Literature DB >> 23773966

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

Dawn H Marotta1, Andre Nantel, Leonid Sukala, Jennifer R Teubl, Jason M Rauceo.   

Abstract

Candida albicans maintains both commensal and pathogenic states in humans. Here, we have defined the genomic response to osmotic stress mediated by transcription factor Sko1. We performed microarray analysis of a sko1Δ/Δ mutant strain subjected to osmotic stress, and we utilized gene sequence enrichment analysis and enrichment mapping to identify Sko1-dependent osmotic stress-response genes. We found that Sko1 regulates distinct gene classes with functions in ribosomal synthesis, mitochondrial function, and vacuolar transport. Our in silico analysis suggests that Sko1 may recognize two unique DNA binding motifs. Our C. albicans genomic analyses and complementation studies in Saccharomyces cerevisiae showed that Sko1 is conserved as a regulator of carbohydrate metabolism, redox metabolism, and glycerol synthesis. Further, our real time-qPCR results showed that osmotic stress-response genes that are dependent on the kinase Hog1 also require Sko1 for full expression. Our findings reveal divergent and conserved aspects of Sko1-dependent osmotic stress signaling.
Copyright © 2013 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  Enrichment mapping; Osmotic stress; SKO1; Transcription factor; Yeast

Mesh:

Substances:

Year:  2013        PMID: 23773966      PMCID: PMC3907168          DOI: 10.1016/j.ygeno.2013.06.002

Source DB:  PubMed          Journal:  Genomics        ISSN: 0888-7543            Impact factor:   5.736


  45 in total

1.  The Hog1 MAP kinase controls respiratory metabolism in the fungal pathogen Candida albicans.

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2.  The MIQE guidelines: minimum information for publication of quantitative real-time PCR experiments.

Authors:  Stephen A Bustin; Vladimir Benes; Jeremy A Garson; Jan Hellemans; Jim Huggett; Mikael Kubista; Reinhold Mueller; Tania Nolan; Michael W Pfaffl; Gregory L Shipley; Jo Vandesompele; Carl T Wittwer
Journal:  Clin Chem       Date:  2009-02-26       Impact factor: 8.327

3.  High-resolution DNA-binding specificity analysis of yeast transcription factors.

Authors:  Cong Zhu; Kelsey J R P Byers; Rachel Patton McCord; Zhenwei Shi; Michael F Berger; Daniel E Newburger; Katrina Saulrieta; Zachary Smith; Mita V Shah; Mathangi Radhakrishnan; Anthony A Philippakis; Yanhui Hu; Federico De Masi; Marcin Pacek; Andreas Rolfs; Tal Murthy; Joshua Labaer; Martha L Bulyk
Journal:  Genome Res       Date:  2009-01-21       Impact factor: 9.043

4.  Structure and function of a transcriptional network activated by the MAPK Hog1.

Authors:  Andrew P Capaldi; Tommy Kaplan; Ying Liu; Naomi Habib; Aviv Regev; Nir Friedman; Erin K O'Shea
Journal:  Nat Genet       Date:  2008-10-19       Impact factor: 38.330

5.  Using RSAT to scan genome sequences for transcription factor binding sites and cis-regulatory modules.

Authors:  Jean-Valery Turatsinze; Morgane Thomas-Chollier; Matthieu Defrance; Jacques van Helden
Journal:  Nat Protoc       Date:  2008       Impact factor: 13.491

6.  Yeast translational response to high salinity: global analysis reveals regulation at multiple levels.

Authors:  Daniel Melamed; Lilach Pnueli; Yoav Arava
Journal:  RNA       Date:  2008-05-21       Impact factor: 4.942

7.  Genome-wide gene expression profiling and a forward genetic screen show that differential expression of the sodium ion transporter Ena21 contributes to the differential tolerance of Candida albicans and Candida dubliniensis to osmotic stress.

