Plasmodium yoelii: antibody response in resistant and susceptible mouse strains

The numbers of antigen-reactive antibody-secreting cells, levels of parasite antigen-specific serum antibodies and numbers of red blood cells staining positive for surface immunoglobulin were determined for susceptible and resistant mouse strains following infection with Plasmodium yoelii 17x. As a control, these parameters also were measured using antigen prepared from normal red blood cells. The relatively susceptible C57BL/6 mice produced more antigen-specific antibody-secreting cells and had higher levels of immunoglobulin positive red blood cells than did DBA/2 mice, but the DBA/2 mice had more antigen-specific IgG in their sera. Both mouse strains possessed cells secreting antibody reactive with soluble normal red blood cell antigen; however, C57BL/6 mice had more IgG positive unparasitized RBC than did DBA/2 mice. Despite possessing fewer antibody positive normal RBC, DBA/2 mice had significantly higher levels of serum antibodies that reacted with soluble red blood cell antigen. These data indicate that levels of serum antibody may not reflect the amounts of antibody produced and that use of any single assay to assess the magnitude of the antibody response may give rise to misleading results.     

Immunity to Plasmodium berghei yoelii in mice. II. Specific and nonspecific cellular and humoral responses during the course of infection.

The kinetics of various specific and nonspecific immunologic responses were examined in BALB/c mice infected with 17X nonlethal Plasmodium berghei yoelii (a self-limiting infection). The sequence of events after infection was characterized by rapid sensitization of splenic T cells to malaria antigen and polyclonal B cell activation, followed by a period of depressed splenic proliferative responses in vitro to mitogens (PHA and LPS) and malaria (specific) antigen. At the same time, suppressed primary in vitro splenic PFC responses to trinitrophenyl-aminoethylcarbamylmethyl-Ficoll (TNP-F) were seen. This suppression was an active process requiring adherent cells. During this period, levels of antimalarial antibody also increased exponentially. As the infection was cleared, splenic malaria antigen-specific proliferative responses were again observed and splenic PFC and in vitro mitogen responses returned to preinfection levels after variable periods of time. Both splenic proliferative responses to malaria antigen and antimalarial antibody responses remained persistently elevated. In addition, some responses were examined in mice infected with 17X lethal P.b. yoelii (a fatal infection); in comparison to the early responses of mice infected with the nonlethal substrain, there was a decrease and delay in the development of a splenic T cell response to malaria antigen and a blunted antimalarial antibody response.     

Mechanism of Epstein-Barr virus-induced human B-lymphocyte activation

The mechanism of Epstein-Barr virus (EBV) activation of human B lymphocytes toward Ig synthesis was investigated in a direct anti-sheep red blood cell (SRBC) antibody plaque-forming cell (PFC) system. Exposure of human peripheral blood lymphocytes to EBV in vitro resulted in an anti-SRBC PFC response in 12 of 16 normal donors. The EBV-induced anti-SRBC PFC response did not require the presence of autologous helper T lymphocytes, but was inhibited by the presence of autologous concanavalin A-generated suppressor T cells. Live virus was required for B-cell activation since the EBV-induced PFC response was inhibited by exposure of EBV to ultraviolet light. Using fluorescent techniques which detected simultaneous intracytoplasmic (ICP) Ig production and the presence of EB nuclear antigen, we found that most, if not all, EBV-activated ICP Ig-positive cells were virally infected. Thus, these studies suggest that viral infection of Ig-producing B lymphocytes is required for EBV-induced polyclonal B-lymphocyte activation. Although the participation of T lymphocytes is not required for the induction of EBV-triggered B-lymphocyte Ig production, activated T lymphocytes can serve as modulators of this response.     

