Optimization Methods in Metabolic Networks
Optimization Methods in Metabolic Networks

Author: Costas D. Maranas

Publisher: John Wiley & Sons

Published: 2016-02-23

Total Pages: 278

ISBN-13: 1119028493

DOWNLOAD EBOOK

Provides a tutorial on the computational tools that use mathematical optimization concepts and representations for the curation, analysis and redesign of metabolic networks Organizes, for the first time, the fundamentals of mathematical optimization in the context of metabolic network analysis Reviews the fundamentals of different classes of optimization problems including LP, MILP, MLP and MINLP Explains the most efficient ways of formulating a biological problem using mathematical optimization Reviews a variety of relevant problems in metabolic network curation, analysis and redesign with an emphasis on details of optimization formulations Provides a detailed treatment of bilevel optimization techniques for computational strain design and other relevant problems

Pathway Analysis and Optimization in Metabolic Engineering
Pathway Analysis and Optimization in Metabolic Engineering

Author: Néstor V. Torres

Publisher: Cambridge University Press

Published: 2002-12-19

Total Pages: 328

ISBN-13: 9781139437615

DOWNLOAD EBOOK

Facility in the targeted manipulation of the genetic and metabolic composition of organisms, combined with unprecedented computational power, is forging a niche for a new subspecialty of biotechnology called metabolic engineering. First published in 2002, this book introduces researchers and advanced students in biology and engineering to methods of optimizing biochemical systems of biotechnological relevance. It examines the development of strategies for manipulating metabolic pathways, demonstrates the need for effective systems models, and discusses their design and analysis, while placing special emphasis on optimization. The authors propose power-law models and methods of biochemical systems theory toward these ends. All concepts are derived from first principles, and the text is richly illustrated with numerous graphs and examples throughout. Special features include: nontechnical and technical introductions to models of biochemical systems; a review of basic methods of model design and analysis; concepts of optimization; and detailed case studies.

Systems and Synthetic Metabolic Engineering
Systems and Synthetic Metabolic Engineering

Author: Yanfeng Liu

Publisher: Academic Press

Published: 2020-07-25

Total Pages: 294

ISBN-13: 0128217537

DOWNLOAD EBOOK

Systems and Synthetic Metabolic Engineering provides an overview of the development of metabolic engineering within medicine that is fueled by systems and synthetic biology. These newly developed, successful strategies of metabolic engineering guide the audience on how to propose and test proper strategies for metabolic engineering research. In addition to introductory, regulatory and challenges in the field, the book also covers dynamic control and autonomous regulation to control cell metabolism, along with computational modeling and industrial applications. The book is written by leaders in the field, making it ideal for synthetic biologists, researchers, students and anyone working in this area. Discusses the current progress of metabolic engineering, focusing on systems biology and synthetic biology Covers introductory, regulatory, strategies, production and challenges in the field Written technically for synthetic biologists, researchers, students, industrialists, policymakers and stakeholders

Metabolic Network Reconstruction and Modeling
Metabolic Network Reconstruction and Modeling

Author: Marco Fondi

Publisher: Humana Press

Published: 2018-08-30

Total Pages: 410

ISBN-13: 9781493985111

DOWNLOAD EBOOK

This volume looks at the latest methodologies used to study cellular metabolism with in silico approaches. The chapters in this book are divided into 3 parts: part I discusses tools and methods used for metabolic reconstructions and basic constraint-based metabolic modeling (CBMM); Part II explores protocols for the generation of experimental data for metabolic reconstruction and modeling, including transcriptomics, proteomics, and mutant generations; and Part III cover advanced techniques for quantitative modeling of cellular metabolism, including dynamic Flux Balance Analysis and multi-objective optimization. Written in the highly successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Cutting-edge and thorough, Metabolic Network Reconstruction and Modeling: Methods and Protocols is a valuable resource for qualified investigators studying cellular metabolism, and novice researchers who want to start working with CBMM.

Predicting Enzyme Targets for Optimization of Metabolic Networks Under Uncertainty
Predicting Enzyme Targets for Optimization of Metabolic Networks Under Uncertainty

Author: David Christopher Flowers

Publisher:

Published: 2012

Total Pages: 105

ISBN-13:

DOWNLOAD EBOOK

Recently, ensemble modeling was applied to metabolic networks for the sake of predicting the effects of genetic manipulations on the observed phenotype of the system. The ensemble of models is generated from experimental wild-type flux data and screened using phenotypic data from gene overexpression and knockout experiments, leaving predictive models. The need for data from multiple genetic perturbation experiments is an inherent limitation to this approach. In this investigation, ensemble modeling is used alongside elementary mode analysis to attempt to predict those enzymatic perturbations that are most likely to result in an increase in a target yield and a target flux when only the wild-type flux distribution is known. Elementary mode analysis indicates the maximum theoretical yield and its associated steady-state flux distribution(s), and the minimal cut set knockouts are determined that eliminate all but the highest-yield elementary modes. These knockouts and other perturbations are simulated using all of the ensemble models, and the distributions of predicted fluxes and yields over the models are compared to elucidate which reactions and metabolites most likely limit the target yield and flux. Additionally, a systematic method is developed to simultaneously identify multiple reactions that are responsible for bottlenecks after the minimal cut set knockouts are performed. These methods are applied to a metabolic network that models 3-deoxy-D-arabinoheptulosonate-7-phosphate (DAHP) production in E. coli. Results show that pyruvate accumulation due to glucose uptake and erythrose-4-phosphate (E4P) shortages resulting from the slow reaction rate of transketolase (Tkt) limit DAHP production. These results are consistent with published data, indicating that a detailed understanding of metabolic networks can be obtained with minimal experimental data. Additionally, the systematic method identifies four enzymes (Tkt, Tal, Pps, and AroG) that, when overexpressed experimentally, increase yield to nearly the maximum theoretical limit. Systematic analysis of a toy network also correctly identifies the post-MCS overexpression that results in the largest increases in yield and absolute fluxes. These results indicates that wild-type steady-state flux data can be used to accurately identify enzyme perturbation targets for increasing yield and target flux values.