Enhanced succinic acid production by Mannheimia employing optimal malate dehydrogenase

Ahn, Jung Ho; Seo, Hogyun; Park, Woojin; Seok, Jihye; Lee, Jong An; Kim, Won Jun; Kim, Gi Bae; Kim, Kyungjin; Lee, Sang Yup

doi:10.1038/s41467-020-15839-z

Cited by 95 publications

(61 citation statements)

References 65 publications

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“…Researchers from KAIST applied metabolic engineering to improve succinic acid production of the capnophilic rumen bacterium Mannheimia succiniciproducens (Lee et al, 2002). They obtained succinic acid yields up to 1.64 mol/mol glucose equivalent (Ahn et al, 2016; Lee et al, 2016) and titers up to 134 g/L (Ahn et al, 2020) by accomplishing almost homo‐succinic acid production. Myriant applied an engineered Escherichia coli strain for large‐scale SA production (Ahn et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Uncoupling growth and succinic acid production in an industrial Saccharomyces cerevisiae strain

Liu

Esen

Pronk

et al. 2021

Biotech & Bioengineering

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This study explores the relation between biomass‐specific succinic acid (SA) production rate and specific growth rate of an engineered industrial strain of Saccharomyces cerevisiae, with the aim to investigate the extent to which growth and product formation can be uncoupled. Ammonium‐limited aerobic chemostat and retentostat cultures were grown at different specific growth rates under industrially relevant conditions, that is, at a culture pH of 3 and with sparging of a 1:1 CO2–air mixture. Biomass‐specific SA production rates decreased asymptotically with decreasing growth rate. At near‐zero growth rates, the engineered strain maintained a stable biomass‐specific SA production rate for over 500 h, with a SA yield on glucose of 0.61 mol mol−1. These results demonstrate that uncoupling of growth and SA production could indeed be achieved. A linear relation between the biomass‐specific SA production rate and glucose consumption rate indicated the coupling of SA production rate and the flux through primary metabolism. The low culture pH resulted in an increased death rate, which was lowest at near‐zero growth rates. Nevertheless, a significant amount of non‐viable biomass accumulated in the retentostat cultures, thus underlining the importance of improving low‐pH tolerance in further strain development for industrial SA production with S. cerevisiae.

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Section: Introductionmentioning

confidence: 99%

Uncoupling growth and succinic acid production in an industrial Saccharomyces cerevisiae strain

Liu

Esen

Pronk

et al. 2021

Biotech & Bioengineering

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“…The power of in silico metabolic modeling has also been seen in a recent SA production study using M. succiniciproducens as a biocatalyst. In this research, GEM [75] was analyzed to characterize malate dehydrogenase (MDH) and finally the overexpression of genes encoding MDH led to the production of the highest overall SA reported to date [99]. This is one of the latest tangible pieces of evidence of applications of model-guided in silico studies in the journey of developing industrially compatible SA-producing strains.…”

Section: E Coli and A Succinogenesmentioning

confidence: 99%

“…Integration of genome-scale metabolic model with dynamic modeling and genetic algorithm to provide simpified gene deletion strategies for the complex evolutionary goals containing multiple targets 2020 [98] M. succiniciproducens Flux variability scanning using genome-scale metabolic model to identify amplification target genes for improved SA production 2020 [99] Likewise, other potential microbes were also evaluated for their metabolic capability of SA production. The fundamental difference in these in silico studies, besides the algorithms employed, is the scope of metabolic network coverage.…”

Section: E Coli and A Succinogenesmentioning

confidence: 99%

Insights on the Advancements of In Silico Metabolic Studies of Succinic Acid Producing Microorganisms: A Review with Emphasis on Actinobacillus succinogenes

et al. 2021

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Succinic acid (SA) is one of the top candidate value-added chemicals that can be produced from biomass via microbial fermentation. A considerable number of cell factories have been proposed in the past two decades as native as well as non-native SA producers. Actinobacillus succinogenes is among the best and earliest known natural SA producers. However, its industrial application has not yet been realized due to various underlying challenges. Previous studies revealed that the optimization of environmental conditions alone could not entirely resolve these critical problems. On the other hand, microbial in silico metabolic modeling approaches have lately been the center of attention and have been applied for the efficient production of valuable commodities including SA. Then again, literature survey results indicated the absence of up-to-date reviews assessing this issue, specifically concerning SA production. Hence, this review was designed to discuss accomplishments and future perspectives of in silico studies on the metabolic capabilities of SA producers. Herein, research progress on SA and A. succinogenes, pathways involved in SA production, metabolic models of SA-producing microorganisms, and status, limitations and prospects on in silico studies of A. succinogenes were elaborated. All in all, this review is believed to provide insights to understand the current scenario and to develop efficient mathematical models for designing robust SA-producing microbial strains.

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“…Quantitative phase imaging (QPI) is a powerful method to observe the morphology of a live specimen without any perturbation; this includes dye staining or fluorescence protein expression 6 . Recently developed three dimensional (3D) QPI techniques provide the 3D refractive index (RI) distributions, containing quantitative information on the concentration of a material, and have been exploited in various applications including biomolecular condensates 7 , biotechnology 8 , microbiology 9 , and cell biology 10 . Although the 3D QPI image can provide the physical properties corresponding to each voxel, a universal and versatile segmentation method is required to simultaneously monitor quantitative dynamics in a whole cell and its organelles.…”

Section: Introductionmentioning

confidence: 99%

Label-free three-dimensional analyses of live cells with deep-learning-based segmentation exploiting refractive index distributions

Choi¹,

Kim²,

et al. 2021

Preprint

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Visualisations and analyses of cellular and subcellular organelles in biological cells is crucial for the study of cell biology. However, existing imaging methods require the use of exogenous labelling agents, which prevents the long-time assessments of live cells in their native states. Here we propose and experimentally demonstrate three-dimensional segmentation of subcellular organelles in unlabelled live cells, exploiting a 3D U-Net-based architecture. We present the high-precision three-dimensional segmentation of cell membrane, nucleus membrane, nucleoli, and lipid droplets of various cell types. Time-lapse analyses of dynamics of activated immune cells are also analysed using label-free segmentation.

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Enhanced succinic acid production by Mannheimia employing optimal malate dehydrogenase

Cited by 95 publications

References 65 publications

Uncoupling growth and succinic acid production in an industrial Saccharomyces cerevisiae strain

Uncoupling growth and succinic acid production in an industrial Saccharomyces cerevisiae strain

Insights on the Advancements of In Silico Metabolic Studies of Succinic Acid Producing Microorganisms: A Review with Emphasis on Actinobacillus succinogenes

Label-free three-dimensional analyses of live cells with deep-learning-based segmentation exploiting refractive index distributions

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