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Author: Jason L. Walther
Publisher:
ISBN:
Category :
Languages : en
Pages : 260
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Book Description
Many current and future applications of biological engineering hinge on our ability to measure, understand, and manipulate metabolism. Many diseases for which we seek cures are metabolic in nature. Small-molecule biomanufacturing almost always involves metabolic engineering. Biofuels, a current topic of great interest, is essentially a metabolic problem. Even bioprocesses that involve complex products, such as enzyme or antibody manufacturing, still rely on a healthy and optimal metabolism and can benefit from a greater understanding therein. A cell's metabolic flux distribution has been proposed to be one of the most solid and meaningful indicators and descriptors of metabolism. Metabolic fluxes represent integrative information and are a function of gene expression, translation, post-translational modifications, and protein-metabolite interactions. Metabolic flux analysis (MFA) is a powerful method for determining these flux distribution through a cellular reaction network. However, MFA has experimental limitations (most notably, a requirement for isotopic steady state) that restrict the scope of biological contexts in which it can be applied. Nonstationary metabolic flux analysis (NMFA) has recently emerged as a combined computational and experimental method that improves upon MFA with the capacity to estimate fluxes even during periods of isotopic transience in metabolism, allowing flux analysis to be applied in a broader range of experimental settings. In this thesis, we have developed and applied robust and efficient NMFA tools and techniques and applied them to understand various cellular physiologies. We built a software package (MetranCL) that combines the elementary metabolite unit (EMU) framework, a new network decomposition strategy termed block decoupling, and a customized differential equation solver. MetranCL performs flux estimations as much as 5000 times faster than the previous state-of-the-art NMFA methods, opening entirely new types of biological systems to the possibility of flux analysis. We applied MetranCL to a simulated large network representing E. coli metabolism and were able to successfully estimate reaction fluxes and metabolite concentrations and their 95% confidence intervals. We investigated a number of different experimental arrangements of measurement time points, and found that in general, measurements earlier in isotopic transience were more sensitive to network parameters and yielded more precise confidence intervals. We also observed that the addition of concentration measurements significantly increased estimate quality. We next used NMFA to compute fluxes from actual experimental measurements taken from brown adipocytes. We designed an appropriate network and successfully fitted simulated measurements to actual measurements (taken at 2, 4, and 6 hours after introducing tracer). A flux distribution was obtained that indicated a high level of pyruvate cycling, a low flux through the TCA cycle, and high lactate production. We developed computational and experimental tools to assist with the design of flux analysis experiments. We built a simulator that calculates the effect of different tracers on flux estimate precision and used it to study a range of different glucose and glutamine tracers in carcinoma metabolism. Of all the stand-alone tracers we tested, we found that [1,2- 13C2]glucose estimated flux distributions with the greatest precision. We built upon this work by constructing an evolutionary algorithm to generate optimal tracer mixtures for different organisms and their respective metabolisms. We applied this algorithm to the same cancer network and found optimal tracer mixtures for the system. We ran experiments with an optimized tracer mixture and compared it to results from typical tracers and saw significant improvements in flux precision. Finally, we applied these methods and tools to evaluate and understand the flux distribution and metabolism of a lipid-overproducing strain of the yeast Yarrowia lipolytica. Since NMFA of this organism required metabolite extracts taken at very precise and proximate time points, we built a rapid sampling apparatus to draw and quench samples of Yarrowia cell culture with a one-second time step. After conducting NMFA under different environmental conditions and at different stages of growth, we found that lipid synthesis fluxes increased when aeration of the cell culture was increased, and observed several corresponding changes in the intracellular flux distribution explaining the overall change in metabolism that occurs with this shift in environmental conditions. In particular, we found that Yarrowia primarily powers lipid production by regulating flux through the pentose phosphate pathway.
