetHis695700GlnTyrMet ThrLysPheAsnGlnArg705710GlyValGluAspAlaLeuValSerLeu715720LysThrGlyLysLeuAspAl aPheIle725TyrAspAlaAlaValLeuAsnTyrLys730735AlaGlyArgAspGluGlyCysLysLeu740745ValThrIleGlySerGlyTyrIlePhe750755AlaThrThrGlyTyrGlyIleAlaLeu760765GlnLysGlySe rProTrpLysArgGln770IleAspLeuAlaLeuLeuGlnPheVal775780GlyAspGlyGluMetGluGluLeuGlu785 790ThrLeuTrpLeuThrGlyIleCysHis795800AsnGluLysAsnGluValMetSerSer805810Gl nLeuAspIleAspAsnMetAlaGly815ValPheTyrMetLeuAlaAlaAlaMet820825AlaLeuSerLeuIleThrPheIleTrp 830835GluHisLeuPheTyrTrpLysLeuArg840845PheCysPheThrGlyValCysSerAsp850 855ArgProGlyLeuLeuPheSerIleSer860ArgGlyIleTyrSerCysIleHisGly865870ValHisIleGluGluLysLysL ysSer875880ProAspPheAsnLeuThrGlySerGln885890SerAsnMetLeuLysLeuLeuArgSer895 900AlaLysAsnIleSerAsnMetSerAsn905MetAsnSerSerArgMetAspSerPro910915LysArgAlaAlaA spPheIleGlnArg920925GlySerLeuIleValAspMetValSer930935AspLysGlyAsnLeuIleTyrSerAsp 940945AsnArgSerPheGlnGlyLysAspSer950IlePheGlyGluAsnMetAsnGluLeu955960GlnT hrPheValAlaAsnArgHisLys965970AspSerLeuSerAsnTyrValPheGln975980GlyGlnHisProLeuThrLeu AsnGlu985990SerAsnProAsnThrValGluValAla995ValSerThrGluSerLysGlyAsnSer1000 1005ArgProArgGlnLeuTrpLysLysSer10101015MetGluSerLeuArgGlnAspSerLeu10201025AsnGlnAsnPro ValSerGlnArgAsp10301035GluLysThrAlaGluAsnArgThrHis1040SerLeuLysSerProArgTyrLeuPro1045 1050GluGluValAlaHisSerAspIleSer10551060GluThrSerSerArgAlaThrCysHis10651070ArgGluProAspAsnAsnLysAsnHis10751080LysThrLysAspAsnPheLysArgSer1085MetAlaSerLysTyrPro LysAspCys10901095SerGluValGluArgThrTyrValLys11001105ThrLysAlaSerSerProArgAspLys1110 1115IleTyrThrIleAspGlyGluLysGlu11201125ProSerPheHisLeuAspProProGln1130PheIle GluAsnIleValLeuProGlu11351140AsnValAspPheProAspThrTyrGln11451150AspHisAsnGluAsnPheArgLysGly 11551160AspSerThrLeuProMetAsnArgAsn11651170ProLeuHisAsnGluAspGlyLeuPro 1175AsnAsnAspGlnTyrLysLeuTyrAla11801185LysHisPheThrLeuLysAspLysGly11901195SerProHisSerGluGl ySerAspArg12001205TyrArgGlnAsnSerThrHisCysArg12101215SerCysLeuSerAsnLeuProThrTyr1220SerGlyHisPheThrMetArgSerPro12251230PheLysCysAspAlaCysLeuArgMet12351240GlyAs nLeuTyrAspIleAspGluAsp12451250GlnMetLeuGlnGluThrGlyAsnPro12551260AlaThrArgGluGlu AlaTyrGlnGln1265AspTrpSerGlnAsnAsnAlaLeuGln12701275PheGlnLysAsnLysLeuLysIleAsn1280 1285ArgGlnHisSerTyrAspAsnIleLeu12901295AspLysProArgGluIleAspLeuSer13001305Arg ProSerArgSerIleSerLeuLys1310AspArgGluArgLeuLeuGluGlyAsn13151320LeuTyrGlySerLeuPheSerValPro 13251330SerSerLysLeuLeuGlyAsnLysSer13351340SerLeuPheProGlnGlyLeuGluAsp1345 1350SerLysArgSerLysSerLeuLeuPro1355AspHisThrSerAspAsnProPheLeu13601365HisThrTyrGlyAspAspG lnArgLeu13701375ValIleGlyArgCysProSerAspPro13801385TyrLysHisSerLeuProSerGlnAla 13901395ValAsnAspSerTyrLeuArgSerSer1400LeuArgSerThrAlaSerTyrCysSer14051410ArgAspS erArgGlyHisSerAspVal14151420TyrIleSerGluHisValMetProTyr14251430AlaAlaAsnLysAsnAsnMetTyr Ser14351440ThrProArgValLeuAsnSerCysSer1445AsnArgArgValTyrLysLysMetPro1450 1455SerIleGluSerAspVal1460(2) INFORMATION FOR SEQ ID NO: 2:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1482 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:2: FROM 1 to 1482(xi) SEQUENCE DESCRIPTION: SEQ ID NO:2:MetLysProSerAlaGluCysCysSer15ProL ysPheTrpLeuValLeuAlaVal1015LeuAlaValSerGlySerLysAlaArg2025SerGlnLysSerAlaProSerIleGly 3035IleAlaValIleLeuValGlyThrSer4045AspGluValAlaIleLysAspAlaHis50GluLysAspAspPheHisHisLeuSer5560ValValProArgValGluLeuValAla6570MetAsnGluThrAspProLysSe rIle7580IleThrArgIleCysAspLeuMetSer8590AspArgLysIleGlnGlyValValLeu 95AlaAspAspThrAspGlnGluAlaIle100105AlaGlnIleLeuAspPheIleSerAla110115GlnThrLeuThrPro IleLeuGlyIle120125HisGlyGlySerSerMetIleMetAla130135AspLysAspGluSerSerMetPhePhe140GlnPheGlyProSerIleGluGlnGln145150AlaSerValMetLeuAsnIleMetGlu155160GluTyr AspTrpTyrIlePheSerIle165170ValThrThrTyrPheProGlyTyrGln175180AspPheValAsnLysIle ArgSerThr185IleGluAsnSerPheValGlyTrpGlu190195LeuGluGluValLeuLeuLeuAspMet20020 5SerLeuAspAspGlyAspSerLysIle210215GlnAsnGlnLeuLysLysLeuGlnSer220225ProIleIle LeuLeuTyrCysThrLys230GluGluAlaThrTyrIlePheGluVal235240AlaAsnSerValGlyLeuThrGlyTyr245 250GlyTyrThrTrpIleValProSerLeu255260ValAlaGlyAspThrAspThrValPro265270 SerGluPheProThrGlyLeuIleSer275ValSerTyrAspGluTrpAspTyrGly280285LeuProAlaArgValArgAspGlyIle 290295AlaIleIleThrThrAlaAlaSerAsp300305MetLeuSerGluHisSerPheIlePro310 315GluProLysSerSerCysTyrAsnThr320HisGluLysArgIleTyrGlnSerAsn325330MetLeuAsnArgTyrLeuIle AsnVal335340ThrPheGluGlyArgAsnLeuSerPhe345350SerGluAspGlyTyrGlnMetHisPro3 55360LysLeuValIleIleLeuLeuAsnLys365GluArgLysTrpGluArgValGlyLys370375TrpLysAspLys SerLeuGlnMetLys380385TyrTyrValTrpProArgMetCysPro390395GluThrGluGluGlnGluAspAspHis 400405LeuSerIleValThrLeuGluGluAla410ProPheValIleValGluSerValAsp415420Pro LeuSerGlyThrCysMetArgAsn425430ThrValProCysGlnLysArgIleIle435440SerGluAsnLysThrAspGl uGluPro445450GlyTyrIleLysLysCysCysLysGly455PheCysIleAspIleLeuLysLysIle460 465SerLysSerValLysPheThrTyrAsp470475LeuTyrLeuValThrAsnGlyLysHis480485GlyLysLysIl eAsnGlyThrTrpAsn490495GlyMetIleGlyGluValValMetLys500ArgAlaTyrMetAlaValGlySerLeu505 510ThrIleAsnGluGluArgSerGluVal515520ValAspPheSerValProPheIleGlu525530Th rGlyIleSerValMetValSerArg535540SerAsnGlyThrValSerProSerAla545PheLeuGluProPheSerAlaA spVal550555TrpValMetMetPheValMetLeuLeu560565IleValSerAlaValAlaValPheVal570 575PheGluTyrPheSerProValGlyTyr580585AsnArgCysLeuAlaAspGlyArgGlu590ProGlyGlyProS erPheThrIleGly595600LysAlaIleTrpLeuLeuTrpGlyLeu605610ValPheAsnAsnSerValProValGln615 620AsnProLysGlyThrThrSerLysIle625630MetValSerValTrpAlaPhePheAla635ValI lePheLeuAlaSerTyrThrAla640645AsnLeuAlaAlaPheMetIleGlnGlu650655GluTyrValAspGlnValSerGlyLeu 660665SerAspLysLysPheGlnArgProAsn670675AspPheSerProProPheArgPheGly 680ThrValProAsnGlySerThrGluArg685690AsnIleArgAsnAsnTyrAlaGluMet695700HisAlaTyrMetGlyLys PheAsnGln705710ArgGlyValAspAspAlaLeuLeuSer715720LeuLysThrGlyLysLeuAspAlaPhe 725IleTyrAspAlaAlaValLeuAsnTyr730735MetAlaGlyArgAspGluGlyCysLys740745LeuValThr IleGlySerGlyLysVal750755PheAlaSerThrGlyTyrGlyIleAla760765IleGlnLysAspSerGlyTrp LysArg770GlnValAspLeuAlaIleLeuGlnLeu775780PheGlyAspGlyGluMetGluGluLeu785790 GluAlaLeuTrpLeuThrGlyIleCys795800HisAsnGluLysAsnGluValMetSer805815SerGlnLeuAsp IleAspAsnMetAla820GlyValPheTyrMetLeuGlyAlaAla825MetAlaLeuSerLeuIleThrPheIle830 835CysGluHisLeuPheTyrTrpGlnPhe840845ArgHisCysPheMetGlyValCysSer850855Gly LysProGlyMetValPheSerIle860SerArgGlyIleTyrSerCysIleHis865870GlyValAlaIleGluGluArgGlnSer87 5880ValMetAsnSerProThrAlaThrMet885890AsnAsnThrHisSerAsnIleLeuArg895 900LeuLeuArgThrAlaLysAsnMetAla905AsnLeuSerGlyValAsnGlySerPro910915GlnSerAlaLeuAspPheIleArg Arg920925GluSerSerValTyrAspIleSerGlu930935HisArgArgSerPheThrHisSerAsp940 945CysLysSerTyrAsnAsnProProCys950GluGluAsnLeuPheSerAspTyrIle955960SerGluValGluArg ThrPheGlyAsn965970LeuGlnLeuLysAspSerAsnValTyr975980GlnAspHisTyrHisHisHisHisArg 985990ProHisSerIleGlySerThrSerSer995IleAspGlyLeuTyrAspCysAspAsn10001005ProPr oPheThrThrGlnProArgSer10101015IleSerLysLysProLeuAspIleGly10201025LeuProSerSerLysHisSer GlnLeu10301035SerAspLeuTyrGlyLysPheSerPhe1040LysSerAspArgTyrSerGlyHisAsp1045 1050AspLeuIleArgSerAspValSerAsp10551060IleSerThrHisThrValThrTyrGly10651070AsnIleGlu GlyAsnAlaAlaLysArg10751080ArgLysGlnGlnTyrLysAspSerLeu1085LysLysArgProAlaSerAlaLysSer 10901095ArgArgGluPheAspGluIleGluLeu11001105AlaTyrArgArgArgProProArgSer111011 15ProAspHisLysArgTyrPheArgAsp11201125LysGluGlyLeuArgAspPheTyrLeu1139AspGlnPheArgThrL ysGluAsnSer11351140ProHisTrpGluHisValAspLeuThr11451150AspIleTyrLysGluArgSerAspAsp1155 1160PheLysArgAspSerValSerGlyGly11651170GlyProCysThrAsnArgSerHisLeu1175LysH isGlyThrGlyAspLysHisGly11801185ValValGlyGlyValProAlaProTrp11901195GluLysAsnLeuThrAsnValAspTrp12001205GluAspArgSerGlyGlyAsnPheCys12101215ArgSerCysProSerLysLeuHisAsn 1220TyrSerSerThrValAlaGlyGlnAsn12251230SerGlyArgGlnAlaCysIleArgCys12351240GluAlaCysLysLys AlaGlyAsnLeu12451250TyrAspIleSerGluAspAsnSerLeu12551260GlnGluLeuAspGlnProAlaAla Pro1265ValAlaValSerSerAsnAlaSerThr12701275ThrLysTyrProGlnSerProThrAsn12801285Ser LysAlaGlnLysLysAsnArgAsn12901295LysLeuArgArgGlnHisSerTyrAsp13001305ThrPheValAsp LeuGlnLysGluGlu1310AlaAlaLeuAlaProArgSerValSer13151320LeuLysAspLysGlyArgPheMetAsp1325 1330GlySerProTyrAlaHisMetPheGlu13351340MetProAlaGlyGluSerSerPheAla13451350 AsnLysSerSerValThrThrAlaGly1355HisHisHisAsnAsnProGlySerGly13601365TyrMetLeuSerLysSerLeuTyrPro 