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Author: Chao Ma
Publisher:
ISBN:
Category : Electronic dissertations
Languages : en
Pages : 214
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Book Description
As a sustainable and environmentally friendly biofuel, biobutanol is a potential substitute for gasoline without any engine modification. The multiple Omics studies were applied to evaluate the change of the expression of host protein and intracellular metabolism in Clostridium tyrobutyricum in response to butanol production. The key enzymes related to carbon balance (i.e. acid and solvent end products and carbohydrates in central pathway), redox balance, energy balance, and cell growth has been studied. It was found that rebalancing both carbon and redox was critical to improve butanol production. These findings were used to achieve high production of biobutanol via integrated metabolic cell-process engineering (MCPE). In a comparative genomics study, the wild type C. tyrobutyricum, the metabolically engineered mutant with down-regulated acetate kinase and evolutionarily engineered strain showing fast cell growth were used to evaluated in butyrate fermentation at pH 6.0 and 37 oC. It was found that the cell growth rate was increased by 61-100% and butyrate productivity was improved by 44-102% by the evolutionarily engineered strain. To understand the mechanism of butyric acid production and cell growth regulation in engineered C. tyrobutyricum mutant, a comparative genomics study was performed. It was concluded that the genome mutations in transcription, translation, amino acid and phosphate transportation and cofactor binding might play important role in regulating cell growth and butyric acid production. Comparative proteomics, which covered 78.1% of open reading frames and 95% of core enzymes, was performed using wild type, mutant producing 37.30 g/L of butyrate and mutant producing 16.68 g/L of butanol. Carbon regulation enzymes in the central metabolic pathway that correlated with butanol production were identified, including thiolase (thl), acetyl-CoA acetyltransferase (ato), 3-hydroxybutyryl-CoA dehydrogenase (hbd) and crotonase (crt). The apparent imbalance of energy and redox was also observed due to the downregulation of acids production and the addition of butanol synthesis pathway. The understanding of the mechanism of carbon redistribution enabled the rational design of metabolic cell and process engineering strategies were revealed to achieve high butanol production in C. tyrobutyricum. With the fundamental understanding, the C. tyrobutyricum was metabolically engineered by rebalancing carbon and redox simultaneously. The overexpression of aldehyde/alcohol dehydrogenase (adhE2) and formate dehydrogenase (fdh) improved butanol titer by 2.15 fold in serum bottle and 2.72 fold in bioreactor. In addition, the proteomics study and metabolite analysis showed that more than 90% of the amino acid in the medium was consumed before the cell entered the stationary phase and some enzymes involved in amino acid metabolism had low expression in butanol producing mutant. Extra yeast extract or casamino acids was fed to the free-cell fermentation the mid-log phase, improving the butanol titer to more than 18 g/L compared to 14 g/L without extra nitrogen supplement. The rational metabolic cell-process engineering facilitated with systems biology understanding was demonstrated a powerful approach in butanol production. Finally, the C. tyrobutyricum was further rationally engineered by integrating multiple regualtors, including 1) heterologous NAD+-fdh that provides extra reducing power, 2) the thiolase (thl) that redirects metabolic flux from C2 to C4, and 3) AdhE2. Two novel mutatns, ACKKO-adhE2-fdh and ACKKO-thl-adhE2-fdh, were constructed and produced 18.37 g/L and 19.41 g/L, respectively. This study demonstrated that systems biology-based metabolic cell-process engineering of C. tyrobutyricum enabled a high production of butanol.
