Using a murine respiratory challenge model we have previously demonstrated a role for Th1 cells in natural immunity against Bordetella pertussis, but could not rule out a role for antibody. Here we have demonstrated that B. pertussis respiratory infection of mice with targeted disruptions of the genes for the IFN-γ receptor resulted in an atypical disseminated disease which was lethal in a proportion of animals, and was characterized by pyogranulomatous inflammation and postnecrotic scarring in the livers, mesenteric lymph nodes and kidneys. Viable virulent bacteria were detected in the blood and livers of diseased animals. An examination of the course of infection in the lung of IFN-γ receptor–deficient, IL-4–deficient and wild-type mice demonstrated that lack of functional IFN-γ or IL-4, cytokines that are considered to play major roles in regulating the development of Th1 and Th2 cells, respectively, did not affect the kinetics of bacterial elimination from the lung. In contrast, B cell–deficient mice developed a persistent infection and failed to clear the bacteria after aerosol inoculation. These findings demonstrate an absolute requirement for B cells or their products in the resolution of a primary infection with B. pertussis, but also define a critical role for IFN-γ in containing bacteria to the mucosal site of infection.
Recent clinical trials have demonstrated that new generation acellular pertussis vaccines can confer protection against whooping cough. However, the mechanism of protective immunity against Bordetella pertussis infection induced by vaccination remains to be defined. We have examined cellular immune responses in children immunized with a range of acellular and whole cell pertussis vaccines. Immunization of children with a potent whole-cell vaccine induced B. pertussis-specific T cells that secreted interferon-y (IFN-y), but not interleukin-5 (IL-5). In contrast, T cells from children immunized with acellular pertussis vaccines secreted IFN-y and/or IL-5 following stimulation with B. pertussis antigens in vitro. These observations suggest that protective immunity conferred by whole-cell vaccines, like natural immunity, is mediated by type 1 T cells, whereas the mechanism of immune protection generated with acellular vaccines may be more heterogenous, involving T cells that secreted type 1 and type 2 cytokines.
The mechanism of protective immunity against Bordetella pertussis generated following recovery from whooping cough in childhood has not yet been elucidated. Studies with a murine respiratory infection model have indicated that cellular immunity, mediated by Th1 cells, plays a role in the clearance of a primary infection with B. pertussis and in protection against subsequent challenge. In the present study, the induction of B. pertussis-specific Th cell subsets in children was examined. Peripheral blood mononuclear cells from B. pertussis-infected or convalescent children proliferated and secreted cytokines following antigen stimulation in vitro. In contrast, responses were weak or undetectable in the majority of children who had not been infected or vaccinated. In all cases, responding T cells produced interferon-gamma but low or undetectable interleukin-5. The findings suggest that Th1 cells may play a role in protective immunity generated following infection with B. pertussis in children.
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