IMGT Repertoire (RPI)
Other DSCAM entries
- Homo sapiens: DSCAM
IMGT RPI entry from gene to protein for Drosophila melanogaster DSCAM
Citing IMGT RPI entry for DSCAM
Duprat, E. et al.
IMGT standardization for alleles and mutations of the V-LIKE-DOMAINs and C-LIKE-DOMAINs
of the immunoglobulin superfamily,
Recent Research Developments in Human Genetics, 2, 111-136 (2004)
with permission from Research Signpost
with permission from Research SignpostIMGT gene name and definition
- IMGT gene name: Drosophila melanogaster DSCAM
- IMGT gene definition: Down syndrome cell adhesion molecule
Chromosomal localization
- Chromosome: 21
- Chromosomal localization: 21q22.2
Gene exon/intron organization
Legend:
- Length of the exons and introns are in base pairs.
- Colors are according to IMGT Color menu for regions and domains
Number of alleles: 1
IMGT reference alleles
| Allele names | Gene functionality | IMGT reference sequences | ||
|---|---|---|---|---|
| Exons | Accession numbers | Molecule type | ||
| DSCAM*01 | F | EX1-2, 3.1, 4, 5.1, 6-7, 8.1, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 1 |
| EX1-2, 3.1, 4, 5.2, 6-7, 8.2, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 2 | ||
| EX1-2, 3.1, 4, 5.3, 6-7, 8.3, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 3 | ||
| EX1-2, 3.1, 4, 5.4, 6-7, 8.3, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 4 | ||
| EX1-2, 3.2, 4, 5.5, 6-7, 8.4, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 5 | ||
| EX1-2, 3.3, 4, 5.6, 6-7, 8.5, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 6 | ||
| EX1-2, 3.3, 4, 5.7, 6-7, 8.6, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 7 | ||
| EX1-2, 3.3, 4, 5.8, 6-7, 8.7, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 8 | ||
| EX1-2, 3.3, 4, 5.9, 6-7, 8.8, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 9 | ||
| EX1-2, 3.4, 4, 5.10, 6-7, 8.9, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 10 | ||
| EX1-2, 3.5, 4, 5.6, 6-7, 8.10, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 11 | ||
| EX1-2, 3.5, 4, 5.11, 6-7, 8.2, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 12 | ||
| EX1-2, 3.5, 4, 5.12, 6-7, 8.6, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 13 | ||
| EX1-2, 3.5, 4, 5.13, 6-7, 8.11, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 14 | ||
| EX1-2, 3.5, 4, 5.14, 6-7, 8.3, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 15 | ||
| EX1-2, 3.5, 4, 5.15, 6-7, 8.5, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 16 | ||
| EX1-2, 3.6, 4, 5.7, 6-7, 8.12, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 17 | ||
| EX1-2, 3.6, 4, 5.16, 6-7, 8.13, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 18 | ||
| EX1-2, 3.6, 4, 5.17, 6-7, 8.2, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 19 | ||
| EX1-2, 3.6, 4, 5.13, 6-7, 8.14, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 20 | ||
| EX1-2, 3.6, 4, 5.2, 6-7, 8.15, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 21 | ||
| EX1-2, 3.6, 4, 5.18, 6-7, 8.16, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 22 | ||
| EX1-2, 3.6, 4, 5.4, 6-7, 8.17, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 23 | ||
| EX1-2, 3.6, 4, 5.14, 6-7, 8.15, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 24 | ||
| EX1-2, 3.6, 4, 5.19, 6-7, 8.4, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 25 | ||
| EX1-2, 3.7, 4, 5.8, 6-7, 8.18, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 26 | ||
| EX1-2, 3.7, 4, 5.20, 6-7, 8.3, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 27 | ||
| EX1-2, 3.7, 4, 5.21, 6-7, 8.19, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 28 | ||
| EX1-2, 3.7, 4, 5.12, 6-7, 8.20, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 29 | ||
| EX1-2, 3.7, 4, 5.22, 6-7, 8.3, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 30 | ||