13701375AspArgValThrGlnAsnProPheIle13801385ProThrPheGlyAspAspGlnCysLeu1390 1395LeuHisGlySerLysSerTyrPhePhe1400ArgGlnProThrValAlaGlyAlaSer14051410LysThrArgProAspPh eArgAlaLeu14151420ValThrAsnLysProValValSerAla14251430LeuHisGlyAlaValProGlyArgPhe 14351440GlnLysAspIleCysIleGlyAsnGln1445SerAsnProCysValProAsnAsnLys14501455AsnPr oArgAlaPheAsnGlySerSer14601465AsnGlyHisValTyrGluLysLeuSer14701475SerIleGluSerAspVal 1480(2) INFORMATION FOR SEQ ID NO: 3:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1239 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:3: FROM 1 to 1239(xi) SEQUENCE DESCRIPTION: SEQ ID NO:3:MetGlyGlyAlaLeuGlyProAlaLeu15LeuLeuThrSerLeuLeuGlyAla Trp1015AlaGlyLeuGlyAlaGlyGlnGlyGlu2025GlnAlaValThrValAlaValValPhe30 35GlySerSerGlyProLeuGlnAlaGln4045AlaArgThrArgLeuThrProGlnAsn50PheLeuAspLeuProLeu GluIleGln5560ProLeuThrIleGlyValAsnAsnThr6570AsnProSerSerIleLeuThrGlnIle75 80CysGlyLeuLeuGlyAlaAlaArgVal8590HisGlyIleValPheGluAspAsnVal95AspThrGluAla ValAlaGlnLeuLeu100105AspPheValSerSerGlnThrHisVal110115ProIleLeuSerIleSerGlyGlySer12 0125AlaValValLeuThrProLysGluPro130135GlySerAlaPheLeuGlnLeuGlyVal140Ser LeuGluGlnGlnLeuGlnValLeu145150PheLysValLeuGluGluTyrAspTrp155160SerAlaPheAlaValIleThrSerLeu165170HisProGlyHisAlaLeuPheLeuGlu175180GlyValArgAlaValAlaAspAlaSer 185TyrLeuSerTrpArgLeuLeuAspVal190195LeuThrLeuGluLeuGlyProGlyGly200205ProArgAlaArgThrGln ArgLeuLeu210215ArgGlnValAspAlaProValLeuVal220225AlaTyrCysSerArgGluGluAlaGlu 230ValLeuPheAlaGluAlaAlaGlnAla235240GlyLeuValGlyProGlyHisValTrp245250LeuValPro AsnLeuAlaLeuGlySer255260ThrAspAlaProProAlaAlaPhePro265270ValGlyLeuIleSerValVa lThrGlu275SerTrpArgLeuSerLeuArgGlnLys280285ValArgAspGlyValAlaIleLeuAla290295LeuGlyAlaHisSerTyrArgArgGln300305TyrGlyThrLeuProAlaProAlaGly310315AspCysArgSe rHisProGlyProVal320SerProAlaArgGluAlaPheTyrArg325330HisLeuLeuAsnValThrTrpGluGly335 340ArgAspPheSerPheSerProGlyGly345350TyrLeuValGlnProThrMetValVal355360Il eAlaLeuAsnArgHisArgLeuTrp365GluMetValGlyArgTrpAspHisGly370375ValLeuTyrMetLysTyrProValTrp 380385ProArgTyrSerThrSerLeuGlnPro390395ValValAspSerArgHisLeuThrVal400 405AlaThrLeuGluGluArgProPheVal410IleValGluSerProAspProGlyThr415420GlyGlyCysValProAsnThrV alPro425430CysArgArgGlnSerAsnHisThrPhe435440SerSerGlyAspIleThrProTyrThr445 450LysLeuCysCysLysGlyPheCysIle455AspIleLeuLysLysLeuAlaLysVal460465ValLysPheSerT yrAspLeuTyrLeu470475ValThrAsnGlyLysHisGlyLysArg480485ValArgGlyValTrpAsnGlyMetIle 490495GlyGluValTyrTyrLysArgAlaAsp500MetAlaIleGlySerLeuThrIleAsn505510GluG luArgSerGluIleIleAspPhe515520SerValProPheValGluThrGlyIle525530SerValMetValAlaArgSer AsnGly535540ThrValSerProSerAlaPheLeuGlu545ProTyrSerProAlaValTrpValMet550 555MetPheValMetCysLeuThrValVal560565AlaIleThrValPheMetPheGluTyr570575PheSerProVal SerTyrAsnGlnAsn580585LeuThrLysGlyLysLysSerGlyGly590ProSerPheThrIleGlyLysSerVal595 600TrpLeuLeuTrpAlaLeuValPheAsn605610AsnSerValProIleGluAsnProArg615620Gly ThrThrSerLysIleMetValLeu625630ValTrpAlaPhePheAlaValIlePhe635LeuAlaSerTyrThrAlaAsnLeu Ala640645AlaPheMetIleGlnGluGlnTyrIle650655AspThrValSerGlyLeuSerAspLys660 665LysPheGlnArgProGlnAspGlnTyr670675ProProPheArgPheGlyThrValPro680AsnGlySerThrGlu ArgAsnIleArg685690SerAsnTyrArgAspMetHisThrHis695700MetValLysPheAsnGlnArgSerVal705 710GluAspAlaLeuThrSerLeuLysMet715720GlyLysLeuAspAlaPheIleTyrAsp725AlaAla ValLeuAsnTyrMetAlaGly730735LysAspGluGlyCysLysLeuValThr740745IleGlySerGlyLysValPheAlaThr 750755ThrGlyTyrGlyIleAlaMetGlnLys760765AspSerHisTrpLysArgAlaIleAsp7 70LeuAlaLeuLeuGlnPheLeuGlyAsp775780GlyGluThrGlnLysLeuGluThrVal785790TrpLeuSerGlyIleCysHis AsnGlu795800LysAsnGluValMetSerSerLysLeu805810AspIleAspAsnMetAlaGlyValPhe 815TyrMetLeuLeuValAlaMetGlyLeu820825AlaLeuLeuValPheAlaTrpGluHis830835LeuValTyrTrp LysLeuArgHisSer840845ValProSerSerSerGlnLeuAspPhe850855LeuLeuAlaPheSerArgGlyIl eTyr860SerCysPheAsnGlyValGlnSerLeu865870ProSerProAlaArgProProSerPro875880Asp LeuThrAlaGlySerAlaGlnAla885890AsnValLeuLysMetLeuGlnAlaAla895900ArgAspMetValSe rThrAlaAspVal905SerGlySerLeuAspArgAlaThrArg910915ThrIleGluAsnTrpGlyAsnAsnArg920 925ArgAlaProAlaProThrThrSerGly930935ProArgSerCysThrProGlyProPro940945GlyGl nProSerProSerGlyTrpArg950ProProGlyGlyGlyArgThrProLeu955960AlaArgArgAlaProGlnProProAla965 970ArgProGlyProAlaGlnGlyArgLeu975980SerProThrCysProGluHisProAla985 990GlyThrLeuGlyMetArgGlyGlyGln995CysGluSerGlyIleArgAspArgThr10001005SerArgProProGluArgArgAla Leu10101015ProGluArgSerLeuLeuHisAlaHis10201025CysHisTyrSerSerPheProArgAla1030 1035GluArgSerGlyArgProPheLeuPro1040LeuPheProGluProProGluProAsp10451050AspLeuProLeu LeuGlyProGluGln10551060LeuAlaArgArgGluAlaLeuLeuArg10651070AlaAlaTrpAlaArgGlyProArgPro 10751080ArgHisAlaSerLeuProSerSerVal1085AlaGluAlaPheThrArgSerAsnPro10901095 LeuProAlaArgCysThrGlyHisAla11001105CysAlaCysProCysProGlnSerArg11101115ProSerCysArgHisVa lAlaGlnThr11201125GlnSerLeuArgLeuProSerTyrArg1130GluAlaCysValGluGlyValProAla1135 1140GlyValAlaAlaThrTrpGlnProArg11451150GlnHisValCysLeuHisThrHisThr11551160HisLe uProPheCysTrpGlyThrVal11651170CysArgHisProProProCysSerSer1175HisSerProTrpLeuIleGlyThr Trp11801185GluProProSerHisArgGlyArgThr11901195LeuGlyLeuGlyThrGlyTyrArgAsp1200 1205SerGlyValLeuGluGluValSerArg12101215GluAlaCysGlyThrGlnGlyPhePro1220ArgSerCysThr TrpArgArgIleSer12251230SerLeuGluSerGluVal1235(2) INFORMATION FOR SEQ ID NO: 4:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1323 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand( D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:4: FROM 1 to 1323(xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:MetArgGlyAlaGlyGlyPr oArgGlyProArgGlyProAlaLysMet151015LeuLeuLeuLeuAlaLeuAlaCysAlaSerProPheProGluGluVal20 2530ProGlyProGlyAlaAlaGlyGlyGlyThrGlyGlyAlaArgProLeu354045AsnValAlaLeuValPheSerGlyProAlaTyrAlaAla GluAlaAla505560ArgLeuGlyProAlaValAlaAlaAlaValArgSerProGlyLeuAsp65707580V alArgProValAlaLeuValLeuAsnGlySerAspProArgSerLeu859095ValLeuGlnLeuCysAspLeuLeuSerGlyLeuArgValHisGlyVal 100105110ValPheGluAspAspSerArgAlaProAlaValAlaProIleLeuAsp115120125PheLeuSerAlaGlnThrSe rLeuProIleValAlaValHisGlyGly130135140AlaAlaLeuValLeuThrProLysGluLysGlySerThrPheLeuGln145150155 160LeuGlySerSerThrGluGlnGlnLeuGlnValIlePheGluValLeu165170175GluGluTyrAspTrpThrSerPheValAlaValThr ThrArgAlaPro180185190GlyHisArgAlaPheLeuSerTyrIleGluValLeuThrAspGlySer195200205L euValGlyTrpGluHisArgGlyAlaLeuThrLeuAspProGlyAla210215220GlyGluAlaValLeuGlyAlaGlnLeuArgSerValSerAlaGlnIle225 230235240ArgLeuLeuPheCysAlaArgGluGluAlaGluProValPheArgAla245250255AlaGluGluAlaGlyLe uThrGlyProGlyTyrValTrpPheMetVal260265270GlyProGlnLeuAlaGlyGlyGlyGlySerGlyValProGlyGluPro275280 285LeuLeuLeuProGlyGlyAlaProLeuProAlaGlyLeuPheAlaVal290295300ArgSerAlaGlyTrpArgAspAspLeuAlaArgArgValAlaAla Gly305310315320ValAlaValValAlaArgGlyAlaGlnAlaLeuLeuArgAspTyrGly325330335PheLeuProGluLeuGlyHisAspCysArgAlaGlnAsnArgThrHis340345350ArgGlyGluSerLeuHisArgTyrPheMetAsnIleThrTrpAspAsn 355360365ArgAspTyrSerPheAsnGluAspGlyPheLeuValAsnProSerLeu370375380ValValIleSerLeuThrArgAspAr gThrTrpGluValValGlySer385390395400TrpGluGlnGlnThrLeuArgLeuLysTyrProLeuTrpSerArgTyr405 410415GlyArgPheLeuGlnProValAspAspThrGlnHisLeuThrValAla420425430ThrLeuGluGluArgProPheValIleValGluPro AlaAspProIle435440445SerGlyThrCysIleArgAspSerValProCysArgSerGlnLeuAsn450455460ArgThrH isSerProProProAspAlaProArgProGluLysArgCys465470475480CysLysGlyPheCysIleAspIleLeuLysArgLeuAlaHisThrIle 485490495GlyPheSerTyrAspLeuTyrLeuValThrAsnGlyLysHisGlyLys500505510LysIleAspGlyValTr pAsnGlyMetIleGlyGluValPheTyrGln515520525ArgAlaAspMetAlaIleGlySerLeuThrIleAsnGluGluArgSer530535 540GluIleValAspPheSerValProPheValGluThrGlyIleSerVal545550555560MetValAlaArgSerAsnGlyThrValSerProSerAla PheLeuGlu565570575ProTyrSerProAlaValTrpValMetMetPheValMetCysLeuThr580585590ValValAlaValThrValPheIlePheGluTyrLeuSerProValGly595600605TyrAsnArgSerLeuAlaThrGlyLysArgProGlyGlySerThrPhe610 615620ThrIleGlyLysSerIleTrpLeuLeuTrpAlaLeuValPheAsnAsn625630635640SerValProValGluAsnPr oArgGlyThrThrSerLysIleMetVal645650655LeuValTrpAlaPhePheAlaValIlePheLeuAlaSerTyrThrAla660 665670AsnLeuAlaAlaPheMetIleGlnGluGluTyrValAspThrValSer675680685GlyLeuSerAspArgLysPheGlnArgProGlnGluGln TyrProPro690695700LeuLysPheGlyThrValProAsnGlySerThrGluLysAsnIleArg705710715720S erAsnTyrProAspMetHisSerTyrMetValArgTyrAsnGlnPro725730735ArgValGluGluAlaLeuThrGlnLeuLysAlaGlyLysLeuAspAla 