Transporter Protein
SPBC16D10.06


    Transport Function
Transporter Name: SPBC16D10.06
Transporter Type: Secondary Transporter
Transporter Family: ZIP (TC#: 2.A.5)
The Zinc (Zn2+)-Iron (Fe2+) Permease (ZIP) Family
Transporter Subfamily: 
Substrate/Function: zinc
TC#: 
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    Genome Locus
PID:   19113293     Blast
Source:   Schizosaccharomyces pombe
Chromosome:   CHR2
Location:   3566968..3568194
Gene:   -
Length:  408
Strand:  +
Code:   -
COG:   -
Product:  putative metal transporter
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    Transmembrane Segment
TMSs: 
TMHMM Server 
Total:     8
TMS 1:  64-86
TMS 2:  99-121
TMS 3:  141-160
TMS 4:  253-275
TMS 5:  285-304
TMS 6:  311-333
TMS 7:  348-370
TMS 8:  383-405
Topology:   >SPBC16D10.06
MSLNNLSNSYNQYLAQESHQILRHLFLNKQYSPLVKRDDDSSATVTCGGDANEFNEYGHLGYRIGAIFVI
LATSLIGMNLPLVLSKITKNRPNVYIEYLYLFARYFGSGVILATAFIHLLAPACNKLYDPCLDDLFGGYD
WAPGICLISCWFILLLEVLLNRYVEWRFGMEIGDHHGPTLGAKQHSHSHEDGAHGVHEHPVYDIEECADG
VEHECVKDDLEEVKLEPYTNTDSTDLTTKEEARSFLLKQQLTAFIILESSIILHSVIIGLTTAVSGEEFK
TLFPVIIFHQAFEGCGLGSRLAGMAWGPKTAWVPWVLGVIYSLVTPIGMAAGLGVREHWDPLAHGSYAAQ
GVLDAISSGILVYAGLVELLAHDFLFSPERERNWYKLIYLLACSMAGTGVMALLGKWA
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    Sequence
Protein Sequence: >SPBC16D10.06 19113293 putative metal transporter [Schizosaccharomyces pombe ]
MSLNNLSNSYNQYLAQESHQILRHLFLNKQYSPLVKRDDDSSATVTCGGDANEFNEYGHLGYRIGAIFVI
LATSLIGMNLPLVLSKITKNRPNVYIEYLYLFARYFGSGVILATAFIHLLAPACNKLYDPCLDDLFGGYD
WAPGICLISCWFILLLEVLLNRYVEWRFGMEIGDHHGPTLGAKQHSHSHEDGAHGVHEHPVYDIEECADG
VEHECVKDDLEEVKLEPYTNTDSTDLTTKEEARSFLLKQQLTAFIILESSIILHSVIIGLTTAVSGEEFK
TLFPVIIFHQAFEGCGLGSRLAGMAWGPKTAWVPWVLGVIYSLVTPIGMAAGLGVREHWDPLAHGSYAAQ
GVLDAISSGILVYAGLVELLAHDFLFSPERERNWYKLIYLLACSMAGTGVMALLGKWA
DNA Sequence: >SPBC16D10.06 19113293 putative metal transporter [Schizosaccharomyces pombe ]
ATGTCTTTAAACAATTTATCTAACTCATATAATCAATATCTTGCTCAAGAATCTCACCAAATATTGAGAC
ATCTTTTTCTTAATAAGCAATATAGTCCATTGGTAAAAAGAGACGATGATAGCTCTGCTACTGTGACTTG
TGGAGGTGATGCCAATGAATTCAACGAATATGGTCATCTGGGATATCGTATTGGTGCCATCTTTGTTATC
TTGGCTACTTCATTAATTGGCATGAACTTACCTTTGGTCCTTTCTAAAATCACCAAAAACAGACCCAACG
TTTATATTGAATATCTCTATCTATTCGCTCGTTATTTTGGTTCTGGTGTTATTTTGGCTACTGCTTTTAT
TCACTTGTTAGCCCCTGCTTGTAACAAGCTTTACGATCCTTGTCTTGACGACCTTTTCGGAGGTTACGAT
TGGGCTCCAGGTATTTGTCTTATTTCTTGTTGGTTTATTCTCTTGTTGGAGGTCCTTTTGAATCGCTATG
TGGAATGGCGGTTCGGTATGGAAATCGGCGATCATCATGGTCCAACTCTTGGTGCCAAACAACACAGTCA
TAGTCACGAAGACGGTGCTCACGGTGTTCATGAACATCCAGTTTATGATATTGAAGAATGTGCCGATGGT
GTTGAGCATGAATGTGTAAAGGATGACTTGGAAGAAGTAAAACTAGAACCTTATACGAATACTGATAGTA
CCGATTTGACTACTAAAGAAGAAGCTCGTAGTTTCTTACTAAAGCAACAACTTACTGCCTTTATAATTCT
TGAATCTAGTATCATTTTGCATAGTGTTATTATCGGTCTTACAACTGCCGTCTCAGGTGAAGAATTTAAA
ACTTTATTTCCCGTCATTATTTTCCATCAGGCCTTTGAAGGTTGTGGTTTAGGTTCTCGTTTGGCGGGAA
TGGCCTGGGGCCCAAAAACTGCATGGGTACCTTGGGTGTTGGGCGTTATCTATTCGTTGGTTACGCCTAT
TGGTATGGCAGCTGGTTTAGGTGTTCGTGAGCATTGGGATCCTCTTGCTCATGGGTCTTATGCTGCCCAA
GGTGTTTTGGATGCTATCTCATCTGGAATTTTGGTTTATGCTGGTTTAGTGGAATTACTTGCACACGATT
TCTTATTTAGTCCTGAAAGAGAACGTAACTGGTATAAGCTTATTTACCTTTTGGCATGCTCGATGGCTGG
TACTGGAGTTATGGCTTTGTTAGGTAAATGGGCTTGA
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    Publications
Publications on this gene:
1.  Yeast 2006 Oct 15; 13(23):913-9.
Gene Ontology annotation status of the fission yeast genome: preliminary coverage approaches 100%.

