Articles producció científica> Bioquímica i Biotecnologia

New genes involved in osmotic stress tolerance in saccharomyces cerevisiae

  • Identification data

    Identifier: PC:1989
    Authors:
    Maite NovoRamon GonzalezPilar MoralesJordi TronchoniGustavo Cordero-BuesoEnrico VaudanoManuel QuirósRafael Torres-PérezEva Valero
    Abstract:
    Adaptation to changes in osmolarity is fundamental for the survival of living cells, and has implications in food and industrial biotechnology. It has been extensively studied in the yeast Saccharomyces cerevisiae, where the Hog1 stress activated protein kinase was discovered about 20 years ago. Hog1 is the core of the intracellular signaling pathway that governs the adaptive response to osmotic stress in this species. The main endpoint of this program is synthesis and intracellular retention of glycerol, as a compatible osmolyte. Despite many details of the signaling pathways and yeast responses to osmotic challenges have already been described, genome-wide approaches are contributing to refine our knowledge of yeast adaptation to hypertonic media. In this work, we used a quantitative fitness analysis approach in order to deepen our understanding of the interplay between yeast cells and the osmotic environment. Genetic requirements for proper growth under osmotic stress showed both common and specific features when hypertonic conditions were induced by either glucose or sorbitol. Tolerance to high-glucose content requires mitochondrial function, while defective protein targeting to peroxisome, GID-complex function (involved in negative regulation of gluconeogenesis), or chromatin dynamics, result in poor survival to sorbitol-induced osmotic stress. On the other side, the competitive disadvantage of yeast strains defective in the endomembrane system is relieved by hypertonic conditions. This finding points to the Golgi-endosome system as one of the main cell components negatively affected by hyperosmolarity. Most of the biological processes highlighted in this analysis had not been previously related to osmotic stress but are probably relevant in an ecological and evolu
  • Others:

    Author, as appears in the article.: Maite Novo; Ramon Gonzalez; Pilar Morales; Jordi Tronchoni; Gustavo Cordero-Bueso; Enrico Vaudano; Manuel Quirós; Rafael Torres-Pérez; Eva Valero
    Department: Bioquímica i Biotecnologia
    URV's Author/s: NOVO MOLINERO, MARIA TERESA; Ramon Gonzalez; Pilar Morales; Jordi Tronchoni; Gustavo Cordero-Bueso; Enrico Vaudano; Manuel Quirós; Rafael Torres-Pérez; Eva Valero
    Keywords: Osmotic stress GID-complex Endomembrane system
    Abstract: Adaptation to changes in osmolarity is fundamental for the survival of living cells, and has implications in food and industrial biotechnology. It has been extensively studied in the yeast Saccharomyces cerevisiae, where the Hog1 stress activated protein kinase was discovered about 20 years ago. Hog1 is the core of the intracellular signaling pathway that governs the adaptive response to osmotic stress in this species. The main endpoint of this program is synthesis and intracellular retention of glycerol, as a compatible osmolyte. Despite many details of the signaling pathways and yeast responses to osmotic challenges have already been described, genome-wide approaches are contributing to refine our knowledge of yeast adaptation to hypertonic media. In this work, we used a quantitative fitness analysis approach in order to deepen our understanding of the interplay between yeast cells and the osmotic environment. Genetic requirements for proper growth under osmotic stress showed both common and specific features when hypertonic conditions were induced by either glucose or sorbitol. Tolerance to high-glucose content requires mitochondrial function, while defective protein targeting to peroxisome, GID-complex function (involved in negative regulation of gluconeogenesis), or chromatin dynamics, result in poor survival to sorbitol-induced osmotic stress. On the other side, the competitive disadvantage of yeast strains defective in the endomembrane system is relieved by hypertonic conditions. This finding points to the Golgi-endosome system as one of the main cell components negatively affected by hyperosmolarity. Most of the biological processes highlighted in this analysis had not been previously related to osmotic stress but are probably relevant in an ecological and evolutionary context.
    Research group: Grup de Recerca en Nutrigenòmica
    Thematic Areas: Biochemistry and technology Bioquímica y tecnología Bioquímica i biotecnologia
    licence for use: https://creativecommons.org/licenses/by/3.0/es/
    ISSN: 1664-302X
    Author identifier: 0000-0002-2454-1990; n/a; 0000-0002-0130-6111; 0000-0001-9227-2713; 0000-0003-1538-066X; 0000-0002-2091-1464; n/a; n/a; n/a
    Record's date: 2016-11-25
    Journal volume: 7
    Papper version: info:eu-repo/semantics/publishedVersion
    Licence document URL: https://repositori.urv.cat/ca/proteccio-de-dades/
    Entity: Universitat Rovira i Virgili
    Journal publication year: 2016
    First page: Art.num. 1545
    Publication Type: Article Artículo Article
  • Keywords:

    Osmotic stress
    Saccharomyces cerevisiae -- Biotecnologia
    Peroxisome
    Osmotic stress
    GID-complex
    Endomembrane system
    Biochemistry and technology
    Bioquímica y tecnología
    Bioquímica i biotecnologia
    1664-302X
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