740745750PheIleTyrAspAlaAlaValLeuAsnTyrMetAlaArgLysAspGlu755760765GlyCysLysLeuValThrIl eGlySerGlyLysValPheAlaThrThr770775780GlyTyrGlyIleAlaLeuHisLysGlySerArgTrpLysArgProIle785790795 800AspLeuAlaLeuLeuGlnPheLeuGlyAspAspGluIleGluMetLeu805810815GluArgLeuTrpLeuSerGlyIleCysHisAsnAsp LysIleGluVal820825830MetSerSerLysLeuAspIleAspAsnMetAlaGlyValPheTyrMet835840845L euLeuValAlaMetGlyLeuSerLeuLeuValPheAlaTrpGluHis850855860LeuValTyrTrpArgLeuArgHisCysLeuGlyProThrHisArgMet865 870875880AspPheLeuLeuAlaPheSerArgGlyMetTyrSerCysCysSerAla885890895GluAlaAlaProProPr oAlaLysProProProProProGlnProLeu900905910ProSerProAlaTyrProAlaAlaArgProProProGlyProAlaPro915920 925PheValProArgGluArgAlaAlaAlaAspArgTrpArgArgAlaLys930935940GlyThrGlyProProGlyGlyAlaAlaLeuAlaAspGlyPheHis Arg945950955960TyrTyrGlyProIleGluProGlnGlyLeuGlyLeuGlyGluAlaArg965970975AlaAlaProArgGlyAlaAlaGlyArgProLeuSerProProThrThr980985990GlnProProGlnLysProProProSerTyrPheAlaIleValArgGlu 99510001005GlnGluProAlaGluProProAlaGlyAlaPheProGlyPheProSer101010151020ProProAlaProProAlaAlaAlaAl aAlaAlaValGlyProProLeu1025103010351040CysArgLeuAlaPheGluAspGluSerProProAlaProSerAlaGly1045 10501055ArgValLeuThrProArgAlaSerArgCysTrpValGlyAlaArgAla106010651070AlaArgAlaLeuGlyProArgProHisHisArgArg ValArgThrAla107510801085ProProProCysAlaTyrLeuAspLeuGluProSerProSerAspSer109010951100GluAspS erGluSerLeuGlyGlyAlaSerLeuGlyGlyLeuGluPro1105111011151120TrpTrpPheAlaAspPheProTyrProTyrAlaGluArgLeuGlyPro 112511301135ProProGlyArgTyrTrpSerValAspLysLeuGlyGlyTrpArgAla114011451150GlySerTrpAspTyrLe uProProArgGlyGlyProAlaTrpHisCys115511601165ArgHisCysAlaSerLeuGluLeuLeuProProProArgHisLeuSer11701175 1180CysSerHisAspGlyLeuAspGlyGlyTrpTrpAlaProProProPro1185119011951200ProTrpAlaAlaGlyProProAlaProArgArgAlaArg CysGlyCys120512101215ProArgProHisProHisArgProArgAlaSerHisArgAlaProAla122012251230AlaAlaProHisHisHisArgHisArgArgAlaAlaGlyGlyTrpAsp123512401245LeuProProProAlaProThrSerArgSerLeuGluAspLeuSerSer1250 12551260CysProArgAlaAlaProThrArgArgLeuThrGlyProSerArgHis1265127012751280AlaArgArgCysProHisAl aAlaHisTrpGlyProProLeuProThr128512901295AlaSerHisArgArgHisArgGlyGlyAspLeuGlyThrArgArgGly1300 13051310SerAlaHisPheSerSerLeuGluSerGluVal13151320(2) INFORMATION FOR SEQ ID NO: 5:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 4392 nucleic acids(B) TYPE: nucleic acid(C) STRANDEDNESS: double strand (D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: cerebellum(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:5: FROM 1 to 4392(xi) SEQUENCE DESCRIPTION: SEQ ID NO:5:ATGGGCAGACTGG GCTACTGGACC24TTGCTGGTATTGCCGGCCCTTCTG48GTCTGGCACGGTCCGGCGCAGAAC72GCGGCGGCGGAGAAGGGTACTCCA96GCGCTGAACATTGCG GTGCTGCTG120GGTCACAGCCACGACGTGACAGAA144CGCGAACTTCGAAATCTGTGGGGC168CCGGAGCAGGCAACCGGCTTGCCC192CTGGATGTGAACGTGGTG GCGTTA216TTGATGAACCGCACTGACCCTAAG240AGCCTCATCACGCATGTGTGCGAC264CTCATGTCCGGGGCGCGCATCCAT288GGCTTGGTGTTTGGAGATGAT ACG312GACCAAGAGGCTGTGGCTCAGATG336CTGGATTTTATCTCCTCACAGACT360TTCATCCCCATCTTGGGCATTCAT384GGGGGTGCATCTATGATCATGGC T408GACAAGGATCCGACATCCACGTTC432TTCCAGTTTGGAGCTTCCATCCAG456CAGCAAGCCACGGTCATGCTGAAG480ATCATGCAGGACTATGACTGGCAT 504GTCTTCTCCTTGGTCACCACCATC528TTCCCTGGCTACAGAGACTTCATC552AGCTTCATCAAGACAACAGTGGAC576AACAGCTTTGTGGGCTGGGATATG600CAGAACGTGATCACACTGGACACC624TCTTTTGAGGACGCCAAGACACAG648GTCCAGCTGAAGAAGATCCACTCC672TCTGTCATCCTGCTCTACTGCTCC696 AAGGATGAGGCTGTCCTCATCCTG720AGCGAGGCTCGCTCTCTTGGCCTC744ACCGGCTACGATTTCTTCTGGATT768GTCCCCAGTTTGGTCTCCGGGAAC792ACA GAGCTCATCCCCAAAGAGTTT816CCATCGGGTCTCATTTCAGTCTCT840TACGACGACTGGGACTACAGTCTG864GAGGCAAGAGTGAGAGACGGTCTT888GGGATC TTAACCACTGCCGCATCT912TCCATGTTGGAGAAATTCTCCTAC936ATTCCCGAGGCCAAGGCCAGCTGC960TACGGGCAGACAGAGAAGCCGGAG984ACCCCGCT ACACACTCTGCACCAA1008TTTATGGTCAATGTGACTTGGGAT1032GGCAAGGACTTGTCCTTCACTGAG1056GAAGGCTATCAGGTGCACCCCAGG1080CTTGTGGTGA TCGTGCTGAATAAG1104GACCGGGAATGGGAAAAGGTGGGC1128AAGTGGGAGAATCAGACTCTGAGG1152CTGCGGCATGCTGTGTGGCCAAGG1176TATAAGTCCTTT TCTGACTGTGAG1200CCAGATGACAACCACCTCAGCATT1224GTCACCTTGGAGGAAGCCCCCTTC1248GTCATCGTAGAAGACATAGACCCA1272CTGACTGAGACCTGC GTCAGGAAC1296ACGGTACCCTGTCGGAAGTTTGTC1320AAGATCAACAATTCAACCAACGAA1344GGGATGAATGTGAAGAAGTGCTGC1368AAGGGGTTCTGCATCGAC ATCCTT1392AAGAAACTGTCCAGAACTGTAAAG1416TTCACCTATGACCTCTACCTGGTG1440ACCAATGGGAAGCATGGGAAAAAG1464GTTAACAATGTGTGGAATGG AATG1488ATAGGCGAAGTGGTCTATCAACGA1512GCAGTTATGGCCGTGGGCTCCCTC1536ACCATCAATGAGGAGCGTTCAGAA1560GTGGTGGACTTCTCCGTGCCCT TT1584GTGGAGACAGGAATCAGTGTCATG1608GTCTCCAGGAGTAATGGCACTGTT1632TCCCCTTCTGCTTTCCTTGAACCC1656TTCAGCGCCTCTGTCTGGGTGATG 1680ATGTTCGTGATGCTGCTCATTGTC1704TCTGCCATTGCTGTCTTCGTTTTT1728GAATACTTCAGTCCTGTTGGATAC1752AACAGAAACTTAGCCAAAGGGAAA177 6GCTCCCCATGGGCCTTCTTTTACC1800ATTGGAAAAGCTATATGGCTCCTC1824TGGGGCCTGGTCTTCAACAATTCT1848GTGCCCGTCCAGAATCCTAAAGGC1872 ACAACCAGCAAGATAATGGTATCA1896GTGTGGGCCTTCTTTGCCGTCATC1920TTCCTTGCAAGTTACACAGCCAAC1944CTGGCTGCCTTCATGATCCAGGAG1968GAG TTTGTGGACCAAGTGACTGGC1992CTCAGTGACAAGAAGTTCCAGAGA2016CCTCATGACTATTCTCCGCCTTTC2040CGATTTGGGACAGTACCCAATGGA2064AGTAC AGAAAGGAATATTCGTAAC2088AACTACCCCTATATGCACCAGTAC2112ATGACCAAATTCAACCAGAGGGGC2136GTAGAGGATGCCTTGGTCAGCTTG2160AAAACTG GGAAGTTGGACGCTTTC2184ATCTATGACGCAGCTGTCTTGAAC2208TACAAGGCCGGGAGGGATGAAGGC2232TGTAAACTGGTGACCATTGGGAGC2256GGGTACATC TTTGCCACCACAGGC2280TATGGAATTGCTCTGCAGAAGGGC2304TCACCCTGGAAGAGGCAGATTGAC2328CTCGCTCTGCTCCAGTTTGTTGGT2352GACGGTGAGATG GAAGAGCTGGAG2376ACACTGTGGCTTACGGGCATCTGC2400CACAACGAGAAGAATGAGGTGATG2424AGCAGCCAGCTGGACATCGACAAC2448ATGGCAGGAGTTTTC TACATGCTG2472GCTGCAGCTATGGCCCTCAGCCTC2496ATCACCTTCATCTGGGAGCACCTC2520TTCTACTGGAAGCTGCGCTTCTGC2544TTCACAGGCGTGTGTTC TGACCGG2568CCCGGGCTGCTCTTCTCCATCAGC2592AGGGGCATCTACAGTTGCATCCAT2616GGAGTGCACATTGAAGAAAAGAAG2640AAGTCTCCAGACTTCAATC TGACT2664GGGTCACAGAGCAACATGCTAAAG2688CTTCTCCGCTCAGCTAAAAACATC2712TCCAACATGTCCAACATGAACTCC2736TCGCGAATGGACTCACCCAAA AGA2760GCTGCTGACTTCATCCAAAGAGGC2784TCACTTATTGTGGACATGGTTTCA2808GACAAGGGAAATTTGATATACTCA2832GATAACAGGTCCTTTCAAGGGAAG 2856GACAGTATATTTGGAGAAAACATG2880AATGAACTGCAAACATTTGTGGCC2904AACAGGCACAAGGATAGTCTCAGT2928AACTATGTGTTTCAGGGACAGCAT29 52CCTCTCACTCTCAATGAGTCCAAC2976CCCAACACAGTGGAGGTGGCTGTC3000AGCACTGAATCCAAAGGGAACTCC3024CGACCCCGGCAGCTTTGGAAGAAA3048TCCATGGAGTCTCTACGCCAGGAT3072TCTCTAAACCAGAACCCAGTCTCC3096CAGAGGGATGAGAAGACTGCAGAG3120AATAGGACCCACTCCCTAAAGAGT3144CC TAGGTATCTTCCAGAAGAGGTA3168GCCCATTCTGACATTTCTGAAACC3192TCAAGCCGGGCCACATGCCACAGG3216GAGCCAGATAATAATAAGAACCAC3240AAGA CCAAGGATAACTTCAAAAGG3264TCAATGGCCTCTAAATACCCCAAG3288GACTGTAGTGAGGTTGAACGTACC3312TACGTGAAAACCAAAGCAAGTTCT3336CCCAGG GATAAGATCTACACCATC3360GATGGTGAGAAGGAGCCCAGCTTC3384CACTTAGATCCTCCACAGTTCATT3408GAAAACATAGTCTTGCCTGAGAAT3432GTGGACTTC CCAGATACCTACCAA3456GATCACAATGAGAATTTCCGCAAG3480GGGGACTCCACACTGCCCATGAAC3504AGGAACCCACTACACAATGAAGAT3528GGGCTTCCCAAC AATGACCAGTAT3552AAACTCTATGCCAAGCACTTTACC3576TTGAAAGACAAGGGTTCCCCACAT3600AGTGAGGGCAGTGATCGATATCGG3624CAGAACTCCACGCA TTGCAGAAGC3648TGCCTCTCAAACCTGCCCACCTAC3672TCAGGCCACTTTACCATGAGATCT3696CCTTTCAAGTGTGATGCCTGTCTG3720CGGATGGGGAACCTCT ATGACATT3744GATGAAGACCAGATGCTTCAGGAG3768ACAGGCAACCCAGCTACTCGTGAG3792GAGGCCTACCAGCAGGACTGGTCA3816CAGAACAACGCCCTCCAG TTCCAG3840AAGAACAAGCTAAAGATTAATCGA3864CAGCACTCCTATGATAACATTCTC3888GACAAACCCAGGGAGATAGACCTT3912AGCAGGCCCTCTCGTAGCATA AGC3936CTCAAGGACAGGGAAAGGCTACTG3960GAGGGCAACTTATACGGGAGCCTG3984TTCAGTGTCCCCTCAAGCAAACTC4008TTGGGGAACAAAAGCTCCCTTTTC 4032CCCCAAGGTCTGGAGGACAGCAAG4056AGGAGCAAATCTCTCTTGCCAGAC4080CATACCTCTGATAATCCTTTCCTC4104CACACGTACGGGGATGACCAACGC4 128TTAGTTATTGGGAGATGTCCCTCG4152GACCCTTACAAACACTCATTGCCA4176TCACAGGCAGTAAATGACAGCTAT4200CTTCGGTCATCCTTGAGGTCAACA4224GCATCATATTGCTCCAGGGACAGT4248CGGGGCCACAGTGATGTGTATATT4272TCAGAGCATGTTATGCCTTATGCT4296GCAAATAAGAATAACATGTACTCT4320A CCCCCAGGGTTTTAAATTCCTGC4344AGCAATAGACGTGTGTACAAGAAA4368ATGCCTAGTATTGAATCTGATGTC4392(2) INFORMATION FOR SEQ ID NO: 6:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 4446 nucleic acids (B) TYPE: nucleic acid(C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:6: FROM 1 to 4446 (xi) SEQUENCE DESCRIPTION: SEQ ID NO:6:ATGAAGCCCAGCGCAGAGTGCTGT24TCTCCCAAGTTCTGGTTGGTGTTG48GCCGTCTTGGCCGTATCGGGCAGC72AAAGCTCGTTCCCAAAAGAGCGC C96CCCAGCATCGGCATCGCTGTCATC120CTCGTGGGCACTTCCGACGAAGTG144GCCATAAAAGATGCCCACGAGAAA168GATGACTTCCATCATCTCTCAGTA 