Literature DB >> 18629074

Genome-wide analysis of the yeast transcriptome upon heat and cold shock.

M Becerra1, L J Lombardía, M I González-Siso, E Rodríguez-Belmonte, N C Hauser, M E Cerdán.   

Abstract

DNA arrays were used to measure changes in transcript levels as yeast cells responded to temperature shocks. The number of genes upregulated by temperature shifts from 30 to 37 or 45 was correlated with the severity of the stress. Pre-adaptation of cells, by growth at 37 previous to the 45 shift, caused a decrease in the number of genes related to this response. Heat shock also caused downregulation of a set of genes related to metabolism, cell growth and division, transcription, ribosomal proteins, protein synthesis and destination. Probably all of these responses combine to slow down cell growth and division during heat shock, thus saving energy for cell rescue. The presence of putative binding sites for Xbp1p in the promoters of these genes suggests a hypothetical role for this transcriptional repressor, although other mechanisms may be considered. The response to cold shock (4) affected a small number of genes, but the vast majority of those genes induced by exposure to 4 were also induced during heat shock; these genes share in their promoters cis-regulatory elements previously related to other stress responses.

Entities:  

Year:  2003        PMID: 18629074      PMCID: PMC2447359          DOI: 10.1002/cfg.301

Source DB:  PubMed          Journal:  Comp Funct Genomics        ISSN: 1531-6912


  16 in total

1.  Processing and quality control of DNA array hybridization data.

Authors:  T Beissbarth; K Fellenberg; B Brors; R Arribas-Prat; J Boer; N C Hauser; M Scheideler; J D Hoheisel; G Schütz; A Poustka; M Vingron
Journal:  Bioinformatics       Date:  2000-11       Impact factor: 6.937

Review 2.  The economics of ribosome biosynthesis in yeast.

Authors:  J R Warner
Journal:  Trends Biochem Sci       Date:  1999-11       Impact factor: 13.807

3.  Microarray data warehouse allowing for inclusion of experiment annotations in statistical analysis.

Authors:  Kurt Fellenberg; Nicole C Hauser; Benedikt Brors; Jörg D Hoheisel; Martin Vingron
Journal:  Bioinformatics       Date:  2002-03       Impact factor: 6.937

4.  Multiple mechanisms regulate expression of low temperature responsive (LOT) genes in Saccharomyces cerevisiae.

Authors:  L Zhang; A Ohta; H Horiuchi; M Takagi; R Imai
Journal:  Biochem Biophys Res Commun       Date:  2001-05-04       Impact factor: 3.575

5.  Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction.

Authors:  P Chomczynski; N Sacchi
Journal:  Anal Biochem       Date:  1987-04       Impact factor: 3.365

6.  Genomic expression programs in the response of yeast cells to environmental changes.

Authors:  A P Gasch; P T Spellman; C M Kao; O Carmel-Harel; M B Eisen; G Storz; D Botstein; P O Brown
Journal:  Mol Biol Cell       Date:  2000-12       Impact factor: 4.138

7.  Cellular lipid composition influences stress activation of the yeast general stress response element (STRE).

Authors:  M T Chatterjee; S A Khalawan; B P Curran
Journal:  Microbiology       Date:  2000-04       Impact factor: 2.777

8.  Remodeling of yeast genome expression in response to environmental changes.

Authors:  H C Causton; B Ren; S S Koh; C T Harbison; E Kanin; E G Jennings; T I Lee; H L True; E S Lander; R A Young
Journal:  Mol Biol Cell       Date:  2001-02       Impact factor: 4.138

9.  Genome-wide analysis of gene expression regulated by the yeast cell wall integrity signalling pathway.

Authors:  U S Jung; D E Levin
Journal:  Mol Microbiol       Date:  1999-12       Impact factor: 3.501

10.  Whole genome analysis of a wine yeast strain.

Authors:  N C Hauser; K Fellenberg; R Gil; S Bastuck; J D Hoheisel; J E Pérez-Ortín
Journal:  Comp Funct Genomics       Date:  2001
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  7 in total

1.  Dynamic transcriptional and metabolic responses in yeast adapting to temperature stress.

Authors:  Katrin Strassburg; Dirk Walther; Hiroki Takahashi; Shigehiko Kanaya; Joachim Kopka
Journal:  OMICS       Date:  2010-06

2.  Understanding the Mechanism of Thermotolerance Distinct From Heat Shock Response Through Proteomic Analysis of Industrial Strains of Saccharomyces cerevisiae.

Authors:  Wenqing Shui; Yun Xiong; Weidi Xiao; Xianni Qi; Yong Zhang; Yuping Lin; Yufeng Guo; Zhidan Zhang; Qinhong Wang; Yanhe Ma
Journal:  Mol Cell Proteomics       Date:  2015-04-29       Impact factor: 5.911

3.  Systematic interpretation of microarray data using experiment annotations.

Authors:  Kurt Fellenberg; Christian H Busold; Olaf Witt; Andrea Bauer; Boris Beckmann; Nicole C Hauser; Marcus Frohme; Stefan Winter; Jürgen Dippon; Jörg D Hoheisel
Journal:  BMC Genomics       Date:  2006-12-20       Impact factor: 3.969

4.  Differential proteomic analysis by SWATH-MS unravels the most dominant mechanisms underlying yeast adaptation to non-optimal temperatures under anaerobic conditions.

Authors:  Tânia Pinheiro; Ka Ying Florence Lip; Estéfani García-Ríos; Amparo Querol; José Teixeira; Walter van Gulik; José Manuel Guillamón; Lucília Domingues
Journal:  Sci Rep       Date:  2020-12-18       Impact factor: 4.379

5.  Stability of metabolic correlations under changing environmental conditions in Escherichia coli--a systems approach.

Authors:  Jedrzej Szymanski; Szymon Jozefczuk; Zoran Nikoloski; Joachim Selbig; Victoria Nikiforova; Gareth Catchpole; Lothar Willmitzer
Journal:  PLoS One       Date:  2009-10-15       Impact factor: 3.240

6.  Rapid Identification of Major QTLS Associated With Near- Freezing Temperature Tolerance in Saccharomyces cerevisiae.

Authors:  Li Feng; He Jia; Yi Qin; Yuyang Song; Shiheng Tao; Yanlin Liu
Journal:  Front Microbiol       Date:  2018-09-11       Impact factor: 5.640

7.  The ABC transporter Pdr18 is required for yeast thermotolerance due to its role in ergosterol transport and plasma membrane properties.

Authors:  Cláudia P Godinho; Rute Costa; Isabel Sá-Correia
Journal:  Environ Microbiol       Date:  2020-10-11       Impact factor: 5.491
  7 in total

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