O antigen protects Bordetella parapertussis from complement

Bordetella pertussis, a causative agent of whooping cough, expresses BrkA, which confers serum resistance, but the closely related human pathogen that also causes whooping cough, Bordetella parapertussis, does not. Interestingly, B. parapertussis, but not B. pertussis, produces an O antigen, a factor shown in other models to confer serum resistance. Using a murine model of infection, we determined that O antigen contributes to the ability of B. parapertussis to colonize the respiratory tract during the first week of infection, but not thereafter. Interestingly, an O antigen-deficient strain of B. parapertussis was not defective in colonizing mice lacking the complement cascade. O antigen prevented both complement component C3 deposition on the surface and complement-mediated killing of B. parapertussis. In addition, O antigen was required for B. parapertussis to systemically spread in complement-sufficient mice, but not complement-deficient mice. These data indicate that O antigen enables B. parapertussis to efficiently colonize the lower respiratory tract by protecting against complement-mediated control and clearance.     

Reciprocal protective immunity against Bordetella pertussis and Bordetella parapertussis in a murine model of respiratory infection

The protective immunity induced by infection with Bordetella pertussis and with Bordetella parapertussis was examined in a murine model of respiratory infection. Convalescent mice that had been infected by aerosol with B. pertussis or with B. parapertussis exhibited a protective immune response against B. pertussis and also against B. parapertussis. Anti-filamentous hemagglutinin (anti-FHA) serum immunoglobulin G (IgG) and anti-FHA lung IgA antibodies were detected in both mice infected with B. pertussis and those infected with B. parapertussis. Antibodies against pertussis toxin (anti-PT) and against killed B. pertussis cells were detected in mice infected with B. pertussis. Pertactin-specific antibodies and antibodies against killed B. parapertussis cells were detected in mice infected with B. parapertussis. Spleen cells from mice infected with B. pertussis secreted interferon-gamma (IFN-gamma) in response to stimulation by FHA or PT. Spleen cells from mice infected with B. parapertussis also secreted IFN-gamma in response to FHA. Interleukin-4 was not produced in response to any of the antigens tested. The profiles of cytokine secretion in vitro revealed induction of a Th1-biased immune response during convalescence from infection by B. pertussis and by B. parapertussis. It is possible that Th1 and Th2 responses against FHA might be related to the reciprocal protection achieved in our murine model.     

Bystander activation of Bordetella pertussis-induced nasal tissue-resident memory CD4 T cells confers heterologous immunity to Klebsiella pneumoniae

Tissue-resident memory CD4 T (T_RM) cells induced by infection with Bordetella pertussis persist in respiratory tissues and confer long-term protective immunity against reinfection. However, it is not clear how they are maintained in respiratory tissues. Here, we demonstrate that B. pertussis-specific CD4 T_RM cells produce IL-17A in response to in vitro stimulation with LPS or heat-killed Klebsiella pneumoniae (HKKP) in the presence of dendritic cells. Furthermore, IL-17A-secreting CD4 T_RM cells expand in the lung and nasal tissue of B. pertussis convalescent mice following in vivo administration of LPS or HKKP. Bystander activation of CD4 T_RM cells was suppressed by anti-IL-12p40 but not by anti-MHCII antibodies. Furthermore, purified respiratory tissue-resident, but not circulating, CD4 T cells from convalescent mice produced IL-17A following direct stimulation with IL-23 and IL-1β or IL-18. Intranasal immunization of mice with a whole-cell pertussis vaccine induced respiratory CD4 T_RM cells that were reactivated following stimulation with K. pneumoniae. Furthermore, the nasal pertussis vaccine conferred protective immunity against B. pertussis but also attenuated infection with K. pneumoniae. Our findings demonstrate that CD4 T_RM cells induced by respiratory infection or vaccination can undergo bystander activation and confer heterologous immunity to an unrelated respiratory pathogen.     