Author: Jason L. Walther
Publisher:
ISBN:
Category :
Languages : en
Pages : 260
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Book Description
Many current and future applications of biological engineering hinge on our ability to measure, understand, and manipulate metabolism. Many diseases for which we seek cures are metabolic in nature. Small-molecule biomanufacturing almost always involves metabolic engineering. Biofuels, a current topic of great interest, is essentially a metabolic problem. Even bioprocesses that involve complex products, such as enzyme or antibody manufacturing, still rely on a healthy and optimal metabolism and can benefit from a greater understanding therein. A cell's metabolic flux distribution has been proposed to be one of the most solid and meaningful indicators and descriptors of metabolism. Metabolic fluxes represent integrative information and are a function of gene expression, translation, post-translational modifications, and protein-metabolite interactions. Metabolic flux analysis (MFA) is a powerful method for determining these flux distribution through a cellular reaction network. However, MFA has experimental limitations (most notably, a requirement for isotopic steady state) that restrict the scope of biological contexts in which it can be applied. Nonstationary metabolic flux analysis (NMFA) has recently emerged as a combined computational and experimental method that improves upon MFA with the capacity to estimate fluxes even during periods of isotopic transience in metabolism, allowing flux analysis to be applied in a broader range of experimental settings. In this thesis, we have developed and applied robust and efficient NMFA tools and techniques and applied them to understand various cellular physiologies. We built a software package (MetranCL) that combines the elementary metabolite unit (EMU) framework, a new network decomposition strategy termed block decoupling, and a customized differential equation solver. MetranCL performs flux estimations as much as 5000 times faster than the previous state-of-the-art NMFA methods, opening entirely new types of biological systems to the possibility of flux analysis. We applied MetranCL to a simulated large network representing E. coli metabolism and were able to successfully estimate reaction fluxes and metabolite concentrations and their 95% confidence intervals. We investigated a number of different experimental arrangements of measurement time points, and found that in general, measurements earlier in isotopic transience were more sensitive to network parameters and yielded more precise confidence intervals. We also observed that the addition of concentration measurements significantly increased estimate quality. We next used NMFA to compute fluxes from actual experimental measurements taken from brown adipocytes. We designed an appropriate network and successfully fitted simulated measurements to actual measurements (taken at 2, 4, and 6 hours after introducing tracer). A flux distribution was obtained that indicated a high level of pyruvate cycling, a low flux through the TCA cycle, and high lactate production. We developed computational and experimental tools to assist with the design of flux analysis experiments. We built a simulator that calculates the effect of different tracers on flux estimate precision and used it to study a range of different glucose and glutamine tracers in carcinoma metabolism. Of all the stand-alone tracers we tested, we found that [1,2- 13C2]glucose estimated flux distributions with the greatest precision. We built upon this work by constructing an evolutionary algorithm to generate optimal tracer mixtures for different organisms and their respective metabolisms. We applied this algorithm to the same cancer network and found optimal tracer mixtures for the system. We ran experiments with an optimized tracer mixture and compared it to results from typical tracers and saw significant improvements in flux precision. Finally, we applied these methods and tools to evaluate and understand the flux distribution and metabolism of a lipid-overproducing strain of the yeast Yarrowia lipolytica. Since NMFA of this organism required metabolite extracts taken at very precise and proximate time points, we built a rapid sampling apparatus to draw and quench samples of Yarrowia cell culture with a one-second time step. After conducting NMFA under different environmental conditions and at different stages of growth, we found that lipid synthesis fluxes increased when aeration of the cell culture was increased, and observed several corresponding changes in the intracellular flux distribution explaining the overall change in metabolism that occurs with this shift in environmental conditions. In particular, we found that Yarrowia primarily powers lipid production by regulating flux through the pentose phosphate pathway.
