Regulation of IgG responses by helper and suppressor T cells activated by pneumococcal capsular polysaccharides

Type 2 antigens are usually unable to prime the helper T cells (TH) required for secondary IgG antibody responses. However, previous results from this laboratory indicated that low doses of the type 2 antigen polyvinylpyrrolidone (PVP) could activate T cells which provided help to PVP-primed B cells for the production of PVP-specific IgG antibody. Therefore, it was of interest to determine if other type 2 antigens may also be able to activate TH. Low doses of S19 or S3 (subimmunogenic for a primary IgM response) activated TH capable of providing help to S19- or S3-CRBC-primed B cells for a secondary IgG response. Higher doses of these antigens (optimally immunogenic for a primary IgM response) activated suppressor T cells (TS). Removal of these TS prior to transfer of T cells to recipient mice resulted in expression of TH function. Therefore, the preferential activation of TH versus TS was dependent on the dose of antigen used for priming. TH activated by low doses of S19 expressed Thy 1 and L3T4 and were antigen specific. In contrast to the ability of low doses of PVP to prime B cells for secondary IgG responses, low doses of S3 and S19 did not prime capsular polysaccharide-specific IgG memory B cells. High doses of S3 were able to prime B cells if TS precursors were first removed by treatment of mice with cyclophosphamide (Cy), whereas high doses of S19 did not prime B cells for secondary IgG responses in either Cy-treated or control mice. These results are discussed in relation to the general observations that type 2 antigens may not activate antigen-specific TH.     

Structural requirements for in vivo and in vitro immunogenicity in hapten-specific delayed hypersensitivity

Affinity changes of hapten-specific IgM antibodies were analysed by plaque inhibition assays and by inhibition with varying quantities of monovalent inhibitor. The resulting data were used for cell population studies, based on the affinity of plaque-forming antibody. Maturation of IgM plaque-forming cell populations was time- and antigen dose-dependent. Maturation was characterized by a consistent increase in the proportions of high affinity and medium affinity cells and a decrease in the proportion of low affinity cell populations. Thus progressive selection of high affinity cells occurred over the entire dose range of immunization. The hapten concentration at which 20% of cells was inhibited decreased with time at all administered antigen concentrations. The inhibitory hapten concentration at which 50 or 70% of cells was inhibited did not change after administration of very large immunizing doses. Thus recruitment of this type of plaque-forming cell depended on dose. In the secondary response, high affinity cells appeared initially but very transiently, and the subsequent rate of population changes was faster than that observed in the primary response. The short productive life of IgM plaque-forming populations may be responsible for the time restriction in IgM as compared to IgG maturation.     

Variations in the responses of C57BL and a mice to sheep red blood cells: II. Analysis of plaque-forming cells

The number of direct and indirect plaque-forming cells (PFC) and the serum hemolytic activity was determined for A/He, C57BL/6J, and B6AF1 mice responding to multiple injections of sheep red blood cells (SRBC). Although the kinetics of the primary response differed, all mice had high numbers of both direct and indirect PFC and low-titered 2-mercaptoethanol (2-ME) sensitive serum antibody. Following multiple SRBC injections, the A/He spleens contained predominantly IgG producing PFC. Their serum antibody activity was resistant to 2-ME signifying the presence of IgG. The serum activity of both the C57BL/6J and B6AF1 mice was sensitive to 2-ME (IgM antibody) over the course of immunization, and although there was a definite IgM PFC memory response, the presence of 7S memory PFC was questionable. The results are discussed in terms of the maturation of the antibody response to SRBC and of the question of the postulated IgM and IgG switch.     