| EX1-2, 3.7, 4, 5.13, 6-7, 8.21, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 31 | ||
| EX1-2, 3.8, 4, 5.23, 6-7, 8.22, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 32 | ||
| EX1-2, 3.8, 4, 5.24, 6-7, 8.8, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 33 | ||
| EX1-2, 3.8, 4, 5.25, 6-7, 8.9, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 34 | ||
| EX1-2, 3.8, 4, 5.14, 6-7, 8.12, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 35 | ||
| EX1-2, 3.9, 4, 5.26, 6-7, 8.12, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 36 | ||
| EX1-2, 3.9, 4, 5.7, 6-7, 8.23, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 37 | ||
| EX1-2, 3.9, 4, 5.12, 6-7, 8.24, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 38 | ||
| EX1-2, 3.10, 4, 5.27, 6-7, 8.13, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 39 | ||
| EX1-2, 3.10, 4, 5.8, 6-7, 8.22, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 40 | ||
| EX1-2, 3.10, 4, 5.28, 6-7, 8.19, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 41 | ||
| EX1-2, 3.10, 4, 5.29, 6-7, 8.23, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 42 | ||
| EX1-2, 3.11, 4, 5.8, 6-7, 8.16, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 43 | ||
| EX1-2, 3.11, 4, 5.11, 6-7, 8.2, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 44 | ||
| EX1-2, 3.11, 4, 5.30, 6-7, 8.12, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 45 | ||
| EX1-2, 3.11, 4, 5.2, 6-7, 8.16, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 46 | ||
| EX1-2, 3.12, 4, 5.31, 6-7, 8.25, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 47 | ||
| EX1-2, 3.12, 4, 5.32, 6-7, 8.25, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 48 | ||
| EX1-2, 3.12, 4, 5.11, 6-7, 8.2, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 49 | ||
| AE013599 | gDNA splicing 50 | |||
| EX1-2, 3.12, 4, 5.33, 6-7, 8.9, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 51 | ||
| EX1-2, 3.12, 4, 5.34, 6-7, 8.26, 9-15, 16.2, 17-23 | AE013599 | gDNA splicing 52 | ||
| EX1-2, 3.12, 4, 5.35, 6-7, 8.15, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 53 | ||
| EX1-2, 3.12, 4, 5.36, 6-7, 8.7, 9-15, 16.1, 17-23 | AE013599 | gDNA splicing 54 | ||
| EX1-2, 3.10, 4, 5.16, 6-7, 24 | AE013599 | gDNA splicing 55 | ||
| EX1-2, 3.10, 4, 5.3, 6-7, 24 | AE013599 | gDNA splicing 56 | ||
| EX1-2, 3.10, 4, 5.29, 6-7, 24 | AE013599 | gDNA splicing 57 | ||
| EX1-2, 3.11, 4, 5.27, 6-7, 24 | AE013599 | gDNA splicing 58 | ||
| EX1-2, 3.11, 4, 5.37, 6-7, 24 | AE013599 | gDNA splicing 59 | ||
| EX1-2, 3.11, 4, 5.15, 6-7, 24 | AE013599 | gDNA splicing 60 | ||
| EX1-2, 3.10, 4, 5.27, 6, 25 | BT001877 | cDNA splicing 61 | ||
| EX1-2, 3.11, 4, 5.35, 6-7, 8.17, 9-12 | BT025950 | cDNA splicing 62 partial | ||
IMGT reference sequences (in FASTA format) for the allele(s): DSCAM*01
- Nucleotide sequence in FASTA format with gaps according to the IMGT unique numbering
- Amino acid sequence in FASTA format with gaps according to the IMGT unique numbering
- Nucleotide sequence in FASTA format without gaps
- Amino acid sequence in FASTA format without gaps
Corresponding protein database accession numbers
IMGT notes:
- (1) Drosophila melanogaster DSCAM gene has 62 alternative splice forms. It has 23 exons. These splice transcripts are the combination of variable exons, EX3 (with 12 variant types), EX5 (with 37 variant types), EX8 (with 26 variant types) and EX16 (with 2 variant types).
Genomic sequence
Coding region sequence
The coding region (CODING-REGION)
sequence starts from INIT-CODON
(or its encoded amino acid) to STOP-CODON
(not included).
The nucleotide sequence is extracted from cDNA (c) sequences and/or is
built by artificial exon joining from genomic DNA (g) sequences.
The amino acid sequence is the translation of the nucleotide sequence.