Selective impairment of B cell function by Neisseria meningitidis

Spleen cells from CBA/J mice infected with Neisseria meningitidis displayed depressed in vitro plaque-forming cell (PFC) responses to T-dependent (sheep red blood cell; SRBC) and T-independent (TNP-LPS, TNP-Ficoll) antigens. The inhibition was observed over a wide range of antigen concentrations. The decreased responsiveness of splenocytes from infected mice was due to a selective impairment of B-cell function since helper-T-cell activity was intact in infected mice as shown by the ability of T-enriched lymphocytes to cooperate with normal B-enriched lymphocytes in the generation of an anti-SRBC response, accessory macrophage function was preserved since adherent spleen cells from bacteria-injected mice were shown to produce normal or increased levels of IL-1 and were able to cooperate with normal non-adherent spleen cells in the generation of PFC against SRBC. Addition of peritoneal cells from normal animals or extraneous IL-1 both failed to restore normal PFC responses in cultures of splenocytes from infected mice. Finally, B-enriched lymphocytes from infected mice produced poor anti-SRBC responses when cultured with either Con A supernatant or T-enriched lymphocytes from normal or infected mice. Cell-mixing experiments failed to detect the presence of suppressor cells in cultures of unfractionated spleen cells or B-enriched lymphocytes from infected mice. Therefore, the immunological unresponsiveness associated with a Neisseria meningitidis infection was attributed to a meningococcus-induced defect(s) in B-cell function. In vivo polyclonal B-cell activation leading to clonal exhaustion did not play a major role in the depression of humoral responses since meningococcal infection induced little or no polyclonal Ig secretion.     

Anaphylatoxin-mediated regulation of human and murine immune responses

C3a and C5a derived from the human complement components C3 and C5, respectively, were found to possess immunoregulatory activities. C3a was found to be capable of suppressing both antigen-specific and polyclonal antibody responses. In contrast, C3a was unable to suppress antigen- or mitogen-induced B or T cell proliferative responses. Helper T cells were found to be the target of C3a-mediated immunosuppression. Suppression occurred via the generation of suppressor T cells. In contrast to the results obtained with C3a, C5a was found to augment both antigen-specific and non-specific in vitro humoral immune responses. Moreover, C5a potentiated antigen- and alloantigen-induced T cell proliferative responses. As opposed to C3ades Arg-77, C5ades Arg retained all of the immunoregulatory activity associated with the intact molecule. Helper T cells are required for C5a-mediated potentiation of the Fc fragment-mediated polyclonal antibody response. Substitution for T cells by a soluble T cell-replacing factor rendered lymphocytes refractory to the enhancing properties of C5a.     

Plasmodium yoelii: effects of red blood cell modification and antibodies on the binding characteristics of the 235-kDa rhoptry protein

The 235-kDa rhoptry protein of the rodent malaria parasite Plasmodium yoelii yoelii was shown to bind to the surface of mouse red blood cells in a calcium-independent process, using a erythrocyte-binding assay. This binding is affected by modification of the surface of the red blood cells by enzymatic treatment. Chymotrypsin and trypsin but not neuraminidase treatment of the erythrocytes significantly reduced the binding of the 235-kDa proteins. The binding of an unrelated 135-kDa protein was abolished by treatment with chymotrypsin. Although the 235-kDa proteins bind to both reticulocytes and mature red blood cells, the binding to mature cells was more pronounced. In the presence of hyperimmune infection serum or specific polyclonal antibodies to the 235-kDa protein its binding to erythrocytes was reduced, further demonstrating the specificity of this ligand-receptor interaction.     

