Bacterial cellular metabolic systems : metabolic regulation of a cell system with 13C-metabolic flux analysis

The metabolic regulation of a cell system is of critical importance in systems biology, and a robust model of these mechanisms is essential in predicting the effects on the metabolism of both the culture environment and the knockout of specific genes. Bacterial cellular metabolic systems focuses on this highly topical subject in relation to culture environment and provides a detailed analysis from gene level to metabolic level regulation, as well as offering a discussion of the most recent modelling approaches. The book begins with an introduction to metabolic mechanisms and to the metabolic regulation of a cell, before moving on to discussing the action of global regulators in response to a specific culture environment. The second half of the book examines conventional flux balance analysis and its applications, 13C-metabolic flux analysis, and the effect of a specific gene knockout on the metabolism.

Figures Tables About the author Chapter 1: Main metabolism Abstract: 1.1 Introduction 1.2 Energy generation in the cell 1.3 Carbohydrate metabolism 1.4 Respiratory chain pathways 1.5 Anaerobic metabolism 1.6 Anaerobic respiration 1.7 Photosynthesis 1.8 Amino acids synthesis 1.9 Nucleic acid synthesis and its control 1.10 Fatty acid metabolism and degradation 1.11 Phosphotransferase system (PTS) 1.12 Carbohydrate metabolism other than glucose 1.13 ATP generation under aerobic and anaerobic conditions 1.14 Metabolic regulation and futile cycle Chapter 2: Brief overview of metabolic regulation of a bacterial cell Abstract: 2.1 Introduction 2.2 Metabolic regulation analysis by protein expressions 2.3 Metabolic regulation during the time course of batch culture 2.4 Reduction of by-product (acetate) formation Chapter 3: Metabolic regulation by global regulators in response to culture environment Abstract: 3.1 Introduction 3.2 Carbon catabolite regulation 3.3 Nitrogen regulation 3.4 Phosphate regulation 3.5 Oxygen level regulation 3.6 Acid shock or the effect of pH 3.7 Heat shock response 3.8 Fatty acid metabolic regulation 3.9 Response to nutrient starvation Chapter 4: Conventional flux balance analysis and its applications Abstract: 4.1 Introduction 4.2 Basis for metabolic flux analysis 4.3 Application to photosynthetic bacteria 4.4 Metabolic flux analysis of a single gene knockout E. coli under anaerobic conditions Chapter 5: 13C-metabolic flux analysis and its applications Abstract: 5.1 Introduction 5.2 Basic principle for flux calculation based on 13C-labeling experiment 5.3 Simple example for flux calculation based on 13C-labeling experiment 5.4 Analytical approach for flux computation 5.5 13C metabolic flux analysis based on GC-MS 5.6 13C-MFA using NMR 5.7 13CMFA for cyanobacteria based on GC-MS and NMR 5.8 Appendix 5.A ΛAP and bPEP in Equation 5.41 Chapter 6: Effect of a specific-gene knockout on metabolism Abstract: 6.1 Introduction 6.2 Effect of ppc and pck gene knockout on metabolism 6.3 Effect of zwf and gnd genes knockout on metabolism 6.4 Effect of pyk gene knockout on metabolism 6.5 Effect of lpdA gene knockout on metabolism 6.6 Effect of sucA and sucC gene knockout on metabolism 6.7 Effect of icdA gene knockout on metabolism 6.8 Effect of pfl gene knockout on metabolism 6.9 Effect of ldhA gene knockout on metabolism Appendices Index