Complement Receptors 1 and 2 in Murine Antibody Responses to IgM-Complexed and Uncomplexed Sheep Erythrocytes

Early complement components are important for normal antibody responses. In this process, complement receptors 1 and 2 (CR1/2), expressed on B cells and follicular dendritic cells (FDCs) in mice, play a central role. Complement-activating IgM administered with the antigen it is specific for, enhances the antibody response to this antigen. Here, bone marrow chimeras between Cr2(-/-) and wildtype mice were used to analyze whether FDCs or B cells must express CR1/2 for antibody responses to sheep erythrocytes (SRBC), either administered alone or together with specific IgM. For robust IgG anti-SRBC responses, CR1/2 must be expressed on FDCs. Occasionally, weak antibody responses were seen when only B cells expressed CR1/2, probably reflecting extrafollicular antibody production enabled by co-crosslinking of CR2/CD19/CD81 and the BCR. When SRBC alone was administered to mice with CR1/2(+) FDCs, B cells from wildtype and Cr2(-/-) mice produced equal amounts of antibodies. Most likely antigen is then deposited on FDCs in a way that optimizes engagement of the B cell receptor, making CR2-facilitated signaling to the B cell superfluous. SRBC bound to IgM will have more C3 fragments, the ligands for CR1/2, on their surface than SRBC administered alone. Specific IgM, forming a complex with SRBC, enhances antibody responses in two ways when FDCs express CR1/2. One is dependent on CR1/2(+) B cells and probably acts via increased transport of IgM-SRBC-complement complexes bound to CR1/2 on marginal zone B cells. The other is independent on CR1/2(+) B cells and the likely mechanism is that IgM-SRBC-complement complexes bind better to FDCs than SRBC administered alone. These observations suggest that the immune system uses three different CR1/2-mediated effector functions to generate optimal antibody responses: capture by FDCs (playing a dominant role), transport by marginal zone B cells and enhanced B cell signaling.     

Antibody-mediated modulation of the immune response

We have studied the ability of monoclonal IgM and IgG antibodies to enhance or suppress immune responses and attempted to dissect the underlying mechanisms. Both IgM and IgG1 antibodies increased the rate of clearance of antigen from the circulation. Monoclonal IgM antibody to SRBC was found to specifically increase antibody responses, enhancement being insensitive to low doses of irradiation (150 R). IgM antibody specifically depressed the delayed hypersensitivity response to SRBC in vivo. Following administration of IgM in vivo, in vitro responses to SRBC were also enhanced. This in vitro enhancement appeared to depend on both T cells and B cells. In contrast, monoclonal IgG1 antibody to SRBC specifically depressed antibody responses in vivo. Such depressed antibody responses were also seen in vitro following IgG1 in vivo and did not appear to be due to the induction of suppressor T cells.     

Effects of antigen-feeding on intestinal and systemic immune responses. III. Antigen-specific serum-mediated suppression of humoral antibody responses after antigen feeding.

Feeding mice sheep erythrocytes (SRBC) caused a significant decrease in splenic IgM antibody responses to SRBC given ip. Reduced IgM responses were due to a suppressor factor in the serum of fed mice rather than due to a lack of IgM antibody-forming cell precursors or to the presence of suppressor T cells. Although feeding initially primed mice to produce greater IgA and IgG anti-SRBC responses after SRBC challenge, the initial primed state was transitory. Mice fed SRBC for longer than 8 weeks had significantly reduced splenic IgG and IgA responses after SRBC challenge.Suppression of IgM responses by serum from fed mice was antigen-specific and not H-2 restricted. Serum from fed mice inhibited the induction of IgM anti-SRBC responses but did not block the expression of already established responses. The size of the suppressor factor and the ability to remove suppressor activity from serum by anti-mouse immunoglobulin suggested that suppression was mediated by antibody. However, the determinants against which the antibody was directed appeared to differ among batches of suppressor sera. Suppressor activity did not appear to be mediated by immune complexes, or soluble antigen. Oral feeding of antigen can have a marked influence on host systemic immune responses when the antigen used for feeding is subsequently administered parenterally. Thus, oral antigen administration may provide a way for specifically manipulating systemic immune responses in vivo. In addition, antigen-feeding may provide a means for producing transferable factors that suppress humoral antibody responses.     