The influence of immune complex-bearing follicular dendritic cells on the IgM response, Ig class switching, and production of high affinity IgG

It is believed that Ag in immune complexes (ICs) on follicular dendritic cells (FDCs) selects high affinity B cells and promotes affinity maturation. However, selection has been documented in the absence of readily detectable ICs on FDCs, suggesting that FDC-ICs may not be important. These results prompted experiments to test the hypothesis that IC-bearing murine FDCs can promote high affinity IgG responses by selecting B cells after stimulating naive IgM(+) cells to mature and class switch. Coculturing naive lambda(+) B cells, FDCs, (4-hydroxy-3-nitrophenyl)acetyl-chicken gamma-globulin (CGG) + anti-CGG ICs, and CGG-primed T cells resulted in FDC-lymphocyte clusters and production of anti-4-hydroxy-5-iodo-3-nitrophenyl acetyl. Class switching was indicated by a shift from IgM to IgG, and affinity maturation was indicated by a change from mostly low affinity IgM and IgG in the first week to virtually all high affinity IgG anti-4-hydroxy-5-iodo-3-nitrophenyl acetyl in the second week. Class switching and affinity maturation were easily detectable in the presence of FDCs bearing appropriate ICs, but not in the absence of FDCs. Free Ag plus FDCs resulted in low affinity IgG, but affinity maturation was only apparent when FDCs bore ICs. Class switching is activation-induced cytidine deaminase (AID) dependent, and blocking FDC-CD21 ligand-B cell CD21 interactions inhibited FDC-IC-mediated enhancement of AID production and the IgG response. In short, these data support the concept that ICs on FDCs can promote AID production, class switching, and maturation of naive IgM(+) B cells, and further suggest that the IC-bearing FDCs help select high affinity B cells that produce high affinity IgG.     

Studies on the control of antibody synthesis. IX. Effect of boosting on antibody affinity.

The effect of boosting on antibody affinity was studied in a haptenic system. Generally, boosting results in the prompt synthesis of high affinity anti-hapten antibody. However, repeated boosting frequently leads to a decrease in the amount and affinity of the serum antibody. Repeated boosting with hapten on a carrier different from that used for priming selectively stimulates synthesis of the highest affinity anti-hapten antibody and does not result in a decrease in affinity. Priming with soluble antigen without adjuvants results in the synthesis of low affinity antibody. After such priming, boosting stimulates low affinity antibody synthesis and repeated boosting leads to a moderate increase in antibody affinity.     

Optimal strategies in immunology III. The IgM-IgG switch

Summary During a primary immune response generally two classes of antibody are produced, immunoglobulin M (IgM) and immunoglobulin G (IgG). It is currently thought that some lymphocytes which initially produce IgM switch to the production of IgG with the same specificity for antigen. During a secondary immune response IgG is the predominant antibody made throughout the response. In this paper we address the question of why such apparently complicated modes of response should have been adapted by evolution.We construct mathematical models of the immune response to growing antigens which incorporate complement dependent cell lysis. By comparing the times required to eliminate antigen we show that under certain conditions it is advantageous for an animal to switch some of its lymphocytes from IgM to IgG production during a primary response, but yet to secrete only IgG during a secondary response. The sensitivity of such a conclusion to parameter variations is studied and the biological basis and implications of our models are fully discussed.Portions of this work were performed under the auspices of the U.S. Department of Energy. A.S.P. was also supported by the National Science Foundation under Grant No. ENG-7904852 and BRSG grant S07 RR05664-11 awarded by the Biomedical Research Support Grant Program, Division of Research Resources, National Institute of Health. A.S.P. is the recepient of an NIH Research Career Development Award 1K04 AI 00357-01. S.R. was a recipient of NIH Fellowship 5 F32 AI05107-02     

Generation of B cell memory and affinity maturation. Induction with Th1 and Th2 T cell clones.

We used an adoptive transfer system and CD4+ T cell clones with defined lymphokine profiles to examine the role of CD4+ T cells and the types of lymphokines involved in the development of B cell memory and affinity maturation. Keyhole limpet hemocyanin (KLH)-specific CD4+ Th2 clones (which produce IL-4 and IL-5 but not IL-2 or IFN-gamma) were capable of inducing B cell memory and affinity maturation, after transfer into nude mice or after transfer with unprimed B cells into irradiated recipients and immunization with TNP-KLH. In addition, KLH-specific Th1 clones, which produce IL-2 and IFN-gamma but not IL-4 or IL-5, were also effective in inducing B cell memory and high affinity anti-TNP-specific antibody. The induction of affinity maturation by Th1 clones occurred in the absence of IL-4, as anti-IL-4 mAb had no effect on the affinity of the response whereas anti-IFN-gamma mAb completely blocked the response. Th1 clones induced predominantly IgG2a and IgG3 antibody, although Th2 clones induced predominantly IgG1 and IgE antibody. We thus demonstrated that some Th1 as well as some Th2 clones can function in vivo to induce Ig synthesis. These results also suggest that a single type of T cell with a restricted lymphokine profile can induce both the terminal differentiation of B cells into antibody secreting cells as well as induce B cell memory and affinity maturation. Moreover, these results suggest that B cell memory and affinity maturation can occur either in the presence of Th2 clones secreting IL-4 but not IFN-gamma, or alternatively in the presence of Th1 clones secreting IFN-gamma but not IL-4.     