192GTTCCCCGGGTGGAGCTGGTAGCC216ATGAACGAGACTGACCCAAAGAGC240ATAATCACCCGCATCTGCGATCTT264ATGTCTGACCGGAAGATCCAGGGG288GTGGTGCTCGCGGATGACACGGAC312CAGGAAGCCATCGCCCAGATCCTC336GATTTCATTTCTGCTCAGACTCTC360ACCCCCATCCTGGGCATCCATGGG384 GGCTCATCTATGATAATGGCAGAT408AAGGATGAGTCCTCCATGTTCTTC432CAGTTTGGCCCATCCATTGAACAG456CAAGCTTCTGTCATGCTCAACATC480ATG GAAGAATACGACTGGTACATC504TTCTCCATCGTCACCACCTACTTC528CCCGGCTACCAGGACTTCGTGAAC552AAGATCCGCAGCACTATTGAGAAC576AGCTTT GTGGGCTGGGAGCTCGAG600GAAGTCCTCCTGCTAGACATGTCT624CTAGACGATGGCGACTCTAAGATT648CAGAATCAGCTGAAGAAGCTGCAG672AGCCCCAT CATTCTCCTCTACTGC696ACAAAGGAAGAAGCCACCTACATC720TTCGAAGTAGCTAACTCAGTTGGG744CTGACTGGCTACGGCTACACATGG768ATCGTGCCGA GTCTGGTGGCGGGG792GATACAGACACGGTGCCTTCAGAG816TTCCCCACGGGGCTCATCTCTGTG840TCATATGACGAATGGGACTATGGC864CTTCCTGCCAGA GTGAGAGATGGG888ATTGCCATCATCACCACTGCTGCC912TCGGACATGCTGTCCGAACACAGT936TTCATCCCTGAGCCCAAGAGCAGT960TGCTACAACACCCAC GAGAAGAGG984ATCTACCAGTCTAACATGCTGAAT1008AGGTATCTGATCAACGTCACTTTT1032GAAGGGAGAAACCTGTCCTTCAGT1056GAAGATGGCTACCAGATG CATCCG1080AAGCTGGTGATAATCCTTCTGAAC1104AAGGAGAGGAAGTGGGAGAGGGTG1128GGAAAATGGAAAGACAAGTCCCTG1152CAGATGAAATACTACGTGTG GCCT1176CGAATGTGTCCAGAGACTGAAGAA1200CAGGAAGATGACCATCTGAGCATC1224GTTACCTTGGAGGAGGCACCGTTT1248GTCATTGTGGAAAGTGTGGACC CT1272CTCAGTGGGACCTGCATGCGGAAT1296ACAGTCCCGTGCCAGAAGCGCATC1320ATCTCTGAGAATAAAACAGATGAG1344GAACCAGGCTACATCAAAAAATGC 1368TGCAAGGGGTTTTGTATTGATATC1392CTTAAGAAAATTTCTAAGTCTGTG1416AAGTTCACCTATGACCTTTACCTG1440GTGACCAATGGCAAGCATGGAAAG146 4AAAATCAACGGGACCTGGAACGGC1488ATGATTGGTGAGGTGGTCATGAAG1512AGGGCCTACATGGCAGTGGGATCA1536CTAACTATCAATGAAGAACGGTCA1560 GAGGTGGTTGACTTCTCTGTGCCC1584TTCATAGAGACTGGCATCAGTGTC1608ATGGTATCACGCAGCAATGGGACT1632GTGTCACCTTCTGCCTTCTTAGAG1656CCA TTCAGTGCTGACGTGTGGGTG1680ATGATGTTTGTGATGCTGCTCATT1704GTCTCTGCTGTAGCTGTCTTTGTC1728TTTGAATACTTCAGCCCTGTGGGT1752TACAA CCGGTGCCTAGCTGATGGC1776AGAGAGCCAGGCGGCCCATCTTTC1800ACCATCGGCAAAGCGATTTGGTTA1824CTCTGGGGTCTGGTGTTTAACAAC1848TCCGTAC CTGTGCAGAACCCAAAG1872GGGACCACCTCCAAGATCATGGTG1896TCAGTGTGGGCCTTCTTTGCTGTC1920ATTTTCCTGGCCAGCTACACTGCC1944AACTTAGCC GCCTTCATGATCCAA1968GAGGAGTATGTGGACCAGGTTTCC1992GGCCTGAGTGACAAGAAGTTCCAG2016AGACCTAATGACTTCTCACCCCCT2040TTCCGCTTTGGG ACTGTGCCCAAT2064GGCAGCACAGAGAGGAATATCCGT2088AATAACTATGCAGAAATGCATGCC2112TACATGGGAAAGTTCAACCAAAGG2136GGTGTAGATGATGCC TTGCTCTCC2160CTGAAAACAGGGAAACTTGATGCA2184TTCATCTACGATGCAGCCGTGCTC2208AACTACATGGCTGGAAGAGACGAA2232GGCTGCAAGCTGGTGAC CATTGGC2256AGTGGCAAGGTCTTTGCTTCTACG2280GGCTATGGCATTGCTATCCAAAAA2304GACTCTGGTTGGAAACGCCAGGTG2328GACCTTGCTATCCTGCAGC TGTTT2352GGAGATGGGGAGATGGAAGAACTG2376GAAGCTCTCTGGCTCACTGGCATT2400TGCCACAATGAGAAGAATGAGGTT2424ATGAGCAGCCAGCTGGACATT GAC2448AACATGGCGGGCGTCTTCTATATG2472TTGGGGGCAGCCATGGCTCTCAGC2496CTCATCACCTTCATCTGTGAACAT2520CTCTTCTATTGGCAGTTCCGACAT 2544TGCTTCATGGGTGTCTGTTCTGGC2568AAGCCTGGCATGGTCTTCTCCATC2592AGCAGAGGTATCTACAGCTGTATC2616CACGGAGTAGCTATAGAGGAGCGC26 40CAATCCGTGATGAACTCCCCCACT2664GCCACCATGAACAACACACACTCC2688AATATCCTACGCTTGCTCCGAACG2712GCCAAAAACATGGCCAACCTGTCT2736GGAGTCAACGGCTCCCCCCAGAGT2760GCCCTGGACTTCATCCGCCGTGAG2784TCCTCTGTCTATGACATCTCTGAG2808CATCGCCGCAGCTTCACGCATTCA2832GA CTGCAAGTCGTACAATAACCCA2856CCCTGTGAGGAAAACCTGTTCAGT2880GACTACATTAGTGAGGTAGAGAGA2904ACATTTGGCAACCTGCAGCTGAAG2928GACA GCAATGTGTACCAAGACCAC2952TATCACCATCACCACCGGCCCCAC2976AGCATCGGCAGCACCAGCTCCATT3000GATGGGCTCTATGACTGTGACAAC3024CCACCC TTTACCACCCAGCCCAGG3048TCAATCAGCAAGAAACCCCTGGAC3072ATTGGCCTGCCCTCCTCCAAACAC3096AGCCAGCTCAGCGACCTGTACGGC3120AAGTTCTCT TTCAAGAGTGACCGC3144TACAGTGGCCATGATGACTTGATT3168CGATCGGATGTCTCAGACATCTCC3192ACGCATACTGTCACCTATGGCAAC3216ATCGAGGGCAAC GCAGCCAAGAGG3240AGGAAGCAGCAATATAAGGACAGT3264CTAAAGAAGCGGCCAGCCTCGGCC3288AAATCTAGGAGGGAGTTTGATGAA3312ATCGAGCTGGCCTA CCGTCGCCGA3336CCACCCCGCTCCCCAGACCACAAG3360CGCTACTTCAGGGACAAAGAAGGG3384CTCCGAGACTTCTACCTGGACCAG3408TTCCGAACAAAGGAGA ACTCGCCT3432CACTGGGAGCACGTGGACTTAACT3456GACATTTACAAAGAACGTAGTGAT3480GACTTCAAGCGAGATTCGGTCAGT3504GGAGGCGGGCCCTGTACC AACAGG3528TCTCACCTTAAACACGGAACAGGC3552GATAAGCACGGAGTGGTAGGCGGG3576GTGCCTGCTCCTTGGGAGAAGAAC3600CTGACCAATGTGGATTGGGAG GAT3624AGGTCTGGGGGCAACTTCTGCCGC3648AGCTGTCCCTCCAAGCTGCACAAT3672TACTCCTCTACGGTGGCAGGGCAA3696AACTCGGGCCGGCAGGCCTGCATC 3720AGGTGTGAGGCCTGCAAGAAGGCT3744GGCAACCTGTATGACATCAGCGAG3768GACAACTCCCTGCAGGAACTGGAC3792CAGCCGGCTGCCCCTGTGGCTGTG3 816TCATCCAACGCCTCCACCACCAAG3840TACCCTCAAAGCCCGACTAATTCC3864AAGGCCCAGAAGAAGAATCGGAAC3888AAACTGCGCCGGCAGCACTCCTAC3912GACACCTTCGTGGACCTGCAGAAG3936GAGGAGGCCGCCTTGGCCCCACGC3960AGCGTGAGCCTGAAAGACAAGGGC3984CGATTCATGGATGGGAGCCCCTAC4008G CCCATATGTTTGAGATGCCAGCT4032GGTGAGAGCTCCTTTGCCAACAAG4056TCCTCAGTGACCACTGCCGGACAC4080CATCACAACAATCCCGGCAGCGGC4104TAC ATGCTCAGCAAGTCGCTCTAC4128CCTGACCGGGTCACGCAAAACCCT4152TTCATCCCCACTTTTGGGGATGAT4176CAGTGCTTGCTTCACGGCAGCAAA4200TCCTAC TTCTTCAGGCAGCCCACG4224GTGGCAGGGGCGTCGAAAACAAGG4248CCGGACTTCCGGGCCCTTGTCACC4272AATAAGCCAGTGGTGTCGGCCCTT4296CATGGGGCT GTGCCAGGTCGTTTC4320CAGAAGGACATTTGTATAGGGAAC4344CAGTCCAACCCCTGTGTGCCTAAC4368AACAAAAACCCCAGGGCTTTCAAT4392GGCTCCAGCAA TGGACATGTTTAT4416GAGAAACTTTCTAGTATTGAGTCT4440GATGTC4446(2) INFORMATION FOR SEQ ID NO: 7:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 3717 nucleic acids(B) TYPE: nucleic acid (C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:7: FROM 1 to 3717(xi) SEQUENCE DESCRIPTION: SEQ ID NO:7: ATGGGTGGAGCCCTGGGGCCCGCC24CTGCTTCTCACTTCACTCCTTGGT48GCTTGGGCAGGGCTGGGCGCAGGG72CAGGGAGAACAGGCCGTGACCGTG96 GCGGTGGTGTTTGGCAGCTCTGGG120CCACTGCAGGCCCAGGCCCGGACT144CGTCTCACCCCGCAGAACTTCCTG168GACTTGCCTCTGGAGATCCAGCCA192 CTCACCATCGGGGTCAACAATACC216AACCCCAGCAGCATCCTCACCCAA240ATCTGTGGGCTCCTGGGTGCCGCC264CGAGTCCACGGCATCGTCTTTGAG288 GACAACGTGGACACTGAGGCCGTG312GCTCAGCTGCTGGATTTCGTCTCC336TCTCAGACCCACGTGCCCATCCTC360AGCATCAGTGGAGGTTCTGCTGTG384 GTCCTCACCCCCAAGGAGCCAGGC408TCCGCCTTTCTACAGCTGGGCGTG432TCCCTGGAGCAGCAGCTGCAGGTG456CTGTTCAAGGTGCTGGAGGAATAC480 GACTGGAGCGCGTTCGCTGTCATC504ACCAGCCTGCACCCGGGCCACGCG528CTCTTCCTCGAGGGCGTGCGCGCC552GTCGCCGACGCCAGCTACCTGAGC576 TGGCGGCTGCTGGACGTGCTCACG600CTGGAGCTGGGCCCCGGTGGGCCG624CGAGCGCGCACTCAGCGCTTACTG648CGCCAGGTCGACGCCCCGGTGCTG672 GTGGCCTACTGCTCCCGTGAAGAG696GCGGAGGTGCTCTTCGCGGAGGCT720GCACAGGCTGGCTTGGTGGGACCC744GGTCACGTGTGGTTAGTACCTAAT768 CTGGCGCTGGGAAGCACCGACGCT792CCCCCTGCAGCCTTCCCAGTGGGC816CTCATCAGTGTGGTCACCGAGAGT840TGGCGCCTTAGCCTACGCCAGAAA864 GTCCGCGACGGTGTAGCCATTCTG888GCCCTCGGTGCCCACAGCTACCGA912CGCCAGTACGGTACCCTTCCAGCC936CCGGCTGGAGACTGCCGAAGCCAC960 CCAGGACCCGTCAGCCCTGCCAGG984GAGGCTTTCTACAGGCATCTGCTG1008AATGTCACCTGGGAAGGCCGAGAC1032TTCTCTTTTAGCCCTGGTGGGTAC1056 CTGGTCCAGCCCACAATGGTTGTG1080ATCGCTCTCAACCGGCATCGCCTC1104TGGGAGATGGTGGGACGGTGGGAT1128CATGGGGTCCTGTACATGAAGTAT1152 CCAGTATGGCCTCGCTACAGCACT1176TCTCTGCAGCCTGTGGTGGACAGC1200CGGCACCTGACAGTGGCCACACTG1224GAAGAAAGGCCTTTTGTCATTGTG1248 GAGAGCCCTGACCCTGGCACAGGT1272GGCTGTGTTCCCAACACTGTGCCC1296TGCCGTAGACAGAGCAACCACACC1320TTCAGCAGCGGGGATATAACCCCC1344 TACACCAAGCTCTGTTGTAAGGGC1368TTCTGCATCGACATCCTCAAGAAG1392CTGGCCAAGGTGGTCAAGTTCTCC1416TACGACTTGTACCTGGTGACCAAC1440 GGCAAGCACGGCAAGAGGGTTCGT1464GGTGTGTGGAATGGTATGATCGGT1488GAGGTATACTACAAGCGGGCAGAC1512ATGGCCATCGGCTCCCTCACCATC1536 AATGAAGAGCGCTCAGAGATTATA1560GACTTCTCTGTGCCTTTTGTGGAG1584ACCGGCATCAGTGTGATGGTGGCA1608AGGAGCAACGGCACCGTCTCCCCC1632 TCGGCTTTTCTGGAGCCCTACAGC1656CCTGCCGTGTGGGTGATGATGTTT1680GTAATGTGCCTCACGGTGGTTGCC1704ATCACTGTCTTCATGTTCGAGTAT1728 TTCAGCCCTGTCAGCTACAACCAG1752AATCTCACCAAGGGCAAGAAGTCA1776GGTGGACCATCCTTCACCATTGGC1800AAGTCCGTGTGGTTGCTGTGGGCA1824 CTGGTCTTCAACAACTCTGTTCCC1848ATCGAGAACCCCCGGGGCACCACC1872AGCAAGATCATGGTCCTGGTGTGG1896GCCTTCTTCGCTGTCATCTTCCTC1920 GCTAGCTACACGGCCAATCTGGCA1944GCCTTCATGATCCAGGAACAATAC1968ATCGACACTGTGTCGGGCCTTAGT1992GACAAGAAGTTTCAGCGGCCTCAA2016 GACCAATACCCACCCTTCCGTTTT2040GGCACGGTACCTAATGGCAGCACA2064GAGAGGAACATTCGTAGCAACTAT2088CGTGACATGCACACTCACATGGTC2112 AAGTTCAACCAGCGCTCGGTGGAG2136GATGCTCTCACAAGCCTGAAGATG2160GGGAAGCTGGACGCCTTCATCTAT2184GATGCCGCCGTCCTCAACTACATG2208 GCGGGCAAGGACGAAGGCTGCAAG2232CTGGTCACCATTGGGTCTGGCAAA2256GTCTTTGCCACCACTGGCTATGGC2280ATTGCCATGCAGAAAGACTCCCAC2304 TGGAAGCGGGCCATAGACCTGGCG2328CTCCTGCAGTTCCTGGGGGATGGG2352GAGACACAGAAGTTGGAGACAGTG2376TGGCTCTCAGGGATCTGCCATAAC2400 GAGAAGAACGAGGTGATGAGCAGC2424AAGCTGGACATTGACAACATGGCG2448GGCGTCTTCTACATGCTGTTGGTG2472GCCATGGGGCTGGCCCTTCTGGTC2496 TTTGCCTGGGAGCACCTGGTCTAC2520TGGAAACTTCGACACTCAGTGCCC2544AGCTCATCCCAGCTGGACTTCCTG2568CTGGCTTTCAGCAGGGGCATCTAC2592 