Catabolic regulation analysis of Escherichia coli and its crp, mlc, mgsA, pgi and ptsG mutants

BackgroundMost bacteria can use various compounds as carbon sources. These carbon sources can be either co-metabolized or sequentially metabolized, where the latter phenomenon typically occurs as catabolite repression. From the practical application point of view of utilizing lignocellulose for the production of biofuels etc., it is strongly desirable to ferment all sugars obtained by hydrolysis from lignocellulosic materials, where simultaneous consumption of sugars would benefit the formation of bioproducts. However, most organisms consume glucose prior to consumption of other carbon sources, and exhibit diauxic growth. It has been shown by fermentation experiments that simultaneous consumption of sugars can be attained by ptsG, mgsA mutants etc., but its mechanism has not been well understood. It is strongly desirable to understand the mechanism of metabolic regulation for catabolite regulation to improve the performance of fermentation.ResultsIn order to make clear the catabolic regulation mechanism, several continuous cultures were conducted at different dilution rates of 0.2, 0.4, 0.6 and 0.7 h-1 using wild type Escherichia coli. The result indicates that the transcript levels of global regulators such as crp, cra, mlc and rpoS decreased, while those of fadR, iclR, soxR/S increased as the dilution rate increased. These affected the metabolic pathway genes, which in turn affected fermentation result where the specific glucose uptake rate, the specific acetate formation rate, and the specific CO2 evolution rate (CER) were increased as the dilution rate was increased. This was confirmed by the 13C-flux analysis. In order to make clear the catabolite regulation, the effect of crp gene knockout (Δcrp) and crp enhancement (crp+ ) as well as mlc, mgsA, pgi and ptsG gene knockout on the metabolism was then investigated by the continuous culture at the dilution rate of 0.2 h-1 and by some batch cultures. In the case of Δcrp (and also Δmlc) mutant, TCA cycle and glyoxylate were repressed, which caused acetate accumulation. In the case of crp+ mutant, glycolysis, TCA cycle, and gluconeogenesis were activated, and simultaneous consumption of multiple carbon sources can be attained, but the glucose consumption rate became less due to repression of ptsG and ptsH by the activation of Mlc. Simultaneous consumption of multiple carbon sources could be attained by mgsA, pgi, and ptsG mutants due to increase in crp as well as cyaA, while glucose consumption rate became lower.ConclusionsThe transcriptional catabolite regulation mechanism was made clear for the wild type E. coli, and its crp, mlc, ptsG, pgi, and mgsA gene knockout mutants. The results indicate that catabolite repression can be relaxed and crp as well as cyaA can be increased by crp+, mgsA, pgi, and ptsG mutants, and thus simultaneous consumption of multiple carbon sources including glucose can be made, whereas the glucose uptake rate became lower as compared to wild type due to inactivation of ptsG in all the mutants considered.

[1]  J. Sambrook,et al.  Molecular Cloning: A Laboratory Manual , 2001 .

[2]  H. Aiba,et al.  Mutations that alter the allosteric nature of cAMP receptor protein of Escherichia coli. , 1985, EMBO Journal.

[3]  T. Szyperski Biosynthetically Directed Fractional 13C‐labeling of Proteinogenic Amino Acids , 1995 .

[4]  T. Szyperski Biosynthetically directed fractional 13C-labeling of proteinogenic amino acids. An efficient analytical tool to investigate intermediary metabolism. , 1995, European journal of biochemistry.

[5]  F. Blattner,et al.  Markerless gene replacement in Escherichia coli stimulated by a double-strand break in the chromosome. , 1999, Nucleic acids research.

[6]  F. Bolivar,et al.  Characterization of sugar mixtures utilization by an Escherichia coli mutant devoid of the phosphotransferase system , 2001, Applied Microbiology and Biotechnology.

[7]  E. Gilles,et al.  The organization of metabolic reaction networks. II. Signal processing in hierarchical structured functional units. , 2001, Metabolic engineering.

[8]  T. Ferenci,et al.  Hungry bacteria--definition and properties of a nutritional state. , 2001, Environmental microbiology.

[9]  S. Ryu,et al.  Heat Shock RNA Polymerase (Eς32) Is Involved in the Transcription of mlc and Crucial for Induction of the Mlc Regulon by Glucose in Escherichia coli * , 2001, The Journal of Biological Chemistry.

[10]  J. Nielsen,et al.  Fuel ethanol production from lignocellulose: a challenge for metabolic engineering and process integration , 2001, Applied Microbiology and Biotechnology.

