Ontogeny of murine B-cell responses to thymus-independent trinitrophenyl antigens.

The ontogeny of B-cell responsiveness to three thymus-independent trinitrophenyl (TNP) antigens has been examined in BALB/c mice in vivo and in vitro. When in vivo splenic plaque-forming cell (PFC) responses to TNP-conjugated lipopolysaccharide (TNP-LPS), Ficoll (TNP-Ficoll), and Brucella abortus (TNP-Brucella) were measured in neonatal and adult mice, a defined sequence of responsiveness was observed. Newborn mice responded well to TNP-LPS, but not to TNP-Ficoll or TNP-Brucella. Neonates injected at 1 day of age responded to TNP-LPS and TNP-Ficoll and mice 5 to 14 days of age responded to TNP-LPS, TNP-Ficoll, and TNP-Brucella. Furthermore, the antigen-reactive populations increased at different rates for the three antigens in the first 2 weeks of life. In vitro experiments confirmed the results obtained in vivo although slightly earlier responsiveness to TNP-Brucella was observed in vitro. PFC inhibition assays with free TNP hapten were performed so that avidity profiles could be examined in neonatal and adult anti-TNP PFC responses. The results clearly demonstrate that once a response becomes detectable in neonatal mice immunized with any of the three TI TNP antigens, fully heterogeneous or “adult-like” responses are found. In addition, experiments comparing avidity profiles in athymic (nu/nu) BALB/c mice and their normal (nu/+) littermates demonstrate that T cells are not required for the generation of fully heterogeneous anti-TNP PFC responses. These results indicate that B cells responsive to different TI TNP antigens mature at different times and at different rates during ontogeny. Late maturation events of such B cells do not include the acquisition of additional V-region specificities as detected in a PFC inhibition assay.     

Differentiation of B-cell subsets after antigen priming.

Short-term DNP-Ficoll priming results in an increased number of in vitro TNP-LPS sensitive cells. This increase is less pronounced after TNP-LPS priming. Both effects are additive, indicating the existence of separate subpopulations of B cells responding to LPS and Ficoll. A similar phenomenon occurs with TNP-LP priming, being more evident in C3H/Tif mice (which have different subsets of B cells responding to LP and LPS). The evolution in the number of anti-TNP precursors after a similar priming schedule is consistent with the above results. These data are in line with the hypothesis of an antigen-driven B1 → B2 switch which affects the synthesis of carrier receptors.     

Modulation of Immune Response by Bacterial Lipopolysaccharide (LPS): Roles of Macrophages and T Cells in In Vitro Adjuvant Effect of LPS on Antibody Response to T Cell-Dependent and T Cell-Independent Antigens

The roles of macrophages and T cells in the adjuvant effect of lipopolysaccharide (LPS) were studied. In vitro anti-trinitrophenyl (anti-TNP) antibody responses to TNP-Ficoll and TNP-keyhole limpet hemocyanine (TNP-KLH) in spleen cells of C57BL/6 mice showed the most enhancement, when LPS was added to cultures at 1 μg/ml 48 hr after culture was started. The responses to these antigens were enhanced markedly by LPS in whole and macrophage-depleted spleen cells. The enhancement was greater in the latter group than in the former. The adjuvant effect among whole, T cell-depleted, macrophage-depleted and both macrophage- and T cell-depleted spleen cells was compared. The response to TNP-Ficoll was enhanced markedly by LPS in all groups. The enhancement was greater in the latter two groups than in the first two groups. The response to TNP-KLH was enhanced by LPS strongly in macrophage-depleted spleen cells, moderately in whole and both macrophage- and T cell-depleted spleen cells, and only slightly in T cell-depleted spleen cells. Enhancement was restored to T cell-depleted spleen cells by adding T cells. The response to TNP-KLH of macrophage-depleted spleen cells of LPS-responsive C3H/HeN mice which was enhanced by LPS was suppressed by adding splenic macrophages of C3H/HeN mice, but not of LPS-nonresponsive C3H/HeJ mice. The response to TNP-KLH of macrophage-depleted spleen cells of C3H/HeJ mice was not enhanced by LPS, irrespective of the addition of macrophages of C3H/HeN mice. The results indicate that B cells are activated directly by LPS, and T cells enhance and macrophages suppress the adjuvant effect of LPS.     

