Bordetella pertussis infection induces a mucosal IL-17 response and long-lived Th17 and Th1 immune memory cells in nonhuman primates.

Despite near universal vaccine coverage, the bacterial pathogen Bordetella pertussis has re-emerged as a major public health concern. We recently developed a baboon (Papio anubis) model of pertussis that provides an excellent model of human pertussis. Using this model, the immune response to pertussis was characterized by measuring cytokines in the nasopharyngeal mucosa of infected baboons. Notably, we observed mucosal expression of interleukin-17 (IL-17) as well as IL-6, IL-23, and several cytokines and chemokines that are orchestrated by IL-17 immune responses. We also found substantial populations of circulating B. pertussis-specific Th17 and Th1 cells in convalescent animals >2 years post-infection consistent with a role in immunological memory to pertussis. Collectively, these data shed important light on the innate and adaptive immune responses to pertussis in a primate infection model and suggest that Th17 and Th1 immune responses contribute to the immunity conferred by natural pertussis infection.

Contribution of regulation by the bvg locus to respiratory infection of mice by Bordetella pertussis.

Whooping cough is an acute respiratory disease caused by the small, gram-negative bacterium Bordetella pertussis. B. pertussis expresses several factors that contribute to its ability to cause disease. These factors include surface-associated molecules, which are involved in the adherence of the organism to respiratory epithelial cells, as well as several extracellular toxins that inhibit host defenses and induce damage to host tissues. The expression of virulence factors in B. pertussis is dependent upon the bvg locus, which consists of three genes: bvgA, bvgS, and bvgR. The bvgAS genes encode a two-component regulatory system consisting of a sensor protein, BvgS, and a transcriptional activator, BvgA. Upon modification by BvgS, BvgA binds to the promoter regions of the bvg-activated genes and activates transcription. One of the bvg-activated genes, bvgR, is responsible for the regulation of the bvg-repressed genes, the functions of which are unknown. The fact that these genes are regulated by the bvg locus suggests that they play a role in the pathogenesis of the bacterium. In order to evaluate the contribution of bvg-mediated regulation to the virulence of B. pertussis and determine if expression of the bvg-repressed genes is required for the virulence of B. pertussis, we examined the ability of B. pertussis mutants, defective in their ability to regulate the expression of the bvg-activated and/or the bvg-repressed genes, to cause disease in the mouse aerosol challenge model. Our results indicate that the bvgR-mediated regulation of gene expression contributes to respiratory infection of mice.

Characterization of the bvgR locus of Bordetella pertussis.

Bordetella pertussis, the causative agent of whooping cough, produces a wide array of factors that are associated with its ability to cause disease. The expression and regulation of these virulence factors is dependent upon the bvg locus (originally designated the vir locus), which encodes two proteins: BvgA, a 23-kDa cytoplasmic protein, and BvgS, a 135-kDa transmembrane protein. It is proposed that BvgS responds to environmental signals and interacts with BvgA, a transcriptional regulator which upon modification by BvgS binds to specific promoters and activates transcription. An additional class of genes is repressed by the bvg locus. Expression of this class, the bvg-repressed genes (vrgs [for vir-repressed genes]), is reduced under conditions in which expression of the aforementioned bvg-activated virulence factors is maximal; this repression is dependent upon the presence of an intact bvgAS locus. We have previously identified a locus required for regulation of all of the known bvg-repressed genes in B. pertussis. This locus, designated bvgR, maps to a location immediately downstream of bvgAS. We have undertaken deletion and complementation studies, as well as sequence analysis, in order to identify the bvgR open reading frame and identify the cis-acting sequences required for regulated expression of bvgR. Studies utilizing transcriptional fusions of bvgR to the gene encoding alkaline phosphatase have demonstrated that bvgR is activated at the level of transcription and that this activation is dependent upon an intact bvgAS locus.

Identification of a locus required for the regulation of bvg-repressed genes in Bordetella pertussis.

In Bordetella pertussis, the coordinate regulation of virulence factor expression is controlled by the products of the bvgAS locus. In the presence of modulating signals such as MgSO4, nicotinic acid, or reduced temperature, the expression of bvg-activated genes is reduced while the expression of bvg-repressed genes is induced. One model for the regulation of bvg-repressed genes predicts the existence of a repressor protein encoded by a bvg-activated gene. Once activated, the product of this bvg-activated gene would bind to and repress transcription from the bvg-repressed genes. We isolated five genetically independent transposon insertion mutants of B. pertussis that have a phenotype consistent with the knockout of a putative bvg-regulated repressor. These mutants constitutively expressed a vrg6-phoA transcriptional fusion but demonstrated normal bvgAS function. Genomic mapping and DNA sequence analysis of the sites of transposon insertion demonstrated that these mutants define a locus downstream of bvgAS. Introduction of an in-frame, 12-bp insertion within this locus also conferred the mutant phenotype, confirming that the phenotype seen in the transposon mutants is the result of disruption of a distinct gene, which we have designated bvgR, and is not a consequence of polar effects on bvgAS.

