CopciAB_462713
Coprinopsis cinerea A43mutB43mut pab1-1 #326

General data

Systematic name CopciAB_462713 Strain Coprinopsis cinerea Okayama 7
Standard name - Synonyms 462713
Uniprot id Functional description Fungal specific transcription factor domain
Location scaffold_3:1291774..1294921 Strand -
Gene length (nt) 3148 Transcript length (nt) 2895
CDS length (nt) 2022 Protein length (aa) 673

Reciprocal best hits in model fungi

Strain name Gene / Protein name

Orthologs in mushroom models

Strain name Gene / Protein name Pident E-value Bits
Hypsizygus marmoreus strain 51987-8 Hypma_RDB26195 42.1 1.699E-145 475
Agrocybe aegerita Agrae_CAA7266980 40.9 2.064E-140 460
Lentinula edodes NBRC 111202 Lenedo1_1075337 37.3 1.484E-117 393
Lentinula edodes W1-26 v1.0 Lentinedodes1_11720 37.3 1.472E-117 393
Pleurotus eryngii ATCC 90797 Pleery1_1511832 35.6 7.526E-116 388
Pleurotus ostreatus PC15 PleosPC15_2_174562 36.2 1.401E-115 387
Pleurotus ostreatus PC9 PleosPC9_1_116076 36 1.371E-115 387
Schizophyllum commune H4-8 Schco3_2627364 36 1.215E-107 364
Agaricus bisporus var. burnettii JB137-S8 Agabi_varbur_1_101348 35.5 3.94E-107 362
Auricularia subglabra Aurde3_1_1276460 30.5 3.192E-88 307
Lentinula edodes B17 Lened_B_1_1_6354 33.8 7.73E-68 245
Agaricus bisporus var bisporus (H97) Agabi_varbisH97_2_191136 37.2 1.361E-62 229
Grifola frondosa Grifr_OBZ72172 30.9 9.022E-51 193