Staphylococcus aureus infection triggers production of neutralizing, V8 protease-specific antibodies

Staphylococcus aureus infection triggers polyclonal B-cell activation. It was sought to further characterize the hypergammaglobulinemia seen in Staphylococcus aureus infection, focusing on the significance of protease-specific B-cell responses. Sera from mice infected with Staphylococcus aureus wild-type strain 8325-4 and two of its isogenic mutants devoid of protease expression were analyzed for the occurrence of polyclonal B-cell activation and the presence of specific antibodies against a set of exoproteases and superantigens. Furthermore, the functional properties of anti-V8-protease antibodies were analyzed in vitro. Polyclonal activation was manifested by increased levels of total serum IgG and IgM in all infected animals and by antibodies to staphylococcal toxins and aureolysin whether these antigens were present in the inoculate or not. Importantly, Staphylococcus aureus mutant lacking the V8-protease did not trigger a response against this enzyme. In contrast, strains expressing the V8-protease elicited V8-protease antibodies, proving the antigen-specific nature of this response. In vitro tests revealed that these antibodies had the capacity to inhibit the V8 protease activity in a dose-dependent manner. It was concluded that exposure to Staphylococcus aureus, in addition to a massive polyclonal B-cell response, gives rise to production of exoprotease-specific antibodies displaying functional properties.     

Retrovirus-induced target cell activation in the early phases of infection: the mouse mammary tumor virus model.

Mouse mammary tumor virus (MMTV) infects B lymphocytes and expresses a superantigen on the cell surface after integration of its reverse-transcribed genome. Superantigen-dependent B- and T-cell activation becomes detectable 2 to 3 days after infection. We show here that before this event, B cells undergo a polyclonal activation which does not involve massive proliferation. This first phase of B-cell activation is T cell independent. Moreover, during the first phase of activation, when only a small fraction of B cells is infected by MMTV(SW), viral DNA is detected only in activated B cells. Such a B-cell activation is also seen after injection of murine leukemia virus but not after injection of vaccinia virus, despite the very similar kinetics and intensity of the immune response. Since retroviruses require activated target cells to induce efficient infection, these data suggest that the early polyclonal retrovirus-induced target cell activation might play an important role in the establishment of retroviral infections.     

Distribution of immunoglobulin isotypes in the nonspecific B-cell response induced by infection with Plasmodium chabaudi adami and Plasmodium yoelii

The nonspecific B-cell response induced by infecting mice with two nonlethal malaria parasites, Plasmodium chabaudi adami and Plasmodium yoelii, was analyzed in an isotype-specific reverse plaque assay. Our results showed different isotypic patterns in the two infections, although cells secreting immunoglobulin of all isotypes were increased to some extent. P. yoelii induced large increases in secreting cells of all isotypes; IgG2a-secreting cells were increased out of proportion to those of the other IgG classes. P. chabaudi induced large increases in secreting cells of all isotypes except IgG1. In addition, there was not a disproportionate increase in cells secreting IgG2a. The data show that these "polyclonal" responses are different during each infection. There are marked similarities between the distribution of "nonspecific isotypes" and the specific antibodies formed in each infection.     

Lipopolysaccharide-induced suppression of the primary immune response to a thymus-dependent antigen.

The immune response to a thymus-dependent antigen was depressed in vivo and in vitro in spleen cells from mice injected with LPS i.p. a few days before challenge with the antigen. Spleen cells from LPS-injected mice could, however, respond with increase DNA synthesis after activation with polyclonal B and T cell activators in vitro. The LPS-activated spleen cells could actively suppress normal cells in their response to the antigen sheep red blood cells. The suppressor cells contained in the LPS-activated spleens were most likely B lymphocytes, and the possible mechanism for their inhibitory function is discussed.     

Dendritic and B-cell function during antibody responses in normal and immunodeficient (xid) mouse spleen cultures