Clearance of Bordetella parapertussis from the lower respiratory tract requires humoral and cellular immunity

Bordetella parapertussis and Bordetella pertussis are closely related species that cause whooping cough, an acute, immunizing disease. Their coexistence in the same host populations at the same time and vaccine studies showing that B. pertussis vaccines have little effect on B. parapertussis infection or disease suggest that the protective immunity induced by each does not efficiently cross protect against the other. Although the mechanisms of protective immunity to B. pertussis have been well studied, those of B. parapertussis have not. The present study explores the mechanism by which B. parapertussis is cleared from the lower respiratory tract by anamnestic immunity. Serum antibodies are necessary and sufficient for elimination of this bacterium, and CD4(+) T cells, complement, and neutrophils are required for serum antibody-mediated clearance. Mice lacking immunoglobulin A had no defect in their ability to control or clear infection. Interestingly, serum antibody-mediated clearance of B. parapertussis did not require Fc receptors that are required for antibody-mediated clearance of B. pertussis. Together these data support a model for the mechanism of protective immunity to B. parapertussis that is similar but distinct from that of B. pertussis.     

The O Antigen Is a Critical Antigen for the Development of a Protective Immune Response to Bordetella parapertussis

Despite excellent vaccine coverage in developed countries, whooping cough is a reemerging disease that can be caused by two closely related pathogens, Bordetella pertussis and B. parapertussis. The two are antigenically distinct, and current vaccines, containing only B. pertussis-derived antigens, confer efficient protection against B. pertussis but not against B. parapertussis. B. pertussis does not express the O antigen, while B. parapertussis retains it as a dominant surface antigen. Since the O antigen is a protective antigen for many pathogenic bacteria, we examined whether this factor is a potential protective antigen for B. parapertussis. In a mouse model of infection, immunization with wild-type B. parapertussis elicited a strong antibody response to the O antigen and conferred efficient protection against a subsequent B. parapertussis challenge. However, immunization with an isogenic mutant lacking the O antigen, B. parapertussis Δwbm, induced antibodies that recognized other antigens but did not efficiently mediate opsonophagocytosis of B. parapertussis. The passive transfer of sera raised against B. parapertussis, but not B. parapertussis Δwbm, reduced B. parapertussis loads in the lower respiratory tracts of mice. The addition of 10 μg of purified B. parapertussis lipopolysaccharide (LPS), which contains the O antigen, but not B. parapertussis Δwbm LPS drastically improved the efficacy of the acellular vaccine Adacel against B. parapertussis. These data suggest that the O antigen is a critical protective antigen of B. parapertussis and its inclusion can substantially improve whooping cough vaccine efficacy against this pathogen.Bordetella pertussis and B. parapertussis are the causative agents of whooping cough, resulting in approximately 50 million cases and 300,000 deaths annually worldwide (28). While whooping cough is considered by the CDC to be a reemerging disease (5), the relative incidences of B. pertussis and B. parapertussis are not clear (50). It is known, however, that the resurgence of whooping cough roughly correlates with the introduction of acellular pertussis vaccines (5). These vaccines contain only B. pertussis-derived antigens and confer little to no protection against B. parapertussis (9, 14, 15, 23, 27, 28). Current acellular pertussis vaccines contain some combination of filamentous hemagglutinin, pertactin, and fimbriae 2 and 3, all of which are expressed by both B. pertussis and B. parapertussis, and pertussis toxin, which is B. pertussis specific (33, 34). Based on genome sequences, the levels of amino acid sequence identity between B. pertussis and B. parapertussis filamentous hemagglutinin, pertactin, and fimbria 2 and 3 proteins are about 98, 91, 71, and 92% (35), and antibodies raised against these antigens from B. pertussis cross-react with B. parapertussis (17, 31). However, immunization with purified B. pertussis filamentous hemagglutinin or pertactin does not confer protection against B. parapertussis (17). B. pertussis fimbriae confer some protection against B. parapertussis, but at much lower levels than they protect against B. pertussis (52). Based on these observations and the fact that B. parapertussis infection induces protective immunity to itself (56, 58), we hypothesized that the lack of protective antigens from B. parapertussis may be part of the reason why current whooping cough vaccines are ineffective against this bacterium.Although B. pertussis and B. parapertussis are very closely related (8, 35, 48), they differ in the structure of their lipopolysaccharides (LPS) (1, 2, 39, 40, 47). B. pertussis produces a lipooligosaccharide containing lipid A and a branched-chain core oligosaccharide with a complex trisaccharide modification but lacks the O antigen due to a natural deletion of the wbm locus responsible for its synthesis (39, 47). B. parapertussis LPS is similar to B. pertussis LPS but lacks the trisaccharide modification and includes an O antigen (39, 40). In addition to conferring serum resistance by inhibiting C3 deposition onto the surfaces of bacteria (11), the O antigen enables B. parapertussis to avoid B. pertussis-induced immunity by preventing antibody binding to cross-reactive antigens on the surfaces of B. parapertussis cells (56, 59). Since the O antigen is one dominant surface antigen recognized by B. parapertussis immune sera (56) and has been shown previously to be a protective antigen of various pathogenic bacteria (22, 36), we hypothesized that the O antigen is a protective antigen of B. parapertussis.To assess the role of the O antigen in the generation of an adaptive immune response to B. parapertussis, the immunity and protection generated by B. parapertussis infection or vaccination were compared to those generated by an isogenic mutant of B. parapertussis lacking the O antigen (Δwbm) (39). Animals immunized with B. parapertussis, but not B. parapertussis Δwbm, were protected against subsequent challenge with B. parapertussis. Mice immunized with B. parapertussis Δwbm were also deficient in the production of B. parapertussis-specific antibodies, and sera collected from these mice were less effective at reducing B. parapertussis colonization upon passive transfer than sera raised against B. parapertussis. The inclusion of LPS from B. parapertussis, but not from B. parapertussis Δwbm, rendered the acellular B. pertussis vaccine Adacel efficacious against B. parapertussis challenge. Together, these data indicate that the O antigen is an important protective antigen of B. parapertussis.     

