Glucose Transport in Escherichia coli Mutant Strains with Defects in Sugar Transport Systems

Steinsiek, Sonja; Bettenbrock, Katja

doi:10.1128/jb.01502-12

Cited by 79 publications

(95 citation statements)

References 68 publications

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“…The qualitative effects on q s and μ of deleting specific PTS and non-PTS transporters in strain W3110 are in agreement with results reported with mutant derivatives of E. coli strains MG1655 and AF1000 having some of the same gene deletions performed in this study [30-32]. However, the magnitude of q s reduction as function of specific gene inactivation differs from our results.…”

Section: Resultssupporting

confidence: 91%

Modification of glucose import capacity in Escherichia coli: physiologic consequences and utility for improving DNA vaccine production

et al. 2013

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BackgroundThe bacterium Escherichia coli can be grown employing various carbohydrates as sole carbon and energy source. Among them, glucose affords the highest growth rate. This sugar is nowadays widely employed as raw material in industrial fermentations. When E. coli grows in a medium containing non-limiting concentrations of glucose, a metabolic imbalance occurs whose main consequence is acetate secretion. The production of this toxic organic acid reduces strain productivity and viability. Solutions to this problem include reducing glucose concentration by substrate feeding strategies or the generation of mutant strains with impaired glucose import capacity. In this work, a collection of E. coli strains with inactive genes encoding proteins involved in glucose transport where generated to determine the effects of reduced glucose import capacity on growth rate, biomass yield, acetate and production of an experimental plasmid DNA vaccine (pHN).ResultsA group of 15 isogenic derivatives of E. coli W3110 were generated with single and multiple deletions of genes encoding glucose, mannose, beta-glucoside, maltose and N-acetylglucosamine components of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), as well as the galactose symporter and the Mgl galactose/glucose ABC transporter. These strains were characterized by growing them in mineral salts medium supplemented with 2.5 g/L glucose. Maximum specific rates of glucose consumption (qs) spanning from 1.33 to 0.32 g/g h were displayed by the group of mutants and W3110, which resulted in specific growth rates ranging from 0.65-0.18 h-1. Acetate accumulation was reduced or abolished in cultures with all mutant strains. W3110 and five selected mutant derivatives were transformed with pHN. A 3.2-fold increase in pHN yield on biomass was observed in cultures of a mutant strain with deletion of genes encoding the glucose and mannose PTS components, as well as Mgl.ConclusionsThe group of E. coli mutants generated in this study displayed a reduction or elimination of overflow metabolism and a linear correlation between qs and the maximum specific growth rate as well as the acetate production rate. By comparing DNA vaccine production parameters among some of these mutants, it was possible to identify a near-optimal glucose import rate value for this particular application. The strains employed in this study should be a useful resource for studying the effects of different predefined qs values on production capacity for various biotechnological products.

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Section: Resultssupporting

confidence: 91%

Modification of glucose import capacity in Escherichia coli: physiologic consequences and utility for improving DNA vaccine production

et al. 2013

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“…For non-transformed E. coli DgalT cultured under glucose or glucose plus galactose, the growth curves were indistinguishable, since glucose is the preferred carbon source and galactose represents no toxicity in the presence of this hexose. This absent toxicity of galactose likely results from carbon catabolite repression exerted by glucose, which represses the galactose uptake systems GalP and Mgl (G€ orke and St€ ulke 2008; Misko et al 1987;Shimizu 2013;Steinsiek and Bettenbrock 2012). In the presence of glycerol, transported into E. coli through facilitated diffusion (Chu et al 2002), the growth rate was approximately half of that observed in the presence of glucose, confirming that this polyol is not as efficient as glucose as a carbon source, as previously described (Chu et al 2002).…”

Section: Resultsmentioning

confidence: 99%

Arginine Functionally Improves Clinically Relevant Human Galactose-1-Phosphate Uridylyltransferase (GALT) Variants Expressed in a Prokaryotic Model

et al. 2015

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Classic galactosemia is a rare genetic disease of the galactose metabolism, resulting from deficient activity of galactose-1-phosphate uridylyltransferase (GALT). The current standard of care is lifelong dietary restriction of galactose, which however fails to prevent the development of long-term complications. Structural-functional studies demonstrated that the most prevalent GALT mutations give rise to proteins with increased propensity to aggregate in solution. Arginine is a known stabilizer of aggregationprone proteins, having already shown a beneficial effect in other inherited metabolic disorders.Herein we developed a prokaryotic model of galactose sensitivity that allows evaluating in a cellular context the mutations' impact on GALT function, as well as the potential effect of arginine in functionally rescuing clinically relevant variants.This study revealed that some hGALT variants, previously described to exhibit no detectable activity in vitro, actually present residual activity when determined in vivo.

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“…The strains used in this study are either wild type E. coli NCM3722 strain 51,52 or its derivatives: NQ1261 (Δ ptsG , deleted of the gene encoding the main glucose transporter PtsG), which grows slowly in glucose medium 53 , NQ1468 used for measuring LacZα induction kinetics, and the WE2015 series of strains used for measuring the translational elongation rate of various proteins using the hybrid LacZα approach described below. E. coli MG1655 strain used in the ribo-seq study of Li et al 3 was also obtained directly from G. W. Li.…”

Section: Methodsmentioning

confidence: 99%

Reduction of translating ribosomes enables Escherichia coli to maintain elongation rates during slow growth

et al. 2016

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Bacteria growing in different conditions experience a broad range of demand on the rate of protein synthesis which profoundly affects cellular resource allocation. During fast growth, protein synthesis is long known to be modulated by adjusting the ribosome content, with the vast majority of ribosomes engaged at a near-maximal rate of elongation. Here we characterized protein synthesis by E. coli systematically, focusing on slow growth conditions. We establish that the translational elongation rate decreases as growth slows down, exhibiting a Michaelis-Menten dependence on the abundance of the cellular translational apparatus. However, an appreciable elongation rate is maintained even towards zero growth including the stationary phase. This maintenance, critical for timely protein synthesis in harsh environments, is accompanied by a drastic reduction in the fraction of active ribosomes. Interestingly, well-known antibiotics such as chloramphenicol also cause substantial reduction in the pool of active ribosomes, instead of slowing down translational elongation as commonly thought.

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Glucose Transport in Escherichia coli Mutant Strains with Defects in Sugar Transport Systems

Cited by 79 publications

References 68 publications

Modification of glucose import capacity in Escherichia coli: physiologic consequences and utility for improving DNA vaccine production

Modification of glucose import capacity in Escherichia coli: physiologic consequences and utility for improving DNA vaccine production

Arginine Functionally Improves Clinically Relevant Human Galactose-1-Phosphate Uridylyltransferase (GALT) Variants Expressed in a Prokaryotic Model

Reduction of translating ribosomes enables Escherichia coli to maintain elongation rates during slow growth

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