Dendritic cells (DC) act as accessory cells for T-dependent antibody responses in two ways. One is to induce a class of stimulating factors (BSF) which allow B lymphocytes to respond to heterologous red cells as antigen. xid DC induce the production of these BSF, but xid B cells totally lack responsiveness. A second mechanism of DC function applies to red cell and haptenated-protein antigens. Here DC, helper T lymphocytes, and antigen-specific B cells interact in discrete clusters. Then the B cells become responsive to BSF. xid DC are fully active in this pathway, and xid B cells develop significant (10-20% of control) responses. This partial reduction in xid B-cell function could be due to the poor viability of xid lymphocytes in vitro. There is a comparable reduction in xid polyclonal responses to alloreactive helper T blasts. The other severe deficit in xid involves antibody formation to haptens on polysaccharide carriers. This response in normal mice is not influenced by DC or by BSF. The only similarity between DNP-Ficoll and RBC plus BSF responses is that both utilize B lymphocytes that do not associate with DC-T clusters, even though helper cells for DNP-Ficoll and for RBC are present in the culture. We conclude that DC function is not altered in xid. The main deficit seems to be in a B-cell activation pathway that is shared by polysaccharide carriers and some but not all BSF, and/or in a B-cell subpopulation that does not interact with carrier-specific helper cells. We speculate that this B-cell alteration primarily involves the Ig delta-poor marginal zone subpopulation of splenic B lymphocytes.     

T-cell immunodeficiency in mice receiving lectin and cyclophosphamide

Cyclophosphamide injections to mice following T cell mitogen (lectins from Lens culinaris and concanavalin A) were shown to suppress (20-40-fold) thymus-dependent response to SRBC. At the same time no damage-specific and polyclonal response to thymus-independent antigen and polyclonal activator of B cells--lipopolysaccharide--has been observed. Injections of lectin and cyclophosphamide to mice prevented the onset of DTH reaction to SRBC and induction of antigen-specific DTH suppressor cells. Thus, cyclophosphamide injection after T cell mitogen leads to T-cell anergy, with B-cell activity remaining unchanged.     

Prostaglandin-mediated suppression of delayed-type hypersensitivity to infected erythrocytes during Babesia microti infection in mice

The mechanism of suppression of delayed-type hypersensitivity (DTH) to intraerythrocytic Babesia microti which occurs during infection in mice was examined. The suppression was not specific for anti-parasite DTH; infected mice immunized and challenged with sheep red blood cells had a similar depression of anti-sheep red blood cell DTH. Sublethal or lethal irradiation did not significantly alter the suppression of the DTH response, and cyclophosphamide pretreatment of infected mice also had no effect on suppression. Multiple passive transfer experiments using serum or regional lymph node cells from immunized or infected and immunized (suppressed) donor animals failed to demonstrate any ability to transfer suppression of DTH. Adherent cells from the spleens or peritoneal exudates of suppressed mice, however, did significantly depress the ability of immunized mice to express a DTH response. The cells responsible for this suppression were Thy 1- and nonspecific esterase+. Treatment of suppressive cell populations with 10 micrograms/ml indomethacin for 24 hr in vitro abrogated their suppressive ability, and in vivo administration of indomethacin to suppressed mice also restored DTH to normal levels. By examining levels of prostaglandin E2 (PGE2) in supernates of cultured peritoneal exudate cells from immune or suppressed mice, it was shown that infected mice had peritoneal exudate cells which produced significantly more PGE2 than similar cells from immune mice. These data suggest that B. microti infection elicits synthesis of PGE2 by macrophage-like cells which results in suppression of DTH to parasite as well as heterologous antigens.     

Polyclonal antibody-forming cell activation and immunomodulation of the in vitro immune response induced by streptococcal extracellular products

The capacity of three different extracellular streptococcal products to induce polyclonal activation of precursors of plaque-forming cells (PFC) was investigated. The gamma fraction (pI = 4.2), previously shown to be only weakly mitogenic, was the most potent activator of rabbit and mouse immunoglobulin-secreting cells. The polyclonal stimulation induced by the two other fractions (kappa: pI = 4.8 and epsilon: pI = 10.3), shown to be mitogenic in both systems, was only observed in the rabbit system. Using these fractions, the in vitro immunomodulation of the anti-sheep red blood cell immune response was also investigated. Both gamma and epsilon fractions were shown to possess adjuvant properties, whereas the kappa fraction was a suppressor of the specific immune response. It appears, therefore, that the diversified immunological activities observed with extracellular streptococcal products can be dissociated and belong to different entities.     