DSCAM*01: AE013599(g)
Nucleotide sequence
1 atgaatatgc ccaacgaacg cctcaaatgg ctaatgctgt tcgcagctgt tgccctcatt 61 gcttgtggta gtcagaccct agctgccaat cccccagatg ccgaccaaaa aggacccgtc 121 ttcctcaagg aacccaccaa ccgcattgac ttctccaact ccacgggcgc agagatcgag 181 tgcaaggcca gcggcaatcc catgcccgag attatttgga tcaggagcga cggtaccgcc 241 gtgggtgatg tgcccggatt gcgtcagatc tcatccgacg gcaagctggt cttccctcca 301 ttccgcgccg aggactaccg ccaggaggtc catgcccagg tgtacgcctg cctggcccgc 361 aaccagttcg gatccattat ctcccgggac gtccatgtgc gagccgtcgt ttcacagttc 421 tacataaccg aggccgagaa tgagtacgta attaaaggga acgcggcggt ggtcaagtgt 481 aagatcccat ccttcgtggc cgatttcgtg caggttgagg cctgggtgga cgaggagggc 541 atggagttgt ggcgcaacaa tgccaccgac gcctatgatg gaaagtacct ggtattgccc 601 tctggagagc tgcacatccg tgaggttgga cccgaggacg gatacaagag ctaccagtgc 661 cgaaccaaac atcgtctgac cggagaaacc cgattaagtg ccacaaaagg acgattggtc 721 atcacagagc ccgttagcag tagtccgccc aaaatcaatg ctctgaccta taagcccaat 781 attgtggagt ccatggcgtc caccgcaata ctttgtcccg cccaaggcta tccagctcct 841 agttttagat ggtacaagtt catcgaagga acaacccgta aacaagctgt ggtgctaaat 901 gaccgtgtga agcaggtctc tggtactctc attattaagg acgcagtagt cgaggactcc 961 ggaaaatacc tgtgcgtggt gaacaattcc gtgggaggcg aaagcgttga gactgtgctt 1021 accgtcactg cccccctatc cgctaagatc gatcctccca cacagacagt tgacttcgga 1081 cgccccgccg tattcacttg ccagtacact ggaaatccca tcaagaccgt tagctggatg 1141 aaggacggca aggctatcgg acacagcgaa cccgtgctgc gcatcgaatc cgtgaagaag 1201 gaggacaagg gcatgtacca gtgcttcgta agaaacgacc aggaatcggc ggaggcgagt 1261 gctgagctga agctcggagg ccgtttcgat ccccccgtca tccgacaggc cttccaggaa 1321 gagaccatgg aacccggacc aagtgtattc ctcaagtgcg tcgccggcgg aaaccccacg 1381 cccgaaattt cctgggaact cgacggcaag aaaatcgcca acaacgatcg ctatcaggtc 1441 ggacagtatg tgacggtcaa cggagatgtg gtttcctatc tgaacataac ctcggtccac 1501 gccaacgatg gcggtctcta caagtgcata gccaagagca aagtgggcgt ggccgaacac 1561 tcggccaagt tgaatgtata tggactgccc tacatccggc aaatggagaa gaaggcaatt 1621 gttgctggag aaaccctgat tgtcacatgt cctgtagctg gataccccat cgattcgatt 1681 gtctgggagc gagataaccg tgccctgccc atcaaccgca aacagaaggt cttccccaac 1741 ggaacgctga ttatcgagaa tgtggaacgg aactcagacc aagcgaccta cacttgcgtt 1801 gccaagaatc aggaaggata ctctgctcga ggatctctgg aagtgcaagt catggtgccg 1861 ccccaggttt tgccctttag tttcggtgaa tccgccgccg atgtcggcga tattgccagt 1921 gccaactgtg tggtgcccaa gggagatctg cccctggaga ttcgctggtc cctcaactct 1981 gctccaatcg taaacggcga aaatgggttt accctggtgc gtctgaataa gcgcacgagt 2041 ctgttaaaca ttgattctct aaatgctttt catcgcggtg tctacaagtg catagccaca 2101 aatccggctg ggaccagtga atatgtagct gaattacaag ttaatgtacc tcccagatgg 2161 atcctcgagc ccaccgataa ggccttcgcc cagggatccg atgccaaggt tgaatgcaag 2221 gctgatggct tccccaaacc ccaagttaca