Regulation of the immune response by antibody. II. The effects of different classes of passive guinea pig antibody on humoral and cell-mediated immunity in rats

The ability of different classes of passively administered guinea pig antibody (γ1, γ2, and IgM) to regulate humoral and cell-mediated immunity to flagellin, polymerized flagellin (POL), and sheep red blood cells (SRBC) was investigated in rats. It was found that at high concentrations, all classes of antibody suppressed the primary antibody responses and usually enhanced the delayed-type hypersensitivity induced by the three antigens. With flagellin and SRBC, the different classes of passive antibody varied in their suppressing and enhancing properties, being in the order: γ2 > γ1 = IgM. At low concentrations, γ1 and IgM enhanced the primary antibody response and suppressed the delayed hypersensitivity induced by flagellin. Such an effect was not observed with either POL or SRBC. Priming for a secondary antibody response was less readily suppressed by all classes of passive antibody. The removal of macrophage cytophilic antibody from γ2 converted this antibody to a preparation (γ2 absorbed) which had effects on humoral and cell-mediated immunity approaching that of γ1 antibody.     

IgM-mediated enhancement of in vivo anti-sheep erythrocyte antibody responses: isotype analysis of the enhanced responses

The direct splenic anti-sheep erythrocyte (anti-SRBC) responses as well as the serum IgG1, IgG2a, IgG2b, and IgG3 anti-SRBC responses of CBA/CaJ mice were monitored 4-35 days after immunization with: (1) a suboptimal dose of SRBC, (2) a suboptimal dose of SRBC plus monoclonal IgM anti-SRBC, or (3) a high dose of SRBC. The direct plaque-forming cell (PFC) responses of mice in treatment group 2 were significantly higher than those in group 1 but similar to the responses in group 3. The serum anti-SRBC antibody responses of all IgG subclasses were significantly enhanced by IgM anti-SRBC and were generally even higher than the responses obtained with high doses of SRBC. The relative proportions of each serum IgG subclass were similar in all three groups. These data suggest that the enhancement of suboptimal anti-SRBC antibody responses by IgM anti-SRBC extends through IgM and all of the IgG subclasses and, further, that the isotype profile in antibody-enhanced responses is similar to that obtained with high doses of SRBC.     

Impaired Antigen Specific Responses and Enhanced Polyclonal Stimulation in Mice Infected with Ehrlichia muris

The immune status of BALB/c mice infected by intraperitoneal inoculation with Ehrlichia muris was examined. The level of E. muris infection in both peritoneal cavity and spleen was greatest at day 10 postinoculation (PI). Thereafter, the infection level was dramatically reduced while the organism persisted for up to 400 days PI. The greatest intraperitoneal infiltration of leukocytes, splenomegaly, and leukocytosis were observed on days 10, 15, and 20 PI, respectively. Infected mice developed marked hypergammaglobulinemia of IgG and IgM that peaked at day 20 PI; however, IgA plummeted at day 15 PI. Of IgG, G2a and G3 increased while G1 and G2b remained constant. Despite hypergammaglobulinemia, both IgG and IgM antibody titers against E. muris were very low throughout the 30-day study. Antibody development and plaque-forming cells against sheep red blood cells (SRBC) were abolished when the antigen was inoculated on day 10 PI. IgM antibody development against SRBC was more severely inhibited than IgG antibody development. However, when mice were immunized with SRBC prior to E. muris infection, antibody development against SRBC was not reduced. Delayed type hypersensitivity reaction to dinitrofluorobenzene was also maximally inhibited when the antigen was administered on day 10 PI. The IFN-γ level in the blood was maximal at day 10 PI. These results indicate that although the vigorous polyclonal activation and protective IFN-γ responses occurred by day 10 PI—which cleared most of the ehrlichial infection—antigen-specific immune stimulation was impaired primarily at the level of antigen-priming at peak parasitemia.     