Polyclonal B-cell stimulative and immunosuppressive activities at different developmental stages of Trypanosoma gambiense

Bloodstream trypomastigote and cultured procyclic (insect midgut) forms of a monomophic strain of Trypanosoma gambiense were tested for their abilities to induce polyclonal B-cell activation (PBA) and immunosuppression (IS) in mice. Injection of a cell homogenate of bloodstream trypomastigotes induced both PBA and IS, while neither PBA nor IS was observed in mice injected with a cell homogenate of cultured procyclics. The results indicate that the substance(s) inducing PBA or IS is related to the developmental stage of the parasites.     

Passive immunization against murine malaria with an IgG3 monoclonal antibody

Spleen cells of BALB/c mice that were immune to the 17X strain of P. yoelii were fused with P3X63Ag8 myeloma cells. Two hundred fifty-three of 1053 hybrid cells produced antibodies reactive with disrupted 17X parasites in a solid phase radioimmunoassay. One of these antibodies, McAb 302, reacted with the merozoites of the 17X (nonlethal) and 17XL (lethal) variants of P. yoelii. Of greater significance, McAb 302 passively protected mice against challenge infection with the lethal variant. Mice treated with this antibody before infection developed low-grade parasitemia (less than 0.3%) of short duration when challenged with P. yoelii 17XL . In contrast, control mice that had been untreated or injected with ascites fluid lacking McAb 302 uniformly died with fulminating malaria upon challenge with the same parasite. In other experiments, McAb 302 was shown capable of controlling blood parasite levels when administered to mice with patent P. yoelii 17XL infections. Although all control mice died, mice protected with a single dose of McAb 302 ultimately cleared their infections. Regardless of how passive immunization was performed, mice given McAb 302 were resistant to subsequent challenge with P. yoelii 17XL , indicating they had developed significant immunity during their initial controlled infections. McAb 302 also showed pronounced passive protective activity against the nonlethal 17X strain of P. yoelii, which is a parasite of reticulocytes. The protection afforded by McAb 302 was specific, because mice passively immunized with this antibody died when challenged with the unrelated P. vinckei. McAb 302 was shown to possess the IgG3 isotype and precipitated a 230-kd protein plus several smaller polypeptides from metabolically labeled parasite antigen preparation derived from both variants of P. yoelii. It did not react with similar preparations of other murine plasmodial species.     

Comparative histopathology of mice infected with the 17XL and 17XNL strains of Plasmodium yoelii

Plasmodium yoelii 17XL was used to investigate the mechanism of Plasmodium falciparum-caused cerebral malaria, although its histological effect on other mouse organs is still unclear. Here, histological examination was performed on mice infected with P. yoelii 17XL; the effect of P. yoelii 17XL infection on anemia and body weight loss, as well as its lesions in the brain, liver, kidney, lung, and spleen, also was investigated. Plasmodium yoelii 17XL-infected red blood cells were sequestered in the microcirculation of the brain and in the kidney. Compared with the nonlethal P. yoelii 17XNL strain, infection by P. yoelii 17XL caused substantial pulmonary edema, severe anemia, and significant body weight loss. Although P. yoelii 17XNL and 17XL produced a similar focal necrosis in the mouse liver, infection of P. yoelii 17XL induced coalescing of red and white pulp. Mortality caused by P. yoelii 17XL may be due to cerebral malaria, as well as respiratory distress syndrome and severe anemia. Plasmodium yoelii 17XL-infected rodent malaria seems to be a useful model for investigating severe malaria caused by P. falciparum.     

