Longitudinal evaluation of serovar-specific immunity to Neisseria gonorrhoeae.
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The serovars of Neisseria gonorrhoeae that are predominant in a community change over time, a phenomenon that may be due to the development of immunity to repeat infection with the same serovar. This study evaluated the epidemiologic evidence for serovar-specific immunity to N. gonorrhoeae. During a 17-month period in 1992-1994, all clients of a sexually transmitted disease clinic in rural North Carolina underwent genital culture for N. gonorrhoeae. Gonococcal isolates were serotyped according to standard methods. Odds ratios for repeat infection with the same serovar versus any different serovar were calculated on the basis of the distribution of serovars in the community at the time of reinfection. Of 2,838 patients, 608 (21.4%; 427 males and 181 females) were found to be infected with N. gonorrhoeae at the initial visit. Ninety patients (14.8% of the 608) had a total of 112 repeat gonococcal infections. Repeat infection with the same serovar occurred slightly more often than would be expected based on the serovars prevalent in the community at the time of reinfection, though the result was marginally nonsignificant (odds ratio = 1.5, 95% confidence interval 1.0-2.4; p = 0.05). Choosing partners within a sexual network may increase the likelihood of repeat exposure to the same serovar of N. gonorrhoeae. Gonococcal infection did not induce evident immunity to reinfection with the same serovar. (+info)
Absolute requirement for an active immune response involving B cells and Th cells in immunity to Plasmodium yoelii passively acquired with antibodies to the 19-kDa carboxyl-terminal fragment of merozoite surface protein-1.
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Vaccination of mice with the leading malaria vaccine candidate homologue, the 19-kDa carboxyl terminus of merozoite surface protein-1 (MSP119), results in sterile immunity to Plasmodium yoelii, with no parasites detected in blood. Although such immunity depends upon high titer Abs at challenge, high doses of immune sera transferred into naive mice reduce parasitemia (and protect from death) but do not result in a similar degree of protection (with most mice experiencing high peak parasitemias); this finding suggests that ongoing parasite-specific immune responses postchallenge are essential. We analyzed this postchallenge response by transferring Abs into manipulated but malaria-naive mice and observed that Abs cannot protect SCID, nude, CD4+ T cell-depleted, or B cell knockout mice, with all mice dying. Thus, in addition to the Abs that develop following MSP119 vaccination, a continuing active immune response postchallenge is required for protection. MSP119-specific Abs can adoptively transfer protection to strains of mice that are not protected following vaccination with MSP119, suggesting that the Ags targeted by the immune response postchallenge include Ags apart from MSP119. These data have important implications for the development of a human malaria vaccine. (+info)
Protective immunity induced in mice by immunization with high-molecular-weight polysaccharide from Pseudomonas aeruginosa.
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A high-molecular-weight alkali-labile polysaccharide (PS) isolated from the slime of immunotype 1 Pseudomonas aeruginosa was tested for its ability to protect mice from lethal challenge with the live, homologous organism. Intraperitoneal (i.p.) injection of 10 to 25 microgram of the PS protected 60 to 70% of the mice against challenge with up to 50 50% lethal dose units. Although single immunization of mice with up to 250 microgram of PS effected protective levels of only 70%, two successive immunizations provided 100% protection. Subcutaneous and intravenous immunization with PS also provided protection to i.p. challenges with immunotype 1 P. aeruginosa, but not to i.p. challenge with immunotype 4 P. aeruginosa. Although lipopolysaccharide (LPS) was found to be more immunogenic than PS in out studies, contamination of the alkali-labile PS with LPS did not account for the protection seen. Alkali treatment (0.1 N NaOH, 37 degrees C, 2 h) of the PS destroyed its protective effectiveness, while similarly treated LPS retained its capacity for inducing immunity in mice. Adsorption and passive protection studies with sera raised to either PS or a mixture of PS and LPS indicated that antibody directed to the alkali-labile PS antigen was capable of contributing to the protection of mice against challenge with P. aeruginosa. (+info)
Protective immunity using recombinant human IL-12 and alum as adjuvants in a primate model of cutaneous leishmaniasis.
(4/500)
Protection from cutaneous leishmaniasis, a chronic ulcerating skin lesion affecting millions, has been achieved historically using live virulent preparations of the parasite. Killed or recombinant Ags that could be safer as vaccines generally require an adjuvant for induction of a strong Th1 response in murine models. Murine rIL-12 as an adjuvant with soluble Leishmania Ag has been shown to protect susceptible mice. We used 48 rhesus macaques to assess the safety, immunogenicity, and efficacy of a vaccine combining heat-killed Leishmania amazonensis with human rIL-12 (rhIL-12) and alum (aluminum hydroxide gel) as adjuvants. The single s.c. vaccination was found to be safe and immunogenic, although a small transient s.c. nodule developed at the site. Groups receiving rhIL-12 had an augmented in vitro Ag-specific IFN-gamma response after vaccination, as well as increased production of IgG. No increase in IL-4 or IL-10 was found in cell culture supernatants from either control or experimental groups. Delayed hypersensitivity reactions were not predictive of protection. Intradermal forehead challenge infection with 107 metacyclic L. amazonensis promastigotes at 4 wk demonstrated protective immunity in all 12 monkeys receiving 2 microgram rhIL-12 with alum and Ag. Partial efficacy was seen with lower doses of rhIL-12 and in groups lacking either adjuvant. Thus, a single dose vaccine with killed Ag using rhIL-12 and alum as adjuvants was safe and fully effective in this primate model of cutaneous leishmaniasis. This study extends the murine data to primates, and provides a basis for further human trials. (+info)
TNF is essential for the cell-mediated protective immunity induced by the radiation-attenuated schistosome vaccine.
