Specific Humoral Immunity versus Polyclonal B Cell Activation in Trypanosoma cruzi Infection of Susceptible and Resistant Mice

Background

The etiologic agent of Chagas Disease is Trypanosoma cruzi. Acute infection results in patent parasitemia and polyclonal lymphocyte activation. Polyclonal B cell activation associated with hypergammaglobulinemia and delayed specific humoral immunity has been reported during T. cruzi infection in experimental mouse models. Based on preliminary data from our laboratory we hypothesized that variances in susceptibility to T. cruzi infections in murine strains is related to differences in the ability to mount parasite-specific humoral responses rather than polyclonal B cell activation during acute infection.

Methodology/Principal Findings

Relatively susceptible Balb/c and resistant C57Bl/6 mice were inoculated with doses of parasite that led to similar timing and magnitude of initial parasitemia. Longitudinal analysis of parasite-specific and total circulating antibody levels during acute infection demonstrated that C57Bl/6 mice developed parasite-specific antibody responses by 2 weeks post-infection with little evidence of polyclonal B cell activation. The humoral response in C57Bl/6 mice was associated with differential activation of B cells and expansion of splenic CD21^highCD23^low Marginal Zone (MZ) like B cells that coincided with parasite-specific antibody secreting cell (ASC) development in the spleen. In contrast, susceptible Balb/c mice demonstrated early activation of B cells and early expansion of MZ B cells that preceded high levels of ASC without apparent parasite-specific ASC formation. Cytokine analysis demonstrated that the specific humoral response in the resistant C57Bl/6 mice was associated with early T-cell helper type 1 (Th1) cytokine response, whereas polyclonal B cell activation in the susceptible Balb/c mice was associated with sustained Th2 responses and delayed Th1 cytokine production. The effect of Th cell bias was further demonstrated by differential total and parasite-specific antibody isotype responses in susceptible versus resistant mice. T cell activation and expansion were associated with parasite-specific humoral responses in the resistant C57Bl/6 mice.

Conclusions/Significance

The results of this study indicate that resistant C57Bl/6 mice had improved parasite-specific humoral responses that were associated with decreased polyclonal B cell activation. In general, Th2 cytokine responses are associated with improved antibody response. But in the context of parasite infection, this study shows that Th2 cytokine responses were associated with amplified polyclonal B cell activation and diminished specific humoral immunity. These results demonstrate that polyclonal B cell activation during acute experimental Chagas disease is not a generalized response and suggest that the nature of humoral immunity during T. cruzi infection contributes to host susceptibility.     

Basophils amplify type 2 immune responses, but do not serve a protective role, during chronic infection of mice with the filarial nematode Litomosoides sigmodontis

Chronic helminth infections induce a type 2 immune response characterized by eosinophilia, high levels of IgE, and increased T cell production of type 2 cytokines. Because basophils have been shown to be substantial contributors of IL-4 in helminth infections, and because basophils are capable of inducing Th2 differentiation of CD4(+) T cells and IgE isotype switching in B cells, we hypothesized that basophils function to amplify type 2 immune responses in chronic helminth infection. To test this, we evaluated basophil function using the Litomosoides sigmodontis filaria model of chronic helminth infection in BALB/c mice. Time-course studies showed that eosinophilia, parasite Ag-specific CD4(+) T cell production of IL-4 and IL-5 and basophil activation and IL-4 production in response to parasite Ag all peak late (6-8 wk) in the course of L. sigmodontis infection, after parasite-specific IgE has become detectable. Mixed-gender and single-sex worm implantation experiments demonstrated that the relatively late peak of these responses was not dependent on the appearance of circulating microfilariae, but may be due to initial low levels of parasite Ag load and/or habitation of the developing worms in the pleural space. Depletion of basophils throughout the course of L. sigmodontis infection caused significant decreases in total and parasite-specific IgE, eosinophilia, and parasite Ag-driven CD4(+) T cell proliferation and IL-4 production, but did not alter total worm numbers. These results demonstrate that basophils amplify type 2 immune responses, but do not serve a protective role, in chronic infection of mice with the filarial nematode L. sigmodontis.     