Central role of T lymphocytes in specific recognition of tumor antigens in 51Cr-leukocyte adherence inhibition

The plaque-forming cell (PFC) response of C57BL/6 mice to NP-coupled sheep red blood cells can be inhibited by administration of microgram doses of a variety of monoclonal anti-NP antibodies of various isotypes prior to immunization. NP-specific PFC are most strongly affected but a drastic reduction of the SRC-specific response also occurs. The latter depends on physical association of the immunizing red cells with NP groups. Inhibition was obtained with antibodies of all IgG subclasses, but was marginal or absent when up to 100 μg IgM or IgD antibodies or F(ab′)₂ fragments were administered. Our experiments lead us to conclude that antibody feedback inhibition is not the function of a particular IgG subclass and that the role of the variable region in feedback inhibition is sufficiently explained by its affinity for the antigen. It was noted that small doses of a monoclonal NP-specific IgM antibody failed to enhance the response to NP-SRC.     

Genetic regulation of the antibody response to H-2Db alloantigens in mice. IV. Antigens that activate helper T cells for IgG, coded for by the non-H-2 genome

When B10.A(5R) mice are immunized with congenic C57BL/10 cells only 2-ME-sensitive antibodies (IgM type) are found directed against H-2Db. To obtain 2-ME-resistant antibodies (IgG type) 5R mice must be immunized with noncongenic cells (e.g., A.BY); in this case non-H-2 cell surface antigens will activate helper T cells to induce anti-Db IgG antibody production by B cells. An attempt was made to define helper antigens that activate helper T cells. Neither N-2 antigens of seven H-2Db recombinant strains nor a limited set of non-H-2 cell surface antigens were able to serve as helper antigens. By using individual backcross mice as antigen, one helper antigen was found on the background of strain A under the conditions used, whereas other backgrounds may carry more than one antigen. The helper antigen is dominantly expressed in F1 mice and has to be presented on the same cell as H-2Db to induce the switch from IgM to IgG.     

Fish immunoglobulins and the genes that encode them

The nature of fish antibodies (concentrating primarily on the most studied species of bony and cartilaginous fishes) is discussed in terms of their immunoglobulin biochemistry and immunobiology. The major serum immunoglobulin (IgM) is described in detail, and structural variants of IgM are discussed in terms of their distribution in different fish species, and different anatomical sites within a fish (e.g. blood, mucus, bile). Structural variation in IgM includes the size of the constituent heavy and light polypeptide chains, and the extent to which they are covalently associated with one another. The intramolecular heterogeneity of binding sites for antigen on IgM is reviewed and possible mechanisms for the phenomenon are presented. The evidence suggests that some, but not all, species of fish possess a detectable J chain in their IgM. The general nature of the fish immune response is that IgM antibody of moderate affinity is produced and prolonged or repeated immunization: (a) fails to produce a switch to production of a non-IgM class of antibody, and (b) fails to induce substantial increases in the affinity of the specific antibodies. Evidence supports a conclusion that fish lack the typical secondary antibody response seen in mammals, and possess antibodies of limited heterogeneity. Our current understanding of the genetic basis for fish antibodies is presented. Fish appear to utilize the same basic genetic elements as mammals to encode and regulate the expression of their immunoglobulins. The teleost heavy chain (IgH) locus resembles that of mammals and amphibia in its organization. The IgH locus of elasmobranchs is arranged in a unique multicluster organization. The light chain loci of elasmobranchs are organized analogously to the heavy chain locus (in multiclusters). The structure of the light chain locus of teleosts is presently unknown. Teleost fish utilize a unique pattern of RNA processing to generate the secreted and membrane receptor forms of the IgM heavy chain. The genes encoding the unique low molecular weight Ig heavy chain found in skates and rays have been cloned and sequenced, and also display the multicluster pattern of organization. Teleost fish appear to have normal numbers of variable regions: it is hypothesized (but as yet unproven) that the failure of their IgM to increase in affinity is due to a deficiency of somatic hypermutational mechanisms in their Ig gene variable regions during B lymphocyte differentiation.     