tggaagaaag cagttggcga cacccccgga 2281 gagtacaagg atctaaagaa gagcgacaac atccgcgtgg aagagggcac tctgcatgtc 2341 gacaacatcc aaaagaccaa cgagggctac tatctgtgcg aggctatcaa tggaataggc 2401 tccggcctct cggctgtgat tatgatcagc gttcaggccc ctccagagtt cacggagaag 2461 ctgcgcaacc agaccgcccg acgaggagaa cccgccgtac tccagtgcga ggcgaagggc 2521 gagaagccca ttggcatctt gtggaacatg aacaacatgc gactggaccc aaagaacgac 2581 aatcggtaca ccattcgtga ggagatcctt tccaccggag ttatgtccag tctgtcgatc 2641 aagcgcaccg agagatccga ctccgcccta ttcacctgtg tcgccactaa tgcctttgga 2701 tccgatgacg ccagcataaa tatgattgtc caggaagttc cggagatgcc atatgctttg 2761 aaggtactcg acaaatccgg acgttccgtg cagctgagct gggcgcaacc ctacgatggc 2821 aactcccctc tggacaggta catcattgag tttaagcgtt ctcgtgcctc ctggagcgaa 2881 attgatcgcg tcatcgtgcc cggacacacc acagaagccc aagtgcagaa gctcagcccc 2941 gccaccacct acaacattcg catcgtggcc gaaaacgcca tcggcacatc ccaatcctct 3001 gaagcggtca ctatcatcac agccgaagaa gcaccctccg gcaagcccca gaacatcaag 3061 gtagaacccg tgaaccagac caccatgcgc gtcacctgga agccaccacc acgcaccgag 3121 tggaacggag agatcctggg ctactacgtc ggctacaagc tatccaacac taactcgtcc 3181 tacgttttcg agaccatcaa cttcatcacc gaggagggca aggagcacaa cctggaactg 3241 cagaacctgc gcgtgtacac ccagtactcc gtggtgatcc aggccttcaa caagatcgga 3301 gctggtccac tgagcgaaga ggagaaacaa ttcacggccg agggaacgcc cagccagcca 3361 cccagtgaca ccgcctgcac caccttaact tcgcagacca ttcgcgtcgg atgggtgagc 3421 ccacccctgg aatccgccaa cggagtgatc aagacctata aggttgtcta tgcccccagt 3481 gacgagtggt atgacgagac caagcgacac tataagaaga cggcctcctc cgacacagtc 3541 ctccatggct taaagaagta caccaactac acaatgcagg tcctggccac aacagccgga 3601 ggcgatggcg tccgcagcgt tcccatccac tgccaaaccg aacccgatgt tcccgaagca 3661 cccactgatg taaaggctct tgttatgggt aacgccgcta tcctggtatc ctggcgccca 3721 ccagcacagc caaacggcat tatcacccag tacaccgtgt actccaaggc cgaaggcgct 3781 gagactgaga caaagaccca gaaggttccc cactaccaga tgagtttcga ggccaccgaa 3841 ctggagaaga acaagcccta cgagttctgg gtgacagcta gcaccaccat tggcgaaggc 3901 cagcagtcta agagcatagt ggccatgccc agcgaccagg tgcccgccaa gatcgcctcc 3961 ttcgacgaca ccttcactgc caccttcaag gaggacgcca agatgccctg cctggccgtt 4021 ggagcccccc aacccgagat cacatggaag atcaagggcg tcgaattcag tgccaacgat 4081 cgcatgcgcg tcctccccga cggatcgctg ctgatcaagt cggtaaatcg ccaggatgcc 4141 ggagactact cctgccacgc cgagaactcg attgctaagg actccatcac gcacaaactg 4201 attgttctgg caccaccaca atcgccccac gtcaccctct cggcaaccac cactgatgcc 4261 ctgactgtaa agttgaagcc ccatgaggga gacactgctc ctctgcatgg atacaccctg 4321 cactacaagc cagaattcgg agaatgggaa acatcggaag tgtctgtcga ctcacagaag 4381 cacaacatcg aaggtctctt gtgcggctcc cgctatcagg tctatgccac aggattcaat 4441 aacattggag ctggcgaagc ttctgacatt ttgaacaccc ggaccaaggg acagaagccc 4501 aagctgcccg