Generation of immune memory by haptenated derivatives of thymus-independent antigens in C57BL/6 mice. I. The differentiation of memory B lymphocytes into antibody-secreting cells depends on the nature of the thymus-independent carrier used for memory induction and/or revelation

It has been previously reported that trinitrophenylated lipopolysaccharide (TNP-LPS), a thymus-independent (TI)-1 antigen, elicits an anamnestic response to TNP in C57BL/6 mice. The ability of these mice to mount a secondary response to TI-2 antigens was analyzed. Priming with DNP-Ficoll or DNP-Dextran, both TI-2 antigens, resulted in an increased frequency of TNP-binding B lymphocytes. Evidence is presented that memory cell-induction by DNP-Ficoll does not require functional T cells. The differentiation into antibody-forming cells (AFC) of memory cells generated by DNP-Dextran or DNP-Ficoll cannot be obtained by a challenge with either antigen. There was no indication that the lack of a secondary response to TI-2 antigens was related to suppressive T cells interfering with memory expression. Memory cells induced by DNP-Dextran or DNP-Ficoll can nevertheless be activated by TNP-LPS. In contrast to the restricted sensitivity of TNP-memory cells generated by TI-2 antigens, TNP-LPS-induced memory cells are indifferently susceptible to TI-1 or TI-2 antigenic stimulation. These results are discussed in terms of memory B-cell subpopulations.     

Immunoregulation in the rat: requirements for in vitro B cell responses to classical TI-1 and TI-2 antigens

The presence of suppressor cells and their mediators has made it difficult to induce B cell mitogenic or immune responses in rat spleen cell cultures. In the present study, we have defined culture conditions required for induction of in vitro thymic independent (TI) immune responses in the rat. Rat spleen cell cultures support low responses to various trinitrophenyl (TNP) haptenated antigens including TNP-Brucella abortus (TNP-BA), TNP-lipopolysaccharide [LPS; either phenol (Ph)- or butanol (Bu)-water extracted], TNP-Ficoll, and TNP-dextran. However, all of these antigens induced good splenic anti-TNP PFC responses when given at appropriate doses in vivo. When spleen cells were depleted of adherent cells and cultured with TI antigens in vitro, good anti-TNP PFC responses were seen with TNP-BA, whereas, lower responses were induced by TNP-LPS (Ph or Bu). No responses were observed in cultures incubated with either TNP-Ficoll or TNP-dextran. Purified splenic B cell cultures [prepared by panning on plates coated with anti-rat F (ab')2] supported good responses to TNP-LPS (Ph or Bu) and TNP-BA. The addition of irradiated splenic adherent cells (macrophages, M phi) to either M phi-depleted or purified B cell cultures completely abrogated in vitro responses to TNP-BA or TNP-LPS (Ph or Bu). Purified splenic B cell cultures generally responded poorly to TNP-Ficoll or TNP-dextran. Addition of indomethacin (IM) to spleen cell cultures abrogated suppression and allowed anti-TNP PFC responses to TNP-BA, TNP-LPS (Ph or Bu), TNP-Ficoll, and TNP-dextran. Furthermore, nude spleen cell cultures treated with IM, also allowed significant TNP-Ficoll and TNP-dextran immune responses; however, untreated cultures did not respond to these antigens. Our studies indicate that rat splenic B cell cultures are responsive to TI antigens, and highest responses occur with the murine TI-1 class, e.g., TNP-BA and TNP-LPS. Inhibition of suppression with IM restored splenic B cell responses to the murine TI-2 class, i.e., TNP-Ficoll and TNP-dextran.     

Priming of peripheral lymph node B cells with TNP-Ficoll: role of lymphokines in B cell differentiation.

We have previously shown that peripheral lymph node (PLN) B lymphocytes of adult DBA/2J mice failed to make an antibody response to type 2 antigen TNP-Ficoll, but exhibited a good antibody response to type 1 antigen TNP-Brucella abortus. In the present study we wanted to find out whether the unresponsiveness of PLN B cells to TNP-Ficoll is due to defects in the early activation and proliferation stage or in the final differentiation stage of B cells. Therefore, we have used a two-step protocol of in vivo immunization of mice with TNP-Ficoll and the subsequent in vitro challenge with TNP-Brucella abortus and studied the anti-TNP plaque-forming cell (PFC) responses. The results indicate a three- to sixfold increase of PFC responses in PLN cell cultures derived from TNP-Ficoll-primed animals compared to saline control mice. This increased antibody response was TNP-specific as 93% of the PFC's were inhibited by TNP-lysine. Limiting dilution experiments confirm that the increase in anti-TNP PFC response from the TNP-Ficoll-primed animals was indeed due to an increase in TNP-specific precursor B cells. Further, the addition of rIL-5 or rIL-6 induced anti-TNP PFC in the TNP-Ficoll-primed and in control PLN cell cultures in the presence of antigen. However, in primed PLN cells lymphokines alone were sufficient to restore anti-TNP PFC response. In conclusion, our results show that in PLN, the TNP-Ficoll can induce proliferation of hapten-specific B cells but not final differentiation. These primed PLN B cells mature into antibody-secreting cells upon stimulation with TNP-BA or lymphokines.     

