Literature DB >> 18434592

Regulation of the Candida albicans cell wall damage response by transcription factor Sko1 and PAS kinase Psk1.

Jason M Rauceo1, Jill R Blankenship, Saranna Fanning, Jessica J Hamaker, Jean-Sebastien Deneault, Frank J Smith, Andre Nantel, Aaron P Mitchell.   

Abstract

The environmental niche of each fungus places distinct functional demands on the cell wall. Hence cell wall regulatory pathways may be highly divergent. We have pursued this hypothesis through analysis of Candida albicans transcription factor mutants that are hypersensitive to caspofungin, an inhibitor of beta-1,3-glucan synthase. We report here that mutations in SKO1 cause this phenotype. C. albicans Sko1 undergoes Hog1-dependent phosphorylation after osmotic stress, like its Saccharomyces cerevisiae orthologues, thus arguing that this Hog1-Sko1 relationship is conserved. However, Sko1 has a distinct role in the response to cell wall inhibition because 1) sko1 mutants are much more sensitive to caspofungin than hog1 mutants; 2) Sko1 does not undergo detectable phosphorylation in response to caspofungin; 3) SKO1 transcript levels are induced by caspofungin in both wild-type and hog1 mutant strains; and 4) sko1 mutants are defective in expression of caspofungin-inducible genes that are not induced by osmotic stress. Upstream Sko1 regulators were identified from a panel of caspofungin-hypersensitive protein kinase-defective mutants. Our results show that protein kinase Psk1 is required for expression of SKO1 and of Sko1-dependent genes in response to caspofungin. Thus Psk1 and Sko1 lie in a newly described signal transduction pathway.

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Year:  2008        PMID: 18434592      PMCID: PMC2441657          DOI: 10.1091/mbc.e08-02-0191

Source DB:  PubMed          Journal:  Mol Biol Cell        ISSN: 1059-1524            Impact factor:   4.138


  42 in total

1.  The yeast protein kinase C cell integrity pathway mediates tolerance to the antifungal drug caspofungin through activation of Slt2p mitogen-activated protein kinase signaling.

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Journal:  Eukaryot Cell       Date:  2003-12

2.  Roles of Candida albicans Dfg5p and Dcw1p cell surface proteins in growth and hypha formation.

Authors:  Elisabetta Spreghini; Dana A Davis; Ryan Subaran; Michelle Kim; Aaron P Mitchell
Journal:  Eukaryot Cell       Date:  2003-08

3.  Disruption of a gene encoding glycerol 3-phosphatase from Candida albicans impairs intracellular glycerol accumulation-mediated salt-tolerance.

Authors:  Jinjiang Fan; Malcolm Whiteway; Shi-Hsiang Shen
Journal:  FEMS Microbiol Lett       Date:  2005-04-01       Impact factor: 2.742

4.  A role for the MAP kinase gene MKC1 in cell wall construction and morphological transitions in Candida albicans.

Authors:  F Navarro-García; R Alonso-Monge; H Rico; J Pla; R Sentandreu; C Nombela
Journal:  Microbiology (Reading)       Date:  1998-02       Impact factor: 2.777

5.  National epidemiology of mycoses survey (NEMIS): variations in rates of bloodstream infections due to Candida species in seven surgical intensive care units and six neonatal intensive care units.

Authors:  M S Rangel-Frausto; T Wiblin; H M Blumberg; L Saiman; J Patterson; M Rinaldi; M Pfaller; J E Edwards; W Jarvis; J Dawson; R P Wenzel
Journal:  Clin Infect Dis       Date:  1999-08       Impact factor: 9.079

6.  Rapid hypothesis testing with Candida albicans through gene disruption with short homology regions.

Authors:  R B Wilson; D Davis; A P Mitchell
Journal:  J Bacteriol       Date:  1999-03       Impact factor: 3.490

7.  Defects in assembly of the extracellular matrix are responsible for altered morphogenesis of a Candida albicans phr1 mutant.

Authors:  L Popolo; M Vai
Journal:  J Bacteriol       Date:  1998-01       Impact factor: 3.490

8.  Isolation of the Candida albicans homologs of Saccharomyces cerevisiae KRE6 and SKN1: expression and physiological function.

