Association between plasma antibody response and protection in rainbow trout Oncorhynchus mykiss immersion vaccinated against Yersinia ruckeri

A key hallmark of the vertebrate adaptive immune system is the generation of antigen-specific antibodies from B cells. Fish are the most primitive gnathostomes (jawed vertebrates) possessing an adaptive immune system. Vaccination of rainbow trout against enteric redmouth disease (ERM) by immersion in Yersinia ruckeri bacterin confers a high degree of protection to the fish. The immune mechanisms responsible for protection may comprise both cellular and humoral elements but the role of specific immunoglobulins in this system has been questioned and not previously described. The present study demonstrates significant increase in plasma antibody titers following immersion vaccination and significantly reduced mortality during Y. ruckeri challenge.Rainbow trout were immersion-vaccinated, using either a commercial ERM vaccine (AquaVac™ ERM vet) or an experimental Y. ruckeri bacterin. Half of the trout vaccinated with AquaVac™ ERM vet received an oral booster (AquaVac™ ERM Oral vet). Sub-groups of the fish from each group were subsequently exposed to 1x10⁹ CFU Y. ruckeri/ml either eight or twenty-six weeks post vaccination (wpv). All vaccinated groups showed 0% mortality when challenged, which was highly significant compared to the non-vaccinated controls (40 and 28% mortality eight and twenty-six weeks post vaccination (wpv), respectively) (P<0.0001). Plasma samples from all groups of vaccinated fish were taken 0, 4, 8, 12, 16 and 26 wpv. and Y. ruckeri specific IgM antibody levels were measured with ELISA. A significant increase in titers was recorded in vaccinated fish, which also showed a reduced bacteremia during challenge. In vitro plasma studies showed a significantly increased bactericidal effect of fresh plasma from vaccinated fish indicating that plasma proteins may play a role in protection of vaccinated rainbow trout.     

Cellular and humoral immunity against vaccinia virus infection of mice

Despite the widespread use of vaccinia virus (VV) as a vector for other Ags and as the smallpox vaccine, there is little information available about the protective components of the immune response following VV infection. In this study, protection against wild-type VV was evaluated in mice with respect to the relative contributions of CD8(+) T cells vs that of CD4(+) T cells and Ab. C57BL/6 mice primed with the Western Reserve strain of VV mount significant IgM and IgG Ab responses, specific cytotoxic T cell responses, IFN-gamma responses in CD4(+) and CD8(+) T cells, and effectively clear the virus. This protection was abrogated by in vivo depletion of CD4(+) T cells or B cells in IgH(-/-) mice, but was not sensitive to CD8(+) T cell depletion alone. However, a role for CD8(+) T cells in primary protection was demonstrated in MHC class II(-/-) mice, where depleting CD8(+) T cells lead to increase severity of disease. Unlike control MHC class II(-/-) mice, the group depleted of CD8(+) T cells developed skin lesions on the tail and feet and had adrenal necrosis. Adoptive transfer experiments also show CD8(+) T cells can mediate protective memory. These results collectively show that both CD4(+) and CD8(+) T cell-mediated immunity can contribute to protection against VV infection. However, CD4(+) T cell-dependent anti-virus Ab production plays a more important role in clearing virus following acute infection, while in the absence of Ab, CD8(+) T cells can contribute to protection against disease.     

Cell-mediated and humoral immunity in mice: cross reaction between lysozyme and S-carboxymethylated lysozyme studied by a modified footpad test.

