Molecular mechanisms in yeast carbon metabolism /

Molecular mechanisms in yeast carbon metabolism /

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Bibliographic Details
Imprint:Heidelberg : Springer, 2014.
Description:1 online resource (viii, 326 pages) : illustrations (some color)
Language:English
Subject:
Microbial metabolism.
Yeast fungi -- Molecular aspects.
Yeast fungi -- Biotechnology.
Microbial metabolism.
Yeast fungi -- Biotechnology.
Format: E-Resource Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/11085007
Hidden Bibliographic Details
Other authors / contributors:Piškur, Jure, editor.
Compagno, Concetta, editor.
ISBN:9783642550133
3642550134
3642550126
9783642550126
9783642550126
Digital file characteristics:text file PDF
Notes:References3 Anaerobic Carbon Metabolism of Saccharomyces cerevisiae; 3.1 ... Introduction; 3.1.1 Many Factors Provide Competence for Anaerobic Growth; 3.1.2 Models Allow for Simulations of Anaerobic Performance; 3.1.3 Haem and Sterols as Sensors of Anaerobiosis; 3.2 ... Remodelling of Carbon Metabolism in the Absence of Oxygen; 3.2.1 High Glycolytic Flux Supports Anaerobic Growth; 3.2.2 The Relative Pentose Phosphate Pathway Flux is Lower Under Anaerobic Than Aerobic Conditions; 3.2.3 Roles of the Isoenzymes of Fermentative Pathway Depend on the Availability of Oxygen.
Online resource; title from PDF title page (SpringerLink, viewed May 15, 2014).
Summary:This book provides a comprehensive review of recent developments and achievements in the field of yeast carbon metabolism, from academic studies on gene expression to biotechnology-relevant aspects. Yeast is one of the most widely studied laboratory organisms and represents one of the most essential models for understanding how any eukaryote cell works. On the other hand, yeast fermentations have for millennia provided us with a variety of biotech products, like wine, beer, vitamins, and recently also with pharmaceutically active heterologous products and biofuels. A key biochemical activity in the yeast cell is the metabolism of carbon compounds, which provides energy for the whole cell, as well as precursors for any of the final fermentation products. A complex set of genes and regulatory pathways control the metabolism of carbon compounds, from nutrient sensing and signal transduction to transcription regulation and post-transcriptional events. Recent advances in comparative genomics and the development of post-genomic tools have provided further insights into the network of genes and enzymes, and into the molecular mechanisms which are responsible for a balanced metabolism of carbon compounds in the yeast cell, and which could be manipulated in the laboratory to increase the yield and quality of yeast biotech products.
Other form:Printed edition: 9783642550126
Standard no.:10.1007/978-3-642-55013-3

MARC

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505 0 |a Introduction to Carbon Metabolism in Yeast -- Glucose Sensing and Signal Transduction in Saccharomyces cerevisiae -- Anaerobic Carbon Metabolism of Saccharomyces cerevisiae -- Systems Biology: Developments and Applications -- Comparative Genomics and Evolutionary Genetics of Yeast Carbon Metabolism -- Similarities and Differences Between Cancer and Yeast Carbohydrate Metabolism -- Carbon Metabolism in Pathogenic Yeasts (Especially Candida): The Role of Cell Wall Metabolism in Virulence -- Molecular Mechanisms in Yeast Carbon Metabolism: Lipid Metabolism and Lipidomics -- Molecular Mechanisms in Yeast Carbon Metabolism: Bioethanol and Other Biofuels -- Wine, Beer and Cider: Unravelling the Aroma Profile -- Production of Metabolites and Heterologous Proteins. 
520 |a This book provides a comprehensive review of recent developments and achievements in the field of yeast carbon metabolism, from academic studies on gene expression to biotechnology-relevant aspects. Yeast is one of the most widely studied laboratory organisms and represents one of the most essential models for understanding how any eukaryote cell works. On the other hand, yeast fermentations have for millennia provided us with a variety of biotech products, like wine, beer, vitamins, and recently also with pharmaceutically active heterologous products and biofuels. A key biochemical activity in the yeast cell is the metabolism of carbon compounds, which provides energy for the whole cell, as well as precursors for any of the final fermentation products. A complex set of genes and regulatory pathways control the metabolism of carbon compounds, from nutrient sensing and signal transduction to transcription regulation and post-transcriptional events. Recent advances in comparative genomics and the development of post-genomic tools have provided further insights into the network of genes and enzymes, and into the molecular mechanisms which are responsible for a balanced metabolism of carbon compounds in the yeast cell, and which could be manipulated in the laboratory to increase the yield and quality of yeast biotech products. 
504 |a References3 Anaerobic Carbon Metabolism of Saccharomyces cerevisiae; 3.1 ... Introduction; 3.1.1 Many Factors Provide Competence for Anaerobic Growth; 3.1.2 Models Allow for Simulations of Anaerobic Performance; 3.1.3 Haem and Sterols as Sensors of Anaerobiosis; 3.2 ... Remodelling of Carbon Metabolism in the Absence of Oxygen; 3.2.1 High Glycolytic Flux Supports Anaerobic Growth; 3.2.2 The Relative Pentose Phosphate Pathway Flux is Lower Under Anaerobic Than Aerobic Conditions; 3.2.3 Roles of the Isoenzymes of Fermentative Pathway Depend on the Availability of Oxygen. 
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