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Previous release (v1)
2025-09-14 17:50:57, GGRNA.v2 : RefSeq release 231 (Jul, 2025)
LOCUS XM_070341941 11045 bp mRNA linear INV 12-DEC-2024
DEFINITION PREDICTED: Littorina saxatilis copper-transporting ATPase 1-like
(LOC138969207), transcript variant X1, mRNA.
ACCESSION XM_070341941
VERSION XM_070341941.1
DBLINK BioProject: PRJNA1148619
KEYWORDS RefSeq.
SOURCE Littorina saxatilis
ORGANISM Littorina saxatilis
Eukaryota; Metazoa; Spiralia; Lophotrochozoa; Mollusca; Gastropoda;
Caenogastropoda; Littorinimorpha; Littorinoidea; Littorinidae;
Littorina.
COMMENT MODEL REFSEQ: This record is predicted by automated computational
analysis. This record is derived from a genomic sequence
(NC_090250) annotated using gene prediction method: Gnomon.
Also see:
Documentation of NCBI's Annotation Process
##Genome-Annotation-Data-START##
Annotation Provider :: NCBI RefSeq
Annotation Status :: Full annotation
Annotation Name :: GCF_037325665.1-RS_2024_12
Annotation Pipeline :: NCBI eukaryotic genome annotation
pipeline
Annotation Software Version :: 10.3
Annotation Method :: Gnomon; cmsearch; tRNAscan-SE
Features Annotated :: Gene; mRNA; CDS; ncRNA
Annotation Date :: 12/06/2024
##Genome-Annotation-Data-END##
FEATURES Location/Qualifiers
source 1..11045
/organism="Littorina saxatilis"
/mol_type="mRNA"
/isolate="snail1"
/isolation_source="shore boulder field crab ecotype"
/db_xref="taxon:31220"
/tissue_type="muscle from the foot"
/dev_stage="adult"
/geo_loc_name="Sweden"
/collection_date="2017"
/linkage_group="LG6"
gene 1..11045
/gene="LOC138969207"
/note="copper-transporting ATPase 1-like; Derived by
automated computational analysis using gene prediction
method: Gnomon. Supporting evidence includes similarity
to: 11 Proteins"
/db_xref="GeneID:138969207"
CDS 160..5151
/gene="LOC138969207"
/codon_start=1
/product="copper-transporting ATPase 1-like isoform X1"
/protein_id="XP_070198042.1"
/db_xref="GeneID:138969207"
/translation="
MMYSRLHKTAQACEEEMEREAVLRLGQLTSADDAVTIQNLLTDQKGVVDAKVQYETREARVRYRPTETNPPILLGVLEDRAFSATIMDIQQSGDAASQKVAIDVDGMTCQSCVRNIEGNISHLDGVKDIHVSLENKQALVVFDASQTSASAVAEGISNMGFDAKVALGGDSGEQTRVIRVEGMTCQSCVRTIEGTMGSKQGISSIRVSLPDNQAIVRFNPCLISARQICEQIDDMGFDASLSDDEFAEIATRNKTPGSSRQCVISIGGMTCNSCVKNIESNISDKPGVKAIKVSLADQNGVVTYDPQIVKAAEIAEMIDDMGFDAKVAQQEDESLSDDEFAQIAARKAGGNGRKSCVISIQGMTCNSCVKNIESNIGAQPGILNIKVSLTDSNGVVTYDSKVTDPAKIAEMIDDMGFDAAVAQHDFPMGDQLANLNRSSNATQTCTISIEGMTCQSCVKKIESNMGNSAGIFSIKVSLADKNCQVDFDPAVVTPAQIGRMISDMGYRAFSLGDAAGTETQTVVVSIKGMTCQSCVNTIEGKLSEHPAVKSIHVSLSDETGTIMYDPSSATPKMLAEAIDDMGFDCAVQDGLKQDRGDQGKTIAHSASAVQMSSTGAVHFNKKVDEAGEFEKCFLTIKGMTCASCVANIERNINKIEGVKSILVSLMAQRAEVKFDPAYILPSQIANAVSDIGFNAKVNEAEGLGQGTVELTITGMTCASCVHLIQSNLLKRHGLLTASVALATSSGKFTFDTEICGPRDIIDAIKDMGFEAYLMTDDDKKAARYDHRDDIKRWRTSFLLSLIFGLPAMIVMIYFMFFYKPSEEGGEDHSNTTTTRPHKKSHKPQFMIADGLSLENLLMFILATPVQFIGGRYFYVQAYKAIKHGATNMDVLVVLATTISYLYSLIVVLVAMGLHERVSPITFFETTPMLMVFISLGRWLEHIAKGKTSEALAKLLSLQPSEAVLVTVDKENTILSEKIISVELVQRGDILKVVPGGKIPIDGKVVSGQSNCDESLITGESMPVSKKEGSTVIGGSINQHGTLLTEATHVGADTTLSQIVKLVEEAQTSKAPIQNLADKIAGIFVPIVCTLSTITLLGWVIAGYVDIKLIEEDFVDNGEVSKSEMIFEKAFQYAITVLSIACPCALGLATPTAVMVGTGVGALNGILIKGGEPLETTHKVRCIVFDKTGTVTHGVPRVARVSMFVTDSVCSFVKMIAICGTAEASSEHPIASAIVKYAKETLEAAVLGKTTDFKAVPGCGLKCKASGIESLLTGLDMDGVRNRRNKQGSLVIRIDSKSSQPSDSLHQALQIDDLAGAVAPATYEVLIGNREWMNRNGLTVTEEMDEVMTEHENQGHTAVLCTVDGVIVSMLAVADTVKSEAHVAIHELKKLVPEIILLTGDNKKTARAIAKQIGIKKVFAEVLPSHKVKKIRQLQAEGHKVAMVGDGVNDSPALAQADVGIAIGTGTDVAVEAADIVLMNSNLLDVFAAIKLSRKTVERIYMNFFFACLYNLLGIPIAAGVFVPWGLSLKPWMASAAMAASSVSVVVSSLGLKLFKKPKMKDLVTQEYHESYAKEQGLQGGVKESNKKSYNVKQTAGENVDDDEIAVYCGADVDAASRSGSRQGSLLSRLSNKIKSATNTPDQLSLLNNDDDLNMNEDSLSARV"
misc_feature 214..>456
/gene="LOC138969207"
/note="Cation-transporting P-type ATPase [Inorganic ion
transport and metabolism]; Region: ZntA; COG2217"
/db_xref="CDD:441819"
misc_feature 463..651
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(478..486,493..495)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 688..879
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(706..714,721..723)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 946..1137
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(964..972,979..981)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 1228..1419
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(1246..1254,1261..1263)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 1495..1683
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(1513..1521,1528..1530)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 1714..1911
/gene="LOC138969207"
/note="Copper chaperone CopZ [Inorganic ion transport and
metabolism]; Region: CopZ; COG2608"
/db_xref="CDD:442020"
misc_feature 2059..2247
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(2074..2082,2089..2091)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 2284..2475
/gene="LOC138969207"
/note="Heavy-metal-associated domain (HMA) is a conserved
domain of approximately 30 amino acid residues found in a
number of proteins that transport or detoxify heavy
metals, for example, the CPx-type heavy metal ATPases and
copper chaperones. HMA domain...; Region: HMA; cd00371"
/db_xref="CDD:238219"
misc_feature order(2302..2310,2317..2319)
/gene="LOC138969207"
/note="metal-binding site [ion binding]"
/db_xref="CDD:238219"
misc_feature 2548..4752
/gene="LOC138969207"
/note="P-type heavy metal-transporting ATPase, similar to
human copper-transporting ATPases, ATP7A and ATP7B;
Region: P-type_ATPase_Cu-like; cd02094"
/db_xref="CDD:319783"
misc_feature order(3580..3582,3586..3588,4684..4686)
/gene="LOC138969207"
/note="putative Cu binding site [ion binding]; other site"
/db_xref="CDD:319783"
misc_feature order(3712..3720,3922..3924,4135..4143,4231..4233,