Estimation of relative antibody affinity at the level of the antibody-secreting cell during maturation of the immune response

The relative affinity of specific antibody secreted by mouse spleen cells following primary immunization with SRBC was estimated by competitive inhibition assay of antibody secreted by PFC as well as by inhibition of observed PFC number. Inhibition of direct and of indirect anti-SRBC plaque assays by the addition of specific antigen (SRBC stromata) gave sigmoid inhibition profiles from which the concentration of antigen required to inhibit 50% of the plaques (PI₅₀) was determined, Alternatively, the sum of the cube of individual plaque diameters (Σd³) provided a measure of total anti-SRBC antibody secreted by PFCs from which the concentration of antigen required to inhibit 50% of the antibody (Ab₅₀) was determined. Ab₅₀, rather than PI₅₀: (a) was a more sensitive measure of inhibition by antigen; (b) decreased following immunization indicating a progressive increase in mean antibody affinity; and (c) correlated with the results of hemolysin transfer experiments, an independent measure of mean affinity of circulating anti-SRBC antibody. From theoretical considerations, estimation of mean antibody affinity requires quantitative analysis of fractional antibody inhibition by antigen. Determination of Ab₅₀, rather than PI₅₀, provides an estimate of bound and of free antibody and therefore should provide a more valid estimate of the relative antibody affinity at the cellular level. Experimentally, utilizing Ab₅₀ analysis, the IgM and IgG responses of C3H mice to immunization with SRBC demonstrated a progressive increase in affinity during maturation of the immune response.     

The class of surface immunoglobulin on virgin and memory B lymphocytes.

The class of surface immunoglobulin receptors for antigen on B cell precursors of different classes of antibody-forming cells was determined by utilizing a technique of class-specific antigen suicide. Spleen cells are first treated with a class-specific antiserum under conditions that result in the stripping of that class from the cell surface. The cells are then permitted to bind a highly radioactive trinitrophenyl (TNP)-conjugated protein, which leads to lethal irradiation of all TNP-specific B cells except those whose TNP receptors had been removed by the class-specific stripping of surface immunoglobulin. In this way, the class of antibody-forming cells resulting from TNP stimulation of B cells with different classes of surface immunoglobulin can be examined. It was found that the virgin B cell precursors of IgM-producing cells are two types: cells bearing IgM receptors only and those bearing both IgM and IgD receptors. All virgin B cells that gave rise to IgG1 antibody-forming cells had both IgM and IgD on their surfaces, demonstrating that an antigen-dependent switch from IgM and IgD to IgG1 production is a common feature of B cell maturation. In contrast, memory B cell precursors of IgG1 antibody-forming cells had predominantly IgG1 as their surface antigen receptor. The implications of these findings on current models of B cell maturation are analyzed.     

Studies on the control of antibody synthesis. XIV. Role of T cells in regulating antibody affinity.

The effect of limiting the number of helper T cells on the affinity of the primary antibody response to a T-dependent antigen (DNP-BGG) was evaluated in a cell transfer system. Lethally irradiated, thymectomized mice were reconstituted with either bone marrow or anti-brain θ antiserum plus complement-treated spleen as the source of B cells. In addition, they received various numbers of thymus cells as a source of helper T cells. The animals were immunized with DNP-BGG 1 day after cell transfer and their splenic anti-DNP PFC response was assayed for magnitude and affinity 3 weeks later. A marked restriction in helper T-cell activity resulted in a primary response which was of low magnitude, which lacked indirect PFC, and which had a very low affinity and restricted heterogeneity. When sufficient thymus cells were given to permit a switch to indirect plaque formation, a highly heterogeneous, high-affinity primary response was elicited. Further increase in the number of thymic cells resulted in a progressive increase in the magnitude of the primary response but had no effect on affinity. Thus, a reduction of 50% in the magnitude of the response as a consequence of limiting the number of T-helper cells had no effect on the affinity of the PFC. The results are consistent with the interpretation that the effect of restriction in T-cell help on antibody affinity is not due to a direct effect on precursors of high-affinity PFC but is secondary to inefficient selection for high-affinity cells when the degree of cell proliferation is markedly reduced.     