Authors:  Brice Enjalbert; Gary P Moran; Claire Vaughan; Tim Yeomans; Donna M Maccallum; Janet Quinn; David C Coleman; Alistair J P Brown; Derek J Sullivan
Journal:  Mol Microbiol       Date:  2009-02-23       Impact factor: 3.501

8.  Transmembrane mucins Hkr1 and Msb2 are putative osmosensors in the SHO1 branch of yeast HOG pathway.

Authors:  Kazuo Tatebayashi; Keiichiro Tanaka; Hui-Yu Yang; Katsuyoshi Yamamoto; Yusaku Matsushita; Taichiro Tomida; Midori Imai; Haruo Saito
Journal:  EMBO J       Date:  2007-07-12       Impact factor: 11.598

9.  Candida albicans RFX2 encodes a DNA binding protein involved in DNA damage responses, morphogenesis, and virulence.

Authors:  Binghua Hao; Cornelius J Clancy; Shaoji Cheng; Suresh B Raman; Kenneth A Iczkowski; M Hong Nguyen
Journal:  Eukaryot Cell       Date:  2009-02-27

10.  Phylogenetic diversity of stress signalling pathways in fungi.

Authors:  Elissavet Nikolaou; Ino Agrafioti; Michael Stumpf; Janet Quinn; Ian Stansfield; Alistair J P Brown
Journal:  BMC Evol Biol       Date:  2009-02-21       Impact factor: 3.260
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  9 in total

1.  The Role of Glycoside Hydrolases in S. gordonii and C. albicans Interactions.

Authors:  Zhiyan Zhou; Biao Ren; Jiyao Li; Xuedong Zhou; Xin Xu; Yuan Zhou
Journal:  Appl Environ Microbiol       Date:  2022-05-04       Impact factor: 5.005

Review 2.  Transcriptional regulation of the caspofungin-induced cell wall damage response in Candida albicans.

Authors:  Marienela Y Heredia; Deepika Gunasekaran; Mélanie A C Ikeh; Clarissa J Nobile; Jason M Rauceo
Journal:  Curr Genet       Date:  2020-09-02       Impact factor: 3.886

3.  High-Throughput Screening Identifies Genes Required for Candida albicans Induction of Macrophage Pyroptosis.

Authors:  Teresa R O'Meara; Kwamaa Duah; Cynthia X Guo; Michelle E Maxson; Ryan G Gaudet; Kristy Koselny; Melanie Wellington; Michael E Powers; Jessie MacAlpine; Matthew J O'Meara; Amanda O Veri; Sergio Grinstein; Suzanne M Noble; Damian Krysan; Scott D Gray-Owen; Leah E Cowen
Journal:  MBio       Date:  2018-08-21       Impact factor: 7.867

4.  Inhibition of Classical and Alternative Modes of Respiration in Candida albicans Leads to Cell Wall Remodeling and Increased Macrophage Recognition.

Authors:  Lucian Duvenage; Louise A Walker; Aleksandra Bojarczuk; Simon A Johnston; Donna M MacCallum; Carol A Munro; Campbell W Gourlay
Journal:  mBio       Date:  2019-01-29       Impact factor: 7.867

5.  Deletion of the SKO1 Gene in a hog1 Mutant Reverts Virulence in Candida albicans.

Authors:  Verónica Urrialde; Daniel Prieto; Susana Hidalgo-Vico; Elvira Román; Jesús Pla; Rebeca Alonso-Monge
Journal:  J Fungi (Basel)       Date:  2019-11-15

Review 6.  The SPFH Protein Superfamily in Fungi: Impact on Mitochondrial Function and Implications in Virulence.

Authors:  Marienela Y Heredia; Jason M Rauceo
Journal:  Microorganisms       Date:  2021-11-03

7.  The Candida albicans stress response gene Stomatin-Like Protein 3 is implicated in ROS-induced apoptotic-like death of yeast phase cells.

Authors:  Karen A Conrad; Ronald Rodriguez; Eugenia C Salcedo; Jason M Rauceo
Journal:  PLoS One       Date:  2018-02-01       Impact factor: 3.240

Review 8.  Stress-Activated Protein Kinases in Human Fungal Pathogens.

Authors:  Alison M Day; Janet Quinn
Journal:  Front Cell Infect Microbiol       Date:  2019-07-17       Impact factor: 5.293

9.  SPT20 Regulates the Hog1-MAPK Pathway and Is Involved in Candida albicans Response to Hyperosmotic Stress.

Authors:  Lianfang Wang; Ruilan Chen; Qiuting Weng; Shaoming Lin; Huijun Wang; Li Li; Beth Burgwyn Fuchs; Xiaojiang Tan; Eleftherios Mylonakis
Journal:  Front Microbiol       Date:  2020-02-21       Impact factor: 5.640
  9 in total

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