Even though transcriptional regulation plays a key role in establishing the metabolic network, the extent to which it actually controls the in vivo distribution of metabolic fluxes through different pathways is essentially unknown. Based on metabolism-wide quantification of intracellular fluxes, we systematically elucidated the relevance of global transcriptional regulation by ArcA, ArcB, Cra, Crp, Cya, Fnr, and Mlc for aerobic glucose catabolism in batch cultures of Escherichia coli. Knockouts of ArcB, Cra, Fnr, and Mlc were phenotypically silent, while deletion of the catabolite repression regulators Crp and Cya resulted in a pronounced slow-growth phenotype but had only a nonspecific effect on the actual flux distribution. Knockout of ArcA-dependent redox regulation, however, increased the aerobic tricarboxylic acid (TCA) cycle activity by over 60%. Like aerobic conditions, anaerobic derepression of TCA cycle enzymes in an ArcA mutant significantly increased the in vivo TCA flux when nitrate was present as an electron acceptor. The in vivo and in vitro data demonstrate that ArcA-dependent transcriptional regulation directly or indirectly controls TCA cycle flux in both aerobic and anaerobic glucose batch cultures of E. coli. This control goes well beyond the previously known ArcA-dependent regulation of the TCA cycle during microaerobiosis.Metabolic networks consist of hundreds of metabolites that are interconnected through a large number of biochemical and regulatory reactions. In principle, metabolites could flow through various reactions, but only few specific pathways are used in reality (20). This distribution of molecular fluxes is regulated by multiple mechanisms at several levels that include gene expression, posttranscriptional control, enzyme kinetics, and allosteric control. While transcriptional regulation is generally considered the main mode of regulation in bacteria, the extent to which it actually controls the distribution of metabolic fluxes through different pathways is mostly unknown. Based on metabolism-wide comparisons of metabolic flux and gene expression during growth on different substrates, the flux through some central metabolic pathways was found to correlate, at least qualitatively, with the expression level, but in many cases there was no apparent correlation (12,24,41,42). In parasitic protists, the glycolytic flux was demonstrated to be rarely completely controlled at the transcriptional level and mostly not even largely controlled at this level (65).Transcriptional regulation itself involves a complex network of global and specific regulators, in which global regulators exhibit pleiotropic phenotypes and regulate several operons that belong to different functional groups (26). In Escherichia coli, only seven global regulators (ArcA, Crp, Fis, Fnr, Ihf, Lrp, and NarL) directly modulate the expression of about one-half of all genes (39). The following three regulators have specific metabolic functions that involve altering expression of genes that are involved in central carbon m...