Expression

Name Summary Attribution Assay type
Carbon metabolism Transcriptional changes along alternative morphogenetic paths of C. cinerea Xie et al. 2020 RNA-Seq
Sample Mean cpm SD cpm Se of mean
sclerotia 195.3101 33.4836 19.3317
oidia 157.9626 21.61 12.4766
vegetative_mycelium 190.7313 23.7863 13.733
primordia 119.3615 3.5116 2.0274
hyphal_knot 189.5443 5.5938 3.2296
young_fruiting_body 113.8693 10.9355 6.3136
Complex carbon sources 1 (long incubation) Expression profiling on diverse complex carbon sources. Hegedus et al. RNA-Seq
Sample Mean cpm SD cpm Se of mean
Control - glucose 211.8191 37.0303 21.3795
Wheat bran 147.3434 41.1713 23.7702
Horse manure 187.2421 50.2371 29.0044
Oak leaves 364.7288 246.6766 142.4188
Hay 178.4478 23.6506 13.6547
Corn stalk 248.2346 26.4686 15.2816
Pectine 290.4441 37.8419 21.848
Microcrystalline cellulose 191.5548 12.3402 7.1246
Xylose 256.4469 31.1533 17.9864
Cellobiose 195.7504 15.6525 9.037
Lignin 159.9096 53.3051 30.7757
Apple peels 193.4579 29.1483 16.8288
Coprinopsis challenged with bacteria Transcriptional response to Bacillus subtilis and Escherichia coli. Kombrink et al. 2018 RNA-Seq
Sample Mean cpm SD cpm Se of mean
Control 144.5158 3.8332 2.2131
Bsubtilis 155.1332 1.0655 0.6152
Ecoli 168.6278 11.6022 6.6985
Early development 1 Time series expression profiling of basidiospore and oidium germination Hegedus et al. QuantSeq
Sample Mean cpm SD cpm Se of mean
BS 0h 503.1219 42.8739 24.7533
BS 4h 204.8875 31.6543 18.2756
BS 8h 117.7125 4.9339 2.8486
BS 12h 89.3514 8.8629 5.117
Oidia 0 h 124.3815 21.9964 12.6996
Oidia 18 h 134.0846 12.202 7.0448
Sclerotia 133.1944 21.2132 12.2474
Early development 2 Time series expression profiling of mycelial growth, light induction and fruiting body initiation. Hegedus et al. QuantSeq
Sample Mean cpm SD cpm Se of mean
DM 12h 73.2168 10.6486 6.148
DM 36h 107.3181 11.2773 6.5109
DM 60h 117.2319 23.8685 13.7805
DM 84h 100.9853 8.3596 4.8264
DM 108h 126.3852 5.3191 3.071
DM 132h 131.8164 12.2757 7.0874
DM 156hAE 225.4271 31.7303 18.3195
ELI1hAE 143.9311 24.7251 14.275
ELI2hAE 142.4391 24.0528 13.8869
LI2hAE 153.1782 25.4963 14.7203
LI6hAE 252.8981 11.7679 6.7942
LI12hAE 192.0872 26.9203 15.5424
LI18hAE 213.016 63.4448 36.6299
LI 24hAE 257.4706 107.2701 61.9324
DM 156hAM 106.6727 11.66 6.7319
ELI1hAM 94.6745 4.6266 2.6711
ELI2hAM 103.6404 6.6023 3.8118
LI2hAM 100.5084 22.6668 13.0867
LI6hAM 113.0168 9.9359 5.7365
LI12hAM 195.5119 26.1948 15.1236
LI18hAM 210.123 44.4213 25.6466
LI 24hAM 145.2585 23.394 13.5065
LI 24hHK 101.7709 17.5101 10.1095
L/D 6h 150.2496 9.5744 5.5278
L/D 12h 149.4972 9.3945 5.4239
L/D 18h 146.2389 44.3 25.5766
L/D 24h 105.0013 3.3165 1.9148
Fruiting body development RNA-Seq analysis of fruiting body development Krizsan et al. 2019 RNA-Seq
Sample Mean cpm SD cpm Se of mean
Vegetative mycelium 98.3029 2.489 1.437
Hyphal knots 167.3858 48.1935 27.8245
Primordium 1 96.1183 12.5916 7.2698