Polyclonal B Cell Activation by Cell Wall Preparations of Gram-Positive Bacteria

The effects of polyclonal B cell activation (PBA) of cell walls and their cell wall fractions obtained from several kinds of gram-positive bacteria were studied using the anti-sheep red blood cell (SRBC) or anti-trinitrophenylated (TNP) SRBC plaque forming cell (PFC) responses of cultured spleen cells from Balb/c, athymic nu/nu, their littermates (nu/+), C3H/He (LPS-responder), C3H/HeJ (LPS-non-responder), (CBA/N × Balb/c) F1 male with an X-linked defect in B cell function and the F1 female mice. The cell walls of Staphylococcus epidermidis (ATCC 155), Lactobacillus plantarum (ATCC 8014), Micrococcus lysodeikticus (NCTC 2665), Mycobacterium rhodochrous (ATCC 184), Streptomyces gardneri (ATCC 23911) and Nocardia corynebacteriodes (ATCC 14898) had the ability to induce polyclonal B cell responses in the spleen cells of Balb/c, nu/nu, nu/+, C3H/He and C3H/HeJ mice. The cell wall fractions prepared by enzymatic digestion from the cell walls of S. epidermidis, S. gardneri or N. corynebacteriodes were also capable of inducing polyclonal B cell responses. The responses of spleen cells from (CBA/N × Balb/c) F1 male mice to these active preparations, except the cell walls of M. rhodochrous, were much lower than those of the F1 female mice. These findings indicate that the majority of the cell wall preparations lacks PBA ability for spleen cells with the CBA/N defect, except for the cell walls of M. rhodochrous which possess this ability. The PBA-ability of synthetic peptidoglycan, muramyl dipeptide (N-acetylmuramyl-L -alanyl-D -isoglutamine, MDP), was also examined, and a similar activity was observed in MDP.     

Differential response of B cells in the lymph node and the spleen to bacterial lipopolysaccharide

In vivo polyclonal activation of B cells in the lymph nodes and the spleens of mice injected with bacterial lipopolysaccharide (LPS) was compared. The peak of anti-trinitrophenylated sheep red blood cells plaque-forming cell (PFC) response in the lymph node was reached 6-8 days after the injection of LPS while that in the spleen was reached at 2 days. The maximal increase in the total number of Ig-producing cells in the lymph node also occurred at the later stage. These differences in time courses of polyclonal activation of B cells between the lymph node and the spleen were not due to the absence of B cells in the lymph node, migration of PFC from the spleen to the lymph node, or qualitative differences of B cells. This phenomenon was dependent on the environmental difference between the lymph node and the spleen, because B cells from the lymph node could respond to LPS rapidly in the spleen. Further, the polyclonal activation of B cells was accelerated in the lymph nodes of mice receiving prior injection of LPS. In in vitro cultures of lymph node cells of those mice, a significant amount of interleukin-1 could be detected by stimulation of LPS. It was possible that the delayed activation of B cells in the lymph node was due to the time lag necessary for construction of the environmental condition suitable for activation of B cells, whereas in the spleen this condition can be provided without delay.     

Plasmodium yoelii: experimental evidences for the conserved epitopes between mouse and human malaria parasite, Plasmodium falciparum

Bioinformatic analyses of gene homologues have revealed functionally conserved epitopes between human and rodent malaria parasites. Here, we present experimental evidence for the presence of functionally and antigenically conserved domains between Plasmodium falciparum and Plasmodium yoelii asexual blood-stages. Merozoite released soluble proteins (MRSPs) from both P. falciparum and P. yoelii bound to heterologous mouse or human red blood cells, respectively. The presence of conserved antigenic epitopes between the two species of parasites was evident by the inhibitory effect of antibodies, developed against P. yoelii in convalescent mice, on P. falciparum growth and merozoite reinvasion in vitro. Furthermore, mice immunized with P. falciparum MRSPs were protected from infection by a P. yoelii challenge. These data indicate that different species of Plasmodium contain antigenically conserved interspecies domains, which are immunogenic and, thus constitute a potential novel antigen source for vaccine development and testing using a mouse model.