AGCTGCTTCAACGGGGTACAGAGC2616CTTCCGAGCCCTGCGCGGCCGCCC2640AGCCCGGACCTTACAGCAGGCTCA2664GCCCAGGCCAATGTGCTGAAGATG2688 CTGCAGGCGGCTCGAGACATGGTG2712AGCACAGCGGACGTGAGCGGCTCT2736TTGGACCGCGCCACTCGTACCATC2760GAGAACTGGGGCAACAATCGCCGC2784 GCGCCTGCTCCCACCACCTCCGGC2808CCGCGGTCATGCACCCCGGGTCCT2832CCGGGACAACCGAGTCCCAGCGGC2856TGGCGGCCTCCCGGTGGGGGCCGC2880 ACCCCGCTAGCGCGCCGGGCCCCG2904CAGCCTCCCGCTCGCCCCGGACCT2928GCGCAGGGTCGCCTCAGCCCGACG2952TGTCCCGAGCATCCTGCAGGCACG2976 CTTGGGATGCGCGGTGGCCAGTGC3000GAGTCGGGCATCAGGGATCGCACC3024TCTCGGCCTCCGGAGCGGCGCGCG3048CTCCCGGAGCGCTCCCTGTTGCAC3072 GCGCACTGCCACTACAGTTCCTTC3096CCTCGAGCAGAGAGGTCAGGGCGC3120CCATTTCTCCCGCTATTCCCGGAG3144CCCCCGGAGCCCGACGACCTGCCG3168 CTGCTCGGGCCGGAACAGCTGGCT3192CGGCGGGAGGCTCTGCTGCGCGCG3216GCCTGGGCCAGGGGCCCGCGCCCT3240CGGCACGCTTCCCTGCCCAGCTCC3264 GTGGCAGAAGCCTTCACTCGATCC3288AACCCTCTGCCTGCCAGGTGTACC3312GGTCACGCCTGCGCTTGCCCATGT3336CCCCAAAGCCGGCCATCCTGCCGG3360 CACGTGGCTCAAACACAGTCGTTG3384CGGCTGCCATCCTACCGGGAGGCC3408TGTGTGGAGGGCGTGCCAGCAGGG3432GTGGCCGCCACCTGGCAGCCCAGA3456 CAGCATGTCTGCCTGCACACCCAT3480ACCCACCTGCCGTTCTGCTGGGGG3504ACTGTCTGCCGTCACCCTCCACCC3528TGTTCCAGCCACAGTCCCTGGCTC3552 ATTGGAACTTGGGAGCCTCCATCA3576CACAGAGGCAGGACCCTGGGGCTA3600GGTACAGGCTACAGGGACAGTGGG3624GTGCTAGAAGAGGTCAGCAGGGAA3648 GCTTGTGGGACACAAGGGTTTCCA3672AGGTCCTGCACCTGGAGGCGGATC3696TCCAGCCTGGAATCAGAAGTG3717(2) INFORMATION FOR SEQ ID NO: 8:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 1456 amino acids (B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:8: FROM 1 to 4368(xi) SEQUENCE DESCRIPTION: SEQ ID NO:8:ArgSerGlnLysSerAlaProSerIleGlyIleAlaValIleLeuVal151015GlyThrSerAspGluValAlaIleLysAspAlaHis GluLysAspAsp202530PheHisHisLeuSerValValProArgValGluLeuValAlaMetAsn354045 GluThrAspProLysSerIleIleThrArgIleCysAspLeuMetSer505560AspArgLysIleGlnGlyValValLeuAlaAspAspThrAspGlnGlu65 707580AlaIleAlaGlnIleLeuAspPheIleSerAlaGlnThrLeuThrPro859095IleLeuGlyI leHisGlyGlySerSerMetIleMetAlaAspLysAsp100105110GluSerSerMetPhePheGlnPheGlyProSerIleGluGlnGlnAla115 120125SerValMetLeuAsnIleMetGluGluTyrAspTrpTyrIlePheSer130135140IleValThrThrTyrPheProGlyTyrGlnAsp PheValAsnLysIle145150155160ArgSerThrIleGluAsnSerPheValGlyTrpGluLeuGluGluVal165170 175LeuLeuLeuAspMetSerLeuAspAspGlyAspSerLysIleGlnAsn180185190GlnLeuLysLysLeuGlnSerProIleIleLeuLeuTyr CysThrLys195200205GluGluAlaThrTyrIlePheGluValAlaAsnSerValGlyLeuThr210215220GlyTyrG lyTyrThrTrpIleValProSerLeuValAlaGlyAspThr225230235240AspThrValProSerGluPheProThrGlyLeuIleSerValSerTyr 245250255AspGluTrpAspTyrGlyLeuProAlaArgValArgAspGlyIleAla260265270IleIleThrThr AlaAlaSerAspMetLeuSerGluHisSerPheIle275280285ProGluProLysSerSerCysTyrAsnThrHisGluLysArgIleTyr29029 5300GlnSerAsnMetLeuAsnArgTyrLeuIleAsnValThrPheGluGly305310315320ArgAsnLeuSerPheSerGluAspGlyTyr GlnMetHisProLysLeu325330335ValIleIleLeuLeuAsnLysGluArgLysTrpGluArgValGlyLys340345 350TrpLysAspLysSerLeuGlnMetLysTyrTyrValTrpProArgMet355360365CysProGluThrGluGluGlnGluAspAspHisLeuSerIleVa lThr370375380LeuGluGluAlaProPheValIleValGluSerValAspProLeuSer385390395400Gly ThrCysMetArgAsnThrValProCysGlnLysArgIleIleSer405410415GluAsnLysThrAspGluGluProGlyTyrIleLysLysCysCysLys 420425430GlyPheCysIleAspIleLeuLysLysIleSerLysSerValLysPhe435440445ThrTyrAspLeuTyrLeu ValThrAsnGlyLysHisGlyLysLysIle450455460AsnGlyThrTrpAsnGlyMetIleGlyGluValValMetLysArgAla465470 475480TyrMetAlaValGlySerLeuThrIleAsnGluGluArgSerGluVal485490495ValAspPheSerValProPheIleGluTh rGlyIleSerValMetVal500505510SerArgSerAsnGlyThrValSerProSerAlaPheLeuGluProPhe515520 525SerAlaAspValTrpValMetMetPheValMetLeuLeuIleValSer530535540AlaValAlaValPheValPheGluTyrPheSerProValGlyTyrAsn54 5550555560ArgCysLeuAlaAspGlyArgGluProGlyGlyProSerPheThrIle565570575Gly LysAlaIleTrpLeuLeuTrpGlyLeuValPheGlnAsnSerVal580585590ProValGlnAsnProLysGlyThrThrSerLysIleMetValSerVal5 95600605TrpAlaPhePheAlaValIlePheLeuAlaSerTyrThrAlaAsnLeu610615620AlaAlaPheMetIleGlnGluGluTy rValAspGlnValSerGlyLeu625630635640SerAspLysLysPheGlnArgProAsnAspPheSerProProPheArg645 650655PheGlyThrValProAsnGlySerThrGluArgAsnIleArgAsnAsn660665670TyrAlaGluMetHisAlaTyrMetGlyLysP heAsnGlnArgGlyVal675680685AspAspAlaLeuLeuSerLeuLysThrGlyLysLeuAspAlaPheIle690695700 TyrAspAlaAlaValLeuAsnTyrMetAlaGlyArgAspGluGlyCys705710715720LysLeuValThrIleGlySerGlyLysValPheAlaSerThrGlyTyr725730735GlyIleAlaIleGlnLysAspSerGlyTrpLysArgGlnValAspLeu740745750AlaIl eLeuGlnLeuPheGlyAspGlyGluMetGluGluLeuGluAla755760765LeuTrpLeuThrGlyIleCysHisAsnGluLysAsnGluValMetSer770 775780SerGlnLeuAspIleAspAsnMetAlaGlyValPheTyrMetLeuGly785790795800AlaAlaMetAlaLeuSerLeuI leThrPheIleCysGluHisLeuPhe805810815TyrTrpGlnPheArgHisCysPheMetGlyValCysSerGlyLysPro820 825830GlyMetValPheSerIleSerArgGlyIleTyrSerCysIleHisGly835840845ValAlaIleGluGluArgGlnSerValMetAsnSer ProThrAlaThr850855860MetAsnAsnThrHisSerAsnIleLeuArgLeuLeuArgThrAlaLys86587087588 0AsnMetAlaAsnLeuSerGlyValAsnGlySerProGlnSerAlaLeu885890895AspPheIleArgArgGluSerSerValTyrAspIleSerGluHisArg900905910ArgSerPheThrHisSerAspCysLysSerTyrAsnAsnProProCys915920925GluGluAsnL euPheSerAspTyrIleSerGluValGluArgThrPhe930935940GlyAsnLeuGlnLeuLysAspSerAsnValTyrGlnAspHisTyrHis945950 955960HisHisHisArgProHisSerIleGlySerThrSerSerIleAspGly965970975LeuTyrAspCysAspAsnPro ProPheThrThrGlnProArgSerIle980985990SerLysLysProLeuAspIleGlyLeuProSerSerLysHisSerGln9951000 1005LeuSerAspLeuTyrGlyLysPheSerPheLysSerAspArgTyrSer101010151020GlyHisAspAspLeuIleArgSerAspValSerAspIleSerThr His1025103010351040ThrValThrTyrGlyAsnIleGluGlyAsnAlaAlaLysArgArgLys1045105010 55GlnGlnTyrLysAspSerLeuLysLysArgProAlaSerAlaLysSer106010651070ArgArgGluPheAspGluIleGluLeuAlaTyrArgArgArgProPro 107510801085ArgSerProAspHisLysArgTyrPheArgAspLysGluGlyLeuArg109010951100AspPheTyrLeuAspGln PheArgThrLysGluAsnSerProHisTrp1105111011151120GluHisValAspLeuThrAspIleTyrLysGluArgSerCysAspPhe1125 11301135LysArgAspSerValSerGlyGlyGlyProCysThrAsnArgSerHis114011451150LeuLysHisGlyThrGlyAspLys HisGlyValValGlyGlyValPro115511601165AlaProTrpGluLysAsnLeuThrAsnValAspTrpGluAspArgSer11701175 1180GlyGlyAsnPheCysArgSerCysProSerLysLeuHisAsnTyrSer1185119011951200SerThrValAlaGlyGlnAsnSerGlyArgGlnAlaCysIl eArgCys120512101215GluAlaCysLysLysAlaGlyAsnLeuTyrAspIleSerGluAspAsn122012251230SerLeuGlnGluLeuAspGlnProAlaAlaProValAlaValSerSer123512401245AsnAlaSerThrThrLysTyrProGlnSerProThrAsnSerLysAla125 012551260GlnLysLysAsnArgAsnLysLeuArgArgGlnHisSerTyrAspThr1265127012751280PheValAspLeuGln LysGluGluAlaAlaLeuAlaProArgSerVal128512901295SerLeuLysAspLysGlyArgPheMetAspGlySerProTyrAlaHis1300 13051310MetPheGluMetProAlaGlyGluSerSerPheAlaAsnLysSerSer131513201325ValThrThrAlaGlyHisHisHisAsnAs nProGlySerGlyTyrMet133013351340LeuSerLysSerLeuTyrProAspArgValThrGlnAsnProPheIle134513501355 1360ProThrPheGlyAspAspGlnCysLeuLeuThrAlaAlaAsnProThr136513701375SerSerGlySerProThrValAlaGlyAlaSerLysThrA rgProAsp138013851390PheArgAlaLeuValThrAsnLysProValValSerAlaLeuHisGly139514001405Ala ValProGlyArgPheGlnLysAspIleCysIleGlyAsnGlnSer141014151420AsnProCysValProAsnAsnLysAsnProArgAlaPheAsnGlySer1425 143014351440SerAsnGlyHisValTyrGluLysLeuSerSerIleGluSerAspVal144514501455(2) INFORMATION FOR SEQ ID NO: 9: (i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 920 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:9: FROM 1 to 920(xi) SEQUENCE DESCRIPTION: SEQ ID NO:9:ArgAlaAlaCysAspProLysIleValAsnIleGlyAlaValLeuSer151015ThrArgLysHisG luGlnMetPheArgGluAlaValAsnGlnAlaAsn202530LysArgHisGlySerTrpLysIleGlnLeuAsnAlaThrSerValThr35 4045HisLysProAsnAlaIleGlnMetAlaLeuSerValCysGluAspLeu505560IleSerSerGlnValTyrAlaIleLeuValSerHis ProProThrPro65707580AsnAspHisPheThrProThrProValSerTyrThrAlaGlyPheTyr8590 95ArgIleProValLeuGlyLeuThrThrArgMetSerIleTyrSerAsp100105110LysSerIleHisLeuSerPheLeuArgThrValProProTyr SerHis115120125GlnSerSerValTrpPheGluMetMetArgValTyrAsnTrpAsnHis130135140IleIleLeuL euValSerAspAspHisGluGlyArgAlaAlaGlnLys145150155160ArgLeuGluThrLeuLeuGluGluArgGluSerLysAlaGluLysVal 165170175LeuGlnPheAspProGlyThrLysAsnValThrAlaLeuLeuMetGlu180185190AlaArgAspLeuGlu AlaArgValIleIleLeuSerAlaSerGluAsp195200205AspAlaAlaThrValTyrArgAlaAlaAlaMetLeuAsnMetThrGly210215 220SerGlyTyrValTrpLeuValGlyGluArgGluIleSerGlyAsnAla225230235240LeuArgTyrAlaProAspGlyIleIleGlyLeu GlnLeuIleAsnGly245250255LysAsnGluSerAlaHisIleSerAspAlaValGlyValValAlaGln260265 270AlaValHisGluLeuLeuGluLysGluAsnIleThrAspProProArg275280285GlyCysValGlyAsnThrAsnIleTrpLysThrGlyProLeuPheLy