An analysis of in vitro B cell immune responsiveness in human lymphatic filariasis

The immunoregulatory mechanisms involved in B cell function in patients with varying clinical manifestations of bancroftian filariasis were examined by studying the ability of peripheral blood mononuclear cells (PBMC) or PBMC subpopulations from patients with elephantiasis, asymptomatic microfilaremia (MF), and acute tropical pulmonary eosinophilia (TPE) to produce polyclonal and parasite-specific antibody in vitro, both spontaneously and in response to a mitogen (PWM) and to parasite antigen. When the spontaneous or mitogen-driven polyclonal responses were examined, all groups produced significant amounts of IgM and IgG; those with TPE produced extremely high levels. However, when in vitro parasite antigen-specific responses were examined, those with MF were unable to produce filaria-specific antibody either spontaneously or in response to PWM or parasite antigen; in contrast, patients with chronic lymphatic obstruction or TPE produced large quantities. Removal of neither adherent cells nor T8+ T cells affected the parasite-specific B cell anergy seen in those with MF. This absent or severely diminished capacity to produce antibody on parasite antigenic stimulation in patients with MF is likely responsible for the low levels of parasite-specific antibody seen in this most common clinical manifestation of bancroftian filariasis. Its inability to be reversed by the removal of "suppressor elements" suggests a state of B cell unresponsiveness to the parasite.     

Density-dependent immune responses against the gastrointestinal nematode Strongyloides ratti

Negative density-dependent effects on the fitness of parasite populations are an important force in their population dynamics. For the parasitic nematode Strongyloides ratti, density-dependent fitness effects require the rat host immune response. By analysis of both measurements of components of parasite fitness and of the host immune response to different doses of S. ratti infection, we have identified specific parts of the host immune response underlying the negative density-dependent effects on the fitness of S. ratti. The host immune response changes both qualitatively from an inflammatory Th1- to a Th2-type immune profile and the Th2-type response increases quantitatively, as the density of S. ratti infection increases. Parasite survivorship was significantly negatively related to the concentration of parasite-specific IgG(1) and IgA, whereas parasite fecundity was significantly negatively related to the concentration of IgA only.     

The roles of IL-10 and TGF-beta in controlling IL-4 and IFN-gamma production during experimental Fasciola hepatica infection

Hosts infected with Fasciola hepatica experience immunosuppression during the acute and chronic phases of the disease. This immunosuppression may allow parasite survival in the face of an ongoing immune response. In bovine hosts early IL-4 and continued IgG1 production is one of the few remaining features of the characteristic type 0/2 helper (Th0/2) response present in the chronic stage of disease. Here we demonstrate elevated levels of parasite-specific, in vitro peripheral blood mononuclear cell (PBMC)-derived transforming growth factor (TGF)-β1 from the early phases of infection and increasing levels of IL-10 as the infection becomes chronic. In vitro neutralisation of these cytokines during culture of PBMCs from experimentally-infected cattle increased IL-4 and IFN-γ production in response to parasite-specific and non-specific stimulation. At 4 weeks p.i. neutralisation of TGF-β results in an increase in parasite driven IL-4, while also having a greater role, compared with IL-10, in influencing specific and non-specific IFN-γ. At 12 weeks p.i. ex vivo parasite driven IL-4 was not restored by inhibiting either IL-10 or TGF-β. However IL-10 influenced both parasite-specific and non-specific IFN-γ production at this time. This highlights the roles of IL-10 and TGF-β in fasciolosis, however the cellular sources of these have yet to be defined. This suggests that suppression of IFN-γ production by parasite molecules occurs during infection and it is possible that the suppression of IFN-γ production may mediate parasite survival in this disease.     

Maternally derived anti-helminth antibodies predict offspring survival in a wild mammal

The transfer of antibodies from mother to offspring provides crucial protection against infection to offspring during early life in humans and domestic and laboratory animals. However, few studies have tested the consequences of variation in maternal antibody transfer for offspring fitness in the wild. Further, separating the immunoprotective effects of antibodies from their association with nutritional resources provided by mothers is difficult. Here, we measured plasma levels of total and parasite-specific antibodies in neonatal (less than 10 days old) wild Soay sheep over 25 years to quantify variation in maternal antibody transfer and test its association with offspring survival. Maternal antibody transfer was predicted by maternal age and previous antibody responses, and was consistent within mothers across years. Neonatal total IgG antibody levels were positively related to early growth, suggesting they reflected nutritional transfer. Neonatal parasite-specific IgG levels positively predicted first-year survival, independent of lamb weight, total IgG levels and subsequent lamb parasite-specific antibody levels. This relationship was partly mediated via an indirect negative association with parasite burden. We show that among-female variation in maternal antibody transfer can have long-term effects on offspring growth, parasite burden and fitness in the wild, and is likely to impact naturally occurring host–parasite dynamics.     