agaaacctcg cttcattgaa gtgtcgtcca actcggtgtc cctgcacttc 4561 aaggcctgga aagatggagg atgccccatg tcgcactttg tggtggagag caagaagcgc 4621 gatcaaattg agtggaacca aatttcgaac aacgtgaagc ccgataacaa ctacgtggtt 4681 ttggacctgg aacccgccac ctggtacaac ctccgcatca ctgcccacaa ctcggctggc 4741 ttcactgtgg ccgaatacga ctttgccacc ttaaccgtta ccggaggcac tatcgcaccc 4801 tcgcgagatt tacccgagtt aagcgccgag gacacgatcc gcattatcct ctcgaaccta 4861 aacttagttg tgcccgtcgt ggcggctctg ctcgtcataa tcatagcgat aattgttatt 4921 tgtatactgc gtagcaaggg caatcaccac aaagacgatg tagtttacaa tcagacaatg 4981 ggacccggcg ccaccctgga caagcgtcgt ccggacctgc gggatgagct cggatacatc 5041 gccccgccca accggaagct gccccccgtt cccggatcca actataatac ctgtgaccgg 5101 attaagcgag gccgcggtgg cctccggtcc aaccactcga cctgggaccc tcgacgcaat 5161 cccaacctgt acgaggagct gaaggccccg ccagtgccga tgcacggcaa ccattacggc 5221 cacgcccacg gcaatgccga gtgccactac aggcatccag gcatggaaga tgaaatctgc 5281 ccctatgcca cgttccacct gctcggattc cgcgaggaaa tggaccctac caaggccatg 5341 aacttccaga ccttccccca ccagaacgga cacgccggcc cagttcccgg acacgcgggc 5401 actatgcttc caccaggaca tccaggacac gtgcactccc gctccggatc gcaatcgatg 5461 cctcgggcca atcgatacca gcgaaagaac agccagggcg gacagtcctc aatctacacg 5521 ccagctcccg aatacgatga tcccgccaac tgtgccgaag aggaccaata tcgtcgatac 5581 acccgcgtca actcgcaagg cggtagcctg tactccggac ccggacccga atacgacgat 5641 cccgccaact gcgcacccga agaggatcag tacggctccc agtacggagg accctatgga 5701 cagccctatg atcactacgg ttcccgggga tccatgggac gtcgtagcat cggctctgct 5761 cgcaatcctg gcaatggatc acccgagcct ccaccaccac caccacgcaa ccacgacatg 5821 agcaactcct cattcaacga ctccaaggag agtaatgaga tctcagaggc agagtgcgat 5881 cgtgaccacg gaccacgcgg aaactacgga gcagtgaagc gatctccaca accgaaagat 5941 cagcgcacca ccgaagaaat gcgcaaactg atagaaagaa acgaaaccgg cccaaaacaa 6001 ctccaactcc aacaagcaaa tggcgcagga ttcacagcct acgatactat ggcagtgtaa
Nucleotide sequence in FASTA format (without gaps)
DSCAM*01
Amino acid sequence
1 MNMPNERLKW LMLFAAVALI ACGSQTLAAN PPDADQKGPV FLKEPTNRID FSNSTGAEIE 61 CKASGNPMPE IIWIRSDGTA VGDVPGLRQI SSDGKLVFPP FRAEDYRQEV HAQVYACLAR 121 NQFGSIISRD VHVRAVVSQF YITEAENEYV IKGNAAVVKC KIPSFVADFV QVEAWVDEEG 181 MELWRNNATD AYDGKYLVLP SGELHIREVG PEDGYKSYQC RTKHRLTGET RLSATKGRLV 241 ITEPVSSSPP KINALTYKPN IVESMASTAI LCPAQGYPAP SFRWYKFIEG TTRKQAVVLN 301 DRVKQVSGTL IIKDAVVEDS GKYLCVVNNS VGGESVETVL TVTAPLSAKI DPPTQTVDFG 361 RPAVFTCQYT GNPIKTVSWM KDGKAIGHSE PVLRIESVKK EDKGMYQCFV RNDQESAEAS 421 AELKLGGRFD PPVIRQAFQE ETMEPGPSVF LKCVAGGNPT PEISWELDGK KIANNDRYQV 481 GQYVTVNGDV VSYLNITSVH ANDGGLYKCI AKSKVGVAEH SAKLNVYGLP YIRQMEKKAI 541 VAGETLIVTC PVAGYPIDSI VWERDNRALP INRKQKVFPN GTLIIENVER NSDQATYTCV 601 AKNQEGYSAR GSLEVQVMVP PQVLPFSFGE SAADVGDIAS ANCVVPKGDL PLEIRWSLNS 661 