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Accession Number: | Q9Y2G3 |
Protein Name: | Probable phospholipid-transporting ATPase IF |
Length: | 1177 |
Molecular Weight: | 134190.00 |
Species: | Homo sapiens (Human) [9606] |
Number of TMSs: | 9 |
Location1 / Topology2 / Orientation3: | Recycling endosome membrane1 / Multi-pass membrane protein2 |
Substrate | phospholipid |
Cross database links:
Entrez Gene ID: | 23200 |
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Pfam: | PF00122 PF00702 |
KEGG: | hsa:23200 |
Gene Ontology
GO:0005769
C:early endosome
GO:0005783
C:endoplasmic reticulum
GO:0016021
C:integral to membrane
GO:0005637
C:nuclear inner membrane
GO:0005886
C:plasma membrane
GO:0055037
C:recycling endosome
GO:0055038
C:recycling endosome membrane
GO:0005524
F:ATP binding
GO:0015662
F:ATPase activity, coupled to transmembrane movement of ions, phosphorylative mechanism
GO:0005488
F:binding
GO:0015075
F:ion transmembrane transporter activity
GO:0000287
F:magnesium ion binding
GO:0004012
F:phospholipid-translocating ATPase activity
GO:0015917
P:aminophospholipid transport
GO:0006812
P:cation transport
GO:0045332
P:phospholipid translocation
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References (8)[1] “Differential expression of putative transbilayer amphipath transporters.” Halleck M.S.et.al. 11015572 [2] “The DNA sequence, annotation and analysis of human chromosome 3.” Muzny D.M.et.al. 16641997 [3] “The status, quality, and expansion of the NIH full-length cDNA project: the Mammalian Gene Collection (MGC).” The MGC Project Teamet.al. 15489334 [4] “Reanalysis of ATP11B, a Type IV P-type ATPase.” Halleck M.S.et.al. 11790799 [5] “Prediction of the coding sequences of unidentified human genes. XIII. The complete sequences of 100 new cDNA clones from brain which code for large proteins in vitro.” Nagase T.et.al. 10231032 [6] “The full-ORF clone resource of the German cDNA consortium.” Bechtel S.et.al. 17974005 [7] “Quantitative phosphoproteomic analysis of T cell receptor signaling reveals system-wide modulation of protein-protein interactions.” Mayya V.et.al. 19690332 [8] “ATP9B, a P4-ATPase (a putative aminophospholipid translocase), localizes to the trans-Golgi network in a CDC50 protein-independent manner.” Takatsu H.et.al. 21914794
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External Searches:
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Analyze:
Predict TMSs (Predict number of transmembrane segments) | ||||
FASTA formatted sequence |
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1: MWRWIRQQLG FDPPHQSDTR TIYVANRFPQ NGLYTPQKFI DNRIISSKYT VWNFVPKNLF 61: EQFRRVANFY FLIIFLVQLM IDTPTSPVTS GLPLFFVITV TAIKQGYEDW LRHNSDNEVN 121: GAPVYVVRSG GLVKTRSKNI RVGDIVRIAK DEIFPADLVL LSSDRLDGSC HVTTASLDGE 181: TNLKTHVAVP ETALLQTVAN LDTLVAVIEC QQPEADLYRF MGRMIITQQM EEIVRPLGPE 241: SLLLRGARLK NTKEIFGVAV YTGMETKMAL NYKSKSQKRS AVEKSMNTFL IIYLVILISE 301: AVISTILKYT WQAEEKWDEP WYNQKTEHQR NSSKILRFIS DFLAFLVLYN FIIPISLYVT 361: VEMQKFLGSF FIGWDLDLYH EESDQKAQVN TSDLNEELGQ VEYVFTDKTG TLTENEMQFR 421: ECSINGMKYQ EINGRLVPEG PTPDSSEGNL SYLSSLSHLN NLSHLTTSSS FRTSPENETE 481: LIKEHDLFFK AVSLCHTVQI SNVQTDCTGD GPWQSNLAPS QLEYYASSPD EKALVEAAAR 541: IGIVFIGNSE ETMEVKTLGK LERYKLLHIL EFDSDRRRMS VIVQAPSGEK LLFAKGAESS 601: ILPKCIGGEI EKTRIHVDEF ALKGLRTLCI AYRKFTSKEY EEIDKRIFEA RTALQQREEK 661: LAAVFQFIEK DLILLGATAV EDRLQDKVRE TIEALRMAGI KVWVLTGDKH ETAVSVSLSC 721: GHFHRTMNIL ELINQKSDSE CAEQLRQLAR RITEDHVIQH GLVVDGTSLS LALREHEKLF 781: MEVCRNCSAV LCCRMAPLQK AKVIRLIKIS PEKPITLAVG DGANDVSMIQ EAHVGIGIMG 841: KEGRQAARNS DYAIARFKFL SKLLFVHGHF YYIRIATLVQ YFFYKNVCFI TPQFLYQFYC 901: LFSQQTLYDS VYLTLYNICF TSLPILIYSL LEQHVDPHVL QNKPTLYRDI SKNRLLSIKT 961: FLYWTILGFS HAFIFFFGSY LLIGKDTSLL GNGQMFGNWT FGTLVFTVMV ITVTVKMALE 1021: THFWTWINHL VTWGSIIFYF VFSLFYGGIL WPFLGSQNMY FVFIQLLSSG SAWFAIILMV 1081: VTCLFLDIIK KVFDRHLHPT STEKAQLTET NAGIKCLDSM CCFPEGEAAC ASVGRMLERV 1141: IGRCSPTHIS RSWSASDPFY TNDRSILTLS TMDSSTC