The mouse sensitized by subcutaneous (sc) injection of lysozyme in emulsion of Freund's complete adjuvant (FCA) was shown by a modified footpad test to develop three kinds of hypersensitivities. Injecting lysozyme in 2.5-mul emulsion of Freund's incomplete adjuvant (FIA) into the footpad elicited strong footpad swelling in 30 min (anaphylactic reaction), in 3 hr (Arthus-type reaction) and in 24 hr (delayed-type hypersensitivity; DTH). The mice showing anaphylactic reaction in the footpad test manifested severe active systemic anaphylaxis, and the sera of these animals showed high IgG1 antibody titers with only sparingly detectable or no IgE antibody titers. In the sensitizing system with the use of FCA, the antigenicity of S-carboxymethylated lysozyme (CM-lysozyme) devoid of the three-dimensional conformation of lysozyme was compared with that of the native molecule. CM-lysozyme and lysozyme completely cross-reacted to each other in DTH, but not at all in the anaphylactic or Arthus-type reaction or in IgG1 antibody production. CM-lysozyme was shown also to have the ability to bestow immunological memory for the induction of humoral immunity against lysozyme; intravenous (iv) injection of lysozyme in saline or sc injection of CM-lysozyme-FCA alone failed to induce immediate hypersensitivities and IgG1 antibody production against lysozyme, but pre-sensitization by sc injection of CM-lysozyme-FCA enabled the animal to induce these responses to significant levels when iv injection of lysozyme in saline was given as a booster.     

Induced humoral immunity and vaccination against major human fungal pathogens

Protection against fungal pathogens can theoretically be elicited by vaccines that stimulate humoral or cellular immunity, or both. There is conclusive evidence that humoral immunity can modify the course of infection against certain pathogenic fungi such as Candida albicans and Cryptococcus neoformans. However, for other fungi, such as Aspergillus fumigatus, the notion that humoral immunity contributes to host defence is unproven. Attempts to evaluate the potential efficacy of humoral immunity using immune sera are often inconclusive, whereas consistent results can be obtained with monoclonal antibodies. Protective monoclonal antibodies can be used to identify antigens that induce useful humoral responses.     

Systemic antitumor protection by vascular-targeted photodynamic therapy involves cellular and humoral immunity

Vascular-targeted photodynamic therapy (VTP) takes advantage of intravascular excitation of a photosensitizer (PS) to produce cytotoxic reactive oxygen species (ROS). These ROS are potent mediators of vascular damage inducing rapid local thrombus formation, vascular occlusion, and tissue hypoxia. This light-controlled process is used for the eradication of solid tumors with Pd-bacteriochlorophyll derivatives (Bchl) as PS. Unlike classical photodynamic therapy (PDT), cancer cells are not the primary target for VTP but instead are destroyed by treatment-induced oxygen deprivation. VTP initiates acute local inflammation inside the illuminated area accompanied by massive tumor tissue death. Consequently, in the present study, we addressed the possibility of immune response induction by the treatment that may be considered as an integral part of the mechanism of VTP-mediated tumor eradication. The effect of VTP on the host immune system was investigated using WST11, which is now in phase II clinical trials for age-related macular degeneration and intended to be evaluated for cancer therapy. We found that a functional immune system is essential for successful VTP. Long-lasting systemic antitumor immunity was induced by VTP involving both cellular and humoral components. The antitumor effect was cross-protective against mismatched tumors, suggesting VTP-mediated production of overlapping tumor antigens, possibly from endothelial origin. Based on our findings we suggest that local VTP might be utilized in combination with other anticancer therapies (e.g., immunotherapy) for the enhancement of host antitumor immunity in the treatment of both local and disseminated disease. Y.S. and A.S are the incumbents of the Tillie and Charles Lubin Professorial Chair in Biochemical Endocrinology, and the Robert and Yaddele Sklare Professorial Chair in Biochemistry, respectively. S.J. is the incumbent of the Pauline Recanati Career Development Chair. D.P. in partial fulfillment of her PhD Thesis requirements at the Feinberg graduate school of the Weizmann Institute of Science.     

Mechanisms of antibody-mediated protection against lymphocytic choriomeningitis virus infection: mother-to-baby transfer of humoral protection.