Author: Chao Ma
Publisher:
ISBN:
Category : Electronic dissertations
Languages : en
Pages : 214
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Book Description
As a sustainable and environmentally friendly biofuel, biobutanol is a potential substitute for gasoline without any engine modification. The multiple Omics studies were applied to evaluate the change of the expression of host protein and intracellular metabolism in Clostridium tyrobutyricum in response to butanol production. The key enzymes related to carbon balance (i.e. acid and solvent end products and carbohydrates in central pathway), redox balance, energy balance, and cell growth has been studied. It was found that rebalancing both carbon and redox was critical to improve butanol production. These findings were used to achieve high production of biobutanol via integrated metabolic cell-process engineering (MCPE). In a comparative genomics study, the wild type C. tyrobutyricum, the metabolically engineered mutant with down-regulated acetate kinase and evolutionarily engineered strain showing fast cell growth were used to evaluated in butyrate fermentation at pH 6.0 and 37 oC. It was found that the cell growth rate was increased by 61-100% and butyrate productivity was improved by 44-102% by the evolutionarily engineered strain. To understand the mechanism of butyric acid production and cell growth regulation in engineered C. tyrobutyricum mutant, a comparative genomics study was performed. It was concluded that the genome mutations in transcription, translation, amino acid and phosphate transportation and cofactor binding might play important role in regulating cell growth and butyric acid production. Comparative proteomics, which covered 78.1% of open reading frames and 95% of core enzymes, was performed using wild type, mutant producing 37.30 g/L of butyrate and mutant producing 16.68 g/L of butanol. Carbon regulation enzymes in the central metabolic pathway that correlated with butanol production were identified, including thiolase (thl), acetyl-CoA acetyltransferase (ato), 3-hydroxybutyryl-CoA dehydrogenase (hbd) and crotonase (crt). The apparent imbalance of energy and redox was also observed due to the downregulation of acids production and the addition of butanol synthesis pathway. The understanding of the mechanism of carbon redistribution enabled the rational design of metabolic cell and process engineering strategies were revealed to achieve high butanol production in C. tyrobutyricum. With the fundamental understanding, the C. tyrobutyricum was metabolically engineered by rebalancing carbon and redox simultaneously. The overexpression of aldehyde/alcohol dehydrogenase (adhE2) and formate dehydrogenase (fdh) improved butanol titer by 2.15 fold in serum bottle and 2.72 fold in bioreactor. In addition, the proteomics study and metabolite analysis showed that more than 90% of the amino acid in the medium was consumed before the cell entered the stationary phase and some enzymes involved in amino acid metabolism had low expression in butanol producing mutant. Extra yeast extract or casamino acids was fed to the free-cell fermentation the mid-log phase, improving the butanol titer to more than 18 g/L compared to 14 g/L without extra nitrogen supplement. The rational metabolic cell-process engineering facilitated with systems biology understanding was demonstrated a powerful approach in butanol production. Finally, the C. tyrobutyricum was further rationally engineered by integrating multiple regualtors, including 1) heterologous NAD+-fdh that provides extra reducing power, 2) the thiolase (thl) that redirects metabolic flux from C2 to C4, and 3) AdhE2. Two novel mutatns, ACKKO-adhE2-fdh and ACKKO-thl-adhE2-fdh, were constructed and produced 18.37 g/L and 19.41 g/L, respectively. This study demonstrated that systems biology-based metabolic cell-process engineering of C. tyrobutyricum enabled a high production of butanol.
Author: Le Yu
Publisher:
ISBN:
Category :
Languages : en
Pages : 211
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Book Description
n-Butanol production by Clostridium tyrobutyricum was enhanced by overexpressing ctfAB genes, which could limit the accumulation of by-products acetate and butyrate. Besides that, two extracellular a-glucosidases were introduced into C. tyrobutyricum. The mutants showed active hydrolytic capability of maltose and soluble starch and an increase in butanol production. Finally, the bottleneck of xylose metabolism in glucose and xylose co-fermentation for biobutanol production was also eliminated.