Primordium 2 86.4859 17.0953 9.87
Young Fruiting body cap 120.747 8.9724 5.1802
Younf fruiting body gill 87.7548 27.0926 15.6419
Young fruiting body stipe 47.3421 8.9012 5.1391
Mature fruiting body cap_gill 122.5664 16.9238 9.7709
Mature fruiting body stipe 115.3201 9.8541 5.6893
Nitrogen sources (12h incubation) Expression profiling on diverse nitrogen sources. Hegedus et al. RNA-Seq
Sample Mean cpm SD cpm Se of mean
Complete medium - control 108.5248 13.5449 7.8202
NH4NO3 109.0454 10.066 5.8116
Proline 145.8995 15.7885 9.1155
Tryptophan 107.6716 44.2646 25.5562
Isoleucin 145.1694 18.0218 10.4049
Arginine 109.1685 11.2508 6.4956
Metionine 121.6545 6.3504 3.6664
NaNO3 113.2421 5.3295 3.077
Plant biomass (12h incubation) Expression profiling on diverse plant biomasses as carbon sources. Hegedus et al. RNA-Seq
Sample Mean cpm SD cpm Se of mean
Glucose - control 108.5248 13.5449 7.8202
Citrus peel 99.5506 12.6233 7.288
Poplar leaves 89.5503 9.8217 5.6706
Typha leaves 79.7972 5.6279 3.2493
Overwintered Salix leaves 82.3854 6.2525 3.6099
Reed flowering 93.2336 22.4957 12.9879
Tigernut 86.0887 6.1389 3.5443
Energy cane 88.6894 9.8712 5.6991
Guar gum 124.2436 32.0638 18.5121
Apple peels 72.2927 12.0077 6.9327
Cellobiose 117.014 7.6145 4.3962
Corn stalk 88.962 10.5585 6.096
Horse manure 79.426 27.7696 16.0328
Lignin 84.7471 13.1626 7.5995
Microcrystalline cellulose 113.8165 7.6535 4.4188
Oak leaves 89.9188 20.4019 11.7791
Pectin esterified 76.6673 11.5261 6.6546
Poplar sawdust 94.5137 11.7243 6.769
Wheat bran 77.4479 6.1552 3.5537
Chlamydomonas reinhardtii 93.2161 9.0216 5.2086
Vertatryl alcohol 119.6973 9.5543 5.5162
Furfural 113.8667 15.9571 9.2128
Autoclaved mycelium 119.3897 16.4018 9.4696
Simple and complex carbon and nitrogen sources Expression profiling on diverse complex carbon and nitrogen sources. Hegedus et al. RNA-Seq
Sample Mean cpm SD cpm Se of mean
Glucose control 219.3712 7.2897 4.2087
Ribose 200.5395 7.3892 4.2662
Mannose 211.3959 0.0406 0.0287
Fructose 223.9151 5.8082 3.3534
Arabinose 204.997 13.1612 7.5986
Xylose 193.6137 3.8504 2.223
Galacturonic acid 202.1591 26.5766 15.344
Rhamnogalacturonan 225.1986 27.4574 15.8526
Pectin esterified 216.1027 14.3694 8.2962
Polygalacturonic acid 249.0295 14.244 8.2238
Sodium acetate 194.5094 10.4183 6.015
No nitrogen 204.7658 8.6609 5.0004
BSA 237.509 9.0085 5.2011
Glutamine 241.4545 11.2814 6.5133
No phosphate 164.7635 7.3176 4.2248
No carbon 197.4403 16.1068 11.3892
No sulphur 248.0141 14.3726 8.298
Simple and complex carbon sources (12h incubation) Expression profiling on diverse complex carbon sources. Hegedus et al. RNA-Seq
Sample Mean cpm SD cpm Se of mean
Glucose - control 108.5248 13.5449 7.8202
Amylose 117.1198 20.2209 11.6746
Fucose 124.7489 26.4346 15.262
Galactose 118.1811 6.3377 3.6591
Lactose 158.3213 31.8713 18.4009
Maltose 137.8394 12.2996 7.1012
Mannitol 151.4747 11.2566 6.499