In vitro parasite antigen-induced antibody responses in human helminth infections

Helminth parasites characteristically induce vigorous antibody responses in human infections, but the immunoregulatory mechanisms determining the level of these responses are not at all understood. To investigate these mechanisms, peripheral blood mononuclear cells were obtained from 10 patients with parasitic helminth infections (three with schistosomiasis, three with onchocerciasis, and four with loiasis), along with six normal controls. These cells were then cultured in vitro and the capacity of the cells to respond to a specific parasite antigenic stimulus was examined by measuring the amount of parasite-specific antibody produced. Parasite antigen alone, without exogenous mitogen, induced an IgG anti-parasite antibody response in vitro. Optimal responses were obtained at extremely low antigen concentrations--concentrations at which little if any polyclonal immunoglobulin production occurred. Additionally, the in vitro induction of parasite-specific antibody was antigen dose-dependent, requiring much lower antigen concentrations than those necessary to induce lymphocyte blastogenesis. Antibody production was shown to require the cooperative interaction of B and T cells. These studies demonstrate that in vitro responses to antigens from naturally acquired parasitic infections, like those in individuals postimmunization, can be utilized to dissect the cellular and humoral factors that regulate antibody production to naturally acquired human pathogens.     

Differential roles of the co-stimulatory molecules GITR and CTLA-4 in the immune response to Trichinella spiralis

We investigated the roles of the regulatory molecules glucocorticoid-induced TNF receptor family-related protein (GITR) and cytotoxic T lymphocyte-associated antigen 4 (CTLA-4) in murine infection with the nematode parasite Trichinella spiralis. Expression of GITR and CTLA-4 was rapidly upregulated on cells in the mesenteric lymph nodes and spleen, with approximately 80% of CD4+ lymphocytes expressing GITR by day 7 post-infection, coinciding with release and dissemination of newborn larvae. As the infection progressed to the chronic muscle phase, expression of GITR returned to normal, whereas CTLA-4 was sustained as late as day 60. Mice treated with anti-GITR antibodies rapidly developed higher titres of parasite-specific IgG1, IgG2a, IgG2b and IgM than controls. This was accompanied by elevated background lymphocyte proliferation, but parasite establishment in the intestine or the muscle was unaffected. In contrast, treatment with anti-CTLA-4 antibody resulted in elevated serum IgE, enhanced production of interleukin-4 and interleukin-10, and lower numbers of parasites recovered from skeletal muscle. These results reveal different temporal and regulatory roles for CTLA-4 and GITR in immune responses to helminth infection.     

Trypanosoma cruzi: predominance of IgG2a in nonspecific humoral response during experimental Chagas' disease.

The kinetic and isotypic pattern of hypergammaglobulinemia has been investigated in C3H/HeJ infected with Trypanosoma cruzi. Hypergammaglobulinemia appeared 14 days postinfection, increased until Day 28 postinfection, and persisted throughout the chronic phase (greater than 60 days of infection). The main isotype secreted was IgG2a, reaching 10-fold the control level. High titers of autoantibodies were found of IgM and IgG subclasses. Isotypic characterization of antibodies against myosin, myelin, and keratin, was performed and determined to be IgG2a subclass in the chronic stage of infection. Specific responses against T. cruzi took place 2 weeks postinfection when the parasitemia was high. Interestingly, parasite-specific response was maximal after 4 weeks of infection and plateaued during the chronic phase when parasites were rare. In contrast to the humoral polyclonal response in the chronic stage, showing a preferential IgG2a pattern, the anti-T. cruzi response consisted of all the different isotypes: IgM, IgG1, IgG3, IgG2a, and IgG2b, throughout the infection. Identical patterns of parasite antigens were recognized by IgG2a and IgG2b antibodies. Few different antigens were identified by the IgG3. Some antigens were recognized by several isotypes, others by only one isotype. With regard to the existence of antigenic cross-reactivities between host and parasite, we designed absorption experiments on parasite-specific immunoadsorbent showing that specific antibodies eluted from the column failed to recognize the natural antigens. These studies suggest that nonspecific and antiparasite-specific responses may be maintained by different regulatory pathways.     