Association of Bordetella pertussis-induced hypersensitivity to serotonin with the H-2 gene complex

Susceptibility to Bordetella pertussis-induced sensitivity to serotonin was found to be associated with the H-2 gene complex in mice. H-2 congenic and independent strains which possess the H-2b and H-2s haplotypes were susceptible to serotonin sensitization by pertussigen (P-HSF) while mice with the H-2k and H-2d haplotypes were resistant. The gene or genes which control susceptibility were found to map to the H-2SbDb end of the H-2 complex; susceptibility appears to be inherited as a co-dominant trait. These findings indicate that HLA typing may be of value in predicting or interpreting possible adverse reactions to pertussis vaccine or infection in humans.     

Nucleotide sequence homology to pertussis toxin gene in Bordetella bronchiseptica and Bordetella parapertussis.

Multiple strains of Bordetella parapertussis and B. bronchiseptica were examined for the presence of nucleotide sequences which hybridized with a cloned 4.5-kilobase (kb) fragment of B. pertussis DNA containing the genes responsible for pertussis toxin expression. All six B. parapertussis strains tested had nucleic acid sequences that hybridized with the cloned 4.5-kb fragment in Southern blot analyses. When the B. parapertussis DNA was digested with restriction endonuclease PstI, the pattern of hybridization was identical to that obtained with B. pertussis. Only five of the seven B. bronchiseptica strains tested had sequences that hybridized with the 4.5-kb fragment. Three of these B. bronchiseptica strains had a hybridization pattern identical to B. pertussis upon PstI digestion and Southern blot analyses. Two B. bronchiseptica strains were shown to lack a PstI cleavage site downstream from the region analogous to that coding for the pertussis toxin structural genes. Monoclonal antibody analyses were unable to detect pertussis toxin subunits S1 and S2 in Western blots with cellular material or culture supernatant from several B. bronchiseptica and B. parapertussis strains that possessed the DNA homologies. In addition, preliminary Northern hybridizations with RNA isolated from B. bronchiseptica and B. parapertussis strains suggested that the homologous regions were not transcribed. The data show that the gene coding for the toxic component of B. pertussis is common in other Bordetella species, though the gene probably is not expressed.     