Transcription activation at the Escherichia coli uhpT promoter by the catabolite gene activator protein.

Transport and utilization of sugar phosphates in Escherichia coli depend on the transport protein encoded by the uhpT gene. Transmembrane induction of uhpT expression by external glucose 6-phosphate is positively regulated by the promoter-specific activator protein UhpA and the global regulator catabolite gene activator protein (CAP). Activation by UhpA requires a promoter element centered at -64 bp, relative to the start of transcription, and activation by CAP requires a DNA site centered at position -103.5. This DNA site binds the cyclic AMP-CAP complex in vitro, and its deletion from the promoter reduces transcription activity to 7 to 9% of the wild-type level. Ten uhpT promoter derivatives with altered spacing between the DNA site for CAP and the remainder of the promoter were constructed. Their transcription activities indicated that the action of CAP at this promoter is dependent on proper helical phasing of promoter elements, with CAP binding on the same face of the helix as RNA polymerase does. Five CAP mutants defective in transcription activation at class I and class II CAP-dependent promoters but not defective in DNA binding or DNA bending (positive control mutants) were tested for the ability to activate transcription. These CAPpc mutants exhibited little or no defect in transcription activation at uhpT, indicating that CAP action at uhpTp involves a different mechanism than that which is used for its action at other classes of CAP-dependent promoters.

Characterization of the activating region of Escherichia coli catabolite gene activator protein (CAP). II. Role at Class I and class II CAP-dependent promoters.

CAP-dependent promoters can be divided into classes based on the position of the DNA site for CAP. In class I CAP-dependent promoters, the DNA site for CAP is located upstream of the DNA site for polymerase; the DNA site for CAP can be located at various distances from the transcription start point, provided that the DNS site for CAP and the DNA site for RNA polymerase are on the same face of the DNA helix. In class II CAP-dependent promoters, the DNA site for CAP overlaps the DNA site for RNA polymerase, replacing the -35 determinants for binding of RNA polymerase. In previous work, we have shown that a surface loop consisting of amino acid residues 152 to 166 of CAP is essential for transcription activation at the best-characterized class I CAP-dependent promoter, the lac promoter, and we proposed that this surface loop makes direct protein-protein contact with RNA polymerase in the ternary complex of lac promoter, CAP, and RNA polymerase. Here, we show that the surface loop consisting of amino acid residues 152 to 166 is essential for transcription activation at other class I CAP-dependent promoters and at a class II CAP-dependent promoter. We show further that the effects of alanine substitutions of residues 152 to 166 are qualitatively identical at the lac promoter and other class I CAP-dependent promoters, but are different at a class II CAP-dependent promoter. We propose that the surface loop consisting of residues 152 to 166 makes identical molecular interactions in transcription activation at all class I CAP-dependent promoters, irrespective of distance between the DNA site for CAP and the transcription start point, but makes a different set of molecular interactions in transcription activation at class II CAP-dependent promoters.

Promoter elements required for positive control of transcription of the Escherichia coli uhpT gene.

The uhpABCT locus of Escherichia coli encodes the transport system which allows the cell to accumulate a variety of sugar phosphates in unaltered form. The expression of uhpT, the gene encoding the transport protein, is regulated by the uhpABC gene products. The UhpA protein is required for expression; its deduced amino acid sequence shows that it belongs to a subfamily of bacterial transcription regulators including NarL, DegU, and FixJ. Members of this subfamily have an amino-terminal phosphorylation domain characteristic of so-called two-component regulators, such as OmpR, CheY, PhoB, and NtrC, and a carboxyl-terminal domain conserved among many transcriptional activators, including LuxR and MalT. The major sequence elements in the uhpT promoter that are needed for uhpT expression were investigated. Northern (RNA) hybridization analysis showed that the uhpT transcript was only present in cells induced for UhpT transport activity. The start site of transcription was identified by primer extension. Comparison of the regions upstream of the uhpT transcription start site in E. coli and Salmonella typhimurium suggested the presence of four sequence elements that might be involved in promoter function: a typical -10 region, a short inverted repeat centered at -32, a long inverted repeat centered at -64, and a cyclic AMP receptor protein-binding sequence centered at -103. Deletion and linker substitution mutations in the promoter demonstrated that the presence of the cyclic AMP receptor protein-binding site resulted in about an eightfold increase in promoter activity and that the -64, -32, and -10 elements were essential for promoter function. In vivo titration of transcriptional activator UhpA by the intact or mutant promoters on multicopy plasmids identified the -64 element as the UhpA-binding site. The two halves of the -64 inverted repeat did not contribute equally to promoter function and did not have to be intact for UhpA titration. The sequence recognized by UhpA is predicted to be 5' -GGCAAAACNNNGAAA.