A solid-phase immunoassay for human immunoglobulin E: use of 125I-labeled protein A as the tracer

A solid-phase immunoassay has been developed for human immunoglobulin (Ig) E. The specific binding of ¹²⁵I-labeled protein A (¹²⁵I-PA) to the Fc region of rabbit IgG anti-IgE served as a quantitative measure of specific anti-IgE antibody bound to the IgE beads under optimal assay conditions. Inhibition of antibody binding by known amounts of standard IgE was reflected in a decreased binding of ¹²⁵I-PA. The degree of inhibition of ¹²⁵I-PA binding was related to the amount of fluid-phase IgE present and gave a standard curve which was used to determine the concentration of IgE in test samples. The sensitivity of this method and a double antibody radioimmunoassay (RIA), which was developed using the same IgE preparation and anti-IgE antibody, was approximately the same. These assays gave similar results when used to determine levels of IgE in normal human sera that had been absorbed with protein A—Sepharose to remove components responsible for specific and nonspecific interference in the assays.     

IgE and IgG are synergistic in antigen-mediated release of thromboxane from human lung macrophages.

The mechanism of IgE-mediated release of thromboxane A2 from human lung macrophages has been studied using a monoclonal chimeric human/mouse IgE antibody and its specific antigen. The cells could be sensitized at 37 degrees C but not at 4 degrees C by incubation with IgE, and released a significant amount of thromboxane A2 (TXA2), measured as the stable hydrolysis product TXB2, in response to an anti-chimeric IgE antibody. In contrast, stimulation of IgE-sensitized macrophages with the specific antigen produced less than 10% of this response. A similar time course for the release of TXB2 and the formation of inositol monophosphate in the presence of LiCl was observed. Cleavage of the Fc domain of the anti-chimeric IgE antibody substantially eliminated its capacity to stimulate IgE-sensitized cells. However, the weak or undetectable response to chimeric IgE plus specific antigen was substantially potentiated by an antigen-specific chimeric IgG antibody. IgG-sensitized macrophages did not respond to antigen challenge by the release of TXB2. Preincubation of the cells with a monoclonal antibody against the low affinity receptor for IgE (Fc epsilon RII/CD23) did not prevent IgE sensitization. We conclude that cell-bound IgE antibody cannot induce the release of TXB2 but has fixed antigen which then must interact with specific IgG antibody and IgG receptors to induce mediator release.     

The transition from specific to nonspecific desensitization in human basophils

Human basophils can be desensitized to IgE-mediated stimuli either specifically (to the desensitizing antigen only) or nonspecifically (to all antigens). It has been suggested that the specificity of desensitization depends on the number of membrane-bound, antigen-specific IgE antibody molecules per basophil. We have varied the number of IgE antibody molecules/basophil by passive sensitization of mixed leukocyte preparations with increasing concentrations of purified IgE anti-penicillin (BPO) antibody. The cells were then desensitized with penicillin-human serum albumin (BPO-HSA). Desensitization was specific (lack of response to BPO-HSA only) with 1000 specific antibody molecules/basophil, and increasingly nonspecific (greater than 70% desensitization to rechallenge with anti-IgE and ragweed antigen E as well as lack of response to BPO-HSA) as the number of antibody molecules was increased to 14,000. This formally established that the number of specific IgE antibody molecules/basophil determines the mode of desensitization.     