Author: Deepak Nagrath
Publisher: Humana
ISBN: 9781071601587
Category : Science
Languages : en
Pages : 0
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Book Description
This volume explores the latest metabolic flux analysis (MFA) techniques that cover the analysis of cellular, organ level, and whole-body metabolism. The chapters in this book discuss topics such as deutrium tracing; isotopologue fractions using GC-TOF; non-targeted mass isotopolome analysis; large-scale profiling of cellular metabolic activities using deep 13C labeling medium; metastases in mice; SWATH; Exo-MFA; metabolic flux from time-course metabolomics; and thermodynamic approaches in flux analysis. 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 comprehensive, Metabolic Flux Analysis in Eukaryotic Cells: Methods and Protocols is a valuable resource for both experts in MFA techniques and researchers getting involved in the role of quantitative studies to uncover the dysregulated pathways in human diseases.
Author: Michael E. Himmel
Publisher: Humana
ISBN: 9781071601945
Category : Medical
Languages : en
Pages : 0
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Book Description
This book illustrates experimental and computational methodologies used to achieve cost effective biological processes for the production of fuels and biochemicals through multiple approaches to increasing yield, titers, and productivity in a robust host. The volume includes the most recent and cutting-edge aspects of pathway engineering, flux analysis, and metabolic enzyme engineering. Each chapter highlights the complexity and challenges of the problem as well as the methods used to solve this problem or changes needed in current methods. As a part of the highly successful Methods in Molecular Biology series, chapters include the kind of detailed implementation advice that gives researchers a much needed boost. Authoritative and practical, Metabolic Pathway Engineering benefits not only scientists working on more fundamental aspects of this endeavor but also those in the biochemical industry working on strain engineering for robust industrial processes.
Author: Weiwen Zhang
Publisher: Springer
ISBN: 9811308543
Category : Medical
Languages : en
Pages : 357
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Book Description
This volume highlights recent breakthroughs in the interdisciplinary areas of synthetic biology, metabolic engineering and bioprocess engineering for the production of green chemicals. It also presents practical experimental and computational tools for the design, construction and manipulation of cyanobacteria cell factories. The respective contributions cover new technologies in the field, such as novel genetic transformation techniques and bioinformatics analysis methods and address various aspects of cyanobacterial synthetic biology, offering a valuable resource for students and researchers in the fields of industry microbiology and biomedical engineering.
Author: Michael R. Dyson
Publisher: Methods Express (Hardcover)
ISBN:
Category : Science
Languages : en
Pages : 318
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Book Description
Protein expression is an increasingly important tool for research on gene function. What is needed is not just a lab manual providing established methods as well as the latest state-of-the-art protocols, but also clear advice on what expression system to choose when. Expression Systems: Methods Expressuniquely fills this need. It covers expression across a broad range of systems, including the following. *Baculovirus expression vectors *CHO cells *E. coli *HEK293-EBNA1 cells *Lactococcus lactis and other gram positive bacteria *S. cerevisiae *transfected insect cells *Pichia pastoris *mammalian cells using BacMam viruses *lentiviral vectors *wheat germ cell-free system The book takes the reader through how to make an informed choice of appropriate system, taking into account the protein target, the time involved, the ultimate use of the expressed protein, and the laboratory equipment required. It also provides step-by-step methods for each system. In addition, the book describes the optimisation of expression strategies, expression engineering using ribosome display, and how to select protein variants with improved expression. Every chapter discusses the merits and limitations of the approaches available, describes the key techniques in full practical detail, and provides sensible advice for immediate use at the bench. In summary, Expression Systems: Methods Expressis a comprehensive laboratory manual and information resource for researchers at all levels, from postgraduate student to principal investigator.