Author: Yali Zhang
Publisher:
ISBN:
Category : Biomass chemicals
Languages : en
Pages :
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Book Description
Author: Juan Gabriel Segovia-Hernandez
Publisher: Woodhead Publishing
ISBN: 0323998054
Category : Science
Languages : en
Pages : 406
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Book Description
Advances and Developments in Biobutanol Production is a comprehensive reference on the production and purification of biobutanol, from the fundamentals to the latest advances. Focusing on selection of biomass, choice of pretreatments, biochemistry and design of fermentation, purification and biofuel application, the book also provides details on biorefinery design, lifecycle analysis, and offers perspectives on future developments. Through detailed analysis, chapters show readers how to overcome the challenges associated with the correct selection of raw material and adequate biomass pretreatment, the selection of microorganisms for fermenting biomass sugars, the purification of effluent coming from fermentation, and the high energy demands of production. Solutions are supported by step-by-step guidance on methodologies and processes, with lab and industry-scale case studies providing real-world examples of their implementation. This book provides readers with a unique and comprehensive reference on the production of biobutanol for biofuel that will be of interest to graduates, researchers and professionals involved in bioenergy and renewable energy. - Presents a holistic approach to the production and purification of biobutanol and its use as the high-value bioproduct - Provides solutions to the major challenges and bottlenecks in biobutanol production, including feedstock, pretreatment, purification, fermentation, high energy demand and recover costs - Offers step-by-step guidance on processes and procedures and describes their applications alongside real-world case studies
Author: Jens Nielsen
Publisher: Springer
ISBN: 3540453008
Category : Science
Languages : en
Pages : 193
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Book Description
Metabolic engineering is a rapidly evolving field that is being applied for the optimization of many different industrial processes. In this issue of Advances in Biochemical Engineering/Biotechnology, developments in different areas of metabolic engineering are reviewed. The contributions discuss the application of metabolic engineering in the improvement of yield and productivity - illustrated by amino acid production and the production of novel compounds - in the production of polyketides and extension of the substrate range - and in the engineering of S. cerevisiae for xylose metabolism, and the improvement of a complex biotransformation process.
Author: Sang Yup Lee
Publisher: John Wiley & Sons
ISBN: 352782345X
Category : Science
Languages : en
Pages : 1075
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Book Description
Learn more about foundational and advanced topics in metabolic engineering in this comprehensive resource edited by leaders in the field Metabolic Engineering: Concepts and Applications delivers a one-stop resource for readers seeking a complete description of the concepts, models, and applications of metabolic engineering. This guide offers practical insights into the metabolic engineering of major cell lines, including E. Coli, Bacillus and Yarrowia Lipolytica, and organisms, including human, animal, and plant). The distinguished editors also offer readers resources on microbiome engineering and the use of metabolic engineering in bioremediation. Written in two parts, Metabolic Engineering begins with the essential models and strategies of the field, like Flux Balance Analysis, Quantitative Flux Analysis, and Proteome Constrained Models. It also provides an overview of topics like Pathway Design, Metabolomics, and Genome Editing of Bacteria and Eukarya. The second part contains insightful descriptions of the practical applications of metabolic engineering, including specific examples that shed light on the topics within. In addition to subjects like the metabolic engineering of animals, humans, and plants, you’ll learn more about: Metabolic engineering concepts and a historical perspective on their development The different modes of analysis, including flux balance analysis and quantitative flux analysis An illuminating and complete discussion of the thermodynamics of metabolic pathways The Genome architecture of E. coli, as well as genome editing of both bacteria and eukarya An in-depth treatment of the application of metabolic engineering techniques to organisms including corynebacterial, bacillus, and pseudomonas, and more Perfect for students of biotechnology, bioengineers, and biotechnologists, Metabolic Engineering: Concepts and Applications also has a place on the bookshelves of research institutes, biotechnological institutes and industry labs, and university libraries. It's comprehensive treatment of all relevant metabolic engineering concepts, models, and applications will be of use to practicing biotechnologists and bioengineers who wish to solidify their understanding of the field.
Author: Hongxin Fu
Publisher: Frontiers Media SA
ISBN: 288974423X
Category : Science
Languages : en
Pages : 158
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Book Description
Author: Christoph Wittmann
Publisher: John Wiley & Sons
ISBN: 3527341811
Category : Science
Languages : en
Pages : 642
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Book Description
The latest volume in the Advanced Biotechnology series provides an overview of the main product classes and platform chemicals produced by biotechnological processes today, with applications in the food, healthcare and fine chemical industries. Alongside the production of drugs and flavors as well as amino acids, bio-based monomers and polymers and biofuels, basic insights are also given as to the biotechnological processes yielding such products and how large-scale production may be enabled and improved. Of interest to biotechnologists, bio and chemical engineers, as well as those working in the biotechnological, chemical, and food industries.