Effect of Nippostrongylus brasiliensis infection on anti-hapten IgE antibody response in the mouse: I. Induction of carrier specific helper cells

Inoculation of infective larvae of Nippostrongylus brasiliensis into A/J, BALB/c, and SJL mice primed intraperitoneally (ip) 3 weeks before infection with 1 μg of dinitrophenylated keyhole limpet hemocyanin (DNP-KLH) mixed with 1 mg Al(OH)₃ induced a carrier effect on anti-DNP IgE and IgG₁ antibody responses when the experimental mice were secondarily immunized with an ip injection of 1 μg of DNP-coupled N. brasiliensis extract (DNP-Nb) plus alum 2 weeks after infection. The magnitude of the hapten specific antibody response did not correlate rigidly with the number of larvae in the inoculum. Thus, a dose of 100 larvae was as effective in inducing the carrier effect as a dose of 800 larvae. Kinetic studies in A/J and BALB/c mice revealed that the anti-DNP IgE antibody response reached a maximum titer 7 days after the secondary immunization. These studies also showed that the enhanced IgE antibody response persisted for more than 40 days, while the response in all control groups terminated prior to that time. Using the adoptive transfer system, it was demonstrated that lymphoid cells obtained from the spleens or the mesenteric lymph nodes of infected mice cooperated with DNP-KLH primed cells to produce hapten specific IgE and IgG, antibodies when the challenge was made with DNP-Nb but not when it was made with 1 μg DNP-ovalbumin, clearly indicating carrier specificity. The helper activity of the cells obtained from infected mice was completely abolished or greatly reduced by the in vitro treatment with anti-θ serum and complement. The helper cells with maximum activity were present as early as 14 days after inoculation. The level of helper activity gradually decreased after 14 days. The results indicate that N. brasiliensis infection is effective in inducing carrier specific helper cells of thymic origin (T cells) in anti-DNP antibody responses. These results confirm those obtained by other investigators and add the new observation that N. brasiliensis infection elicits special helper T cells which induce an enhancement as well as a prolongation of anti-DNP IgE antibody response.     

Cytophilic binding of IgE to the macrophage. II. Immunologic release of lysosomal enzyme from macrophages by IgE and anti-IgE in the rat: a new mechanism of macrophage activation.

Rat peritoneal macrophages release lysosome granule-associated β-glucuronidase, but not cytoplasmic leucine aminopeptidase, after successive incubation with purified IgE protein and ?-specific anti-IgE antibody or anti-IgE F(ab′)₂ fragments. The selective release of β-glucuronidase was shown to proceed by a first step of binding of the purified IgE to the cell surface, followed by IgE-anti-IgE reaction on the macrophage, whereas the possibility of cell activation by IgE-anti-IgE complexes in the bulk phase was ruled out. Heating rat IgE destroyed its ability to mediate lysosomal enzyme release. The characteristics of macrophage activation, insofar as the binding of IgE is concerned, were in agreement with those reported for the fixation of IgE to the mononuclear phagocyte, optimal binding of IgE being achieved with 20 min incubation. Preincubation of rat macrophages with rat IgG, either aggregated or not aggregated, did not inhibit the selective release of β-glucuronidase by the successive addition of IgE and anti-IgE antibody. Simultaneous incubation of macrophage monolayers with rat IgE and aggregated rat IgG did not reduce the subsequent activation by addition of anti-IgE. These studies indicated that rat macrophages can bind rat IgE through a specific receptor, with no interference of the classical Fc (γ) receptor, and are triggered to release lysosomal enzymes upon conformational changes of the IgE molecule by anti-IgE antibody. Antibody-dependent macrophage cytotoxicity in rat schistosomiasis is mediated by IgE antibody to the parasite, which may therefore function by activating the macrophage to an efficient effector cell.     

Reaginic antibody formation in the mouse. X. Possible role of suppressor T cells in transient IgE antibody responses.

The kinetics of IgE antibody response to alum-absorbed dinitrophenyl derivatives of ovalbumin (DNP-OA) was dependent on the dose of immunogen. A persistent IgE antibody response was obtained when high responder BDF1 mice were immunized with a minimum (0.05 microgram) dose. An increase of the immunogen to 10 microgram depressed IgE antibody responses but enhanced IgG antibody responses of both hapten and carrier specificities. Determination of T helper cell activity and B memory cells after immunization with different doses of antigen indicated that minimum immunogen was favorable for developing helper activity, whereas 1 to 10 microgram immunogen were more favorable than a 0.05-microgram dose for developing both IgE and IgG B memory cells. Nevertheless, neither helper T cells nor B memory cells in the spleen explains a transient IgE antibody response to a high (10 microgram) dose of DNP-OA. Evidence was obtained that immunization with 10 microgram OA induced generation of antigen-specific suppressor T cells, which were not detectable after immunization with 0.05 microgram OA. Transfer of suppressor T cells to DNP-OA-primed mice depressed both anti-hapten and anti-carrier IgE antibody responses. The results suggested strongly that suppressor T cells are involved in a transient IgE antibody response to a high-dose immunogen.     

