The transcriptional regulator CcpN of Bacillus subtilis has been recently characterized as a repressor of two gluconeogenic genes, gapB and pckA, and of a small noncoding regulatory RNA, sr1, involved in arginine catabolism. Deletion of ccpN impairs growth on glucose and strongly alters the distribution of intracellular fluxes, rerouting the main glucose catabolism from glycolysis to the pentose phosphate (PP) pathway. Using transcriptome analysis, we show that during growth on glucose, gapB and pckA are the only protein-coding genes directly repressed by CcpN. By quantifying intracellular fluxes in deletion mutants, we demonstrate that derepression of pckA under glycolytic condition causes the growth defect observed in the ccpN mutant due to extensive futile cycling through the pyruvate carboxylase, phosphoenolpyruvate carboxykinase, and pyruvate kinase. Beyond ATP dissipation via this cycle, PckA activity causes a drain on tricarboxylic acid cycle intermediates, which we show to be the main reason for the reduced growth of a ccpN mutant. The high flux through the PP pathway in the ccpN mutant is modulated by the flux through the alternative glyceraldehyde-3-phosphate dehydrogenases, GapA and GapB. Strongly increased concentrations of intermediates in upper glycolysis indicate that GapB overexpression causes a metabolic jamming of this pathway and, consequently, increases the relative flux through the PP pathway. In contrast, derepression of sr1, the third known target of CcpN, plays only a marginal role in ccpN mutant phenotypes.Regulation of metabolism enables microbes to grow efficiently on a large variety of carbon sources. Partly, these regulation processes ensure efficient resource allocation by expressing substrate-specific transporters and catabolic enzymes only when the substrate is present (38). However, regulation must also avoid simultaneous activity of incompatible or counteracting reactions. A well-known example is the simultaneous presence of ATP-consuming and ATP-generating enzymes that would lead to ATP-dissipating futile cycles (6, 10, 36). Another relevant case is the expression of isoenzymes with different cofactor specificities (9,21,27,33,38) that may catalyze opposite fluxes through key reactions (7,9,11,16). A particularly challenging situation is therefore the switch from glycolytic to gluconeogenic substrates, where large fluxes through the metabolism backbone have to be reversed because the two groups of substrates enter metabolism at two opposite ends.While allosteric regulation of enzyme activities plays an important role in fine-tuning and rapid adaptation to nutritional changes, transcriptional regulation is probably the main mechanism that allows the organism to respond metabolically to a nutrient shift by promoting the operation of a new optimal subset of reactions and adjusting the fluxes through the different central pathways for the establishment of a new steady state (26). One of the most thoroughly studied control mechanisms is carbon catabolite repression, by which the pre...