Rhamnose 139.021 9.5457 5.5112
Sorbitol 144.7096 5.4616 3.1532
Trehalose 130.3874 36.5411 21.097
Glycerol 129.6842 19.1305 11.045
Glucuronic acid 141.3197 2.1596 1.2468
Arabinan 132.6111 19.3233 11.1563
Galactan 97.1896 8.6982 5.0219
Galactomannan 93.7867 12.403 7.1609
Glucan 127.9517 17.3554 10.0201
Xylan 103.2041 18.5667 10.7195
Xyloglucan 117.8246 26.0449 15.037
Arabinogalactan 116.0782 16.2133 9.3608
Pectin 59.5149 14.046 8.1095
Rhamnogalacturonan 61.4364 6.9534 4.0145
Polygalacturonic acid 165.7623 64.1338 37.0277
Mannan 116.0356 13.0484 7.5335
Amylopectin 90.2441 8.7188 5.0338
Inulin 108.3459 6.6051 3.8134
BSA 96.994 6.2998 3.6372
Starvation induced by water agar transfer Expression profiling on starvation induced by transfer to water agar Hegedus et al. QuantSeq
Sample Mean cpm SD cpm Se of mean
Control 117.2319 23.8685 13.7805
2h WAT 95.3212 16.0755 9.2812
4h WAT 158.8024 6.9391 4.0063
8h WAT 132.2513 15.5507 8.9782
16h WAT 132.0959 22.7478 13.1334
24h WAT 133.237 11.1809 6.4553
WAT hyphal knot -30h 118.8876 5.327 3.0756
WAT hyphal knot -22h 121.5605 17.6128 10.1688
WAT hyphal knot -15h 142.8307 26.3601 15.219
WAT hyphal knot -7.5h 139.646 13.6605 7.8869
WAT hyphal knot 151.2305 21.2511 12.2693
WAT hyphal knot +7.5h 133.8301 6.3996 3.6948
Straw time series Time series expression profiling on straw as a carbon source Hegedus et al. RNA-Seq
Sample Mean cpm SD cpm Se of mean
Glucose control 98.0656 23.4948 13.5647
Straw 3h 170.2433 49.1119 28.3548
Straw 6h 173.5714 92.085 53.1653
Straw 12h 134.1827 43.4696 25.0972
Straw 24h 116.9744 22.6623 13.0841
Stress conditions 1 Expression profiling under various stress conditions Hegedus et al. QuantSeq
Sample Mean cpm SD cpm Se of mean
Flask control 78.1247 2.5022 1.4446
Frost (-20C, 30min) 79.8249 7.724 4.4595
Heat shock (47C, 2h) 193.4187 2.0514 1.1843
High CO2 103.9446 17.0231 9.8283
Drought (4% agar, 12h) 86.5476 4.5016 2.599
Oxidative (1mM H2O2, 3h) 86.799 5.1099 2.9502
Acidic (pH4, 3h) 69.6417 5.7481 3.3187
Alkaline (pH9, 3h) 65.1754 7.6555 4.4199
Osmotic (sorbitol 2h) 60.7587 12.8575 7.4233
CongoRed (3h) 84.6734 15.4512 8.9207
Cobalt chloride control 123.4215 10.5784 6.1074
Cobalt chloride 2mM 146.1077 20.2284 11.6789
Stress conditions 2 Expression profiling under various stress conditions Hegedus et al. QuantSeq
Sample Mean cpm SD cpm Se of mean
Flask control 77.7168 29.5538 17.0629
Cold stimulation 86.4991 25.2407 14.5727
Scratched surface 86.6565 7.7918 4.4986
Ca2+, 200mM, 24h 90.4201 15.7178 9.0747
Cu2+, 2mM, 6h 83.3987 7.1289 4.1159
Voriconazole 118.3031 10.834 6.255
Trichoderma interaction, early 81.2562 6.6364 3.8315
Trichoderma interaction 60h 77.9043 13.4729 7.7786
Cobalt chloride 2mM repeat 107.3167 17.9818 10.3818
Hypoxia 88.7855 16.4914 9.5213
Hypoxia control 98.1317 7.325 4.2291
Protoplastation control 170.1461 29.9009 21.1431
Protoplastation 3.5h 153.268 36.0222 25.4716
Protoplastation 1.5h 164.5523 6.0242 4.2597

