Coordinate regulation of the Escherichia coli formate dehydrogenase fdnGHI and fdhF genes in response to nitrate,nitrite, and formate: roles for NarL and NarP

Escherichia coli possesses three distinct formate dehydrogenase enzymes encoded by the fdnGHI, fdhF, and fdoGHI operons. To examine how two of the formate dehyrogenase operons (fdnGHI and fdhF) are expressed anaerobically in the presence of low, intermediate, and high levels of nitrate, nitrite, and formate, chemostat culture techniques were employed with fdnG-lacZ and fdhF-lacZ reporter fusions. Complementary patterns of gene expression were seen. Optimal fdhF-lacZ expression occurred only at low to intermediate levels of nitrate, while high nitrate levels caused up to 10-fold inhibition of gene expression. In contrast, fdnG-lacZ expression was induced 25-fold in the presence of intermediate to high nitrate concentrations. Consistent with prior reports, NarL was able to induce fdnG-lacZ expression. However, NarP could not induce expression; rather, it functioned as an antagonist of fdnG-lacZ expression under low-nitrate conditions (i.e., it was a negative regulator). Nitrite, a reported signal for the Nar sensory system, was unable to stimulate or suppress expression of either formate dehydrogenase operon via NarL and NarP. The different gene expression profiles of the alternative formate dehydrogenase operons suggest that the two enzymes have complementary physiological roles under environmental conditions when nitrate and formate levels are changing. Revised regulatory schemes for NarL- and NarP-dependent nitrate control are presented for each operon.     

Differential regulation by the homologous response regulators NarL and NarP of Escherichia coli K-12 depends on DNA binding site arrangement

The NarL and NarP proteins are homologous response regulators of Escherichia coli that control the expression of several operons in response to nitrate and nitrite. A consensus heptameric NarL DNA-binding sequence has been identified, and previous observations suggest that the NarP protein has a similar sequence specificity. However, some operons are regulated by NarL alone, whereas others are controlled by both NarL and NarP. In this study, DNase I footprinting experiments with the fdnG , nirB and nrfA control regions revealed that NarP only binds to heptamer sequences organized as an inverted repeat with a 2 bp spacing (7–2–7 sites). The NarL protein also binds to these 7–2–7 sites but, unlike NarP, also recognizes heptamers in other arrangements. These results provide an explanation for the regulation of some operons by NarL alone and for the different effects of NarL and NarP at common target operons, such as fdnG and nrfA . To investigate this differential DNA binding further, derivatives of the nrfA control region were constructed in which the spacing of the 7–2–7 heptamers was increased (7– n –7 constructs). Increasing the spacing to four or more basepairs abolished NarP binding and significantly reduced NarL binding. The NarL protein also had a reduced binding affinity for heptamers adjacent to the 7– n –7 heptamer pair, suggesting a decrease in cooperative interactions. In conclusion, we propose that 7–2–7 sites are preferred by both NarL and NarP. NarL can also recognize other binding site arrangements, an ability that appears to be lacking in NarP.     

Expression of the narX, narL, narP, and narQ genes of Escherichia coli K-12: regulation of the regulators.

The products of four Escherichia coli genes (narX, narL, narQ, and narP) regulate anaerobic respiratory gene expression in response to nitrate and nitrite. We used lacZ gene and operon fusions to monitor the expression of these nar regulatory genes in response to different growth conditions. Maximal expression of the narXL operon required molybdate, nitrate, and integration host factor. Expression of the narP and narQ genes was weakly repressed by nitrate. The NarL and NarP proteins were required for full nitrate induction of narXL operon expression, whereas the nitrate repression of narP and narQ expression was mediated solely by the NarL protein. narXL operon expression was unaffected by anaerobiosis, whereas expression of narP and narQ was induced approximately fourfold. The Fnr and ArcA proteins were not required for this anaerobic induction.     