APIVNGENGF TLVRLNKRTS LLNIDSLNAF HRGVYKCIAT NPAGTSEYVA ELQVNVPPRW 721 ILEPTDKAFA QGSDAKVECK ADGFPKPQVT WKKAVGDTPG EYKDLKKSDN IRVEEGTLHV 781 DNIQKTNEGY YLCEAINGIG SGLSAVIMIS VQAPPEFTEK LRNQTARRGE PAVLQCEAKG 841 EKPIGILWNM NNMRLDPKND NRYTIREEIL STGVMSSLSI KRTERSDSAL FTCVATNAFG 901 SDDASINMIV QEVPEMPYAL KVLDKSGRSV QLSWAQPYDG NSPLDRYIIE FKRSRASWSE 961 IDRVIVPGHT TEAQVQKLSP ATTYNIRIVA ENAIGTSQSS EAVTIITAEE APSGKPQNIK 1021 VEPVNQTTMR VTWKPPPRTE WNGEILGYYV GYKLSNTNSS YVFETINFIT EEGKEHNLEL 1081 QNLRVYTQYS VVIQAFNKIG AGPLSEEEKQ FTAEGTPSQP PSDTACTTLT SQTIRVGWVS 1141 PPLESANGVI KTYKVVYAPS DEWYDETKRH YKKTASSDTV LHGLKKYTNY TMQVLATTAG 1201 GDGVRSVPIH CQTEPDVPEA PTDVKALVMG NAAILVSWRP PAQPNGIITQ YTVYSKAEGA 1261 ETETKTQKVP HYQMSFEATE LEKNKPYEFW VTASTTIGEG QQSKSIVAMP SDQVPAKIAS 1321 FDDTFTATFK EDAKMPCLAV GAPQPEITWK IKGVEFSAND RMRVLPDGSL LIKSVNRQDA 1381 GDYSCHAENS IAKDSITHKL IVLAPPQSPH VTLSATTTDA LTVKLKPHEG DTAPLHGYTL 1441 HYKPEFGEWE TSEVSVDSQK HNIEGLLCGS RYQVYATGFN NIGAGEASDI LNTRTKGQKP 1501 KLPEKPRFIE VSSNSVSLHF KAWKDGGCPM SHFVVESKKR DQIEWNQISN NVKPDNNYVV 1561 LDLEPATWYN LRITAHNSAG FTVAEYDFAT LTVTGGTIAP SRDLPELSAE DTIRIILSNL 1621 NLVVPVVAAL LVIIIAIIVI CILRSKGNHH KDDVVYNQTM GPGATLDKRR PDLRDELGYI 1681 APPNRKLPPV PGSNYNTCDR IKRGRGGLRS NHSTWDPRRN PNLYEELKAP PVPMHGNHYG 1741 HAHGNAECHY RHPGMEDEIC PYATFHLLGF REEMDPTKAM NFQTFPHQNG HAGPVPGHAG 1801 TMLPPGHPGH VHSRSGSQSM PRANRYQRKN SQGGQSSIYT PAPEYDDPAN CAEEDQYRRY 1861 TRVNSQGGSL YSGPGPEYDD PANCAPEEDQ YGSQYGGPYG QPYDHYGSRG SMGRRSIGSA 1921 RNPGNGSPEP PPPPPRNHDM SNSSFNDSKE SNEISEAECD RDHGPRGNYG AVKRSPQPKD 1981 QRTTEEMRKL IERNETGPKQ LQLQQANGAG FTAYDTMAV*
Amino acid sequence in FASTA format (without gap)
DSCAM*01
Legend:
- Colors are according to IMGT Color menu for regions and domains
- Nucleotide and amino acid letters (in bold) in purple, green or blue are according to IMGT Color menu for splicing types.
IMGT links
IMGT Repertoire
- Chromosomal localization:
- Alignment of alleles:
- Protein displays:
- IMGT Collier de perles: C-LIKE-DOMAIN [D1], [D2], [D3], [D4], [D5], [D6], [D7], [D8], [D9], [D10]
External links
Nomenclature
- HGNC:
Genome databases
- Entrez Gene: 35652
- GENATLAS:
- GeneCards:
- OMIM:
Sequence databases
- EMBL: AE013599, BT001877, BT025950
- GenBank: AE013599, BT001877, BT025950
- DDBJ: AE013599, BT001877, BT025950
- Swiss-Prot:
- TrEMBL:
- NCBI:
Structure database
- PDB:
Created: 16/07/2007
Last updated: Friday, 22-Sep-2023 18:33:01 CEST
Authors: Phani vijay Garapati and Marie-Paule Lefranc
Editor: Chantal Ginestoux
Last updated: Friday, 22-Sep-2023 18:33:01 CEST
Authors: Phani vijay Garapati and Marie-Paule Lefranc
Editor: Chantal Ginestoux
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