Author: Mohamed Al-Rubeai
Publisher: Springer
ISBN: 3319103202
Category : Medical
Languages : en
Pages : 766
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Book Description
Animal cells are the preferred “cell factories” for the production of complex molecules and antibodies for use as prophylactics, therapeutics or diagnostics. Animal cells are required for the correct post-translational processing (including glycosylation) of biopharmaceutical protein products. They are used for the production of viral vectors for gene therapy. Major targets for this therapy include cancer, HIV, arthritis, cardiovascular and CNS diseases and cystic fibrosis. Animal cells are used as in vitro substrates in pharmacological and toxicological studies. This book is designed to serve as a comprehensive review of animal cell culture, covering the current status of both research and applications. For the student or R&D scientist or new researcher the protocols are central to the performance of cell culture work, yet a broad understanding is essential for translation of laboratory findings into the industrial production. Within the broad scope of the book, each topic is reviewed authoritatively by experts in the field to produce state-of-the-art collection of current research. A major reference volume on cell culture research and how it impacts on production of biopharmaceutical proteins worldwide, the book is essential reading for everyone working in cell culture and is a recommended volume for all biotechnology libraries.
Author:
Publisher: Academic Press
ISBN: 9780120342570
Category : Science
Languages : en
Pages : 405
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Book Description
Prion Proteins is "issue-oriented" and edited by a well-known authority in the field. Topics covered include structure, diversity, and energetics as well as the diseases associated with prion proteins.
Author: Vijai K. Pasupuleti
Publisher: Springer Science & Business Media
ISBN: 1402066740
Category : Science
Languages : en
Pages : 237
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Book Description
Protein hydrolysates, otherwise commonly known as peptones or peptides, are used in a wide variety of products in fermentation and biotechnology industries. The term “peptone” was first introduced in 1880 by Nagelli for growing bacterial cultures. However, later it was discovered that peptones derived from the partial digestion of proteins would furnish organic nitrogen in readily available form. Ever since, p- tones, which are commonly known as protein hydrolysates, have been used not only for growth of microbial cultures, but also as nitrogen source in commercial fermen- tions using animal cells and recombinant microorganisms for the production of value added products such as therapeutic proteins, hormones, vaccines, etc. Today, the characterization, screening and manufacturing of protein hyd- lysates has become more sophisticated, with the introduction of reliable analytical instrumentation, high throughput screening techniques coupled with statistical design approaches, novel enzymes and efficient downstream processing equipment. This has enabled the introduction of custom-built products for specialized appli- tions in diverse fields of fermentation and biotechnology, such as the following. 1. Protein hydrolysates are used as much more than a simple nitrogen source. For example, the productivities of several therapeutic drugs made by animal cells and recombinant microorganisms have been markedly increased by use of p- tein hydrolysates. This is extremely important when capacities are limited. 2. Protein hydrolysates are employed in the manufacturing of vaccines by ferm- tation processes and also used as vaccine stabilizers.
Author: Manuel J.T. Carrondo
Publisher: Springer Science & Business Media
ISBN: 940115404X
Category : Science
Languages : en
Pages : 816
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Book Description
Animal cell technology has undergone a rapid transformation over the last decade from a research tool and highly specialised technology to a central resource for innovation in pharmaceutical research and development. These proceedings of the 14th Meeting of the European Society for Animal Cell Technology (Vilamoura, Portugal, May 1996) bring up to date the historical perspective of animal cell technology for the benefit of society, `From Vaccines to Genetic Medicine', and will charter this vital technology for the years to come. Strong contributions are grouped in the traditional ESACT areas of 'Cell and Physiology Engineering' dealing with cell state, including genetics, and its environment, and 'Animal Cell Process Engineering' covering integration of bioreaction with bioseparation coupled with on-line monitoring to improve protein production and consistency. Extensive coverage of metabolic engineering on synthesis, folding, assembly, transiting and secretion is dealt with in the session on 'Recombinant Proteins: Biosynthesis and Bioprocessing'. Two traditional but expanding areas of animal cell technology relevance are highlighted in the broad sessions of 'Animal Cells as Tools for Discovery and Testing' and 'Animal Cell Vaccines: Present and Future'. Two sessions finally cover the more recent domains of animal cell technology work - 'Tissue Engineering and Biomedical Devices' and 'Cells and Vectors for Genetic Medicine' - where one can foresee a very bright future.