Complement-Activating IgM Enhances the Humoral but Not the T Cell Immune Response in Mice

IgM antibodies specific for a certain antigen can enhance antibody responses when administered together with this antigen, a process believed to require complement activation by IgM. However, recent data show that a knock-in mouse strain, Cμ13, which only produces IgM unable to activate complement, has normal antibody responses. Moreover, the recently discovered murine IgM Fc receptor (FcµR or TOSO/FAIM3) was shown to affect antibody responses. This prompted the re-investigation of whether complement activation by specific IgM is indeed required for enhancement of antibody responses and whether the mutation in Cµ13 IgM also caused impaired binding to FcµR. The results show that IgM from Cµ13 and wildtype mice bound equally well to the murine FcµR. In spite of this, specific Cμ13 IgM administered together with sheep red blood cells or keyhole limpet hemocyanine was a very poor enhancer of the antibody and germinal center responses as compared with wildtype IgM. Within seconds after immunization, wildtype IgM induced deposition of C3 on sheep red blood cells in the blood. IgM which efficiently enhanced the T-dependent humoral immune response had no effect on activation of specific CD4⁺ T cells as measured by cell numbers, cell division, blast transformation, or expression of the activation markers LFA-1 and CD44 in vivo. These observations confirm the importance of complement for the ability of specific IgM to enhance antibody responses and suggest that there is a divergence between the regulation of T- and B-cell responses by IgM.     

Granulocyte-macrophage colony-stimulating factor augments the primary antibody response by enhancing the function of antigen-presenting cells

Purified, recombinant-derived murine granulocyte-monocyte colony-stimulating factor was found to enhance the primary in vitro immune response to SRBC by murine spleen cells. In determining the mechanism of this augmentation, it was found that only splenic adherent cells and neither resting nor activated T cells nor B cells expressed specific receptors for GM-CSF. When splenic adherent cells were pulsed briefly with GM-CSF before addition to macrophage-depleted cultures, they reconstituted the PFC response to a significantly greater degree than did control macrophages. Splenic adherent cells incubated overnight with SRBC plus GM-CSF were also more efficient antigen-presenting cells than splenic adherent cells incubated with antigen alone. The mechanism of this enhanced antigen presentation was found to be due to a GM-CSF-dependent increase in the level of IL 1 secretion and Ia antigen expression. Consistent with these data was the finding that GM-CSF augmented IL 2 production by splenic T cells in response to suboptimal concentrations of Con A. Finally, the day 5 in vivo antibody response (as measured by serum titers) of mice immunized with a low dose of SRBC was enhanced by two daily inoculations of GM-CSF. Thus, the role that GM-CSF plays in augmenting immune responses may not be solely accounted for by its ability to cause the proliferation or differentiation of macrophages, but more than likely includes its ability to enhance the function of antigen-presenting macrophages.     

Suppression and augmentation of the primary in vitro immune response by different classes of antibodies

The capacity of purified γG₁ and γG₂ anti-sheep red blood cell (SRBC) antibodies to exert antigen-specific feedback regulations on the primary in vitro immune response to SRBC was studied. Antibodies were administered to the culture in the native form, as sheep erythrocyte-antibody complexes or as pepsin-derived F(ab′)₂ antibody fragments. Marked differences in the feedback regulatory effects of γG₁ and γG₂ antibodies were found. Antibodies of the γG₁ class suppressed the immune response to SRBC, whereas γG₂ antibodies isolated from the same serum exerted an augmenting effect on antibody synthesis. These opposing feedback effects on in vitro antibody synthesis were immunologically specific, relatively insensitive to changes in antigen concentrations, and could be elicited by either adding antibodies and antigen separately to the culture or as preformed antigen-antibody complexes. Experiments comparing the activities of the F(ab′)₂ antibody fragments with the parent γG₁ and γG₂ antibodies suggested that the Fc fragments may be involved in these regulatory effects on the immune response. It is concluded that the antigen-specific suppressive and augmenting effects on antibody synthesis shown here are determined by the antibody class. In addition, we suggest that these opposing antibody-mediated feedback effects may represent one of the important elements of the immune response.     

Serum and Egg Antibody Responses in Chickens to Escherichia coli

The effects of Freund’s adjuvants on antibody production in chickens against E. coli whole cells were examined. The levels of anti-E. coli IgG antibodies in serum were higher when Freund’s complete (FCA) or incomplete adjuvant (FIA) was administered than that without adjuvant. Production of antibodies recognizing E. coli cells and their lipopolysaccharide was enhanced by FIA, while both FIA and FCA enhanced production of antibodies recognizing outer membrane components. In contrast, serum IgM antibody levels were higher when no adjuvant was used. Anti-E. coli IgG antibodies in serum were efficiently transferred to egg yolk, giving antibody activity in egg yolk similar to that in serum. However, anti-E. coli IgM antibodies were not detected in the egg, suggesting that egg (white) IgM was not influenced by antigenic stimulation of the humoral immune system. Antimicrobial activity of the egg yolk IgG was highest when the bacteria antigen was injected with FIA.     