s290295300ArgValLeuMetSerSerLysTyrAlaAspGlyValThrGlyArgVal305310315320GluPhe AsnGluAspGlyAspArgLysPheAlaAsnTyrSerIleMet325330335AsnLeuGlnAsnArgLysLeuValGlnValGlyIleTyrAsnGlyThr 340345350HisValIleProAsnAspArgLysIleIleTrpProGlyGlyGluThr355360365GluLysProArgGlyTyrGln MetSerThrArgLeuLysIleValThr370375380IleHisGlnGluProPheValTyrValLysProThrMetSerAspGly3853903 95400ThrCysLysGluGluPheThrValAsnGlyAspProValLysLysVal405410415IleCysThrGlyProAsnAspThrSerProGl ySerProArgHisThr420425430ValProGlnCysCysTyrGlyPheCysValAspLeuLeuIleLysLeu435440 445AlaArgThrMetAsnPheThrTyrGluValHisLeuValAlaAspGly450455460LysPheGlyThrGlnGluArgValAsnAsnSerAsnLysLysGluTrp465 470475480AsnGlyMetMetGlyGluLeuLeuSerGlyGlnAlaAspMetIleVal485490495AlaPro LeuThrIleAsnAsnGluArgAlaGlnTyrIleGluPheSer500505510LysProPheLysTyrGlnGlyLeuThrIleLeuValLysLysGluIle515 520525ProArgSerThrLeuAspSerPheMetGlnProPheGlnSerThrLeu530535540TrpLeuLeuValGlyLeuSerValHisVa lValAlaValMetLeuTyr545550555560LeuLeuAspArgPheSerProPheGlyArgPheLysValAsnSerGlu565 570575GluGluGluGluAspAlaLeuThrLeuSerSerAlaMetTrpPheSer580585590TrpGlyValLeuLeuGlnSerGlyIleGlyGluG lyAlaProArgSer595600605PheSerAlaArgIleLeuGlyMetValTrpAlaGlyPheAlaMetIle610615620Ile ValAlaSerTyrThrAlaAsnLeuAlaAlaPheLeuValLeuAsp625630635640ArgProGluGluArgIleThrGlyIleAsnAspProArgLeuArgAsn 645650655ProSerAspLysPheIleTyrAlaThrValLysGlnSerSerValAsp660665670IleTyrPh eArgArgGlnValGluLeuSerThrMetTyrArgHisMet675680685GluLysHisAsnTyrGluSerAlaAlaGluAlaIleGlnAlaValArg690 695700AspAsnLysLeuHisAlaPheIleTrpAspSerAlaValLeuGluPhe705710715720GluAlaSerGlnLysCysAspLeuV alThrThrGlyGluLeuPhePhe725730735ArgSerGlyPheGlyIleGlyMetArgLysAspSerProTrpLysGln740745 750AsnValSerLeuSerIleLeuLysSerHisGluAsnGlyPheMetGlu755760765AspLeuAspLysThrTrpValArgTyrGlnGluCysAsp SerArgSer770775780AsnAlaProAlaThrLeuThrPheGluAsnMetAlaGlyValPheMet785790795800 LeuValAlaGlyGlyIleValAlaGlyIlePheLeuIlePheIleGlu805810815IleAlaTyrLysArgHisLysAspAlaArgArgLysGlnMetGlnLeu 820825830AlaPheAlaAlaValAsnValTrpArgLysAsnLeuGlnAspArgLys835840845SerGlyArgAlaG luProAspProLysLysLysAlaThrPheArgAla850855860IleThrSerThrLeuAlaSerSerPheLysArgArgArgSerSerLys865870 875880AspThrSerThrGlyGlyGlyArgGlyAlaLeuGlnAsnGlnLysAsp885890895ThrValLeuProArgArgAlaIle GluArgGluGluGlyGlnLeuGln900905910LeuCysSerArgHisArgGluSer915920(2) INFORMATION FOR SEQ ID NO: 10:(i) SEQUENCE CHARACTERISTICS: (A) LENGTH: 920 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME (K) RELEVANT RESIDUES IN SEQ ID NO:10: FROM 1 to 920(xi) SEQUENCE DESCRIPTION: SEQ ID NO:10:ArgAlaAlaCysAspProLysIleValAsnIleGlyAlaValLeuSer151015ThrArgLysHisGluGlnMetPheA rgGluAlaValAsnGlnAlaAsn202530LysArgHisGlySerTrpLysIleGlnLeuAsnAlaThrSerValThr3540 45HisLysProAsnAlaIleGlnMetAlaLeuSerValCysGluAspLeu505560IleSerSerGlnValTyrAlaIleLeuValSerHisProProThrPro65707580AsnAspHisPheThrProThrProValSerTyrThrAlaGlyPheTyr859095 ArgIleProValLeuGlyLeuThrThrArgMetSerIleTyrSerAsp100105110LysSerIleHisLeuSerPheLeuArgThrValProProTyrSerHis 115120125GlnSerSerValTrpPheGluMetMetArgValTyrAsnTrpAsnHis130135140IleIleLeuLeuValSerAspAs pHisGluGlyArgAlaAlaGlnLys145150155160ArgLeuGluThrLeuLeuGluGluArgGluSerLysAlaGluLysVal165 170175LeuGlnPheAspProGlyThrLysAsnValThrAlaLeuLeuMetGlu180185190AlaArgAspLeuGluAlaArgValIleI leLeuSerAlaSerGluAsp195200205AspAlaAlaThrValTyrArgAlaAlaAlaMetLeuAsnMetThrGly210215220SerGlyTyrValTrpLeuValGlyGluArgGluIleSerGlyAsnAla225230235240LeuArgTyrAlaProAspGlyIleIleGlyLeuGlnLeuIleAsn Gly245250255LysAsnGluSerAlaHisIleSerAspAlaValGlyValValAlaGln260265270Al aValHisGluLeuLeuGluLysGluAsnIleThrAspProProArg275280285GlyCysValGlyAsnThrAsnIleTrpLysThrGlyProLeuPheLys290 295300ArgValLeuMetSerSerLysTyrAlaAspGlyValThrGlyArgVal305310315320GluPheAsnGluAspGlyA spArgLysPheAlaAsnTyrSerIleMet325330335AsnLeuGlnAsnArgLysLeuValGlnValGlyIleTyrAsnGlyThr340 345350HisValIleProAsnAspArgLysIleIleTrpProGlyGlyGluThr355360365GluLysProArgGlyTyrGlnMetSerThrArg LeuLysIleValThr370375380IleHisGlnGluProPheValTyrValLysProThrMetSerAspGly385390395 400ThrCysLysGluGluPheThrValAsnGlyAspProValLysLysVal405410415IleCysThrGlyProAsnAspThrSerProGlySerProArgHis Thr420425430ValProGlnCysCysTyrGlyPheCysValAspLeuLeuIleLysLeu435440445AlaArgT hrMetAsnPheThrTyrGluValHisLeuValAlaAspGly450455460LysPheGlyThrGlnGluArgValAsnAsnSerAsnLysLysGluTrp465470 475480AsnGlyMetMetGlyGluLeuLeuSerGlyGlnAlaAspMetIleVal485490495AlaProLeuThrIleAsn AsnGluArgAlaGlnTyrIleGluPheSer500505510LysProPheLysTyrGlnGlyLeuThrIleLeuValLysLysGluIle51552 0525ProArgSerThrLeuAspSerPheMetGlnProPheGlnSerThrLeu530535540TrpLeuLeuValGlyLeuSerValHisValValAlaValMet LeuTyr545550555560LeuLeuAspArgPheSerProPheGlyArgPheLysValAsnSerThr565570 575SerAspGlnSerAsnAlaLeuThrLeuSerSerAlaMetTrpPheSer580585590TrpGlyValLeuLeuAsnSerGlyIleGlyGluGlyAlaProArgSe r595600605PheSerAlaArgIleLeuGlyMetValTrpAlaGlyPheAlaMetIle610615620IleValAlaSerTyr ThrAlaAsnLeuAlaAlaPheLeuValLeuAsp625630635640ArgProGluGluArgIleThrGlyIleAsnAspProArgLeuArgAsn64 5650655ProSerAspLysPheIleTyrAlaThrValLysGlnSerSerValAsp660665670IleTyrPheArgArgGlnVal GluLeuSerThrMetTyrArgHisMet675680685GluLysHisAsnTyrGluSerAlaAlaGluAlaIleGlnAlaValArg690695 700AspAsnLysLeuHisAlaPheIleTrpAspSerAlaValLeuGluPhe705710715720GluAlaSerGlnLysCysAspLeuValThrThrGlyGl uLeuPhePhe725730735ArgSerGlyPheGlyIleGlyMetArgLysAspSerProTrpLysGln740745 750AsnValSerLeuSerIleLeuLysSerHisGluAsnGlyPheMetGlu755760765AspLeuAspLysThrTrpValArgTyrGlnGluCysAspSerArgSer 770775780AsnAlaProAlaThrLeuThrPheGluAsnMetAlaGlyValPheMet785790795800LeuValAlaGly GlyIleValAlaGlyIlePheLeuIlePheIleGlu805810815IleAlaTyrLysArgHisLysAspAlaArgArgLysGlnMetGlnLeu820 825830AlaPheAlaAlaValAsnValTrpArgLysAsnLeuGlnAspArgLys835840845SerGlyArgAlaGluProAspProLy sLysLysAlaThrPheArgAla850855860IleThrSerThrLeuAlaSerSerPheLysArgArgArgSerSerLys865870875 880AspThrSerThrGlyGlyGlyArgGlyAlaLeuGlnAsnGlnLysAsp885890895ThrValLeuProArgArgAlaIleGluArgGluGluG lyGlnLeuGln900905910LeuCysSerArgHisArgGluSer915920(2) INFORMATION FOR SEQ ID NO: 11:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 9 nucleic acids (B) TYPE: nucleic acid(C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:11: FROM 1 to 9(xi) SEQUENCE DESCRIPTION: SEQ ID NO:11:CCAGGTGCA 9(2) INFORMATION FOR SEQ ID NO: 12:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 7 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: peptide(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse (F) TISSUE TYPE: brain(ix) FEATURE:(D) OTHER INFORMATION: Xaa in location 5 is Ile or Met(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:12: FROM 1 to 7(xi) SEQUENCE DESCRIPTION: SEQ ID NO:12:TrpAsnGlyMetXaaGlyGlu15(2) INFORMATION FOR SEQ ID NO: 13:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 7 amino acids(B) TYPE: amino acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: protein(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:13: FROM 1 to 7(xi) SEQUENCE DESCRIPTION: SEQ ID NO:13:TyrThrAlaAsnLeuAlaAla15(2) INFORMATION FOR SEQ ID NO: 14:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 20 nucleic acids(B) TYPE: nucleic acid (C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: other nucleic acid(senseprimerofPCRreaction)(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(ix) FEATURE:(D) OTHER INFORMATION: Y in location 1 is T or C, W in location 9 is A or T and N in location14 is A, T, G or C(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:14: FROM 1 to 20(xi) SEQUENCE DESCRIPTION: SEQ ID NO:14:TGGAAYGGWATG ATNGGNGA20(2) INFORMATION FOR SEQ ID NO: 15:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 20 nucleic acids(B) TYPE: nucleic acid(C) STRANDEDNESS: single strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: other nucleic acid (anti-sense primer of PCR reaction)(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(ix) FEATURE:(D) OTHER INFORMATION: D in location 3 is G, A or T, Y inlocation 6 is T or C, R in location8 is A or G and N in location 15 is A, T, G or C(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:15: FROM 1 to 20(xi) SEQUENCE DESCRIPTION: SEQ ID NO:15:GCDGCYARRTTDGCNRTRTA 20(2) INFORMATION FOR SEQ ID NO: 16:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 3969 nucleic acids(B) TYPE: nucleic acid(C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION: (A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:16: FROM 1 to 3969(xi) SEQUENCE DESCRIPTION: SEQ ID NO:16:ATGCGCGGCGCCGGTGGCCCCCGCGGCCCTCGGGGCCCCGCTAAGATG48CTGTTGCTGCTGGCGCTGGCGTGCGCCAGCCCG TTCCCGGAGGAGGTG96CCGGGGCCGGGCGCGGCCGGCGGGGGCACGGGCGGGGCGCGGCCGCTC144AACGTGGCGCTGGTCTTCTCTGGCCCGGCGTACGCGGCCGAGGCGGCG192CGCTTGGGCCCGGCCGT GGCGGCGGCAGTGCGCAGCCCGGGCCTGGAC240GTACGGCCCGTGGCGCTGGTGCTCAACGGCTCCGACCCTCGCAGCCTT288GTGCTGCAGCTCTGCGACCTGCTGTCGGGGCTGCGCGTGCACGGCGTG336 GTGTTCGAGGACGACTCGCGCGCGCCCGCCGTCGCGCCCATTCTCGAC384TTCCTGTCGGCGCAGACCTCGCTGCCCATCGTGGCCGTGCACGGCGGC432GCCGCGCTCGTACTCACACCCAAGGAGAAGGGCTCCACC TTCCTGCAG480CTTGGCTCCTCCACAGAGCAACAGCTGCAGGTCATTTTTGAGGTGCTG528GAGGAGTACGACTGGACATCCTTTGTGGCAGTGACTACGCGTGCCCCA576GGCCATCGAGCCTTCTTGTCATA CATCGAGGTGCTGACTGATGGCAGC624CTGGTGGGCTGGGAGCATCGAGGAGCGCTGACACTGGACCCCGGAGCG672GGTGAGGCCGTCCTGGGCGCACAGCTCCGTAGTGTCAGTGCGCAGATC720CGCCTG CTCTTCTGCGCCCGCGAGGAGGCAGAGCCTGTTTTCCGGGCG768GCAGAAGAGGCTGGTCTCACTGGGCCTGGCTACGTCTGGTTCATGGTG816GGACCTCAGCTGGCCGGAGGTGGGGGCTCCGGGGTCCCTGGGGAA CCA864CTTCTTCTGCCAGGAGGTGCCCCACTGCCTGCTGGGCTGTTTGCAGTG912CGCTCTGCTGGCTGGCGTGACGACTTGGCACGTCGAGTGGCTGCTGGT960GTGGCGGTGGTGGCCAGAGGTGCCCAGGC CCTGCTGCGAGACTATGGC1008TTCCTGCCTGAGCTGGGCCATGACTGTCGCGCCCAGAATCGCACCCAC1056CGCGGGGAGAGTCTGCACAGGTATTTCATGAACATCACCTGGGATAAC1104CGAGACTACTCC TTCAATGAGGATGGCTTTCTGGTAAACCCGTCACTG1152GTAGTCATCTCCCTCACCAGAGACAGGACGTGGGAAGTGGTGGGCAGC1200TGGGAACAGCAGACCCTCCGCCTCAAGTACCCTCTATGGTCCCGCTAT12 48GGCCGCTTCCTGCAGCCGGTGGATGACACGCAGCACCTCACTGTGGCC1296ACGCTGGAGGAGAGACCTTTTGTCATTGTAGAGCCTGCAGACCCCATC1344AGCGGCACTTGCATCAGAGACTCGGTTCCCTGCCG GAGCCAGCTCAAC1392CGTACCCACAGCCCTCCGCCTGACGCTCCCCGCCCGGAGAAGAGATGC1440TGCAAGGGTTTCTGCATTGACATTTTGAAGAGGCTGGCGCACACCATC1488GGTTTCAGCTATGACCTC TACCTGGTTACCAACGGCAAGCATGGCAAG1536AAGATCGATGGCGTCTGGAATGGCATGATTGGTGAGGTGTTCTATCAG1584CGTGCGGACATGGCCATCGGCTCCCTCACCATCAATGAGGAGCGGTCA1632GA GATCGTGGACTTCTCCGTCCCTTTTGTAGAGACAGGCATCAGCGTC1680ATGGTGGCACGCAGCAATGGCACTGTGTCCCCCTCTGCCTTCCTCGAG1728CCCTACAGCCCCGCTGTGTGGGTGATGATGTTCGTCATGTG CCTCACC1776GTGGTCGCCGTCACAGTTTTCATCTTTGAGTACCTCAGTCCTGTGGGC1824TATAACCGAAGCCTGGCCACGGGCAAACGCCCCGGAGGCTCTACCTTC1872ACCATTGGGAAATCCATCTGGCTG CTGTGGGCCCTGGTGTTCAACAAC1920TCCGTGCCAGTGGAGAATCCTCGGGGCACCACCAGCAAGATCATGGTG1968CTGGTGTGGGCCTTCTTTGCCGTCATCTTTCTTGCCAGCTATACAGCC2016AATCTGGC TGCCTTCATGATCCAGGAGGAGTACGTGGACACCGTGTCT2064GGGCTCAGCGACCGGAAGTTCCAGCGGCCCCAGGAGCAATACCCACCC2112CTGAAGTTTGGAACGGTGCCCAATGGGTCCACGGAGAAGAATATCCG A2160AGCAACTACCCTGATATGCACAGCTACATGGTGCGATACAACCAGCCA2208AGAGTGGAGGAGGCGCTCACTCAGCTCAAGGCAGGGAAACTGGACGCC2256TTCATCTATGACGCAGCAGTGCTCAACTAC ATGGCCCGAAAGGATGAG2304GGCTGCAAGCTGGTCACCATCGGCTCAGGCAAGGTCTTCGCCACCACT2352GGTTATGGCATCGCCCTACACAAGGGCTCCCGCTGGAAGAGGCCCATC2400GACCTGGCGCTGCT GCAGTTCCTGGGGGACGATGAGATTGAGATGCTG2448GAGCGGCTGTGGCTTTCAGGGATCTGCCACAACGACAAAATCGAGGTG2496ATGAGCAGCAAGCTGGATATCGACAACATGGCAGGTGTCTTCTACATG2544CTCCTCGTGGCCATGGGCCTCTCCTTGCTGGTCTTCGCCTGGGAACAC2592CTTGTGTACTGGCGACTGCGGCACTGTCTGGGGCCCACCCACCGCATG2640GATTTCCTACTGGCCTTCTCCAGGGGTATGTACAGC TGCTGCAGCGCT2688GAGGCTGCTCCGCCGCCGGCCAAACCCCCGCCACCGCCGCAGCCGCTG2736CCCAGTCCGGCGTATCCCGCCGCTCGCCCACCCCCTGGCCCCGCACCC2784TTCGTGCCCCGAGAGCGCGC AGCCGCCGACCGCTGGCGCCGGGCCAAG2832GGCACAGGGCCCCCGGGGGGCGCAGCGCTAGCCGACGGCTTCCACCGA2880TACTACGGCCCCATCGAGCCGCAGGGGCTGGGCCTCGGCGAGGCGCGC2928GCG GCACCGAGAGGCGCAGCCGGACGCCCACTGTCCCCACCCACCACA2976CAGCCCCCACAGAAGCCACCACCTTCCTACTTCGCCATCGTGCGCGAG3024CAAGAGCCGGCCGAGCCCCCCGCCGGCGCCTTCCCGGGCTTT CCATCT3072CCGCCCGCTCCGCCTGCCGCCGCAGCCGCCGCCGTCGGGCCGCCACTG3120TGCCGCCTGGCTTTCGAGGACGAGAGCCCGCCCGCGCCCTCGGCTGGC3168CGCGTTCTGACCCCGAGAGCCAGCCG CTGTTGGGTGGGGGCGCGGGCG3216GCCCGAGCGCTGGGGCCCCGACCGCACCACCGCCGCGTCCGCACCGCG3264CCACCACCGTGCGCCTACCTGGACCTCGAGCCTTCGCCTTCGGACTCC3312GAGGATTCG GAGAGCCTGGGCGGAGCGTCGCTCGGTGGCCTGGAGCCC3360TGGTGGTTCGCCGACTTCCCCTACCCGTATGCGGAGCGCCTCGGGCCG3408CCGCCCGGCCGCTACTGGTCGGTTGACAAGCTCGGGGGCTGGCGCGCT 3456GGTAGCTGGGACTACCTGCCCCCGCGCGGCGGCCCCGCATGGCACTGC3504CGCCACTGCGCCAGCCTGGAGCTGCTACCGCCACCACGCCATCTCAGC3552TGCTCGCACGACGGCCTAGACGGTGGCTGGTG GGCGCCTCCGCCTCCA3600CCCTGGGCTGCGGGGCCACCGGCCCCGCGCCGGGCGCGCTGTGGTTGT3648CCGCGACCGCACCCGCACCGCCCCCGGGCTTCGCACCGTGCGCCCGCC3696GCCGCACCGCACCAC CACCGACACAGGCGCGCGGCGGGTGGCTGGGAC3744CTCCCGCCGCCCGCGCCCACCTCGCGTTCGCTGGAGGACCTGAGCTCC3792TGCCCACGGGCGGCCCCCACGCGCAGGCTCACCGGGCCCTCGCGCCAC3840GCGCGCCGCTGTCCGCACGCTGCGCATTGGGGGCCGCCCCTGCCCACC3888GCATCTCACCGGAGACACCGGGGCGGGGACCTGGGCACACGCAGGGGC3936TCTGCGCACTTCTCCAGCCTGGAGTCCGAGGTA 3969(2) INFORMATION FOR SEQ ID NO: 17:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 4368 nucleic acids(B) TYPE: nucleic acid(C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain( x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:17: FROM 1 to 4368(xi) SEQUENCE DESCRIPTION: SEQ ID NO:17:CGTTCCCAAAAGAGCGCCCCCAGCATCGGCATCGCTGTCATCCTCGTG48GGCACTTCCGACGAAGTGGCCATA AAAGATGCCCACGAGAAAGATGAC96TTCCATCATCTCTCAGTAGTTCCCCGGGTGGAGCTGGTAGCCATGAAC144GAGACTGACCCAAAGAGCATAATCACCCGCATCTGCGATCTTATGTCT192GACCGGAA GATCCAGGGGGTGGTGCTCGCGGATGACACGGACCAGGAA240GCCATCGCCCAGATCCTCGATTTCATTTCTGCTCAGACTCTCACCCCC288ATCCTGGGCATCCATGGGGGCTCATCTATGATAATGGCAGATAAGGA T336GAGTCCTCCATGTTCTTCCAGTTTGGCCCATCCATTGAACAGCAAGCT384TCTGTCATGCTCAACATCATGGAAGAATACGACTGGTACATCTTCTCC432ATCGTCACCACCTACTTCCCCGGCTACCAG GACTTCGTGAACAAGATC480CGCAGCACTATTGAGAACAGCTTTGTGGGCTGGGAGCTCGAGGAAGTC528CTCCTGCTAGACATGTCTCTAGACGATGGCGACTCTAAGATTCAGAAT576CAGCTGAAGAAGCT GCAGAGCCCCATCATTCTCCTCTACTGCACAAAG624GAAGAAGCCACCTACATCTTCGAAGTAGCTAACTCAGTTGGGCTGACT672GGCTACGGCTACACATGGATCGTGCCGAGTCTGGTGGCGGGGGATACA720GACACGGTGCCTTCAGAGTTCCCCACGGGGCTCATCTCTGTGTCATAT768GACGAATGGGACTATGGCCTTCCTGCCAGAGTGAGAGATGGGATTGCC816ATCATCACCACTGCTGCCTCGGACATGCTGTCCGAA CACAGTTTCATC864CCTGAGCCCAAGAGCAGTTGCTACAACACCCACGAGAAGAGGATCTAC912CAGTCTAACATGCTGAATAGGTATCTGATCAACGTCACTTTTGAAGGG960AGAAACCTGTCCTTCAGTGA AGATGGCTACCAGATGCATCCGAAGCTG1008GTGATAATCCTTCTGAACAAGGAGAGGAAGTGGGAGAGGGTGGGAAAA1056TGGAAAGACAAGTCCCTGCAGATGAAATACTACGTGTGGCCTCGAATG1104TGT CCAGAGACTGAAGAACAGGAAGATGACCATCTGAGCATCGTTACC1152TTGGAGGAGGCACCGTTTGTCATTGTGGAAAGTGTGGACCCTCTCAGT1200GGGACCTGCATGCGGAATACAGTCCCGTGCCAGAAGCGCATC ATCTCT1248GAGAATAAAACAGATGAGGAACCAGGCTACATCAAAAAATGCTGCAAG1296GGGTTTTGTATTGATATCCTTAAGAAAATTTCTAAGTCTGTGAAGTTC1344ACCTATGACCTTTACCTGGTGACCAA TGGCAAGCATGGAAAGAAAATC1392AACGGGACCTGGAACGGCATGATTGGTGAGGTGGTCATGAAGAGGGCC1440TACATGGCAGTGGGATCACTAACTATCAATGAAGAACGGTCAGAGGTG1488GTTGACTTC TCTGTGCCCTTCATAGAGACTGGCATCAGTGTCATGGTA1536TCACGCAGCAATGGGACTGTGTCACCTTCTGCCTTCTTAGAGCCATTC1584AGTGCTGACGTGTGGGTGATGATGTTTGTGATGCTGCTCATTGTCTCT 1632GCTGTAGCTGTCTTTGTCTTTGAATACTTCAGCCCTGTGGGTTACAAC1680CGGTGCCTAGCTGATGGCAGAGAGCCAGGCGGCCCATCTTTCACCATC1728GGCAAAGCGATTTGGTTACTCTGGGGTCTGGT GTTTCAGAACTCCGTA1776CCTGTGCAGAACCCAAAGGGGACCACCTCCAAGATCATGGTGTCAGTG1824TGGGCCTTCTTTGCTGTCATTTTCCTGGCCAGCTACACTGCCAACTTA1872GCCGCCTTCATGATC CAAGAGGAGTATGTGGACCAGGTTTCCGGCCTG1920AGTGACAAGAAGTTCCAGAGACCTAATGACTTCTCACCCCCTTTCCGC1968TTTGGGACTGTGCCCAATGGCAGCACAGAGAGGAATATCCGTAATAAC2016TATGCAGAAATGCATGCCTACATGGGAAAGTTCAACCAAAGGGGTGTA2064GATGATGCCTTGCTCTCCCTGAAAACAGGGAAACTTGATGCATTCATC2112TACGATGCAGCCGTGCTCAACTACATGGCTGGAAGAGA CGAAGGCTGC2160AAGCTGGTGACCATTGGCAGTGGCAAGGTCTTTGCTTCTACGGGCTAT2208GGCATTGCTATCCAAAAAGACTCTGGTTGGAAACGCCAGGTGGACCTT2256GCTATCCTGCAGCTGTTTGGA GATGGGGAGATGGAAGAACTGGAAGCT2304CTCTGGCTCACTGGCATTTGCCACAATGAGAAGAATGAGGTTATGAGC2352AGCCAGCTGGACATTGACAACATGGCGGGCGTCTTCTATATGTTGGGG2400GCAGC CATGGCTCTCAGCCTCATCACCTTCATCTGTGAACATCTCTTC2448TATTGGCAGTTCCGACATTGCTTCATGGGTGTCTGTTCTGGCAAGCCT2496GGCATGGTCTTCTCCATCAGCAGAGGTATCTACAGCTGTATCCA CGGA2544GTAGCTATAGAGGAGCGCCAATCCGTGATGAACTCCCCCACTGCCACC2592ATGAACAACACACACTCCAATATCCTACGCTTGCTCCGAACGGCCAAA2640AACATGGCCAACCTGTCTGGAGTCAAC GGCTCCCCCCAGAGTGCCCTG2688GACTTCATCCGCCGTGAGTCCTCTGTCTATGACATCTCTGAGCATCGC2736CGCAGCTTCACGCATTCAGACTGCAAGTCGTACAATAACCCACCCTGT2784GAGGAAAACCT GTTCAGTGACTACATTAGTGAGGTAGAGAGAACATTT2832GGCAACCTGCAGCTGAAGGACAGCAATGTGTACCAAGACCACTATCAC2880CATCACCACCGGCCCCACAGCATCGGCAGCACCAGCTCCATTGATGGG 2928CTCTATGACTGTGACAACCCACCCTTTACCACCCAGCCCAGGTCAATC2976AGCAAGAAACCCCTGGACATTGGCCTGCCCTCCTCCAAACACAGCCAG3024CTCAGCGACCTGTACGGCAAGTTCTCTTTCAAG AGTGACCGCTACAGT3072GGCCATGATGACTTGATTCGATCGGATGTCTCAGACATCTCCACGCAT3120ACTGTCACCTATGGCAACATCGAGGGCAACGCAGCCAAGAGGAGGAAG3168CAGCAATATAAGGACAG