General data

Systematic name -
Protein id CopciAB_462713.T0
Description Fungal specific transcription factor domain

Annotation summary

0 200 400 600 673

Conserved domains

Analysis Signature accession Signature description InterPro Accession Start End
CDD cd00067 GAL4 IPR001138 24 59
Pfam PF11951 Fungal specific transcription factor domain IPR021858 352 670

SignalP

Prediction Start End Score
No records

Transmembrane domains

Domain n Start End Length
No records

InterPro

Accession Description
IPR001138 Zn(2)Cys(6) fungal-type DNA-binding domain
IPR021858 Fungal transcription factor
IPR036864 Zn(2)-C6 fungal-type DNA-binding domain superfamily

GO

Go id Term Ontology
GO:0000981 DNA-binding transcription factor activity, RNA polymerase II-specific MF
GO:0006355 regulation of transcription, DNA-templated BP
GO:0008270 zinc ion binding MF

KEGG

KEGG Orthology
K21547

EggNOG

COG category Description
S Fungal specific transcription factor domain

CAZy

Class Family Subfamily
No records

Transcription factor

Group
c6 zn

Conservation of CopciAB_462713 across fungi.

Arrow shows the origin of gene family containing CopciAB_462713.

Protein

Sequence id CopciAB_462713.T0
Sequence >CopciAB_462713.T0
MPASPKASQAKKAAASAKNKGAVRAKTGCYTCRIRRKKCDEERTERDTCRTCERLRLECLGFGAKRPEWLRENKN
VVLLRDKIKAFLASQGLIKGHSGTGSRTAEQGHMILQLSGDPSQSHYHSSSSESPPSRTLSLSSDDDRHRLVTSS
IRDQREDSAWFNPGYGSGLHSLHRSDSPFSNASYDEVSPHHAYTLPNSSGSLVDSSRLSPAIRSTFSRWYTEVPI
DIMDNLNGLSISGFASSSTDGHATKDPSTMLFTMPTNWLPSDLVETSIENYVQMIAEIQYLLGDRKTLPQMIWDS
YRSHPNSKAALTLLNKVYWRRQQHPTQPVLTDSEMHSNLAVLLQELEKGRFDDPDDAIAALHGVSMFLFDGGQGA
WRDFLKLATRYVKKVLHNPQYTSPKDALLFATAKDAFIVKTAIWFDVLASITTQEPPTFIQEIRTMFGPVHHGVY
NSQFDTDPQCSMMSPMGCENRVVWALAETSTLAHWKYTEDVRCRLSVSDLVIRAQEIENVLYQKSYEPMPASGED
DNDMEQLRFLASEIFRCSTRLFLSAVVNNDHPQVRQIQDLVDECMAVFHNLFKTPTLDQFKVSRSVIRSTVFGIY
LVGALTHNRQHREHLLEHIERESRGLHGGVGEGVGNCGSIRKMLEHVWKESDADPAKPVPWRRVLKEYQILLV
Length 673