IgG Suppresses Antibody Responses in Mice Lacking C1q,C3, Complement Receptors 1 and 2, or IgG Fc-Receptors

Antigen-specific IgG antibodies, passively administered to mice or humans together with large particulate antigens like erythrocytes, can completely suppress the antibody response against the antigen. This is used clinically in Rhesus prophylaxis, where administration of IgG anti-RhD prevents RhD-negative women from becoming immunized against RhD-positive fetal erythrocytes aquired transplacentally. The mechanisms by which IgG suppresses antibody responses are poorly understood. We have here addressed whether complement or Fc-receptors for IgG (FcγRs) are required for IgG-mediated suppression. IgG, specific for sheep red blood cells (SRBC), was administered to mice together with SRBC and the antibody responses analyzed. IgG was able to suppress early IgM- as well as longterm IgG-responses in wildtype mice equally well as in mice lacking FcγRIIB (FcγRIIB knockout mice) or FcγRI, III, and IV (FcRγ knockout mice). Moreover, IgG was able to suppress early IgM responses equally well in mice lacking C1q (C1qA knockout mice), C3 (C3 knockout mice), or complement receptors 1 and 2 (Cr2 knockout mice) as in wildtype mice. Owing to the previously described severely impaired IgG responses in the complement deficient mice, it was difficult to assess whether passively administered IgG further decreased their IgG response. In conclusion, Fc-receptor binding or complement-activation by IgG does not seem to be required for its ability to suppress antibody responses to xenogeneic erythrocytes.     

Immunopotentiating effects of the adjuvants SGP and Quil A. I. Antibody responses to T-dependent and T-independent antigens

The present study was undertaken to compare the effects of two adjuvants, SGP (a starch-acrylamide polymer) and Quil A (purified saponin), with that of aluminum hydroxide (Al(OH)3) on murine primary antibody responses to T-independent (TI) and T-dependent (TD) antigens. All three adjuvants augmented the responses to the TD antigens, dinitrophenyl-keyhole limpet hemocyanin (DNP-KLH), and sheep erythrocytes (SRBC). SGP was the most potent adjuvant and increased the primary IgG response to DNP-KLH as much as 90-fold. Quil A and Al(OH)3 had comparable effects on the primary response to DNP-KLH, but Quil A was less effective than Al(OH)3 for augmenting the primary response to SRBC. Quil A and SGP both augmented the primary IgM and IgG responses to trinitrophenyl-lipopolysaccharide (TNP-LPS), TNP-Brucella (TI-1 antigens), and TNP-Ficoll (TI-2 antigens). Al(OH)3, like most commonly used adjuvants, had little or no effect on responses to TI antigens. The kinetics of the response to TNP-Ficoll was altered by SGP, since peak responses were maintained for at least 7 days, while the response to TNP-Ficoll alone peaked on Day 4 and had declined considerably by Day 7. Both SGP and Quil A could augment responses to both optimal and suboptimal doses of antigen. The adjuvant activity of SGP was diminished, but still effective, when smaller amounts of SGP were used with the immunizing antigen, and all three adjuvants were able to augment primary responses when given in separate injections from the antigen. These results demonstrate that SGP is a very effective adjuvant, and show that both Quil A and SGP have a unique ability to increase antibody responses to TI antigens, suggesting that their effects may be mediated at least partially through B cells.     

Serum-mediated suppression of nonspecific B-cell activation. III. Selective inhibition of the polyclonal B-cell response by normal mouse serum

