Mutational analysis of the high-affinity BvgA binding site in the fha promoter of Bordetella pertussis

In order to define a consensus binding sequence for the response regulator BvgA, we have undertaken a systematic analysis of contributions made by each nucleotide within the heptad half-sites that are present in an inverted orientation at the promoter for the fha operon. Using in vitro binding assays, we examined the full complement of 21 single point mutations symmetrically arranged in this heptad repeat. Both gel shift and nitrocellulose filter-binding assays provided evidence that nucleotides at positions 3 (thymidine), 4 (cytosine) and 7 (adenine) in the binding heptad contribute substantially to sequence-specific recognition by BvgA. Furthermore, a T to A conversion at position 6 reduced binding. Selected binding site mutations were introduced into a modified fha promoter and examined for their effects on BvgA activation of promoter activity in vivo. Only those substitutions most severely affecting binding in vitro affected promoter activity in vivo. The in vivo effects of substitutions that had a significant effect on binding in vitro but did not severely affect in vivo promoter activity under standard culture conditions could be detected in vivo either in combination with additional substitutions or from their effect on the sensitivity of the mutant promoters to modulation by magnesium sulphate.     

Role of BvgA phosphorylation and DNA binding affinity in control of Bvg-mediated phenotypic phase transition in Bordetella pertussis

To investigate the mechanism by which the Bordetella BvgAS phosphorelay controls expression of at least three distinct phenotypic phases, we isolated and characterized two B. pertussis mutants that were able to express Bvg- and Bvg(i) phase phenotypes but not Bvg+ phase phenotypes. In both cases, the mutant phenotype was due to a single nucleotide change in bvgA resulting in a single amino acid substitution in BvgA. In vitro phosphorylation assays showed that BvgA containing the T194M substitution was significantly impaired in its ability to use either BvgS or acetyl phosphate as a substrate for phosphorylation. Binding studies indicated that this mutant protein was able to bind an oligonucleotide containing a high-affinity BvgA binding site in a manner similar to wild-type BvgA, but was defective for binding the fhaB promoter in the absence of RNA polymerase (RNAP). By contrast, BvgA containing the R152H substitution had wild-type phosphorylation properties but was severely defective in its ability to bind either the high-affinity BvgA binding site-containing oligonucleotide or the fhaB promoter by itself. Both mutant BvgA proteins were able to bind the fhaB promoter in the presence of RNAP however, demonstrating the profound effect that RNAP has on stabilizing the ternary complexes between promoter DNA, BvgA and RNAP. Our results are consistent with the hypothesis that BvgAS controls expression of multiple phenotypic phases by adjusting the intracellular concentration of BvgA-P and they demonstrate the additive nature of BvgA binding site affinity and protein-protein interactions at different Bvg-regulated promoters.     

Characterization of DNA binding sites for the BvgA protein of Bordetella pertussis.

Expression of virulence-associated genes in Bordetella pertussis is under the control of the pleiotropic regulator BvgA. Although previous studies have identified recognition sequences for BvgA in several promoter regions, their structures have not been clearly characterized. We show that the BvgA binding sites within the bvgp(1) and cyaA promoters consist of inverted repeats and suggest that inverted-repeat motifs may represent the recognition elements for DNA-BvgA interaction.     

Molecular characterization of the BvgA response regulator of Bordetella holmesii

The BvgAS system controls the expression of most virulence factors in Bordetella pertussis. Recently, we identified an orthologous system in the related human pathogen Bordetella holmesii. However, while we found that the orthologous histidine kinases BvgS could be functionally exchanged between the two species, the B. holmesii response regulator BvgA(BH) could not substitute for its B. pertussis counterpart in vivo and, accordingly, was not able to bind to B. pertussis virulence promoters in vitro. Here we show that a hybrid response regulator consisting of the B. pertussis derived DNA-binding output domain of BvgA(BP) combined with the B. holmesii receiver domain binds to BvgA(BP) regulated virulence promoters of B. pertussis in vitro and is functional in B. pertussis in vivo. This shows that the inability of BvgA(BH) to complement BvgA(BP) in B. pertussis is due to the small number of sequence variations present in its output domain. However, by mutation analysis we show that four amino acid exchanges present in the helix-turn-helix motif of BvgA(BH) as compared to BvgA(BP) are not the only reason for its inability to substitute for BvgA(BP) but additional mutations present in the output domain must play a role.