Multiple regulatory elements for the glpA operon encoding anaerobic glycerol-3-phosphate dehydrogenase and the glpD operon encoding aerobic glycerol-3-phosphate dehydrogenase in Escherichia coli: further characterization of respiratory control.

In Escherichia coli, sn-glycerol-3-phosphate can be oxidized by two different flavo-dehydrogenases, an anaerobic enzyme encoded by the glpACB operon and an aerobic enzyme encoded by the glpD operon. These two operons belong to the glp regulon specifying the utilization of glycerol, sn-glycerol-3-phosphate, and glycerophosphodiesters. In glpR mutant cells grown under conditions of low catabolite repression, the glpA operon is best expressed anaerobically with fumarate as the exogenous electron acceptor, whereas the glpD operon is best expressed aerobically. Increased anaerobic expression of glpA is dependent on the fnr product, a pleiotropic activator of genes involved in anaerobic respiration. In this study we found that the expression of a glpA1(Oxr) (oxygen-resistant) mutant operon, selected for increased aerobic expression, became less dependent on the FNR protein but more dependent on the cyclic AMP-catabolite gene activator protein complex mediating catabolite repression. Despite the increased aerobic expression of glpA1(Oxr), a twofold aerobic repressibility persisted. Moreover, anaerobic repression by nitrate respiration remained normal. Thus, there seems to exist a redox control apart from the FNR-mediated one. We also showed that the anaerobic repression of the glpD operon was fully relieved by mutations in either arcA (encoding a presumptive DNA recognition protein) or arcB (encoding a presumptive redox sensor protein). The arc system is known to mediate pleiotropic control of genes of aerobic function.     

ERA, a novel cis-acting element required for autoregulation and ethanol repression of PDC1 transcription in Saccharomyces cerevisiae

During anaerobic growth, expression of the fdnGHI and narGHJI operons of Escherichia coli is induced by the NarL protein in response to nitrate. The fdnG operon control region contains four NarL-binding sites (termed NarL heptamers) between positions −70 and −130. The two central NarL heptamers of fdnG are arranged as an inverted repeat and are essential for regulation by NarL. We used mutational analysis of these central heptamers to investigate the precise sequence requirements for NarL-dependent induction. Mutations were examined for their effects on NarL-dependent expression in vivo . Substitutions at position 1 of either heptamer had the strongest effect whereas substitutions at position 7 had the weakest effect. For some positions, alterations in both heptamers had a stronger effect than either of the single changes. The 2 bp spacing between these NarL heptamers was also important for normal nitrate induction. The narG operon control region has at least eight NarL heptamers arranged in two groups. Previous work has shown that nucleotide substitutions in two of these heptamers, centred at positions −195 and −89, severely reduce nitrate induction of narG operon expression in vivo and significantly interfere with NarL–DNA interactions in vitro . Substitutions in heptamers −185 and −101 affected narG operon induction only when the concentration of phospho-NarL was low (during growth in the presence of nitrite). Changes in each of the other four NarL heptamers studied had little or no effect on nitrate or nitrite induction of narG operon expression or on NarL–DNA interactions in vitro