Glycerol-3-Phosphate-Induced Catabolite Repression in<i>Escherichia coli</i>

Eppler, Tanja; Postma, Pieter W.; Schütz, Alexandra; Völker, Uwe; Boos, Winfried

doi:10.1128/jb.184.11.3044-3052.2002

Cited by 50 publications

(53 citation statements)

References 36 publications

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“…On the other hand, the glycerol uptake rate was enhanced in the glpK mutant most probably because of reduced inhibitory effect of fructose 1,6-bisphosphate on GlpK, as shown previously for this mutant 10 . This results in increased transfer of phosphate from phosphorylated EIIA Glc to produce glycerol-3-phosphate 28 . The resulting decrease in phosphorylated EIIA Glc will in turn reduce adenylate cyclase activity and cAMP production.…”

Section: Resultsmentioning

confidence: 99%

Global metabolic network reorganization by adaptive mutations allows fast growth of Escherichia coli on glycerol

et al. 2014

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Comparative whole-genome sequencing enables the identification of specific mutations during adaptation of bacteria to new environments and allelic replacement can establish their causality. However, the mechanisms of action are hard to decipher and little has been achieved for epistatic mutations, especially at the metabolic level. Here we show that a strain of Escherichia coli carrying mutations in the rpoC and glpK genes, derived from adaptation in glycerol, uses two distinct metabolic strategies to gain growth advantage. A 27-bp deletion in the rpoC gene first increases metabolic efficiency. Then, a point mutation in the glpK gene promotes growth by improving glycerol utilization but results in increased carbon wasting as overflow metabolism. In a strain carrying both mutations, these contrasting carbon/energy saving and wasting mechanisms work together to give an 89% increase in growth rate. This study provides insight into metabolic reprogramming during adaptive laboratory evolution for fast cellular growth.

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Section: Resultsmentioning

confidence: 99%

Global metabolic network reorganization by adaptive mutations allows fast growth of Escherichia coli on glycerol

et al. 2014

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“…It has been previously reported that a similarly truncated mutant of adenylate cyclase had lower activity and was not repressed by glycerol-3-phosphate 22 . We hypothesize that wild-type strain MG1655 grows slowly on glycerol because some critical genes are misexpressed as a result of inappropriate levels of catabolite repression and that the attenuating mutations in cyaA and pdxK/crr relieve this misexpression.…”

Section: Analysis Of Mutationsmentioning

confidence: 92%

Comparative genome sequencing of Escherichia coli allows observation of bacterial evolution on a laboratory timescale

et al. 2006

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We applied whole-genome resequencing of Escherichia coli to monitor the acquisition and fixation of mutations that conveyed a selective growth advantage during adaptation to a glycerol-based growth medium. We identified 13 different de novo mutations in five different E. coli strains and monitored their fixation over a 44-d period of adaptation. We obtained proof that the observed spontaneous mutations were responsible for improved fitness by creating single, double and triple site-directed mutants that had growth rates matching those of the evolved strains. The success of this new genome-scale approach indicates that real-time evolution studies will now be practical in a wide variety of contexts.Comparative genomics has been almost entirely focused on genomic changes over long periods of time, on the order of millions of years. A new microarray-based method of whole-genome resequencing called comparative genome sequencing (CGS) 1 now makes it cost efficient to monitor bacterial evolution comprehensively over short time periods as well. This capability is important because many microbial phenomena, such as the emergence of new pathogens and the acquisition of antibiotic resistance factors, can occur over relatively short time scales. Experimental evolution of bacteria and viruses 2,3 is a facile approach to study these topics. It has been used to test predictions of evolutionary theory 4 and to study parallel changes in populations evolved for 20,000 generations 5 , acquisition of antibiotic resistance 1 and in vitro symbiosis 6 . Our laboratory has used experimental evolution as a tool for metabolic engineering 7 and to study the recovery of strains with gene knockouts in central metabolic genes 8 . Nevertheless, much remains unknown about genome plasticity over short evolutionary timescales.It is a common mistake to think of bacteria as static; that is, to assume that a culture grown overnight is the same as it was the day before. It has been estimated that nearly 10% of the individual bacteria in a Salmonella enterica population carry large-scale genome rearrangements 9 , and in a suboptimal environment, selection can alter a population very rapidly. The 10-20 generations that occur in the process of growing a bacterial culture are sufficient to create a heterogeneous population, depending on the magnitude of the selective advantage of adaptive mutations. This problem is avoided by using strains of bacteria that are adapted to common laboratory media, but there are interesting cases where a seemingly straightforward growth medium poses a great challenge to a bacterium.An example is E. coli K-12 grown in minimal medium supplemented with glycerol as the carbon and energy source. Despite a complete pathway for glycerol catabolism, large variations in the growth rates of various strains have been noted 10 . Growth of the sequenced strain MG1655 has been observed to differ from computational predictions based on flux balance analysis 11 . Upon extended logarithmic growth in glycerol minimal medium, the growth rate...

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“…coli prefers glucose rather than other sugars for its growth and glucose represses the catabolism of other sugars (Hogema et al, 1997). The glucose PTS is related to catabolite repression, chemotaxis regulation, glycogen phosphorylase, and multiple regulatory interactions (Lux et al, 1995;Postma et al, 1996;Seok et al, 1997;Saier, 1998;Eppler et al, 2002). Adenylate cyclase is activated when glucose in the medium is depleted.…”

Section: Biological Modelmentioning

confidence: 99%

Computer-aided rational design of the phosphotransferase system for enhanced glucose uptake in Escherichia coli

Nishio

Usuda

Matsui

et al. 2008

Journal of Biotechnology

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Glycerol-3-Phosphate-Induced Catabolite Repression inEscherichia coli

Cited by 50 publications

References 36 publications

Global metabolic network reorganization by adaptive mutations allows fast growth of Escherichia coli on glycerol

Global metabolic network reorganization by adaptive mutations allows fast growth of Escherichia coli on glycerol

Comparative genome sequencing of Escherichia coli allows observation of bacterial evolution on a laboratory timescale

Computer-aided rational design of the phosphotransferase system for enhanced glucose uptake in Escherichia coli

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