Role of Bordetella O antigen in respiratory tract infection

Lipopolysaccharide (LPS), as the major surface molecule of gram-negative bacteria, interacts with the host in complex ways, both inducing and protecting against aspects of inflammatory and adaptive immunity. The membrane-distal repeated carbohydrate structure of LPS, the O antigen, can prevent antibody functions and may vary as a mechanism of immune evasion. Genes of the wbm locus are required for the assembly of O antigen on the animal pathogen Bordetella bronchiseptica and the human pathogen B. parapertussis. However, the important human pathogen B. pertussis lacks these genes and a number of in vitro and in vivo characteristics associated with O antigen in other organisms. To determine the specific functions of O antigen in these closely related Bordetella subspecies, we compared wbm deletion (Deltawbm) mutants of B. bronchiseptica and B. parapertussis in a variety of assays relevant to natural respiratory tract infection. Complement was not activated or depleted by wild-type bordetellae expressing O antigen, but both Deltawbm mutants activated complement and were highly sensitive to complement-mediated killing in vitro. Although the O-antigen structures appear to be substantially similar, the two mutants differed strikingly in their defects within the respiratory tract. The B. parapertussis Deltawbm mutant was severely defective in colonization of the tracheas and lungs of mice, while the B. bronchiseptica Deltawbm mutant showed almost no defect. While in vitro characteristics such as serum resistance may be attributable to O antigen directly, the role of O antigen during infection appears to be more complex, possibly involving factors differing among the closely related bordetellae or different interactions between each one and its host.     

Role of antibodies against Bordetella pertussis virulence factors in adherence of Bordetella pertussis and Bordetella parapertussis to human bronchial epithelial cells

Immunization with whole-cell pertussis vaccines (WCV) containing heat-killed Bordetella pertussis cells and with acellular vaccines containing genetically or chemically detoxified pertussis toxin (PT) in combination with filamentous hemagglutinin (FHA), pertactin (Prn), or fimbriae confers protection in humans and animals against B. pertussis infection. In an earlier study we demonstrated that FHA is involved in the adherence of these bacteria to human bronchial epithelial cells. In the present study we investigated whether mouse antibodies directed against B. pertussis FHA, PTg, Prn, and fimbriae, or against two other surface molecules, lipopolysaccharide (LPS) and the 40-kDa outer membrane porin protein (OMP), that are not involved in bacterial adherence, were able to block adherence of B. pertussis and B. parapertussis to human bronchial epithelial cells. All antibodies studied inhibited the adherence of B. pertussis to these epithelial cells and were equally effective in this respect. Only antibodies against LPS and 40-kDa OMP affected the adherence of B. parapertussis to epithelial cells. We conclude that antibodies which recognize surface structures on B. pertussis or on B. parapertussis can inhibit adherence of the bacteria to bronchial epithelial cells, irrespective whether these structures play a role in adherence of the bacteria to these cells.     

Serum immunoglobulin G antibody responses to Bordetella pertussis lipooligosaccharide and B. parapertussis lipopolysaccharide in children with pertussis and parapertussis

Serum immunoglobulin G (IgG) antibodies against the lipooligosaccharide (LOS) of Bordetella pertussis and the lipopolysaccharide (LPS) of Bordetella parapertussis were measured by enzyme-linked immunosorbent assay in paired sera from 40 children with pertussis and 14 with parapertussis. Wide differences in the individual responses were noted. Both anti-LOS and -LPS IgG levels increased significantly in the children with pertussis, as did anti-LPS but not anti-LOS in those with parapertussis.     