Exacerbation of murine cutaneous leishmaniasis by adoptive transfer of parasite-specific helper T cell populations capable of mediating Leishmania major-specific delayed-type hypersensitivity

The effect of adoptive transfer of in vitro-propagated Leishmania major-specific T cell populations on the course of experimentally induced cutaneous leishmaniasis was studied in mice. The L. major-specific T cells expressed the T helper/inducer phenotype and were able in vitro to a) mount a specific proliferative response, b) provide specific helper activity for antibody responses, c) activate parasitized macrophages resulting in L. major destruction, and d) secrete macrophage-activating factors as tested in a tumoricidal assay. These T cells were also found capable of transferring parasite-specific delayed-type hypersensitivity responses to normal syngeneic mice. Results indicated that the i.v. transfer of these L. major-specific T cell populations into normal syngeneic mice exacerbated cutaneous lesions induced by infection with L. major. This effect on the disease process appeared to be dependent upon recognition of parasite antigens by the injected T cells because no exacerbation of the disease process was seen after the transfer of similar T cell populations specific for an antigen unrelated to the parasite, namely ovalbumin. However, the inclusion of ovalbumin in the L. major infecting inoculum resulted in an exacerbating effect of ovalbumin-specific T cells on cutaneous leishmaniasis. These unexpected results were supported by observations showing that immunization of mice with L. major antigens in complete Freund's adjuvant 7 days before infection with L. major led to exacerbated lesions. A similar aggravation of L. major-induced cutaneous lesions was also observed in mice previously immunized with an unrelated antigen provided that this antigen was included in the L. major infecting inoculum.     

IFN-gamma regulates the isotypes of Ig secreted during in vivo humoral immune responses

The lymphokine IFN-gamma has been shown in vitro to stimulate IgG2a secretion and inhibit IgG1 and IgE secretion by LPS-activated B lymphocytes. To determine whether IFN-gamma has a similar isotype regulatory role in vivo, we studied the abilities of rIFN-gamma and a mAb to IFN-gamma to modify the isotypes of Ig secreted in mice injected with a goat antibody to mouse IgD, which by itself induces large increases in levels of serum IgG1 and IgE and a relatively small increase in serum IgG2a. Multiple injections of IFN-gamma substantially inhibited production of IgG1 and IgE, and stimulated production of IgG2a in affinity purified goat antibody specific for mouse IgD-treated mice; anti-IFN-gamma antibody blocked the effects of IFN-gamma and in fact enhanced IgG1 and IgE secretion and inhibited the IgG2a response in these mice. The role of IFN-gamma in the selection of isotypes of Ig produced in response to injection of mice with the bacterium Brucella abortus (BA) was also studied, because killed, fixed BA are known to stimulate IFN secretion and a predominantly IgG2a antibody response. Anti-IFN-gamma antibody strongly suppressed IgG2a secretion and stimulated IgG1, but not IgE, secretion in BA-immunized mice. BA suppressed IgG1 and IgE secretion and enhanced IgG2a secretion in affinity purified goat antibody specific for mouse IgD-injected mice; treatment of these mice with anti-IFN-gamma antibody reversed the effects of BA on IgG1 and IgG2a secretion, but not the suppressive effect of BA on IgE secretion. These observations demonstrate that IFN-gamma has an important and perhaps unique physiologic role in the stimulation of IgG2a secretion and in the suppression of secretion of IgG1, whereas bacterial antigens can suppress IgE secretion by other mechanisms in addition to IFN-gamma secretion.     

