Insertional mutagenesis of an industrial strain of<i>Streptococcus thermophilus</i>

Labarre, C; Schirawski, Jan; Zwet, Anneke van der; Fitzgerald, Gerald F.; Sinderen, Douwe van

doi:10.1111/j.1574-6968.2001.tb10697.x

Cited by 9 publications

(2 citation statements)

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“…To solve these problems, natural cell factories, especially bacteria and fungi, come into notice, due to their superior metabolic capabilities. Traditional microbe breeding for industrial applications involves application of random mutagenesis and screening processes to reform productive strains, get rid of byproduct formation and add beneficial characters . However, this breeding technique also leads to uncertain changes in genotype and phenotype.…”

Section: Introductionmentioning

confidence: 99%

DCEO Biotechnology: Tools To Design, Construct, Evaluate, and Optimize the Metabolic Pathway for Biosynthesis of Chemicals

et al. 2017

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Chemical synthesis is a well established route for producing many chemicals on a large scale, but some drawbacks still exist in this process, such as unstable intermediates, multistep reactions, complex process control, etc. Biobased production provides an attractive alternative to these challenges, but how to make cells into efficient factories is challenging. As a key enabling technology to develop efficient cell factories, design-construction-evaluation-optimization (DCEO) biotechnology, which incorporates the concepts and techniques of pathway design, pathway construction, pathway evaluation, and pathway optimization at the systems level, offers a conceptual and technological framework to exploit potential pathways, modify existing pathways and create new pathways for the optimal production of desired chemicals. Here, we summarize recent progress of DCEO biotechnology and examples of its application, and provide insights as to when, what and how different strategies should be taken. In addition, we highlight future perspectives of DCEO biotechnology for the successful establishment of biorefineries.

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Section: Introductionmentioning

confidence: 99%

DCEO Biotechnology: Tools To Design, Construct, Evaluate, and Optimize the Metabolic Pathway for Biosynthesis of Chemicals

et al. 2017

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“…Biofuels can be produced by oleaginous microorganisms, such as yeast, fungi, and bacteria . Traditional microbial strains for industrial applications have been developed by random mutagenesis and screening processes . However, these approaches result in unknown genotypic/phenotypic changes and can cause unwanted alterations in the genome that may become problematic when the fermentation conditions need to be modified.…”

Section: Introductionmentioning

confidence: 99%

Enhancing microbial production of biofuels by expanding microbial metabolic pathways

Chen

2017

Biotech and App Biochem

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Fatty acid, isoprenoid, and alcohol pathways have been successfully engineered to produce biofuels. By introducing three genes, atfA, adhE, and pdc, into Escherichia coli to expand fatty acid pathway, up to 1.28 g/L of fatty acid ethyl esters can be achieved. The isoprenoid pathway can be expanded to produce bisabolene with a high titer of 900 mg/L in Saccharomyces cerevisiae. Short- and long-chain alcohols can also be effectively biosynthesized by extending the carbon chain of ketoacids with an engineered "+1" alcohol pathway. Thus, it can be concluded that expanding microbial metabolic pathways has enormous potential for enhancing microbial production of biofuels for future industrial applications. However, some major challenges for microbial production of biofuels should be overcome to compete with traditional fossil fuels: lowering production costs, reducing the time required to construct genetic elements and to increase their predictability and reliability, and creating reusable parts with useful and predictable behavior. To address these challenges, several aspects should be further considered in future: mining and transformation of genetic elements related to metabolic pathways, assembling biofuel elements and coordinating their functions, enhancing the tolerance of host cells to biofuels, and creating modular subpathways that can be easily interconnected.

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