Bordetella pertussis-induced impairment of relaxation of rat trachea to isoprenaline and histamine and its reversal with hydrocortisone

Bordetella pertussis vaccination of rats resulted in impairment of relaxation to isoprenaline and histamine of partially contracted tracheal smooth muscle. The concentration range of carbachol (10(-6) to 5 x 10(-6) M) required for contraction (ED50) did not differ from the control group. Pretreatment of vaccinated animals with hydrocortisone was found to reverse the inhibition of spasmolytic activity.     

Role of antibodies in immunity to Bordetella infections

The persistence of Bordetella pertussis and B. parapertussis within vaccinated populations and the reemergence of associated disease highlight the need to better understand protective immunity. The present study examined host immunity to bordetellae and addressed potential concerns about the mouse model by using a comparative approach including the closely related mouse pathogen B. bronchiseptica. As previously observed with B. pertussis, all three organisms persisted throughout the respiratory tracts of B-cell-deficient mice, indicating that B cells are required for bacterial clearance. However, adoptively transferred antibodies rapidly cleared B. bronchiseptica but not human pathogens. These results obtained with the mouse model are consistent with human clinical observations, including the lack of correlation between antibody titers and protection, as well as the limited efficacy of intravenous immunoglobulin treatments against human disease. Together, this evidence suggests that the mouse model accurately reflects substantial differences between immunities to these organisms. Although both B. pertussis and B. parapertussis are more closely related to B. bronchiseptica than they are to each other, they share the ability to resist rapid clearance from the lower respiratory tract by adoptively transferred antibodies, an adaptation that correlates with their emergence as human pathogens that circulate within vaccinated populations.     

Murine lung immunity to a soluble antigen

Although it is known that soluble antigen is immunogenic when deposited in the respiratory tract, less is known about lung immunity to soluble antigen than is known about lung immunity to particulate antigen. To test the hypothesis that soluble antigen triggers antigen-specific immunity in the respiratory tract in a fashion similar to that reported for particulate antigen, we examined the development of local and systemic immunity in C57BL/6 mice after intratracheal (i.t.) instillation of a soluble, large molecular weight protein neoantigen, keyhole limpet hemocyanin (KLH). Specific anti-KLH IgG and IgM first appeared in the sera of mice on day 7 after primary immunization by i.t. instillation of KLH, with specific serum antibody concentrations remaining elevated at day 11. Cell populations prepared from lung-associated lymph nodes of immunized mice released specific anti-KLH IgG and IgM in vitro; peak levels were obtained from cells isolated 7 days after antigen instillation, with levels of specific antibody released by cells isolated on days 9 and 11 decreasing markedly. Cultured spleen cells obtained from mice after primary immunization released only low levels of specific IgM, and no specific IgG. No specific antibody was released by cell populations derived from the lungs of animals undergoing primary immunization. When presensitized mice were given an i.t. challenge with KLH, responses differed markedly from those following primary immunization. Lung-associated lymph node cell populations from challenged mice released greater amounts of specific antibody earlier than did cell populations from mice undergoing primary immunization.(ABSTRACT TRUNCATED AT 250 WORDS)     

Serum Immunoglobulin G Antibody Responses to Bordetella pertussis Lipooligosaccharide and B. parapertussis Lipopolysaccharide in Children with Pertussis and Parapertussis

Serum immunoglobulin G (IgG) antibodies against the lipooligosaccharide (LOS) of Bordetella pertussis and the lipopolysaccharide (LPS) of Bordetella parapertussis were measured by enzyme-linked immunosorbent assay in paired sera from 40 children with pertussis and 14 with parapertussis. Wide differences in the individual responses were noted. Both anti-LOS and -LPS IgG levels increased significantly in the children with pertussis, as did anti-LPS but not anti-LOS in those with parapertussis.     