TCTAAAGAAGCGGCCAGCCTCGGCCAAATCT3216AGGAGGGAGTTTGATGAAATCGAGCTGGCCTACCGTCGCCGACCACCC3264CGCTCCCCAGACCACAAGCGCTACTTCAGGGACAAAGAAGGGCTCCGA3312 GACTTCTACCTGGACCAGTTCCGAACAAAGGAGAACTCGCCTCACTGG3360GAGCACGTGGACTTAACTGACATTTACAAAGAACGTAGTTGTGACTTC3408AAGCGAGATTCGGTCAGTGGAGGCGGGCCCTGTACCAAC AGGTCTCAC3456CTTAAACACGGAACAGGCGATAAGCACGGAGTGGTAGGCGGGGTGCCT3504GCTCCTTGGGAGAAGAACCTGACCAATGTGGATTGGGAGGATAGGTCT3552GGGGGCAACTTCTGCCGCAGCTG TCCCTCCAAGCTGCACAATTACTCC3600TCTACGGTGGCAGGGCAAAACTCGGGCCGGCAGGCCTGCATCAGGTGT3648GAGGCCTGCAAGAAGGCTGGCAACCTGTATGACATCAGCGAGGACAAC3696TCCCTG CAGGAACTGGACCAGCCGGCTGCCCCTGTGGCTGTGTCATCC3744AACGCCTCCACCACCAAGTACCCTCAAAGCCCGACTAATTCCAAGGCC3792CAGAAGAAGAATCGGAACAAACTGCGCCGGCAGCACTCCTACGAC ACC3840TTCGTGGACCTGCAGAAGGAGGAGGCCGCCTTGGCCCCACGCAGCGTG3888AGCCTGAAAGACAAGGGCCGATTCATGGATGGGAGCCCCTACGCCCAT3936ATGTTTGAGATGCCAGCTGGTGAGAGCTC CTTTGCCAACAAGTCCTCA3984GTGACCACTGCCGGACACCATCACAACAATCCCGGCAGCGGCTACATG4032CTCAGCAAGTCGCTCTACCCTGACCGGGTCACGCAAAACCCTTTCATC4080CCCACTTTTGGG GATGATCAGTGCTTGCTTACGGCAGCAAATCCTACT4128TCTTCAGGCAGCCCAACGGTGGCAGGGGCGTCGAAAACAAGGCCGGAC4176TTCCGGGCCCTTGTCACCAATAAGCCAGTGGTGTCGGCCCTTCATGGG42 24GCTGTGCCAGGTCGTTTCCAGAAGGACATTTGTATAGGGAACCAGTCC4272AACCCCTGTGTGCCTAACAACAAAAACCCCAGGGCTTTCAATGGCTCC4320AGCAATGGACATGTTTATGAGAAACTTTCTAGTAT TGAGTCTGATGTC4368(2) INFORMATION FOR SEQ ID NO: 18:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 2760 nucleic acids(B) TYPE: nucleic acid(C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain (x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA(B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:18: FROM 1 to 2760(xi) SEQUENCE DESCRIPTION: SEQ ID NO:18:CGCGCTGCCTGCGACCCCAAGATTGTCAACATCGGCGCGGTGCTGAGC48ACGCGCAAGCACGAGCAGATG TTCCGCGAGGCAGTAAACCAGGCCAAT96AAGCGACACGGCTCTTGGAAGATACAGCTCAACGCCACTTCTGTCACC144CACAAGCCCAACGCCATACAGATGGCCCTGTCAGTGTGTGAGGACCTC192ATCT CTAGCCAGGTCTACGCTATCCTAGTTAGTCACCCGCCTACTCCC240AACGACCACTTCACTCCCACCCCTGTCTCCTACACAGCTGGCTTCTAC288AGAATCCCCGTCCTGGGGCTGACTACCCGAATGTCCATCTACT CTGAC336AAGAGCATCCACCTGAGCTTCCTTCGCACCGTACCACCCTACTCCCAC384CAGTCCAGCGTCTGGTTTGAGATGATGCGCGTCTACAACTGGAACCAT432ATCATCCTGCTGGTCAGCGATGACCAC GAGGGCCGGGCAGCGCAGAAG480CGCCTGGAGACGTTGCTGGAGGAGCGTGAGTCCAAGGCAGAGAAGGTG528CTGCAGTTTGACCCAGGAACCAAGAATGTGACGGCTCTGCTGATGGAA576GCCCGGGACC TGGAAGCCCGGGTCATCATCCTTTCTGCAAGCGAGGAC624GACGCTGCCACCGTATACCGCGCAGCCGCGATGCTGAACATGACTGGC672TCTGGGTACGTGTGGCTCGTCGGGGAGCGCGAGATCTCTGGGAATGCC 720CTGCGCTACGCTCCTGACGGCATCATCGGACTTCAGCTAATCAACGGC768AAGAACGAGTCGGCCCACATCAGTGACGCTGTGGGCGTGGTGGCACAG816GCAGTCCACGAGCTCCTAGAAAAGGAGAACATC ACTGATCCACCGCGG864GGTTGCGTGGGCAACACCAACATCTGGAAGACAGGACCACTGTTCAAG912AGGGTGCTGATGTCTTCCAAGTATGCAGATGGAGTGACTGGCCGTGTG960GAATTCAATGAGGATG GGGACCGGAAGTTTGCCAACTATAGTATCATG1008AACCTGCAGAACCGCAAGCTGGTGCAAGTGGGCATCTACAATGGTACC1056CATGTCATCCCAAATGACAGGAAGATCATCTGGCCAGGAGGAGAGACA1104 GAGAAGCCTCGAGGATACCAGATGTCCACCAGACTAAAGATAGTGACA1152ATCCACCAAGAACCCTTCGTGTATGTCAAGCCCACAATGAGTGATGGC1200ACATGCAAAGAGGAGTTCACAGTCAATGGTGACCCTGTC AAGAAGGTG1248ATCTGTACGGGGCCTAATGACACATCCCCAGGAAGCCCACGTCACACA1296GTGCCCCAGTGCTGTTATGGCTTCTGCGTTGACCTGCTCATCAAGCTG1344GCACGGACCATGAATTTTACCT ACGAGGTGCACCTTGTGGCAGATGGC1392AAGTTTGGCACACAGGAGCGGGTAAACAACAGCAACAAAAAGGAGTGG1440AACGGAATGATGGGAGAGCTGCTCAGTGGTCAAGCAGACATGATCGTG1488GCTCCA CTGACCATTAACAATGAGCGTGCGCAGTACATAGAGTTCTCC1536AAGCCCTTCAAGTACCAGGGCCTGACCATTCTGGTCAAGAAGGAGATC1584CCTCGGAGCACACTGGACTCATTCATGCAGCCCTTTCAGAGCACA CTG1632TGGCTGCTGGTGGGGCTGTCAGTTCATGTGGTGGCCGTGATGCTGTAC1680CTGCTGGACCGCTTCAGTCCCTTTGGCCGATTTAAGGTGAACAGCGAG1728GAGGAGGAGGAGGATGCACTGACCCTGT CCTCTGCCATGTGGTTTTCC1776TGGGGCGTCCTGCTCCAGTCTGGCATTGGGGAAGGTGCCCCCCGGAGT1824TTCTCTGCTCGTATCCTAGGCATGGTGTGGGCTGGTTTTGCCATGATC1872ATCGTGGCTTCC TACACTGCCAACCTGGCAGCCTTCCTGGTGCTGGAT1920AGGCCTGAGGAGCGCATCACAGGCATCAATGACCCCAGGCTCAGAAAC1968CCCTCAGACAAGTTCATCTATGCAACTGTAAAACAGAGCTCTGTGGAT2 016ATCTACTTCCGGAGGCAGGTGGAGTTGAGCACCATGTACCGGCACATG2064GAGAAGCACAATTATGAGAGTGCAGCTGAGGCCATCCAGGCTGTGCGG2112GACAACAAGCTCCATGCCTTCATCTGGGACTCAG CTGTGCTGGAGTTT2160GAGGCTTCACAGAAGTGCGATCTGGTGACCACGGGTGAGCTGTTCTTC2208CGCTCCGGCTTTGGCATCGGCATGCGCAAGGACAGCCCCTGGAAGCAA2256AATGTGTCCCTGTCCATA CTCAAGTCCCATGAGAATGGCTTCATGGAA2304GACCTGGATAAGACATGGGTTCGGTATCAAGAATGTGACTCCCGCAGC2352AATGCCCCTGCCACCCTCACTTTTGAGAACATGGCAGGGGTCTTCATG2400C TGGTGGCTGGAGGCATCGTAGCTGGGATCTTCCTCATTTTCATCGAG2448ATCGCCTACAAGCGACACAAGGATGCCCGTAGGAAGCAGATGCAGCTG2496GCTTTTGCAGCCGTGAACGTGTGGAGGAAGAACCTGCAGG ATAGAAAG2544AGTGGTAGAGCAGAGCCCGACCCTAAAAAGAAAGCCACATTTAGGGCT2592ATCACCTCCACCCTGGCCTCCAGCTTCAAGAGACGTAGGTCCTCCAAA2640GACACGAGCACCGGGGGTGGACGC GGCGCTTTGCAAAACCAAAAAGAC2688ACAGTGCTGCCGCGACGCGCTATTGAGAGGGAGGAGGGCCAGCTGCAG2736CTGTGTTCCCGTCATAGGGAGAGC2760(2) INFORMATION FOR SEQ ID NO: 19:(i) SEQUENCE CHARACTERISTICS:(A) LENGTH: 2760 nucleic acids(B) TYPE: nucleic acid(C) STRANDEDNESS: double strand(D) TOPOLOGY: linear(ii) MOLECULE TYPE: cDNA(vi) ORIGINAL SOURCE:(A) ORGANISM: mouse(F) TISSUE TYPE: brain(x) PUBLICATION INFORMATION:(A) AUTHORS: Masayoshi MISHINA (B) TITLE: NOVEL PROTEINS AND GENES CODING THE SAME(K) RELEVANT RESIDUES IN SEQ ID NO:19: FROM 1 to 2760(xi) SEQUENCE DESCRIPTION: SEQ ID NO:19:CGCGCTGCCTGCGACCCCAAGATTGTCAACATCGGCGCGGTGCTGAGC48ACGCGCAAGCACGAGCAGATGTTCCGCGAGGCAGTAAACCAGGCCAAT 96AAGCGACACGGCTCTTGGAAGATACAGCTCAACGCCACTTCTGTCACC144CACAAGCCCAACGCCATACAGATGGCCCTGTCAGTGTGTGAGGACCTC192ATCTCTAGCCAGGTCTACGCTATCCTAGTTAGT CACCCGCCTACTCCC240AACGACCACTTCACTCCCACCCCTGTCTCCTACACAGCTGGCTTCTAC288AGAATCCCCGTCCTGGGGCTGACTACCCGAATGTCCATCTACTCTGAC336AAGAGCATCCACCTGA GCTTCCTTCGCACCGTACCACCCTACTCCCAC384CAGTCCAGCGTCTGGTTTGAGATGATGCGCGTCTACAACTGGAACCAT432ATCATCCTGCTGGTCAGCGATGACCACGAGGGCCGGGCAGCGCAGAAG480 CGCCTGGAGACGTTGCTGGAGGAGCGTGAGTCCAAGGCAGAGAAGGTG528CTGCAGTTTGACCCAGGAACCAAGAATGTGACGGCTCTGCTGATGGAA576GCCCGGGACCTGGAAGCCCGGGTCATCATCCTTTCTGCA AGCGAGGAC624GACGCTGCCACCGTATACCGCGCAGCCGCGATGCTGAACATGACTGGC672TCTGGGTACGTGTGGCTCGTCGGGGAGCGCGAGATCTCTGGGAATGCC720CTGCGCTACGCTCCTGACGGCA TCATCGGACTTCAGCTAATCAACGGC768AAGAACGAGTCGGCCCACATCAGTGACGCTGTGGGCGTGGTGGCACAG816GCAGTCCACGAGCTCCTAGAAAAGGAGAACATCACTGATCCACCGCGG864GGTTGC GTGGGCAACACCAACATCTGGAAGACAGGACCACTGTTCAAG912AGGGTGCTGATGTCTTCCAAGTATGCAGATGGAGTGACTGGCCGTGTG960GAATTCAATGAGGATGGGGACCGGAAGTTTGCCAACTATAGTATC ATG1008AACCTGCAGAACCGCAAGCTGGTGCAAGTGGGCATCTACAATGGTACC1056CATGTCATCCCAAATGACAGGAAGATCATCTGGCCAGGAGGAGAGACA1104GAGAAGCCTCGAGGATACCAGATGTCCA CCAGACTAAAGATAGTGACA1152ATCCACCAAGAACCCTTCGTGTATGTCAAGCCCACAATGAGTGATGGC1200ACATGCAAAGAGGAGTTCACAGTCAATGGTGACCCTGTCAAGAAGGTG1248ATCTGTACGGGG CCTAATGACACATCCCCAGGAAGCCCACGTCACACA1296GTGCCCCAGTGCTGTTATGGCTTCTGCGTTGACCTGCTCATCAAGCTG1344GCACGGACCATGAATTTTACCTACGAGGTGCACCTTGTGGCAGATGGC1 392AAGTTTGGCACACAGGAGCGGGTAAACAACAGCAACAAAAAGGAGTGG1440AACGGAATGATGGGAGAGCTGCTCAGTGGTCAAGCAGACATGATCGTG1488GCTCCACTGACCATTAACAATGAGCGTGCGCAGT ACATAGAGTTCTCC1536AAGCCCTTCAAGTACCAGGGCCTGACCATTCTGGTCAAGAAGGAGATC1584CCTCGGAGCACACTGGACTCATTCATGCAGCCCTTTCAGAGCACACTG1632TGGCTGCTGGTGGGGCTG TCAGTTCATGTGGTGGCCGTGATGCTGTAC1680CTGCTGGACCGCTTCAGTCCCTTTGGCCGATTTAAGGTGAACAGCACC1728AGTGACCAGTCAAATGCACTGACCCTGTCCTCTGCCATGTGGTTTTCC1776T GGGGCGTCCTGCTCAACTCTGGCATTGGGGAAGGTGCCCCCCGGAGT1824TTCTCTGCTCGTATCCTAGGCATGGTGTGGGCTGGTTTTGCCATGATC1872ATCGTGGCTTCCTACACTGCCAACCTGGCAGCCTTCCTGG TGCTGGAT1920AGGCCTGAGGAGCGCATCACAGGCATCAATGACCCCAGGCTCAGAAAC1968CCCTCAGACAAGTTCATCTATGCAACTGTAAAACAGAGCTCTGTGGAT2016ATCTACTTCCGGAGGCAGGTGGAG TTGAGCACCATGTACCGGCACATG2064GAGAAGCACAATTATGAGAGTGCAGCTGAGGCCATCCAGGCTGTGCGG2112GACAACAAGCTCCATGCCTTCATCTGGGACTCAGCTGTGCTGGAGTTT2160GAGGCTT CACAGAAGTGCGATCTGGTGACCACGGGTGAGCTGTTCTTC2208CGCTCCGGCTTTGGCATCGGCATGCGCAAGGACAGCCCCTGGAAGCAA2256AATGTGTCCCTGTCCATACTCAAGTCCCATGAGAATGGCTTCATGG AA2304GACCTGGATAAGACATGGGTTCGGTATCAAGAATGTGACTCCCGCAGC2352AATGCCCCTGCCACCCTCACTTTTGAGAACATGGCAGGGGTCTTCATG2400CTGGTGGCTGGAGGCATCGTAGCTGGGATC TTCCTCATTTTCATCGAG2448ATCGCCTACAAGCGACACAAGGATGCCCGTAGGAAGCAGATGCAGCTG2496GCTTTTGCAGCCGTGAACGTGTGGAGGAAGAACCTGCAGGATAGAAAG2544AGTGGTAGAGCAG AGCCCGACCCTAAAAAGAAAGCCACATTTAGGGCT2592ATCACCTCCACCCTGGCCTCCAGCTTCAAGAGACGTAGGTCCTCCAAA2640GACACGAGCACCGGGGGTGGACGCGGCGCTTTGCAAAACCAAAAAGAC268 8ACAGTGCTGCCGCGACGCGCTATTGAGAGGGAGGAGGGCCAGCTGCAG2736CTGTGTTCCCGTCATAGGGAGAGC2760