Immunological memory to tetanus toxoid is established and maintained in the vitamin A-depleted rat

We have previously shown that vitamin A deficiency severely impairs the young rat's ability to produce specific antibodies after primary immunization with tetanus toxoid (TT). In the present studies, we asked whether immunologic memory to TT is established even in the vitamin A-depleted animal, and if so, whether such memory can be elicited after subsequent repletion with retinol. Vitamin A-depleted rats produced very low concentrations of TT-specific IgM and IgG antibodies in both the primary and secondary responses; however, the ratios of secondary to primary IgM anti-TT and of IgG anti-TT were normal. When rats were repleted with retinol 1 day after immunization, IgM and IgG anti-TT concentrations in both the primary and secondary responses were at least as great as those of control rats. For rats repleted with retinol 2 days before the booster immunization, secondary IgM and IgG anti-TT concentrations were equal in magnitude to those of vitamin A-sufficient controls. For all groups, the kinetics of the antibody response were similar. We conclude that immunological memory is intact in the vitamin A-depleted animal, as shown by 1) the normal ratio of its secondary to primary antibody responses, 2) the restoration of a quantitatively normal secondary antibody response in previously vitamin A-depleted animals repleted with retinol just before boosting with TT, and 3) a normal class switch from IgM to IgG. Retinol deficiency is also characterized by an abnormal elevation of total plasma IgG, despite the inability of the vitamin A-depleted animal to produce normal quantities of specific antibodies after challenge with antigen.     

Comparative effect on humoral response of four different proteins covalently linked on BSA-containing liposomes

The humoral response to encapsulated BSA appears to be a classical TD antigen response with a high ratio of IgG to IgM, whereas that to covalently-linked antigen is more complex, characterized by an enhanced synthesis of IgM, leading to an equal production of IgM and IgG. In a recent paper, we observed that surface-linked Con A on BSA-containing liposomes changed the isotype distribution to encapsulated BSA so as to mimic the response to surface-linked antigen. In the present study, we compared the immune response to BSA in BALB/c mice immunized with the antigen encapsulated into liposomes coated with one of four different proteins: Con A, Myo, MSA, or PWM. The humoral response was analyzed by measurements of antibody production (total Ig, IgM, and IgG isotypes) on serum samples obtained by cardiac puncture. It can be concluded from our results that any surface-linked protein may affect the interaction between liposome-associated antigen and immunocompetent cells.     

Differential immunosuppressive effects of ascites fluid from mastocytoma-bearing mice on primary vs secondary immunocyte responses.

The effects of immunosuppressive ascites fluids from mastocytoma-bearing mice on the primary vs secondary immune response to sheep red blood cells (SRBC) was examined. Injection of mice with ascites fluid from tumor-bearing mice markedly depressed the primary immune response of normal syngeneic mice challenged with SRBC. However, there was a preferential depression of the 19S IgM antibody response as compared with the 7S IgG response. Injection of ascites fluid shortly before secondary immunization of mice with SRBC also resulted in depressed IgM PFC responses but only a slight to moderate depression of IgG PFC. Treatment of mice with the ascites fluid before primary immunization had little if any effect on the secondary IgG PFC response, although the IgM response was moderately depressed. These results indicate that the immunosuppressive factor(s) present in the ascites fluid of mastocytoma-bearing mice has a differential effect on distinct classes of immunocytes. Those immunocytes or their precursors involved in formation of low efficiency 7S IgG antibody are more resistant to immunodepression. Such differences appear due to different sensitivities of cells involved in the immune response system.     

