Microbial production of lactic acid

Eiteman, Mark A.; Ramalingam, Subramanian

doi:10.1007/s10529-015-1769-5

Cited by 83 publications

(54 citation statements)

References 111 publications

(104 reference statements)

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“…The main fermentation products of citrate were acetate and formate, whereas the main products of glucose fermentation were lactate, ethanol, acetate and formate. This product profile is typically observed in heterolactic fermenters (Eiteman & Ramalingam, 2015 flocculiformis (Scheff et al, 1984), T. pasteurii (Schink et al, 1984), T. collinsii (Liu et al, 2002), T. palustris (Zhilina et al, 1995), and T. patagoniensis (Pikuta et al, 2006). All these species can use a broad range of sugars and polyols for growth.…”

Section: Authorsmentioning

confidence: 91%

Description of Trichococcus ilyis sp. nov. by combined physiological and in silico genome hybridization analyses

Strepis

Sánchez‐Andrea

Gelder

et al. 2016

International Journal of Systematic and Evolutionary Microbiology

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Section: Authorsmentioning

confidence: 91%

Description of Trichococcus ilyis sp. nov. by combined physiological and in silico genome hybridization analyses

Strepis

Sánchez‐Andrea

Gelder

et al. 2016

International Journal of Systematic and Evolutionary Microbiology

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“…On the other hand, metabolites produced in microbial cell factories such as small Fig. 4 Two approaches to creating synthetic microbes: (1) creating life de novo, creating an artificial cell at least needs to integrate three main components: containment, cellular processes, and information and (2) bioengineering approach, using a refined version of genetic engineering, designing, and inserting elements inside the cells to perform specialized functions molecule (e.g., ethanol [89], lactic acid [90,91], glycerol [92]), antibiotic [93] (e.g., penicillin), pigment [94], protein [95] and glycoprotein [96], polysaccharide (e.g., hyaluronic acid [97], bacterial cellulose [98]), and even virus-like particles (as vaccine) [99] have been widely used in the production and life of human beings (Fig. 6).…”

Section: Microbial Cell Factories: Manufacturing Functional Metabolitesmentioning

confidence: 99%

Fabrication of nanocomposites and hybrid materials using microbial biotemplates

Shi

Ullah

et al. 2017

Adv Compos Hybrid Mater

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Microbes are important part of life that vary in sizes and shapes, diverse surface chemistry and biology, and porous nature of their cell walls. Besides their importance in industrial processes such as fermentation, these serve as biotemplates and provide a biomimetic approach for fabrication of multifarious complex constructs with predefined features, ordered composites and hybrid nanomaterials, microdevices, and micro/nanorobots through various strategies. The template or building blocks for such approaches can be bacterial, algal, and fungal cells or virus particles. Here, we have summarized recent advancements in biofabrication based on live microbes. Using engineering approaches and suitable methods, live microbes can be manipulated as functional Bmicro/nanodevices and -robots^to further perform biological functions such as replication, distribution, motility, formation of colonies, and secretion of metabolites at will. Biofabrication based on microbes provides effective methods to control and manipulate microbes as functional live building blocks to create micro/nanodevices and -robots for biomedical and energy applications.

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“…Lactic acid bacteria, especially, Lactobacillus species, are often employed in lactic acid production. For large-scale lactic acid production, fermenting microorganisms with high acid tolerance, simple nutritional requirements and capability of growth at high cell density are pursued [27]. To this end, S. cerevisiae was engineered for lactic acid production by integrating lactate dehydrogenase (LDH) gene into its genome [28,29].…”

Section: Production Of Bulk Chemicalsmentioning

confidence: 99%

Advances in Metabolic Engineering of Saccharomyces cerevisiae for the Production of Industrially and Clinically Important Chemicals

Turanlı-Yıldız¹,

Hacısalihoğlu²,

Çakar³

2017

Old Yeasts - New Questions

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Sustainable production of chemicals is of increasing importance, due to depletion of petroleum and environmental concerns. In addition to its importance in basic research as a simple, eukaryotic model organism, Saccharomyces cerevisiae has long been exploited in industry because of its physiological properties. And today, the development in genetic engineering toolbox and genome-scale metabolic models of S. cerevisiae has extended its application range to new products and bioprocesses. In addition, evolutionary engineering strategies have been useful in improving cellular properties of S. cerevisiae, such as tolerance to product toxicity and inhibitors. In this chapter, recent metabolic and evolutionary engineering studies that involve S. cerevisiae for the production of bulk chemicals and ine chemicals including lavours and pharmaceuticals are reviewed. It was shown that metabolic engineering particularly allowed the improvement of pharmaceuticals production, which will enable economic and large-scale production of many valuable pharmaceuticals. It is clear that S. cerevisiae will continue to be an important host for future metabolic engineering and metabolic pathway engineering applications to produce a variety of industrially and clinically important chemicals.

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Microbial production of lactic acid

Cited by 83 publications

References 111 publications

Description of Trichococcus ilyis sp. nov. by combined physiological and in silico genome hybridization analyses

Description of Trichococcus ilyis sp. nov. by combined physiological and in silico genome hybridization analyses

Fabrication of nanocomposites and hybrid materials using microbial biotemplates

Advances in Metabolic Engineering of Saccharomyces cerevisiae for the Production of Industrially and Clinically Important Chemicals

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