FOG02835
EOG89P8JT
sce:PRY2;PRY1;PRY3
Genes: 68
EOG89P8JT
sce:PRY2;PRY1;PRY3
Genes: 68
SGD Description
Sterol binding protein involved in the export of acetylated sterols; secreted glycoprotein and member of the CAP protein superfamily (cysteine-rich secretory proteins (CRISP), antigen 5, and pathogenesis related 1 proteins); sterol export function is redundant with that of PRY1; may be involved in detoxification of hydrophobic compounds; PRY2 has a paralog, PRY1, that arose from the whole genome duplication|Sterol binding protein involved in the export of acetylated sterols; secreted glycoprotein and member of the CAP protein superfamily (cysteine-rich secretory proteins (CRISP), antigen 5, and pathogenesis related 1 proteins); sterol export function is redundant with that of PRY2; may be involved in detoxification of hydrophobic compounds; PRY1 has a paralog, PRY2, that arose from the whole genome duplication|Cell wall-associated protein involved in export of acetylated sterols; member of the CAP protein superfamily (cysteine-rich secretory proteins (CRISP), antigen 5, and pathogenesis related 1 proteins); role in mating efficiency; expression of full-length transcript is daughter cell-specific; in response to alpha factor, a short transcript starting at +452 is expressed and the long form is repressed by Ste12p
AspGD Description
Has domain(s) with predicted extracellular region localization
References
Hamada K, et al. (1998 Apr). Screening for glycosylphosphatidylinositol (GPI)-dependent cell wall proteins in Saccharomyces cerevisiae.
Braun BR, et al. (2000 May). TUP1, CPH1 and EFG1 make independent contributions to filamentation in candida albicans.
Braun BR, et al. (2000 Sep). Identification and characterization of TUP1-regulated genes in Candida albicans.
Kadosh D, et al. (2001 Apr). Rfg1, a protein related to the Saccharomyces cerevisiae hypoxic regulator Rox1, controls filamentous growth and virulence in Candida albicans.
Colman-Lerner A, et al. (2001 Dec 14). Yeast Cbk1 and Mob2 activate daughter-specific genetic programs to induce asymmetric cell fates.
Leng P, et al. (2001 Jul). Efg1, a morphogenetic regulator in Candida albicans, is a sequence-specific DNA binding protein.
Lane S, et al. (2001 Oct). The basic helix-loop-helix transcription factor Cph2 regulates hyphal development in Candida albicans partly via TEC1.
Monteoliva L, et al. (2002 Aug). Large-scale identification of putative exported proteins in Candida albicans by genetic selection.
Terashima H, et al. (2002 Feb). Sequence-based approach for identification of cell wall proteins in Saccharomyces cerevisiae.
Nantel A, et al. (2002 Oct). Transcription profiling of Candida albicans cells undergoing the yeast-to-hyphal transition.
Sohn K, et al. (2003 Jan). EFG1 is a major regulator of cell wall dynamics in Candida albicans as revealed by DNA microarrays.
Tsong AE, et al. (2003 Nov 14). Evolution of a combinatorial transcriptional circuit: a case study in yeasts.
Bensen ES, et al. (2004 Dec). Transcriptional profiling in Candida albicans reveals new adaptive responses to extracellular pH and functions for Rim101p.
Law GL, et al. (2005). The undertranslated transcriptome reveals widespread translational silencing by alternative 5' transcript leaders.
García-Sánchez S, et al. (2005 Jun). Global roles of Ssn6 in Tup1- and Nrg1-dependent gene regulation in the fungal pathogen, Candida albicans.
Yin QY, et al. (2005 May 27). Comprehensive proteomic analysis of Saccharomyces cerevisiae cell walls: identification of proteins covalently attached via glycosylphosphatidylinositol remnants or mild alkali-sensitive linkages.
Bickel KS, et al. (2006 Nov). Role of the transcription activator Ste12p as a repressor of PRY3 expression.
Bennett RJ, et al. (2006 Oct). The role of nutrient regulation and the Gpa2 protein in the mating pheromone response of C. albicans.