(5/500)
C57BL/6 mice exposed to the radiation-attenuated schistosome vaccine exhibit high levels of protective immunity. The cell-mediated pulmonary effector mechanism involves IFN-gamma-producing CD4+ T cells in a focal response around challenge larvae. IFN-gamma can promote production of TNF and can synergize with this cytokine in its actions on responder cells. We have examined whether TNF plays a role in lung phase immunity to schistosomes using mice with a disrupted gene for TNFRI (TNFRI-/-). The most dramatic finding was that the schistosome vaccine elicited no protection whatsoever in these mice. However, this could not be attributed to a lack of responder cells, because more lymphocytes were lavaged from the airways of TNFRI-/- than wild-type mice. Furthermore, CD4+ T cells were equally represented in airway populations from the two groups and produced IFN-gamma upon Ag stimulation in vitro. In contrast, pulmonary macrophage function was defective in TNFRI-/- mice, as indicated by a failure to up-regulate inducible NO synthase mRNA. Histopathological analysis revealed that focal infiltrates were of similar size and cell composition in the two groups but that more parasites were free of foci in the TNFRI-/- mice. These animals had a greatly impaired IgG response to schistosomes, which may explain their lack of residual protection due to Ab in a situation where cell-mediated immunity is disabled. We suggest that the absence of protective immunity could result from a retarded build-up of leukocytes around migrating lung worms and/or a deficit in accessory cell function within a focus, both of which would permit parasite escape. (+info)
Contribution of adjuvant to adaptive immune responses in mice against Actinobacillus pleuropneumoniae.
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The authors have previously demonstrated that adjuvant-mediated differences in early cellular responses to antigens significantly affect subsequent adaptive immune responses. To investigate further the contribution of adjuvant to adaptive immune responses, outer-membrane proteins (OMP) purified from the respiratory pathogen Actinobacillus pleuropneumoniae, given either alone (antigen group) or complexed with SAMA4 (vaccine group), were injected intradermally into groups of mice. Controls were given PBS. Inclusion of adjuvant did not significantly alter the kinetics of antibody responses against OMP in serum or respiratory tract washings (RTW) over 21 weeks. Re-exposure to OMP at 21 weeks also induced identical recall responses in both immunized groups. However, differences between the responses of the vaccine and antigen groups were apparent when sera and RTW were reacted against OMP and OMP-derived polysaccharide antigens (ODPA). Serum and RTW reactivity against protein antigens was stronger in the vaccine group than in the antigen group. Serum and RTW from the vaccine group also reacted against a greater number of proteins than did the antigen group. Although serum reactivity against ODPA was equivalent for both groups, RTW from the vaccine group reacted only faintly against ODPA compared with the antigen group. The results suggested that shifting of antibody reactivity away from polysaccharide antigens toward protein antigens was an adjuvant-mediated effect. The rapid death of controls following intranasal inoculation confirmed that protection was ultimately dependent on the presence of specific antibodies in the serum and respiratory tract. However, since both groups responded equally to intranasal infection with A. pleuropneumoniae, as seen by the rapid clearance of bacteria from the lungs, the biological significance of any differences between the groups was unclear. Knowledge of the effects of adjuvants may provide a rational basis for adjuvant selection and the ability to manipulate immunological outcomes more precisely. (+info)
Beta-defensins: linking innate and adaptive immunity through dendritic and T cell CCR6.
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Defensins contribute to host defense by disrupting the cytoplasmic membrane of microorganisms. This report shows that human beta-defensins are also chemotactic for immature dendritic cells and memory T cells. Human beta-defensin was selectively chemotactic for cells stably transfected to express human CCR6, a chemokine receptor preferentially expressed by immature dendritic cells and memory T cells. The beta-defensin-induced chemotaxis was sensitive to pertussis toxin and inhibited by antibodies to CCR6. The binding of iodinated LARC, the chemokine ligand for CCR6, to CCR6-transfected cells was competitively displaced by beta-defensin. Thus, beta-defensins may promote adaptive immune responses by recruiting dendritic and T cells to the site of microbial invasion through interaction with CCR6. (+info)
Dendritic cells at the end of the millennium.
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We have recently proposed a dual role for dendritic cells (DC) in the amplification of innate immune responses and in the activation of adaptive immune responses. The DC are localized along the major routes of entry of micro-organisms, where they perform a sentinel function for incoming pathogens. Soon after interaction with appropriate stimuli, DC undergo a coordinated process of maturation and respond to danger signals by re- programming their functions. The DC first regulate leucocyte recruitment at the site of inflammation, through the production of chemokines, inflammatory cytokines and interferons, and then they acquire migratory properties and undergo a rapid switch in chemokine receptor expression. This allows them to leave the inflamed tissue and to reach the lymph node T cell area. During this migration, DC complete their maturation process and acquire the ability to prime T cell responses. Thus, DC bridge innate and adaptive immunity. (+info)