[11]  B. Dien,et al.  Use of catabolite repression mutants for fermentation of sugar mixtures to ethanol , 2001, Applied Microbiology and Biotechnology.

[12]  B. Dien,et al.  Fermentation of sugar mixtures using Escherichia coli catabolite repression mutants engineered for production of L-lactic acid , 2002, Journal of Industrial Microbiology and Biotechnology.

[13]  Kazuyuki Shimizu,et al.  Gene expression patterns for metabolic pathway in pgi knockout Escherichia coli with and without phb genes based on RT-PCR. , 2003, Journal of biotechnology.

[14]  K. Shimizu,et al.  Metabolic flux analysis of Escherichia coli K12 grown on 13C-labeled acetate and glucose using GC-MS and powerful flux calculation method. , 2003, Journal of biotechnology.

[15]  H. Mori,et al.  Analysis of Escherichia coli anaplerotic metabolism and its regulation mechanisms from the metabolic responses to altered dilution rates and phosphoenolpyruvate carboxykinase knockout , 2003, Biotechnology and bioengineering.

[16]  T. Inada,et al.  Accumulation of Glucose 6-Phosphate or Fructose 6-Phosphate Is Responsible for Destabilization of Glucose Transporter mRNA inEscherichia coli * , 2003, The Journal of Biological Chemistry.

[17]  E. Gilles,et al.  Time hierarchies in the Escherichia coli carbohydrate uptake and metabolism. , 2004, Bio Systems.

[18]  M. Araúzo-Bravo,et al.  Effect of a pyruvate kinase (pykF-gene) knockout mutation on the control of gene expression and metabolic fluxes in Escherichia coli. , 2004, FEMS microbiology letters.

[19]  Hirotada Mori,et al.  Effect of zwf gene knockout on the metabolism of Escherichia coli grown on glucose or acetate. , 2004, Metabolic engineering.

[20]  Francisco Bolívar,et al.  Adaptation for fast growth on glucose by differential expression of central carbon metabolism and gal regulon genes in an Escherichia coli strain lacking the phosphoenolpyruvate:carbohydrate phosphotransferase system. , 2005, Metabolic engineering.

[21]  Francisco Bolívar,et al.  Replacement of the glucose phosphotransferase transport system by galactose permease reduces acetate accumulation and improves process performance of Escherichia coli for recombinant protein production without impairment of growth rate. , 2006, Metabolic engineering.

[22]  K. Shimizu,et al.  Effect of fadR gene knockout on the metabolism of Escherichia coli based on analyses of protein expressions, enzyme activities and intracellular metabolite concentrations , 2006 .

[23]  Andreas Kremling,et al.  A Quantitative Approach to Catabolite Repression in Escherichia coli* , 2006, Journal of Biological Chemistry.

[24]  H. Mori,et al.  Construction of Escherichia coli K-12 in-frame, single-gene knockout mutants: the Keio collection , 2006, Molecular systems biology.

[25]  Pei Yee Ho,et al.  Multiple High-Throughput Analyses Monitor the Response of E. coli to Perturbations , 2007, Science.

[26]  K. Shimizu,et al.  Growth phase-dependent changes in the expression of global regulatory genes and associated metabolic pathways in Escherichia coli , 2008, Biotechnology Letters.

[27]  B. Görke,et al.  Carbon catabolite repression in bacteria: many ways to make the most out of nutrients , 2008, Nature Reviews Microbiology.

[28]  K. Shimizu,et al.  Altered acetate metabolism and biomass production in several Escherichia coli mutants lacking rpoS-dependent metabolic pathway genes. , 2008, Molecular bioSystems.

[29]  Mohammad M. Ataai,et al.  Pyruvate Kinase-Deficient Escherichia coli Exhibits Increased Plasmid Copy Number and Cyclic AMP Levels , 2009, Journal of bacteriology.

[30]  K. Shanmugam,et al.  Deletion of methylglyoxal synthase gene (mgsA) increased sugar co-metabolism in ethanol-producing Escherichia coli , 2009, Biotechnology Letters.

[31]  Sarah A. Lee,et al.  A substrate‐selective co‐fermentation strategy with Escherichia coli produces lactate by simultaneously consuming xylose and glucose , 2009, Biotechnology and bioengineering.

[32]  Nobuyoshi Ishii,et al.  13C‐metabolic flux analysis for batch culture of Escherichia coli and its pyk and pgi gene knockout mutants based on mass isotopomer distribution of intracellular metabolites , 2010, Biotechnology progress.