The role of antiviral antibodies in resistance to lymphocytic choriomeningitis virus (LCMV) infection was explored. Immune serum and monoclonal antibodies prevented fatal T-cell-mediated immunopathology following acute LCMV infections. In addition, 10- and 14-day-old mice that received maternally derived anti-LCMV antibodies through nursing were protected from an otherwise lethal LCMV challenge. Detailed investigation of the mechanism(s) by which these antiviral antibodies provided was carried out by using anti-LCMV monoclonal antibodies. Protection correlated directly with the ability of the antibodies to reduce viral titers in the tissues of conventional (K. E. Wright and M. J. Buchmeier, J. Virol. 65:3001-3006, 1991) and nude mice. However, this reduction was not simply a reflection of virus neutralizing activity, since not all antibodies which neutralized in vitro were protective. A correlation was also found between immunoglobulin isotype and protection: all of the protective antibodies were immunoglobulin G2a (IgG2a), while IgG1 antibodies mapping to the same epitopes were not. Protection appeared to be associated with events controlled by the Fc region. Functional F(ab')2 fragments which retained in vitro neutralizing activity were not protective in vivo. Furthermore, this Fc-associated function was not related to complement-mediated cell lysis, since C5-deficient mouse strains were also protected. These results suggest a role for antibody in protection from arenavirus infections and indicate that a distinct immunoglobulin subclass, IgG2a, may be essential for this protection.     

Interaction of immunoglobulins with charged biopolymers: significance in the regulation of humoral immunity

When subjected to ion exchange chromatography on QAE-Sephadex A-50 or gel filtration of Sephadex G-200 under conditions that cause the dissociation of immune complexes at pH 4.05, immunoglobulins both from serum and its immunoglobulin fraction increase their interaction with charged antigens as native DNA and cardiolipin. Ion exchange chromatography also leads to the deaggregation of complexes. It was demonstrated that immunoglobulins bind DNA molecule through its F(ab)2 fragments. Based on data obtained, the suggestion was made that interaction between immunoglobulins and charged serum biopolymers is an important factor in humoral immunity regulation. Namely, high specificity of immunological reactions may be supported by elimination of non-specific binding provided electrostatic interactions from all the potential spectrum of antigen-antibody reactions.     

Intranasal Immunization with Yersinia enterocolitica O:8 Cellular Extract Protects against Local Challenge Infection

Yersinia enterocolitica is enteropathogenic for humans and rodents. Immune protection from oral and respiratory pathogens may be most effectively elicited following intranasal (i.n.) vaccination. An experimental murine intranasal challenge model was used to evaluate the immunogenicity of a Y. enterocolitica O:8 cellular extract (CE) in mucosa. This antigenic preparation has demonstrated to induce protection by subcutaneous immunization. Mice were immunized intranasally with two doses of CE. Immunized and nonimmunized animals were challenged with 5×10⁶ colony-forming units (CFU) by nasal infection. Antibodies in serum and bronchoalveolar lavage (b.a.l.) fluid were assessed before and 48 hr after challenge. The CFU were determined by analysis of lung homogenate samples. The CE immunization induced significant b.a.l.-specific IgA and IgG, and serum-specific IgG, IgA and IgM. Histopathological studies 24 and 48 hr postchallenge demonstrated that immunization protected against progressive lesions resulting from Y. enterocolitica invasion of the pulmonary mucosa. The CFU in the lungs showed that CE immunization led to significant clearance as compared to the bacterial level in nonimmunized controls. From the results obtained, it can be concluded that CE can induce local and systemic immunity and protect against nasal infection.     

Global stability of models of humoral immunity against multiple viral strains

We analyse, from a mathematical point of view, the global stability of equilibria for models describing the interaction between infectious agents and humoral immunity. We consider the models that contain the variables of pathogens explicitly. The first model considers the situation where only a single strain exists. For the single strain model, the disease steady state is globally asymptotically stable if the basic reproductive ratio is greater than one. The other models consider the situations where multiple strains exist. For the multi-strain models, the disease steady state is globally asymptotically stable. In the model that does not explicitly contain an immune variable, only one strain with the maximum basic reproductive ratio can survive at the steady state. However, in our models explicitly involving the immune system, multiple strains coexist at the steady state.     

Multilocus Electrophoretic Assessment of the Genetic Structure and Diversity of Yersinia ruckeri

Multilocus isoenzyme electrophoresis was used to screen 47 field isolates of Yersinia ruckeri for electrophoretic variation at 15 enzyme loci. Only four electrophoretic types were observed, thus indicating that the genetic structure of Y. ruckeri is clonal. Forty-two isolates were of one electrophoretic type, a reflection of the low amount of genetic diversity extant in this species. Although sorbitol fermentation has been considered to be indicative of a second biotype, no significant gene frequency differences were found between the group of 20 isolates that readily used sorbitol as the sole carbon source and the group of 27 that did not.     