4351..4359,4417..4419,4426..4428,4435..4437,4492..4494,
4501..4503)
/gene="LOC138969207"
/note="putative ATP binding site [chemical binding]; other
site"
/db_xref="CDD:319783"
polyA_site 11045
/gene="LOC138969207"
/experiment="COORDINATES: polyA evidence [ECO:0006239]"
ORIGIN
cccaaccctttcgatattgagagctacgtacaacttttaggacatgcgaccgactatggacaattgctctgtcatcggattggcggagaatgttatcagtattctccctgtgagcatttgagatcagttgtctcgtctcgaactttgctgtgtgcaggtatgatgtattctagactccacaagacggcccaggcatgcgaagaggagatggagagggaggcagtactgcgactaggtcagctgaccagcgctgacgatgcagtgaccatccaaaacttgttgaccgatcagaaaggcgttgtggacgccaaggtgcagtatgagacgagagaggcgcgtgtgaggtacaggcccacagagaccaaccccccgatcttgctgggtgtgctggaagaccgcgcgttctcagccaccatcatggacattcagcagtctggagacgccgcctcacagaaggtggccatcgacgttgacggcatgacctgccagtcgtgtgtgcgcaacattgagggcaacatctcacaccttgacggggtcaaggacatccacgtgtcgctggagaacaagcaggccctggtggtcttcgacgcgtcccagacgtcagccagcgccgtggcggaagggatcagtaacatgggattcgacgccaaggtggctttgggaggggactctggggaacaaacaagagtgattcgagtggagggcatgacctgccagtcctgcgtacgcaccatcgagggcaccatgggaagcaagcagggcatcagcagcattcgagtcagcttgcccgacaaccaggccatcgtacggttcaatccctgcctgatatctgcccggcagatttgtgaacagattgatgatatgggctttgatgcttctctcagtgacgatgaatttgcggaaattgcaactcggaataagacgccaggcagcagcaggcagtgtgtgatcagcattggaggaatgacgtgtaactcttgcgtgaagaacattgagtccaacatcagcgacaaaccaggggtcaaggccatcaaggtgtccttggctgaccagaacggtgtggtgacctacgaccctcagatcgtgaaggcggctgagatcgctgaaatgattgacgacatgggctttgacgctaaggtggctcagcaggaggatgagagcctgagtgacgatgagtttgcccagattgccgccaggaaggcaggagggaacggacgcaagtcttgtgtcatcagcattcagggcatgacgtgcaactcatgtgtgaagaacattgagtccaacatcggtgctcagccaggcatcctcaacatcaaagtgtccttgacagactctaatggcgtggtgacctatgacagcaaggtcacggatccagcgaagatcgctgaaatgattgatgacatggggtttgacgctgcagtggcccagcatgactttcccatgggtgaccagctggccaatctcaaccgttcgagcaacgccactcagacttgcaccatcagcatcgagggaatgacctgccagtcatgcgtgaaaaagattgaaagcaacatgggcaattcagcgggcatcttcagcatcaaagtgtctctcgctgacaagaactgtcaggtggattttgaccccgcagtggtgactcccgcccagatcgggcgaatgatttctgacatgggatacagagcgttttctcttggagacgcagcggggacagaaacacagacagtggtcgtatccatcaagggcatgacctgccagtcctgcgtcaacaccatcgagggcaaactgtcggaacacccggctgtcaagagtatccatgtgtcgctgtctgatgagacggggacaataatgtacgaccccagcagtgccacgcctaagatgctggctgaagccatcgatgacatgggattcgactgtgctgtgcaagatggcctcaaacaggacaggggagaccagggaaagacaattgctcattctgcgagtgcggttcaaatgagcagcactggcgctgtacacttcaacaaaaaagtggacgaggccggtgaattcgagaaatgcttcctcaccatcaagggcatgacctgtgcatcctgcgtcgccaacatcgagagaaacatcaataaaattgaaggcgtgaaaagtatcctggtgtccctgatggcacagagggcagaggtcaagtttgaccccgcctacatccttccctcacaaatcgccaacgcagtctccgacattggcttcaacgccaaggtcaacgaggcagagggactgggacaaggcactgtggaactaacaatcacaggcatgacgtgcgcatcatgtgttcacctgatccagagcaatttgttaaaacgccatggtcttctgacggcgtctgttgctttagccacctcttctggaaagttcacctttgacaccgagatctgcgggcccagagacatcattgacgccattaaggatatggggtttgaggcgtacctaatgacagatgatgacaagaaggccgctcgctacgatcacagggatgatatcaaacgatggagaacgtcgttcctgttgtcgctgatcttcgggctgccagccatgatagtgatgatctacttcatgtttttctacaaaccttcggaggagggaggggaggatcacagcaacaccaccaccacccgcccccacaagaagtcccacaagcctcagttcatgatcgctgatggcttgtccttggaaaatctcctcatgtttatcttggccacacctgtgcagttcatcggtggacgatacttctacgtccaagcgtacaaggcgataaaacacggagcgaccaacatggatgttctggttgtcctggcaaccaccatctcctacctgtattccttgattgtggttctggtggccatggggctgcacgagagagtttcacccatcactttctttgagaccacgcctatgttgatggtcttcatttcccttggcagatggctggaacatattgctaagggcaagaccagcgaagccctggccaagctgctatcactacagccatcagaagcggtgctggtgacggtggacaaggagaacaccatcctgtcggagaagatcatcagtgtggagctggtgcagcgcggtgacatcctcaaggtggtgccgggcggcaagatccccatcgacggcaaggtggtcagcggtcaatctaactgcgacgagtctctcatcacgggggagagcatgcctgtgtccaaaaaggaagggtccaccgtgattggtggcagtatcaaccagcacggcactctgctgacggaagcaacacacgttggggccgacaccacactctcacagattgtcaagctggtggaagaagcacagacatctaaggcccctattcagaatctggcagacaagatagctggtatctttgtgcctattgtgtgtacgctgtccactatcacgctgctgggctgggtcatcgctggatatgtggacattaaactcattgaagaagactttgtggacaacggagaagtgtcaaagagcgagatgatcttcgagaaggcgttccagtacgccatcacggtgctgagcatcgcctgtccctgtgccctcgggctggccacacccactgctgtcatggtggggacaggggtcggggcactcaacggcattctcatcaagggaggcgagccgctagaaaccacacacaaggtgcgttgcatcgtgtttgacaagactggcacagtaacacacggcgtgccccgagttgcgcgtgtgtccatgtttgtgacagactcggtgtgttctttcgtcaagatgatcgcaatctgtggcactgctgaggccagcagtgaacaccccatcgcttctgctatcgtcaagtatgccaaggagactctagaggcagcggtgctgggcaaaacgacagacttcaaggctgtgccagggtgcggcctcaagtgcaaggcgtccgggatcgaatccctgctgacggggctggacatggacggtgtgaggaaccgccgcaacaagcagggcagtttggtcatccgcatcgactccaagtccagtcagccgtccgacagtctgcaccaggccttgcagattgacgatctggcgggagcagtggcaccggcaacgtacgaagtgctgatcggaaaccgggagtggatgaatcgaaacggtctgacggtgacagaggaaatggatgaggtgatgacagagcatgagaatcagggtcatactgcagttctctgcactgttgatggtgtgattgtttccatgctggcggtagcagacacagtcaagtcggaggcccatgttgccatccatgagctgaagaagttggtgccagagattatcctcctgacgggcgacaacaagaaaacggcacgggccattgctaagcagattggaataaagaaggtgtttgcggaggtgttgccatcccacaaggtgaagaagattcgtcagctgcaggcagagggtcacaaggtggccatggttggagacggagtgaatgattcgccggccctagctcaggctgacgtcggcatcgctataggcactggcactgacgtggctgtggaggctgccgacattgttctcatgaatagcaacctcttggatgttttcgctgccattaaactgtcaagaaaaacagttgaacgcatctatatgaacttcttctttgcctgtctctacaacttacttggcatccccattgctgctggagtgtttgtaccttggggcctgtccctcaaaccctggatggcttccgctgctatggcagcctcctctgtctctgtcgtggtctcgtctctgggtctcaaattgttcaaaaagcccaagatgaaagatctggtaacacaggagtaccacgagtcctacgcgaaggaacagggtctccaaggaggggtcaaggagtccaacaagaagtcctacaacgtgaaacagacggcgggagagaatgttgatgacgatgaaatcgctgtctactgtggggccgatgtggacgc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//
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@meso_cacase at
DBCLS
This page is licensed under a
Creative Commons Attribution 4.0 International License (CC BY 4.0).
If you use GGRNA in your work, please cite:
Naito Y, Bono H. (2012)
GGRNA: an ultrafast, transcript-oriented search engine for genes and transcripts.
Nucleic Acids Res., 40, W592-W596.
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