Coding

Sequence id CopciAB_462713.T0
Sequence >CopciAB_462713.T0
ATGCCAGCCAGTCCAAAGGCTTCCCAGGCAAAGAAGGCCGCGGCCTCTGCAAAGAACAAGGGGGCCGTCCGTGCA
AAGACCGGTTGCTATACGTGCAGAATCCGACGAAAGAAATGCGACGAGGAGCGCACAGAGCGAGACACGTGCAGG
ACCTGTGAGCGTCTGCGTCTCGAATGCTTGGGCTTTGGCGCCAAACGGCCCGAGTGGCTGAGGGAAAACAAGAAT
GTCGTCCTCCTCCGCGACAAGATCAAGGCTTTCCTCGCGTCACAGGGCCTCATCAAGGGCCACTCAGGCACTGGC
TCTCGCACTGCTGAGCAGGGACACATGATCTTGCAGCTCTCGGGAGACCCAAGCCAGTCCCACTACCACAGCTCC
TCCTCGGAGAGCCCACCTTCAAGGACCCTCTCCCTTTCCTCCGACGATGACCGGCATCGCCTCGTCACCTCTTCC
ATTCGTGATCAACGTGAGGACTCAGCCTGGTTCAATCCTGGATACGGCTCTGGCCTCCATTCTCTCCATCGCTCC
GACTCGCCCTTCTCGAATGCCAGTTACGACGAGGTTTCACCTCATCACGCCTACACACTCCCTAATTCCTCTGGT
AGCTTAGTTGACTCATCCCGCCTCTCCCCTGCAATCCGAAGTACGTTCTCGAGGTGGTATACCGAAGTGCCAATC
GACATCATGGACAACTTGAACGGTCTCTCAATCAGCGGCTTCGCATCAAGTTCGACAGACGGCCACGCCACCAAG
GACCCATCTACAATGTTGTTCACGATGCCCACCAACTGGCTACCAAGTGACCTCGTCGAAACTTCAATCGAGAAC
TACGTCCAAATGATCGCTGAGATTCAGTATCTGTTGGGAGACCGCAAGACACTACCGCAGATGATTTGGGATTCG
TATCGGTCGCATCCCAACTCGAAGGCGGCATTGACATTGTTGAACAAGGTGTACTGGAGAAGACAGCAACATCCA
ACCCAACCTGTGCTCACCGACTCGGAGATGCATTCGAACCTCGCCGTGTTGTTACAAGAGCTAGAGAAAGGAAGA
TTCGACGACCCTGACGATGCCATCGCGGCACTACATGGAGTCTCCATGTTCCTTTTCGACGGAGGGCAAGGTGCC
TGGCGCGACTTCCTCAAGCTCGCCACTAGATACGTGAAGAAGGTCCTCCACAACCCGCAATACACGAGTCCCAAA
GACGCTCTCCTCTTCGCCACTGCCAAAGATGCATTCATCGTCAAGACAGCCATCTGGTTTGACGTCCTCGCTTCC
ATCACCACTCAAGAGCCACCTACGTTCATCCAGGAGATCCGAACCATGTTCGGTCCTGTTCACCATGGCGTCTAC
AACTCCCAATTCGATACTGACCCTCAGTGTTCGATGATGTCGCCCATGGGTTGCGAGAACCGGGTAGTGTGGGCG
TTGGCGGAAACTTCGACCCTCGCTCACTGGAAGTATACAGAGGATGTCAGGTGCCGACTGAGCGTCAGCGACCTC
GTCATTCGGGCACAAGAGATCGAGAACGTACTCTATCAAAAATCATACGAGCCGATGCCTGCGTCGGGTGAGGAC
GACAACGACATGGAACAACTCCGATTCCTGGCCTCGGAGATCTTCCGATGCTCTACGCGGCTCTTCCTCTCGGCT
GTGGTGAACAATGACCACCCACAAGTTCGACAGATCCAAGATCTCGTGGACGAGTGCATGGCGGTGTTCCATAAC
TTGTTCAAGACACCAACACTGGACCAGTTCAAGGTTTCGAGGTCAGTAATCCGAAGCACAGTGTTCGGTATTTAC
TTGGTTGGTGCCCTCACCCACAATCGCCAACACCGAGAGCACCTGCTGGAACACATAGAAAGAGAATCGAGGGGC
CTGCATGGTGGCGTAGGGGAAGGAGTGGGGAATTGTGGGTCGATTCGAAAGATGCTAGAGCACGTTTGGAAAGAG
TCGGATGCTGATCCCGCAAAGCCTGTTCCGTGGCGGAGGGTCCTCAAGGAGTATCAAATCCTCCTTGTCTGA
Length 2022