Normal, nonimmune adult serum is known to inhibit in vitro immune responses when present in sufficient amounts. The significance of inhibition of the immune response by serum, however, is not known. Previous work suggested that normal mouse plasma or serum (NMS) was selectively more inhibitory to nonantigen-specific (e.g., polyclonal) as compared to antigen-specific responses. This led to the hypothesis that constituents of serum (or plasma) may serve naturally to minimize the polyclonal type of antibody response, preserving immune specificity. The present study further examined the effect of NMS on polyclonal versus antigen-specific antibody responses. Under the in vitro assay conditions used, 0.5% NMS supported bacterial endotoxin (ET)-induced mitogenic and polyclonal B lymphocyte responses, antigen (SRBC, TNP-KLH)-specific antibody (IgM, IgG) responses, and antigen-induced or -specific T-lymphocyte proliferative responses, while 5% NMS inhibited all of these responses. However, antigen-specific T-lymphocyte responses could be restored by a 10-fold increase in the antigen concentration and antigen-specific antibody responses could be restored by the addition of ET (10 micrograms/ml) as adjuvant. On the other hand, the mitogenic response to ET remained suppressed regardless of ET concentration. Thus, despite significant reduction of the mitogenic and polyclonal properties of ET in 5% NMS (greater than 70% suppression), sufficient antigenic stimuli permitted optimal specific T- and B-cell responses. Many naturally occurring antigens, e.g., bacterial, fungal, and viral, have inherent B-cell mitogenic and polyclonal activity in addition to adjuvanticity and the presence of the serum inhibitory factor may serve to minimize their indiscriminate polyclonal stimulation of antibody.     

Anti-IgM but not anti-IgD antibodies inhibit cell division of normal human mature B cells.

Insolubilized anti-IgD antibody markedly increased DNA synthesis in and cell division of normal peripheral blood B cells (PBL-B) when used in combination with IL-4. Anti-IgM antibodies also induced DNA synthesis of PBL-B, but their ability to induce cell division was less than that of anti-IgD antibodies even when used in combination with IL-4. Moreover, anti-IgM antibodies inhibited cell division of PBL-B stimulated with insolubilized anti-IgD antibody plus IL-4 without affecting DNA synthesis. Anti-IgM antibodies also inhibited Staphylococcus aureus Cowan I-induced cell division of PBL-B without affecting DNA synthesis. These results indicate that cross-linkage of surface IgM (sIgM) in mature B cells generates negative signals to inhibit cell division of mature B cells. Because anti-IgD antibodies did not inhibit cell division at all, the role of sIgD in the regulation of cell division of mature B cells may be quite different from that of sIgM. IFN-alpha/beta promoted cell division of PBL-B stimulated with insolubilized anti-IgD antibody plus IL-4. They also counteracted the inhibitory effect of anti-IgM antibody on cell division of PBL-B.     

Behavior of the idiotypic network in conventional immune responses. II. Affinity and heterogeneity of idiotypic and anti-idiotypic antibodies following immunization with T-independent and T-dependent antigens.

The relative affinity and heterogeneity of affinity of idiotypic and anti-idiotypic antibodies in mice immunized with the T-independent antigen DNP-Ficoll and the T-dependent antigen DNP-HGG were measured by a plaque inhibition assay. Idiotypic plaque-forming cells (PFC) were detected by a conventional assay utilizing DNP-coated SRBC. Anti-idiotypic PFC were detected with SRBC coated with affinity-purified anti-DNP antibody of rabbit origin. It was found that both idiotypic and anti-idiotypic antibodies elicited by immunization with the T-independent antigen had lower affinity and were less heterogeneous than the corresponding antibodies originating in mice immunized with the T-dependent antigen. In addition, the affinity and heterogeneity values of the idiotypic antibodies were correlated with the affinity and heterogeneity values of the anti-idiotypic antibodies from the same mice. This finding indicates that idiotypic and anti-idiotypic antibodies mutually regulate each other, thus pointing to internal immunoregulatory effects of the idiotypic network with respect to these parameters.     

Cell-associated IgM, but not IgD or I-A/E, is important in the activation of suppressor T cells by antigen-primed B cells

The ability of transferred antigen-primed immune B cells to induce T cell-mediated suppression of the antibody response to Type III pneumococcal polysaccharide (SSS-III) could be blocked or eliminated by prior treatment of B cells with F(ab')2 anti-Ig or anti-IgM antibodies; however, F(ab')2 anti-IgD antibodies, or M5/114 (monoclonal anti-I-A/E antibody), had no effect on activation of suppression by SSS-III-primed B cells. Thus, cell-associated IgM antibody plays an important role in the activation of suppressor T cells during the antibody response to SSS-III.     