Filarial parasite-specific T cell lines: induction of IgE synthesis

The development of T lymphocyte lines and clones of defined specificity has provided an important method for investigating T cell recognition of foreign antigens as well as T cell influence on B cell activity. We described previously a parasite-specific T cell line (TCL) derived from a patient with a naturally acquired filarial infection and elevated levels of serum IgE. The TCL is composed of Leu-3+ helper cells and is maintained independent of exogenous growth factors. In the present study, we used these T cells to investigate their immunoregulatory function on the in vitro IgE response. These parasite-specific T cells can provide isotype-specific help for antigen-induced IgE production by B cells in vitro. Autologous T cells profoundly suppress IgE production in a concentration-dependent manner. Furthermore, soluble factors generated from these filarial-specific TCL after antigen stimulation are able to induce the production of IgE in normal human cells not already synthesizing measurable amounts of IgE in vitro. Partial physicochemical characterization of this factor has shown that it is heat labile, has an m.w. between 10,000 and 30,000 M(r), and is a mannose-rich glycoprotein.     

Vaccination-induced protection of lambs against the parasitic nematode Haemonchus contortus correlates with high IgG antibody responses to the LDNF glycan antigen

Lambs respond to vaccination against bacteria and viruses but have a poor immunological response to nematodes. Here we report that they are protected against the parasitic nematode Haemonchus contortus after vaccination with excretory/secretory (ES) glycoproteins using Alhydrogel as an adjuvant. Lambs immunized with ES in Alhydrogel and challenged with 300 L3 larvae/kg body weight had a reduction in cumulative egg output of 89% and an increased percentage protection of 54% compared with the adjuvant control group. Compared to the adjuvant dimethyl dioctadecyl ammonium bromide, Alhydrogel induced earlier onset and significantly higher ES- specific IgG, IgA, and IgE antibody responses. In all vaccinated groups a substantial proportion of the antibody response was directed against glycan epitopes, irrespective of the adjuvant used. In lambs vaccinated with ES in Alhydrogel but not in any other group a significant increase was found in antibody levels against the GalNAcbeta1,4 (Fucalpha1,3)GlcNAc (fucosylated LacdiNAc, LDNF) antigen, a carbohydrate antigen that is also involved in the host defense against the human parasite Schistosoma mansoni. In lambs the LDNF-specific response increased from the first immunization onward and was significantly higher in protected lambs. In addition, an isotype switch from LDNF-specific IgM to IgG was induced that correlated with protection. These data demonstrate that hyporesponsiveness of lambs to H. contortus can be overcome by vaccination with ES glycoproteins in a strong T-helper 2 type response-inducing aluminum adjuvant. This combination generated high and specific antiglycan antibody responses that may contribute to the vaccination-induced protection.     

IgE antibody responses against Japanese cedar pollen in the mouse

IgE antibody responses against Japanese cedar pollen in the mouse were investigated to develop a mouse model of human allergy for combinations of factors including pollen administration routes, elicitation antigens and inbred mouse strains. Daily short term inhalation of native pollen or intratracheal administration of pollen suspended in saline induced IgE antibody responses in DBA/2, BDF1 and Balb/c mice, but failed to induce any detectable responses in C57BL/6 and C57BL/10 mice. Intraperitoneal injection of pollen suspension also induced IgE antibody responses in DBA/2, BDF1 and Balb/c mice but not in C57BL/6 mice. IgE antibody responses against pollen described above were detected by passive cutaneous anaphylaxis (PCA) reactions using crude extract of pollen as an elicitation antigen. On the other hand, IgE antibodies specific for antigen Sugi basic protein (AgSBP), which is a major allergen of pollen in humans (Yasueda, H., Yui, Shimizu, T., and Shida, T., 1983. Isolation and partial characterization of the major allergen from Japanese cedar (Cryptomeria japonica) pollen. J. Allergy Clin. Immunol. 71: 77-86), were also detected by PCA reactions using AgSBP in the sera from mice which received secondary or the tertiary stimulation by pollen. These results suggest that IgE antibody responses against Japanese cedar pollen in the mouse can be induced by airway sensitization and that the responses are genetically controlled by H-2-linked immune response genes. The results also suggest that not only IgE antibody responses specific for components other than AgSBP but also responses specific for AgSBP can be induced in the mouse by repeating appropriate sensitization by pollen.