Transcript

Sequence id CopciAB_462713.T0
Sequence >CopciAB_462713.T0
AGCCTGACCTCCCCACACCACTGCAACTCTCTTGATTCTATTATTTTCTCTATCCTCTCTCTCTTCATCGTCTGT
ATCCATAGTCTCAACGCCCACTGTATTCTTCAACAAAACTCCATCGACGACAACGCCCACCACTGGCACTAGCCG
CCCAGCATGCCAGCCAGTCCAAAGGCTTCCCAGGCAAAGAAGGCCGCGGCCTCTGCAAAGAACAAGGGGGCCGTC
CGTGCAAAGACCGGTTGCTATACGTGCAGAATCCGACGAAAGAAATGCGACGAGGAGCGCACAGAGCGAGACACG
TGCAGGACCTGTGAGCGTCTGCGTCTCGAATGCTTGGGCTTTGGCGCCAAACGGCCCGAGTGGCTGAGGGAAAAC
AAGAATGTCGTCCTCCTCCGCGACAAGATCAAGGCTTTCCTCGCGTCACAGGGCCTCATCAAGGGCCACTCAGGC
ACTGGCTCTCGCACTGCTGAGCAGGGACACATGATCTTGCAGCTCTCGGGAGACCCAAGCCAGTCCCACTACCAC
AGCTCCTCCTCGGAGAGCCCACCTTCAAGGACCCTCTCCCTTTCCTCCGACGATGACCGGCATCGCCTCGTCACC
TCTTCCATTCGTGATCAACGTGAGGACTCAGCCTGGTTCAATCCTGGATACGGCTCTGGCCTCCATTCTCTCCAT
CGCTCCGACTCGCCCTTCTCGAATGCCAGTTACGACGAGGTTTCACCTCATCACGCCTACACACTCCCTAATTCC
TCTGGTAGCTTAGTTGACTCATCCCGCCTCTCCCCTGCAATCCGAAGTACGTTCTCGAGGTGGTATACCGAAGTG
CCAATCGACATCATGGACAACTTGAACGGTCTCTCAATCAGCGGCTTCGCATCAAGTTCGACAGACGGCCACGCC
ACCAAGGACCCATCTACAATGTTGTTCACGATGCCCACCAACTGGCTACCAAGTGACCTCGTCGAAACTTCAATC
GAGAACTACGTCCAAATGATCGCTGAGATTCAGTATCTGTTGGGAGACCGCAAGACACTACCGCAGATGATTTGG
GATTCGTATCGGTCGCATCCCAACTCGAAGGCGGCATTGACATTGTTGAACAAGGTGTACTGGAGAAGACAGCAA
CATCCAACCCAACCTGTGCTCACCGACTCGGAGATGCATTCGAACCTCGCCGTGTTGTTACAAGAGCTAGAGAAA
GGAAGATTCGACGACCCTGACGATGCCATCGCGGCACTACATGGAGTCTCCATGTTCCTTTTCGACGGAGGGCAA
GGTGCCTGGCGCGACTTCCTCAAGCTCGCCACTAGATACGTGAAGAAGGTCCTCCACAACCCGCAATACACGAGT
CCCAAAGACGCTCTCCTCTTCGCCACTGCCAAAGATGCATTCATCGTCAAGACAGCCATCTGGTTTGACGTCCTC
GCTTCCATCACCACTCAAGAGCCACCTACGTTCATCCAGGAGATCCGAACCATGTTCGGTCCTGTTCACCATGGC
GTCTACAACTCCCAATTCGATACTGACCCTCAGTGTTCGATGATGTCGCCCATGGGTTGCGAGAACCGGGTAGTG
TGGGCGTTGGCGGAAACTTCGACCCTCGCTCACTGGAAGTATACAGAGGATGTCAGGTGCCGACTGAGCGTCAGC
GACCTCGTCATTCGGGCACAAGAGATCGAGAACGTACTCTATCAAAAATCATACGAGCCGATGCCTGCGTCGGGT
GAGGACGACAACGACATGGAACAACTCCGATTCCTGGCCTCGGAGATCTTCCGATGCTCTACGCGGCTCTTCCTC
TCGGCTGTGGTGAACAATGACCACCCACAAGTTCGACAGATCCAAGATCTCGTGGACGAGTGCATGGCGGTGTTC
CATAACTTGTTCAAGACACCAACACTGGACCAGTTCAAGGTTTCGAGGTCAGTAATCCGAAGCACAGTGTTCGGT
ATTTACTTGGTTGGTGCCCTCACCCACAATCGCCAACACCGAGAGCACCTGCTGGAACACATAGAAAGAGAATCG
AGGGGCCTGCATGGTGGCGTAGGGGAAGGAGTGGGGAATTGTGGGTCGATTCGAAAGATGCTAGAGCACGTTTGG
AAAGAGTCGGATGCTGATCCCGCAAAGCCTGTTCCGTGGCGGAGGGTCCTCAAGGAGTATCAAATCCTCCTTGTC
TGAAAATCAGTACGGTGGATCGCAGGAAGTTCGCTCTGCATCCTTGCTCATCGTTACCCAATGGCCGCCGACGCT
TTCGTTATCTCGTGTTTCAGTGATCACACAGTCTTTCGCGACACGGCTCCTCACTGACAGCCCAAACCACCATTT
CCTACTCGAACCATCCTATCATCGCCATCGCATCATAATCAACATATTCATCAACTGCACATATCCCATCACAAG
TTCACCAATCCCTGATTGACGAATCCTCCTCCTCGGCTTTGGGTGCTGCGCAATTCAGTTGTAACGGTTTCCGGT
TTTCAAAGTTTCTCCGACTTTGTGGTTTTATCGTTTCTTTCTTTCTTTCTTTACTTCTTTACCATATACTCTTAA
TTTTGTGGCGCATCCGAACTTGCTAAACCGCGAGTCATATGTTGCCTTCCATCTTCCACACCATAGGTTAATTCT
ATGGCCATCATCGTAGATTGATCAAGGTGAAACGACCAACCGACGGGAGCATTTGAGGCCTAGGTCTAACCGCTT
CCCAATACAGTTATCGGTTCTCCTCGCTATCCCTGGCTTGGTTCCACCACTTATGTTTCCAATAAATCAGCATCT
TTTCAACTTTCTTTAGTACTTCTCTGCTCTCCAATTTCTCCATTTTCCTTTCTACTTGGTTAATCTGTCCGCATG
TACCGTATCGTTCAAACACCAAAAATGTCACCACATTCCCACTTT
Length 2895