Flow sorting of antigen-binding B cell subsets

Antigen binding was used as a probe in the definition of functional B cell heterogeneity. Unprimed, anti-Thy 1 and complement-treated spleen cells were stained with fluorescent trinitrophenylated bovine serum albumin (FL-TNP-BSA). These cells were sorted, fluorescence negative from fluorescence positive, by using a multiparameter cell sorter and assayed for precursor frequency in antibody responses to TNP by limiting dilution analysis. The cells that bound FL-TNP-BSA were demonstrated to be enriched for antibody-forming precursors to the antigens TNP-lipopolysaccharide (LPS), TNP-sheep red blood cells (SRBC), and TNP- or DNP-Ficoll, whereas the fluorescence negative cells were depleted for these responses. B cells that bound FL-TNP-BSA were then sorted into populations that bound a moderate or high amount of FL-TNP-BSA. The B cells responsive to TNP-LPS and TNP-SRBC were present in both the moderate and high binding populations. In contrast, the B cells responsive to TNP- or DNP-Ficoll were present only in the cells that bound a moderate amount of FL-TNP-BSA. These experiments suggest that there is a population of B cells in adult mouse spleen that binds large amounts of antigen, and that can respond to antigen carried on LPS or SRBC but not carried on Ficoll.     

Modulation of mouse anti-SRBC antibody response by placental extracts

Mouse placental extracts (PE) and corresponding Sephadex G-200 fractions were administered to isogeneic CBA mice along with an optimal immunizing dose of SRBC. Spleen cells were harvested 8 days later and transferred to CBA recipients, subsequently immunized with SRBC. The immunoregulatory activity of spleen cells from PE-treated donors was compared to cells from liver extract (LE)-treated controls or from mice immunized with SRBC only, using Cunningham's PFC direct and indirect tests. Within the dose range used, selective modulatory activities were obtained with cells from PE, but not from LE, treated mice, the latter being comparable to cell transfer effects from donors immunized with SRBC only. Spleen cells from animals injected with low doses of PE (0.25 to 4 mg per mouse) added to immunizing SRBC had a suppressive effect on the primary IgM response of recipients immunized against SRBC. In contrast, when SRBC were given to donor animals with higher doses of PE (8 to 13 mg), transferred spleen cells potentiated the IgM response of the recipients. These opposite suppressive and potentiating activities were found in distinct Sephadex G-200 fractions of 40 and 60 kDa, respectively. When the effect of PE treatment was tested within the same animal, the indirect secondary PFC response following a challenge with SRBC was significantly modified. We observed an overall suppression of the different isotypes after treatment with lower doses of PE or with its 40-kDa fraction. PE doses of 0.5 to 2 mg resulted in a stronger inhibition of IgM than IgG₁ production. This phenomenon was also obtained with the 40 KDa fraction. IgG₂ responses were significantly reduced by all doses of this fraction. In contrast, all doses of the 60-kDa fraction gave a strong stimulation of IgG₂ and IgM responses and a constant suppression of the IgG₁ response. This shows a clear dissociation between IgG₁ and C'-fixing (IgM, IgG₂) antibody classes as far as the influence of placental substances is concerned in their regulation. These data emphasize the relevance of isogeneic placental products as a useful physiological material capable of modulating xenogeneic immune responses (as well as allogeneic systems).     

Brood size and immunity costs in zebra finches Taeniopygia guttata

Birds rearing experimentally enlarged broods have lower antibody responses to a novel antigen, and we tested three hypotheses that could explain this result. We used zebra finches Taeniopygia guttata inoculated with sheep red blood cells (SRBC) as a study system, for which this trade-off was previously demonstrated. 1. Compensatory cellular immunity: The humoral immune response is slow, and removal of SRBC through up-regulated cellular immunity could pre-empt an antibody response. However, cellular immune response to PHA decreased with increasing brood size, allowing rejection of this hypothesis. 2. Costs of antibody-production: Chicks in large broods grow less well, and birds with large broods may allocate resources to chicks instead of antibodies when these are costly. Compared to saline controls, SRBC suppressed metabolic rate in the hours following immunisation, but there was no effect in the following night, or at any time 4 and 8 days later. Fitness costs were measured by repeatedly immunising parents with SRBC while rearing young. Chick growth, parental condition, and subsequent reproduction of the parents were not affected by SRBC. We conclude that the costs of antibody formation cannot explain the trade-off between brood size and antibody responsiveness. 3. Costs of immune system maintenance: Maintaining a system enabling antibody-formation may be very costly, and birds rearing large broods may have down-regulated this system. Based on this hypothesis we predicted that antibody formation would still be reduced in parents rearing large broods when immunised after rearing the chicks. Our results confirmed this prediction, and we suggest that birds rearing large broods have lower antibody responses because they economised on the maintenance costs of the immune system.