Authors:  T Mio; T Yamada-Okabe; T Yabe; T Nakajima; M Arisawa; H Yamada-Okabe
Journal:  J Bacteriol       Date:  1997-04       Impact factor: 3.490

9.  Characterization of the transcriptional response to cell wall stress in Saccharomyces cerevisiae.

Authors:  André Boorsma; Hans de Nobel; Bas ter Riet; Bastiaan Bargmann; Stanley Brul; Klaas J Hellingwerf; Frans M Klis
Journal:  Yeast       Date:  2004-04-15       Impact factor: 3.239

10.  Isolation from Candida albicans of a functional homolog of the Saccharomyces cerevisiae KRE1 gene, which is involved in cell wall beta-glucan synthesis.

Authors:  C Boone; A Sdicu; M Laroche; H Bussey
Journal:  J Bacteriol       Date:  1991-11       Impact factor: 3.490
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  42 in total

1.  Modeling the transcriptional regulatory network that controls the early hypoxic response in Candida albicans.

Authors:  Adnane Sellam; Marco van het Hoog; Faiza Tebbji; Cécile Beaurepaire; Malcolm Whiteway; André Nantel
Journal:  Eukaryot Cell       Date:  2014-03-28

2.  The Rim Pathway Mediates Antifungal Tolerance in Candida albicans through Newly Identified Rim101 Transcriptional Targets, Including Hsp90 and Ipt1.

Authors:  Cécile Garnaud; Encar García-Oliver; Yan Wang; Danièle Maubon; Sébastien Bailly; Quentin Despinasse; Morgane Champleboux; Jérôme Govin; Muriel Cornet
Journal:  Antimicrob Agents Chemother       Date:  2018-02-23       Impact factor: 5.191

Review 3.  Master and commander in fungal pathogens: the two-component system and the HOG signaling pathway.

Authors:  Yong-Sun Bahn
Journal:  Eukaryot Cell       Date:  2008-10-24

4.  Efg1 Controls caspofungin-induced cell aggregation of Candida albicans through the adhesin Als1.

Authors:  Christa Gregori; Walter Glaser; Ingrid E Frohner; Cristina Reinoso-Martín; Steffen Rupp; Christoph Schüller; Karl Kuchler
Journal:  Eukaryot Cell       Date:  2011-10-28

5.  Nucleosome assembly factors CAF-1 and HIR modulate epigenetic switching frequencies in an H3K56 acetylation-associated manner in Candida albicans.

Authors:  John S Stevenson; Haoping Liu
Journal:  Eukaryot Cell       Date:  2013-02-15

6.  Rapid redistribution of phosphatidylinositol-(4,5)-bisphosphate and septins during the Candida albicans response to caspofungin.

Authors:  Hassan Badrane; M Hong Nguyen; Jill R Blankenship; Shaoji Cheng; Binghua Hao; Aaron P Mitchell; Cornelius J Clancy
Journal:  Antimicrob Agents Chemother       Date:  2012-06-11       Impact factor: 5.191

7.  An extensive circuitry for cell wall regulation in Candida albicans.

Authors:  Jill R Blankenship; Saranna Fanning; Jessica J Hamaker; Aaron P Mitchell
Journal:  PLoS Pathog       Date:  2010-02-05       Impact factor: 6.823

8.  Genome-wide transcriptional profiling and enrichment mapping reveal divergent and conserved roles of Sko1 in the Candida albicans osmotic stress response.

Authors:  Dawn H Marotta; Andre Nantel; Leonid Sukala; Jennifer R Teubl; Jason M Rauceo
Journal:  Genomics       Date:  2013-06-15       Impact factor: 5.736

Review 9.  From elements to modules: regulatory evolution in Ascomycota fungi.

Authors:  Dana J Wohlbach; Dawn Anne Thompson; Audrey P Gasch; Aviv Regev
Journal:  Curr Opin Genet Dev       Date:  2009-10-29       Impact factor: 5.578

10.  Fungal echinocandin resistance.

Authors:  Louise A Walker; Neil A R Gow; Carol A Munro
Journal:  Fungal Genet Biol       Date:  2009-09-19       Impact factor: 3.495
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