The napF and narG Nitrate Reductase Operons in Escherichia coli Are Differentially Expressed in Response to Submicromolar Concentrations of Nitrate but Not Nitrite

Escherichia coli synthesizes two biochemically distinct nitrate reductase enzymes, a membrane-bound enzyme encoded by the narGHJI operon and a periplasmic cytochrome c-linked nitrate reductase encoded by the napFDAGHBC operon. To address why the cell makes these two enzymes, continuous cell culture techniques were used to examine napF and narG gene expression in response to different concentrations of nitrate and/or nitrite. Expression of the napF-lacZ and narG-lacZ reporter fusions in strains grown at different steady-state levels of nitrate revealed that the two nitrate reductase operons are differentially expressed in a complementary pattern. The napF operon apparently encodes a "low-substrate-induced" reductase that is maximally expressed only at low levels of nitrate. Expression is suppressed under high-nitrate conditions. In contrast, the narGHJI operon is only weakly expressed at low nitrate levels but is maximally expressed when nitrate is elevated. The narGHJI operon is therefore a "high-substrate-induced" operon that somehow provides a second and distinct role in nitrate metabolism by the cell. Interestingly, nitrite, the end product of each enzyme, had only a minor effect on the expression of either operon. Finally, nitrate, but not nitrite, was essential for repression of napF gene expression. These studies reveal that nitrate rather than nitrite is the primary signal that controls the expression of these two nitrate reductase operons in a differential and complementary fashion. In light of these findings, prior models for the roles of nitrate and nitrite in control of narG and napF expression must be reconsidered.     

Nitrate- and nitrite-sensing protein NarX of Escherichia coli K-12: mutational analysis of the amino-terminal tail and first transmembrane segment.

Nitrate and nitrite control of anaerobic respiratory gene expression is mediated by dual two-component regulatory systems. The sensors NarX and NarQ each communicate nitrate and nitrite availability to the response regulators NarL and NarP. In the presence of nitrate, the NarX protein acts as a positive regulator ("kinase") of both NarL and NarP activity. In the presence of nitrite, the NarX protein acts primarily as a negative regulator ("phosphatase") of NarL activity but remains a positive regulator of NarP activity. In other topologically similar sensory proteins, such as the methyl-accepting chemotaxis proteins, the transmembrane regions are important for signal transduction. We therefore used localized mutagenesis of the amino-terminal coding region to isolate mutations in narX that confer an altered signaling phenotype. Five of the mutations studied alter residues in the amino-terminal cytoplasmic tail, and five alter residues in the first transmembrane segment. Based on patterns of target operon expression in various regulatory mutant strain backgrounds, most of the mutant NarX proteins appear to have alterations in negative control function. One mutant, with a change of residue Leu-11 to Pro in the cytoplasmic tail, exhibits strikingly altered patterns of NarL- and NarP-dependent gene expression. We conclude that the amino terminus of the NarX protein is important for the differential response to nitrate and nitrite.     

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     

Nitrate repression of the Escherichia coli pfl operon is mediated by the dual sensors NarQ and NarX and the dual regulators NarL and NarP.

The pfl operon is expressed at high levels anaerobically. Growth of Escherichia coli in the presence of nitrate or nitrite led to a 45% decrease in expression when cells were cultivated in rich medium. Nitrate repression, however, was significantly enhanced (sevenfold) when the cells were cultured in minimal medium. Regulation of pfl expression by nitrate was dependent on the NarL, NarP, NarQ, and NarX proteins but independent of FNR, ArcA, and integration host factor, which are additional regulators of pfl expression. Strains unable to synthesize any one of the NarL, NarP, NarQ, or NarX proteins, but retaining the capacity to synthesize the remaining three, exhibited essentially normal nitrate regulation. In contrast, narL narP and narX narQ double null mutants were devoid of nitrate regulation when cultured in rich medium but they retained some nitrate repression (1.3-fold) when grown in minimal medium. By using lacZ fusions, it was possible to localize the DNA sequences required to mediate nitrate repression to the pfl promoter-regulatory region. DNase I footprinting studies identified five potential binding sites for the wild-type NarL protein in the pfl promoter-regulatory region. Specific footprints were obtained only when NarL was phosphorylated with acetyl phosphate before the binding reaction was performed. Each of the protected regions contained at least one heptamer sequence which has been deduced from mutagenesis studies to be essential for NarL binding (K. Tyson, A. Bell, J. Cole, and S. Busby, Mol. Microbiol. 7:151-157, 1993).