Gene

Sequence id CopciAB_462713.T0
Sequence >CopciAB_462713.T0
AGCCTGACCTCCCCACACCACTGCAACTCTCTTGATTCTATTATTTTCTCTATCCTCTCTCTCTTCATCGTCTGT
ATCCATAGTCTCAACGCCCACTGTATTCTTCAACAAAACTCCATCGACGACAACGCCCACCACTGGCACTAGCCG
CCCAGCATGCCAGCCAGTCCAAAGGCTTCCCAGGCAAAGAAGGCCGCGGCCTCTGCAAAGAACAAGGGGGCCGTC
CGTGCAAAGACCGGTTGCTATACGTGCAGAATCCGACGAAAGGTGAGAGCGCCCACGTTTCTCGACGAGCGCCTG
GAGCTGTTTGACTCATTAGTGGCGCCTTTTTTTCAGAAATGCGACGAGGAGCGCACAGAGCGAGACACGTGCAGG
ACCTGTGAGCGTCTGCGTCTCGAATGCTTGGGCTTTGGCGCCAAACGGCCCGAGTGGCTGAGGGTAAGCTTTTTT
GACGCCTGTGGGTACAGCGCTTGCTCATGGTCAACTCTAGGAAAACAAGAATGTCGTCCTCCTCCGCGACAAGAT
CAAGGCTTTCCTCGCGTCACAGGGCCTCATCAAGGGCCACTCAGGCACTGGCTCTCGCACTGCTGAGCAGGGACA
CATGATCTTGCAGCTCTCGGGAGACCCAAGCCAGTCCCACTACCACAGCTCCTCCTCGGAGAGCCCACCTTCAAG
GACCCTCTCCCTTTCCTCCGACGATGACCGGCATCGCCTCGTCACCTCTTCCATTCGTGATCAACGTGAGGACTC
AGCCTGGTTCAATCCTGGATACGGCTCTGGTACGCCTTCCCCTATTTTCGTACAGTGGCATGCCACTCACACTTC
TATTCCTTCCCTCAGGCCTCCATTCTCTCCATCGCTCCGACTCGCCCTTCTCGAATGCCAGTTACGACGAGGTTT
CACCTCATCACGCCTACACACTCCCTAATTCCTCTGGTAGCTTAGTTGACTCATGTGAGAATCTGTACCACTATT
GAACGCTGTAATGACCTGTATTTTAACACTTGATTTATTTGTTTTCCCAGCCCGCCTCTCCCCTGCAATCCGAAG
TACGTTCTCGAGGTGGTATACCGAAGTGCCAATCGACATCATGGACAACTTGAACGGTCTCTCAATCAGCGGCTT
CGCATCAAGTTCGACAGACGGCCACGCCACCAAGGACCCATCTACAATGTTGTTCACGATGCCCACCAACTGGCT
ACCAAGTGACCTCGTCGAAACTTCAATCGAGAACTACGTCCAAATGATCGCTGAGATTCAGTATCTGTTGGGAGA
CCGCAAGACACTACCGCAGATGATTTGGGATTCGTATCGGTCGCATCCCAACTCGAAGGCGGCATTGACATTGTT
GAACAAGGTGTACTGGAGAAGACAGCAACATCCAACCCAACCTGTGCTCACCGACTCGGAGATGCATTCGAACCT
CGCCGTGTTGTTACAAGAGCTAGAGAAAGGAAGATTCGACGACCCTGACGATGCCATCGCGGCACTACATGGAGT
CTCCATGTTCCTTTTCGACGGAGGGCAAGGTGCCTGGCGCGACTTCCTCAAGCTCGCCACTAGATACGTGAAGAA
GGTCCTCCACAACCCGCAATACACGAGTCCCAAAGACGCTCTCCTCTTCGCCACTGCCAAAGATGCATTCATCGT
CAAGACAGCCATCTGGTTTGACGTCCTCGCTTCCATCACCACTCAAGAGCCACCTACGTTCATCCAGGAGATCCG
AACCATGTTCGGTCCTGTTCACCATGGCGTCTACAACTCCCAATTCGATACTGACCCTCAGTGTTCGATGATGTC
GCCCATGGGTTGCGAGAACCGGGTAGTGTGGGCGTTGGCGGAAACTTCGACCCTCGCTCACTGGAAGTATACAGA
GGATGTCAGGTGCCGACTGAGCGTCAGCGACCTCGTCATTCGGGCACAAGAGATCGAGAACGTACTCTATCAAAA
ATCATACGAGCCGATGCCTGCGTCGGGTGAGGACGACAACGACATGGAACAACTCCGATTCCTGGCCTCGGAGAT
CTTCCGATGCTCTACGCGGCTCTTCCTCTCGGCTGTGGTGAACAATGACCACCCACAAGTTCGACAGATCCAAGA
TCTCGTGGACGAGTGCATGGCGGTGTTCCATAACTTGTTCAAGACACCAACACTGGACCAGTTCAAGGTTTCGAG
GTCAGTAATCCGAAGCACAGTGTTCGGTATTTACTTGGTTGGTGCCCTCACCCACAATCGCCAACACCGAGAGCA
CCTGCTGGAACACATAGAAAGAGAATCGAGGGGCCTGCATGGTGGCGTAGGGGAAGGAGTGGGGAATTGTGGGTC
GATTCGAAAGATGCTAGAGCACGTTTGGAAAGAGTCGGATGCTGATCCCGCAAAGCCTGTTCCGTGGCGGAGGGT
CCTCAAGGAGTATCAAATCCTCCTTGTCTGAAAATCAGTACGGTGGATCGCAGGAAGTTCGCTCTGCATCCTTGC
TCATCGTTACCCAATGGCCGCCGACGCTTTCGTTATCTCGTGTTTCAGTGATCACACAGTCTTTCGCGACACGGC
TCCTCACTGACAGCCCAAACCACCATTTCCTACTCGAACCATCCTATCATCGCCATCGCATCATAATCAACATAT
TCATCAACTGCACATATCCCATCACAAGTTCACCAATCCCTGATTGACGAATCCTCCTCCTCGGCTTTGGGTGCT
GCGCAATTCAGTTGTAACGGTTTCCGGTTTTCAAAGTTTCTCCGACTTTGTGGTTTTATCGTTTCTTTCTTTCTT
TCTTTACTTCTTTACCATATACTCTTAATTTTGTGGCGCATCCGAACTTGCTAAACCGCGAGTCATATGTTGCCT
TCCATCTTCCACACCATAGGTTAATTCTATGGCCATCATCGTAGATTGATCAAGGTGAAACGACCAACCGACGGG
AGCATTTGAGGCCTAGGTCTAACCGCTTCCCAATACAGTTATCGGTTCTCCTCGCTATCCCTGGCTTGGTTCCAC
CACTTATGTTTCCAATAAATCAGCATCTTTTCAACTTTCTTTAGTACTTCTCTGCTCTCCAATTTCTCCATTTTC
CTTTCTACTTGGTTAATCTGTCCGCATGTACCGTATCGTTCAAACACCAAAAATGTCACCACATTCCCACTTT
Length 3148