Interaction between cytokines and 8-mercaptoguanosine in humoral immunity: synergy with interferon

In previous studies it has been demonstrated that a T cell-like differentiation signal is transmitted by C8-substituted guanine ribonucleosides such as 8-mercaptoguanosine (8MGuo) to antigen-stimulated B cells. A large subset of potentially reactive B cells remains unresponsive to antigen even in the presence of signals provided by these nucleosides except when this signal is preceded by a soluble activity present in mixed lymphocyte culture supernatants. Studies with purified preparations of interleukin (IL)-1, IL-2, IL-3, granulocyte-macrophage colony stimulating factor, B cell stimulatory factor 1 (IL-4), and B cell growth factor II (IL-5) indicated that none of these activities is capable of synergizing with 8MGuo to augment B cell responsiveness to antigen. Therefore, supernatants from a number of cloned cell lines were examined for activity that could synergize with 8MGuo, in order to determine the cellular source of this activity. Soluble products secreted by cloned 24/G1 T cells act synergistically with 8MGuo to evoke enhanced antibody responses to specific antigen in populations of purified B cells. Because concanavalin (Con) A-activated 24/G1 cells produce large quantities of interferon-gamma (IFN-gamma), the possibility that interferons might mediate synergy with 8MGuo was investigated. Purified murine IFN-gamma is unable to interact synergistically with 8MGuo; moreover, treatment of active 24/G1 supernatants with monoclonal anti-IFN-gamma antibodies or at pH 2 fails to abrogate their ability to synergize. In contrast to IFN-gamma, when B cells were supplemented with either IFN-alpha or IFN-beta, antigen-dependent synergy with 8MGuo was observed. However, abrogation of IFN-alpha and IFN-beta activity with specific antibodies fails to interfere with synergy between 8MGuo and mixed lymphocyte culture or Con A supernatants. Therefore, it appears that although IFN-alpha and IFN-beta are not responsible for the synergizing activity present in activated T cell supernatants, they nonetheless represent a previously unrecognized source of synergizing activity.     

Immunization with MIC1 and MIC4 induces protective immunity against Toxoplasma gondii

Host cell invasion by Toxoplasma gondii is tightly coupled to the apical release of micronemal proteins (MIC). In this work, we evaluated the protective effect encountered in C57BL/6 mice immunized with MIC1 and MIC4 purified from soluble tachyzoite antigens by affinity to immobilized lactose. The immunized mice presented high serum levels of IgG1 and IgG2b specific antibodies. MIC1/4-stimulated spleen cells from immunized mice produced IL-2, IL-12, IFN-gamma, IL-10, but not IL-4, suggesting the induction of a polarized Th1 type immune response. When orally challenged with 40 cysts of the ME49 strain, the immunized mice had 68% fewer brain cysts than the control mice. Immunization was associated with 80% survival of the mice challenged with 80 cysts, contrasting with 100% mortality of the non-immunized mice in the acute phase. In this phase, there was much lower parasitism in the lungs and small intestine of the immunized mice, and they did not exhibit the early-stage signs of intestinal necrosis, which was clearly detected in the control mice. Our data demonstrate that MIC1 and MIC4 triggered a protective response against toxoplasmosis, and that these antigens are targets for the further development of a vaccine.     

A dam mutant of Yersinia pestis is attenuated and induces protection against plague

We have constructed a dam mutant of Yersinia pestis GB. In BALB/c mice inoculated subcutaneously, the median lethal dose of the mutant was at least 2000-fold higher than the wild type. Mice inoculated with sub-lethal doses of the mutant were protected against a subsequent challenge with virulent Y. pestis. The effect of dam inactivation on gene expression was examined using a DNA microarray, which revealed increased expression of a number of genes associated with the SOS response. These results confirm the key role of Dam in the regulation of virulence, and its potential role as a target for the generation of attenuated strains of pathogenic bacteria.