Aslett M ,Wood V ,

Wellcome Trust Sanger Institute, Cambridge CB10 1HH, UK.

In this review, we present an overview of the Gene Ontology (GO) structure and describe how the GO is implemented for Sz. pombe and made available via Sz. pombe GeneDB (http://www.genedb.org/genedb/pombe/). We give a detailed progress report of Sz. pombe GO annotation, providing the current status of both manual and automatic annotations. Fission yeast has at least one GO annotation for 98.3% of its genes (excluding annotations to 'unknown' terms), greater than the current percentage coverage for any other organism. Approximately 65% (3225 gene products) have at least one annotation to each of the three ontologies (biological process, cellular component and molecular function). Approximately 30% (1443 gene products) have GO terms derived directly from small-scale experiments in fission yeast, supporting the validity of fission yeast as a model eukaryote and a reference organism.

Publication Type: Review;
2.  Nat Biotechnol 2006 Jul ; 7(24):841-7.
ORFeome cloning and global analysis of protein localization in the fission yeast Schizosaccharomyces pombe.

Matsuyama A ,Arai R ,Yashiroda Y ,Shirai A ,Kamata A ,Sekido S ,Kobayashi Y ,Hashimoto A ,Hamamoto M ,Hiraoka Y ,Horinouchi S ,Yoshida M ,

Chemical Genetics Laboratory, RIKEN, Wako, Saitama 351-0198, Japan.

Cloning of the entire set of an organism's protein-coding open reading frames (ORFs), or 'ORFeome', is a means of connecting the genome to downstream 'omics' applications. Here we report a proteome-scale study of the fission yeast Schizosaccharomyces pombe based on cloning of the ORFeome. Taking advantage of a recombination-based cloning system, we obtained 4,910 ORFs in a form that is readily usable in various analyses. First, we evaluated ORF prediction in the fission yeast genome project by expressing each ORF tagged at the 3' terminus. Next, we determined the localization of 4,431 proteins, corresponding to approximately 90% of the fission yeast proteome, by tagging each ORF with the yellow fluorescent protein. Furthermore, using leptomycin B, an inhibitor of the nuclear export protein Crm1, we identified 285 proteins whose localization is regulated by Crm1.

Publication Type: Research Support, Non-U.S. Gov't;
Comment In: Nat Biotechnol. 2006 Jul;24(7):789-90
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    External Links

THE SEEDThe SEED  
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    NBCI Gene Page
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