Author: Ngoc phuong thao Nguyen
Publisher:
ISBN:
Category :
Languages : en
Pages : 215
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Book Description
Current ly, there is a resurgence of interest in Clostridium acetobutylicum, the biocatalyst of the historical Weizmann process, to produce n-butanol for use both as a bulk chemical and as a renewablc alternative transportation fuel. This thesis describes a method of homologous recombination by replicative plasmid to delete or introduce genes in C. acetobutylicum . This method was successfull y used to delete genes, includin g CACJ502, CAC3535, CAC2879 (upp), to generate C. acetobutylicum. These strains are readily transformable without any previous plasmid methylation and can serve as hosts for a "marker-less" genetic exchange system. A mutant C. acetobutylicum (C. acetobuty licum CAB 1060) was successfully genera ted. This final mutant produces mainly bu tanol, with ethanol and traces of acetate at a molar rati o of 7:1 :1 . This CAB 1060 strain was subjected to a new continuous fermentation process using i) in situ extraction of alcohols by distillation under low pressure and ii) high cell density cultures to increase the titer, yield and productivity of n-butanol production to levels that have never been previously açhieved in any organism . A second homologous recombination method using non-replicative plasmid for marker less gene modification is also described in this thesis. This method allows the simultaneou s inactivation of two genes. lt has been successfully used to construct a mutant unable to produce hydrogen and useful, as a platform strain, for further engineering of C. acetobutylicum to continuously produce bulk chemicals and fuels.
Author: Xiaoguang Liu
Publisher:
ISBN:
Category : Biochemical engineering
Languages : en
Pages :
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Book Description
Abstract: The main goal of this research was to develop an economical process for butyric acid and hydrogen production by Clostridium tyrobutyricum. First, metabolically engineered mutants, PPTA-Em and PAK-Em with knocked-out pta and ack genes, were characterized by Southern hybridization, enzyme assay, protein expression, and final product tolerance analysis. The original pta and ack genes were inactivated in the mutants, and the activities of PTA, AK, and hydrogenase changed greatly. SDS-PAGE and 2D electrophoresis showed that both PTA and AK were deleted from mutants. Butyric acid tolerance was also significantly improved in these mutants. Second, free cell fermentation by PPTA-Em from glucose showed that butyric acid concentration reached about 40 g/L with yield of 0.38 g/g and higher productivity 0.63 g/L·h. The immobilization fermentation using fibrous-bed bioreactor (FBB) produced butyric acid at a concentration of 50 g/L. It was found that different sugar sources affected fermentation, protein expression, and metabolic flux. Third, a higher butyric acid yield (0.42 g/g) and final concentration (42 g/L) was obtained with PAK-Em from free cell fermentation. Hydrogen production by PAK-Em also increased significantly with yield of 2.61 and hydrogen/carbon dioxide ratio of 1.44. Fourth, through adaptation in the FBB fibrous matrix, the highest butyric acid concentration of 81 g/L was obtained at pH 6.3 by PAK-Em with yield of approx. 0.45 g/g. A mutant that produced even more hydrogen, with hydrogen/carbon dioxide ratio of 2.69 and with very fast growth rate, was also discovered from the FBB adaptation. Different pHs (from pH 5.0 to pH 7.0) and sugar sources (glucose, xylose, and fructose) were applied to FBB fermentation to better understand the metabolic mechanism. Metabolic shift analysis proved that both PTA-AK metabolic pathways were blocked by the gene manipulation. Finally, shotgun DNA microarray is being applied to globally study bacterial genomic function, and to analyze and identify the key genes and proteins present in C. tyrobutyricum under different environmental conditions. The novel metabolically engineered mutants and the FBB application are important to the development of an economical bioprocess for butyric acid and hydrogen production from biomass by C. tyrobutyricm.
