Literature DB >> 9544531

The phosphatase system in Saccharomyces cerevisiae.

Y Oshima1.   

Abstract

The yeast Saccharomyces cerevisiae has at least six species of acid and alkaline phosphatases with different cellular localizations, as well as inorganic phosphate (Pi) transporters. Most of the genes encoding these enzymes are coordinately repressed and derepressed depending on the Pi concentration in the growth medium. The Pi signals are conveyed to these genes through a regulatory circuit consisting of a set of positive and negative regulatory proteins. This phosphatase system is interested as one of the best systems for studying gene regulation in S. cerevisiae due to the simplicity of phenotype determination in genetic analysis. With this methodological advantage, considerable amounts of genetic and molecular evidence in phosphatase regulation have been accumulated in the past twenty-five years. This article summarizes the current progress of research into this subject.

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Year:  1997        PMID: 9544531     DOI: 10.1266/ggs.72.323

Source DB:  PubMed          Journal:  Genes Genet Syst        ISSN: 1341-7568            Impact factor:   1.517


  74 in total

1.  Saccharomyces cerevisiae GATA sequences function as TATA elements during nitrogen catabolite repression and when Gln3p is excluded from the nucleus by overproduction of Ure2p.

Authors:  K H Cox; R Rai; M Distler; J R Daugherty; J A Coffman; T G Cooper
Journal:  J Biol Chem       Date:  2000-06-09       Impact factor: 5.157

2.  Computational inference of transcriptional regulatory networks from expression profiling and transcription factor binding site identification.

Authors:  Peter M Haverty; Ulla Hansen; Zhiping Weng
Journal:  Nucleic Acids Res       Date:  2004-01-02       Impact factor: 16.971

3.  Genetic analysis of chromatin remodeling using budding yeast as a model.

Authors:  David J Steger; Erin K O'Shea
Journal:  Methods Enzymol       Date:  2004       Impact factor: 1.600

4.  An intracellular phosphate buffer filters transient fluctuations in extracellular phosphate levels.

Authors:  Melissa R Thomas; Erin K O'Shea
Journal:  Proc Natl Acad Sci U S A       Date:  2005-06-22       Impact factor: 11.205

5.  The acid phosphatase Pho5 of Saccharomyces cerevisiae is not involved in polyphosphate breakdown.

Authors:  Nadeshda Andreeva; Larisa Ledova; Lubov Ryasanova; Tatiana Kulakovskaya; Michail Eldarov
Journal:  Folia Microbiol (Praha)       Date:  2019-04-01       Impact factor: 2.099

6.  Genetic and genomic approaches to develop rice germplasm for problem soils.

Authors:  Abdelbagi M Ismail; Sigrid Heuer; Michael J Thomson; Matthias Wissuwa
Journal:  Plant Mol Biol       Date:  2007-08-17       Impact factor: 4.076

7.  Shining a light on post-translational modification.

Authors:  Nigel G J Richards
Journal:  HFSP J       Date:  2008-03-12

8.  Differential cofactor requirements for histone eviction from two nucleosomes at the yeast PHO84 promoter are determined by intrinsic nucleosome stability.

Authors:  Christian J Wippo; Bojana Silic Krstulovic; Franziska Ertel; Sanja Musladin; Dorothea Blaschke; Sabrina Stürzl; Guo-Cheng Yuan; Wolfram Hörz; Philipp Korber; Slobodan Barbaric
Journal:  Mol Cell Biol       Date:  2009-03-23       Impact factor: 4.272

Review 9.  Phosphorus acquisition and use: critical adaptations by plants for securing a nonrenewable resource.

Authors:  Carroll P Vance; Claudia Uhde-Stone; Deborah L Allan
Journal:  New Phytol       Date:  2003-03       Impact factor: 10.151

Review 10.  Responses to phosphate deprivation in yeast cells.

Authors:  Kamlesh Kumar Yadav; Neelima Singh; Ram Rajasekharan
Journal:  Curr Genet       Date:  2015-11-28       Impact factor: 3.886
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