Regulation of the secondary in vitro antibody response by endogenous natural killer cells: kinetics, isotype preference, and non-identity with T suppressor cells

Our previous studies had demonstrated that depletion of endogenous natural killer (NK) cells resulted in an augmented primary antibody response in vivo and in vitro. We have now examined the effect of NK cell depletion on the in vitro secondary response to antigen. Treatment of primed murine spleen cells with anti-NK-1.1 allo-antibody and complement before culture resulted in a significant increase in the magnitude of the antigen-specific plaque-forming cell (PFC) response. This treatment did not affect the proportions of Lyt-2+, L3T4+, or sIg+ cells in the population, however, indicating that the augmentation in PFC was not due to changes in the ratio of T to B cells. Removal of endogenous NK cells had a greater effect on the IgG (indirect) PFC response (100 to 200% increase) than on the IgM (direct) PFC response (25 to 50% increase). In contrast, removal of Lyt-2+ cells before culture affected the IgM and IgG responses similarly. Moreover, the kinetics of augmentation differed between cultures depleted of Lyt-2+ cells and those depleted of NK-1.1+ cells. NK cells appeared to act earlier in the response than did T suppressor cells. The NK-1.1+ cells involved in antibody regulation were not involved in the generation of the in vitro derived T suppressor cells. The conclusion that the regulation of the antibody response by NK-1.1+ cells is distinct from that involving T suppressor cells was confirmed in experiments in which removal of both regulatory cell populations resulted in an increase in PFC that was greater than in cultures depleted of either NK or T suppressor cells.     

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.     

Comparison of naturally acquired antibody responses against the C-terminal processing products of Plasmodium vivax Merozoite Surface Protein-1 under low transmission and unstable malaria conditions in Sri Lanka

We report here, for the first time, a comparison of naturally acquired antibody responses to the 42 and 19 kDa C-terminal processing products of Plasmodium vivax Merozoite Surface Protein-1 assayed by ELISA using p42 and p19 baculovirus-derived recombinant proteins, respectively. Test populations comprised patients with microscopy confirmed acute P. vivax infections from two regions endemic for vivax malaria where low transmission and unstable malaria conditions prevail, and a non-endemic urban area, in Sri Lanka. The antibody prevalence to the two proteins, both at the individual and population levels, tend to respond more to p42 than to p19 in all test areas, where >14% of individuals preferentially recognized p42, compared with <2% for p19. In patients with no previous exposure to malaria, 21% preferentially recognized p42, whereas none exclusively recognized p19. A significantly lower prevalence of anti-p19 IgM, but not anti-p42 IgM, was observed among residents from endemic areas compared with their non-endemic counterparts. Individuals from both endemic areas produced significantly less anti-p19 IgM compared with anti-p42 IgM. IgG1 was the predominant IgG isotype for both antigens in all individuals. With increasing exposure to malaria in both endemic areas, anti-p19 antibody responses were dominated by the functionally important IgG1 and IgG3 isotypes, with a concurrent reduction in IgM that was lacking in the non-endemic residents. This antibody switch was also reflected for PvAMA-1 as we previously reported with the identical battery of sera. In contrast, the antibody switch for p42 was restricted to endemic residents with more extensive exposure. These results suggest that an IgM-dominated antibody response against the p42 polymorphic region in endemic residents may interfere with the development of an IgG-dominated "protective" isotype shift to p19, that may complicate vaccine development.     

On the control between cell-mediated, IgM and IgG immunity

An hypothesis is proposed here describing some of the conditions that determine the type of response an antigen will induce, and explaining how the induction of one type of immunity affects the induction of other types of immunity. In more detail, the hypothesis attempts to account for the following observations: Some antigens induce only cell-mediated immunity, whereas others can, under different conditions, induce either cell-mediated or humoral immunity. The humoral response to most antigens consists of an initial period of IgM antibody synthesis, followed by a period of IgG synthesis. Some polymeric antigens induce the synthesis of only IgM antibody. There is a tendency for the immune response to an antigen, at a particular time, to be exclusively of the cell-mediated, IgM or IgG type.The hypothesis may also be relevant to some observations that, I believe, have been incorrectly interpreted to mean that “tolerance” to some antigens requires the presence of T (thymus-derived) cells specific for these antigens. The hypothesis suggests teleological reasons for the existence of the different types of immunity. It also suggests ways of controlling the type of response an antigen induces.