The calculus of immunity: quantitating antigen processing

Peptide ligands destined for binding MHC class I molecules are generated by the proteasome in the cytoplasm and transported to the endoplasmic reticulum for loading onto newly synthesized class I molecules. A new study now provides a quantitative analysis of how total protein turnover in the cell relates to the efficiency of generating peptide epitopes presented by class I molecules.     

The adenylate cyclase toxin from Bordetella pertussis--a novel promising vehicle for antigen delivery to dendritic cells

Bordetella pertussis secretes an adenylate cyclase toxin (CyaA or ACT) that targets primarily cells expressing the alphaMbeta2 integrin (CD11b/CD18) receptor. This toxin can deliver its N-terminal catalytic AC domain (400 amino acid residues) into the cytosol directly across the cytoplasmic membrane. Various heterologous CD8+, as well as CD4+ T-cell epitopes have been engineered into genetically detoxified CyaA and the resulting toxoids were successfully used as vectors for delivery of inserted epitopes into antigen-presenting cells. Upon processing and presentation, these recombinant CyaAs trigger specific MHC class I and/or class II-restricted T-cell responses both in vitro and in vivo.     

Adjuvant effect of Bordetella pertussis vaccine to sheep erythrocytes in mice: enhancement of cell-mediated immunity by subcutaneous administration of adjuvant and antigen.

The subcutaneous route (s.c.) was used to study the adjuvant effect of Bordetella pertussis vaccine (PV) on cell-mediated immunity to sheep erythorcytes (SRBC). The immune response was measured by a sensitive assay procedure in which the antigen is injected intracutaneously into the mouse ear and the inflammatory swelling is measured with calipers. PV significantly enhanced cell-mediated immunity to SRBC, and the enhancement persisted for at least 3 weeks. PV administered up to 6 days before SRBC also significantly enhanced the response; PV injected 1 or more days after SRBC was not effective. In addition, it was found that PV per se released into the suspension medium a cell-free component(s) (pertussis supernatant) that contributed significantly to adjuvanticity. The adjuvanticity of both PV and PS was completely eliminated by heat.     

Bordetella parapertussis Survives the Innate Interaction with Human Neutrophils by Impairing Bactericidal Trafficking inside the Cell through a Lipid Raft-Dependent Mechanism Mediated by the Lipopolysaccharide O Antigen

Whooping cough is a reemerging disease caused by two closely related pathogens, Bordetella pertussis and Bordetella parapertussis. The incidence of B. parapertussis in whooping cough cases has been increasing since the introduction of acellular pertussis vaccines containing purified antigens that are common to both strains. Recently published results demonstrated that these vaccines do not protect against B. parapertussis due to the presence of the O antigen on the bacterial surface that impairs antibody access to shared antigens. We have investigated the effect of the lack of opsonization of B. parapertussis on the outcome of its interaction with human neutrophils (polymorphonuclear leukocytes [PMNs]). In the absence of opsonic antibodies, PMN interaction with B. parapertussis resulted in nonbactericidal trafficking upon phagocytosis. A high percentage of nonopsonized B. parapertussis was found in nonacidic lysosome marker (lysosome-associated membrane protein [LAMP])-negative phagosomes with access to the host cell-recycling pathway of external nutrients, allowing bacterial survival as determined by intracellular CFU counts. The lipopolysaccharide (LPS) O antigen was found to be involved in directing B. parapertussis to PMN lipid rafts, eventually determining the nonbactericidal fate inside the PMN. IgG opsonization of B. parapertussis drastically changed this interaction by not only inducing efficient PMN phagocytosis but also promoting PMN bacterial killing. These data provide new insights into the immune mechanisms of hosts against B. parapertussis and document the crucial importance of opsonic antibodies in immunity to this pathogen.