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Kontinuierliche Aceton-Butanol-Gärung durch Clostridium acetobutylicumBahl, Hubert, January 1983 (has links)
Thesis--Göttingen. / In Periodical Room.
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N-Butanol Fermentation and Integrated Recovery Process: Adsorption, Gas Stripping and PervaporationLiu, Fangfang 12 November 2014 (has links)
No description available.
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Carbonyl Inhibition and Detoxification in Butanol and Carboxylic Acid Fermentation of Lignocellulosic BiomassZhang, Yu January 2021 (has links)
No description available.
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Development of genetic tools for metabolic engineering of Clostridium pasteurianumPyne, Michael E 21 April 2015 (has links)
Reducing the production cost of industrial biofuels will greatly facilitate their proliferation and co-integration with fossil fuels. The cost of feedstock is the largest cost in most fermentation bioprocesses and therefore represents an important target for cost reduction. Meanwhile, the biorefinery concept advocates revenue growth through complete utilization of by-products generated during biofuel production. Taken together, the production of biofuels from low-cost crude glycerol, available in oversupply as a by-product of bioethanol production, in the form of thin stillage, and biodiesel production, embodies a remarkable opportunity to advance affordable biofuel development. However, few bacterial species possess the natural capacity to convert glycerol as a sole source of carbon and energy into value-added bioproducts. Of particular interest is the anaerobe Clostridium pasteurianum, the only microorganism known to convert glycerol alone directly into butanol, which currently holds immense promise as a high-energy biofuel and bulk chemical. Unfortunately, genetic and metabolic engineering of C. pasteurianum has been fundamentally impeded due to a complete lack of genetic tools and techniques available for the manipulation of this promising bacterium. This thesis encompasses the development of fundamental genetic tools and techniques that will permit extensive genetic and metabolic engineering of C. pasteurianum.
We initiated our genetic work with the development of an electrotransformation protocol permitting high-level DNA transfer to C. pasteurianum together with accompanying selection markers and vector components. The CpaAI restriction-modification system was found to be a major barrier to DNA delivery into C. pasteurianum which we overcame by in vivo methylation of the recognition site (5’-CGCG-3’) using the M.FnuDII methyltransferase. Systematic investigation of various parameters involved in the cell growth, washing and pulse delivery, and outgrowth phases of the electrotransformation procedure significantly elevated the electrotransformation efficiency up to 7.5 × 104 transformants µg-1 DNA, an increase of approximately three orders of magnitude. Key factors affecting the electrotransformation efficiency include cell-wall-weakening using glycine, ethanol-mediated membrane solubilization, field strength of the electric pulse, and sucrose osmoprotection.
Following development of a gene transfer methodology, we next aimed to sequence the entire genome of C. pasteurianum. Using a hybrid approach involving 454 pyrosequencing, Illumina dye sequencing, and single molecule real-time sequencing platforms, we obtained a near-complete genome sequence comprised of 12 contigs, 4,420,100 bp, and 4,056 candidate protein-coding genes with a GC content of 30.0%. No extrachromosomal elements were detected. We provide an overview of the genes and pathways involved in the organism’s central fermentative metabolism.
We used our developed electrotransformation procedure to investigate the use of established clostridial group II intron biology for constructing chromosomal gene knockout mutants of C. pasteurianum. Through methylome analysis of C. pasteurianum genome sequencing data and transformation assays of various vector deletion constructs, we identified a new Type I restriction-modification system that inhibits transfer of vectors harboring group II intron gene knockout machinery. We designated the new restriction system CpaAII and proposed a recognition sequence of 5’-AAGNNNNNCTCC-3’. Overcoming restriction by CpaAII, in addition to low intron retrohoming efficiency, allowed the isolation of a gene knockout mutant of C. pasteurianum with a disrupted CpaAI Type II restriction system. The resulting mutant strain should be efficienty transformed with plasmid DNA lacking M.FnuDII methylation.
Lastly, we investigated the use of plasmid-based gene overexpression and chromosomal gene downregulation to alter gene expression in C. pasteurianum. Using a β-galactosidase reporter gene, we characterized promoters corresponding to the ferredoxin and thiolase genes of C. pasteurianum and show that both promoters permitted high-level, constitutive gene expression. The thiolase promoter was then utilized to drive transcription of an antisense RNA molecule possessing complementarity to mRNA of our β-galactosidase reporter gene. Our antisense RNA system demonstrated 52-58% downregulation of plasmid encoded β-galactosidase activity throughout the duration of growth. In an attempt to perturb the central fermentative metabolism of C. pasteurianum and enhance butanol titers, we prepared several antisense RNA constructs for downregulation of 1,3-propanediol, butyrate, and hydrogen production pathways. The resulting downregulation strains are expected to exhibit drastically altered central fermentative metabolism and product distribution.
Taken together, we have demonstrated that C. pasteurianum is amendable to genetic manipulation through the development of methods for plasmid DNA transfer and gene overexpression, knockdown, and knockout. Further, our genome sequence should provide valuable nucleotide sequence information for the application of our genetic tools. Thus, the genome sequence, electrotransformation method, and associated genetic tools and techniques reported here should promote extensive genetic manipulation and metabolic engineering of this biotechnologically important bacterium.
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