Jackson BE, et al. (2007 Jun). Corneal virulence of Candida albicans strains deficient in Tup1-regulated genes.
Clancy CJ, et al. (2008 May). Immunoglobulin G responses to a panel of Candida albicans antigens as accurate and early markers for the presence of systemic candidiasis.
Sorgo AG, et al. (2010 Aug). Mass spectrometric analysis of the secretome of Candida albicans.
Hernáez ML, et al. (2010 May 7). Identification of Candida albicans exposed surface proteins in vivo by a rapid proteomic approach.
Synnott JM, et al. (2010 Nov). Regulation of the hypoxic response in Candida albicans.
Sorgo AG, et al. (2011 Aug). Effects of fluconazole on the secretome, the wall proteome, and wall integrity of the clinical fungus Candida albicans.
Chen C, et al. (2011 Aug 18). An iron homeostasis regulatory circuit with reciprocal roles in Candida albicans commensalism and pathogenesis.
Singh RP, et al. (2011 Jul 15). Cap2-HAP complex is a critical transcriptional regulator that has dual but contrasting roles in regulation of iron homeostasis in Candida albicans.
Mayer FL, et al. (2012). The novel Candida albicans transporter Dur31 Is a multi-stage pathogenicity factor.
Ene IV, et al. (2012 Nov). Carbon source-induced reprogramming of the cell wall proteome and secretome modulates the adherence and drug resistance of the fungal pathogen Candida albicans.
Bailey UM, et al. (2012 Nov 2). Analysis of congenital disorder of glycosylation-Id in a yeast model system shows diverse site-specific under-glycosylation of glycoproteins.
Choudhary V, et al. (2012 Oct 16). Pathogen-Related Yeast (PRY) proteins and members of the CAP superfamily are secreted sterol-binding proteins.
Pierce JV, et al. (2013 Jan). Normal adaptation of Candida albicans to the murine gastrointestinal tract requires Efg1p-dependent regulation of metabolic and host defense genes.
Röhm M, et al. (2013 Jan). A family of secreted pathogenesis-related proteins in Candida albicans.
Nishida N, et al. (2013 May 20). ABC transporters and cell wall proteins involved in organic solvent tolerance in Saccharomyces cerevisiae.
| Mitochondrial localization predictions | ||
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| Predotar | TargetP | MitoProt |
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| Raw data
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| Phobius transmembrane predictions
6 genes with posterior transmembrane prediction > 50% |
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FOG02836
EOG89P8JT
sce:absent
Genes: 6
EOG89P8JT
sce:absent
Genes: 6
| Mitochondrial localization predictions | ||
|---|---|---|
| Predotar | TargetP | MitoProt |
 |
 |
 |
| Raw data
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| Phobius transmembrane predictions
0 genes with posterior transmembrane prediction > 50% |
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FOG02837
EOG89P8JT
sce:absent
Genes: 4
EOG89P8JT
sce:absent
Genes: 4
| Mitochondrial localization predictions | ||
|---|---|---|
| Predotar | TargetP | MitoProt |
 |
 |
 |
| Raw data
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| Phobius transmembrane predictions
0 genes with posterior transmembrane prediction > 50% |
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FOG02838
EOG89P8JT
sce:absent
Genes: 3
EOG89P8JT
sce:absent
Genes: 3
AspGD Description
Has domain(s) with predicted extracellular region localization
| Mitochondrial localization predictions | ||
|---|---|---|
| Predotar | TargetP | MitoProt |
 |
 |
 |
| Raw data
|
||
| Phobius transmembrane predictions
1 genes with posterior transmembrane prediction > 50% |
||
FOG02839
EOG89P8JT
sce:absent
Genes: 3
EOG89P8JT
sce:absent
Genes: 3
| Mitochondrial localization predictions | ||
|---|---|---|
| Predotar | TargetP | MitoProt |
 |
 |
 |
| Raw data
|
||
| Phobius transmembrane predictions
0 genes with posterior transmembrane prediction > 50% |
||