Clonal anergy of memory B cells in epitope-specific regulation.

Immunization of carrier (keyhole limpet hemocyanin (KLH)) primed mice with the hapten-carrier TNP-KLH induces specific suppression for the IgG anti-TNP-response without interfering with the response to epitopes on the carrier molecule. To examine the status of hapten-specific memory B cells from suppressed mice, highly enriched populations of TNP-specific memory B cells were purified from the spleen of TNP-KLH (control) or KLH/TNP-KLH (suppressed) immunized mice and tested in vitro for their ability to respond to TD or TI (TNP-KLH, TNP-LPS) antigenic challenge in presence of a KLH-specific Th cell line. Similar numbers of TNP-specific B cells with the characteristics of memory B cells were obtained from control and suppressed mice. TNP-specific B cells from suppressed mice could be triggered to IgG production by TNP-LPS but had an impaired ability to differentiate into IgG-secreting cells in response to TNP-KLH. This impaired IgG response to TNP-KLH was not due to an active suppression by a subset of TNP-specific B cells, or to an impedence of memory cells to a class switching but to an intrinsic memory B cell defect. TNP-specific B cells from suppressed mice were as efficient as memory B cells from control mice to present TNP-KLH to KLH-specific Th cells and to proliferate in response to T cell help. Our data support the view that the effector mechanism of epitope specific regulation does not interfere with the development of hapten-specific memory B cells but that these cells have an intrinsic defect that prevents their differentiation into active IgG antibody secreting cells in response to a T-dependent antigenic challenge.     

In vivo immune response to TNP hapten coupled to thymus-independent carrier lipopolysaccharide

Lipopolysaccharide has been utilized as a carrier for the TNP hapten, producing an antigen which induces an in vivo thymus-independent antibody response to TNP as determined using athymic nude mice and their normal littermates. The immune response to TNP-LPS was investigated at both the antibody-forming cell and the serum antibody levels.The primary response to an optimal dose of TNP-LPS (1.0 μg) exhibited unusual kinetics reaching a sharp peak on day 3 of 58,000 anti-TNP PFC/spleen. Serum antibody to TNP was first detected on day 3 and reached a maximum log₂ titer of 17.5 on day 5, an uncommonly high level for hapten-carrier conjugates and most carriers. Both the anti-TNP serum antibody and PFCs were exclusively IgM. No IgG antibody was detected in the primary response through 28 days postimmunization, nor was any detected in any experiment described in this paper. The primary PFC response to 1.0 μg of TNP-LPS was specific for TNP, producing no evidence of polyclonal antibody synthesis. The relative affinities of PFC-secreted antibody were investigated using hapten inhibition. The hapten inhibition curves for TNP-LPS and TNP-SRBC were very similar, indicating that relatively high affinity antibody was elicited by TNP-LPS. The secondary response to this dose following priming with TNP-SRBC or TNP-LPS was similar to the primary response, though the peak was less sharp in both cases. The response to the homologous secondary challenge shifted somewhat, reaching a peak on days 3–4. The effect of various doses in priming or challenging for the secondary response to TNP-LPS was investigated. Using an increased PFC response as a criterion, no dose was optimal for priming or immunological memory to TNP-LPS. While the adoptive primary response to TNP-LPS reached a low level peak on day 7, the adoptive secondary attained a maximum on day 6. This shift in kinetics in intact mice and in adoptive hosts in comparing primary to secondary responses indicated that a state of B cell priming may be induced. However, its full expression may be suppressed by endogenous factors at the time of priming, such as the high level of circulating anti-TNP antibody or residual antigen. Adoptive transfer would remove the cells from these influences, allowing such B cell priming to manifest itself fully.     

Induction of primary and inhibition of secondary antibody response to hapten by hapten conjugates of type III pneumococcal polysaccharide.

Tri- or dinitrophenylated pneumococcal polysaccharide type III (TNP- or DNP SIII)) induced a primary 19S anti-TNP response without generating immunological memory to the hapten in LAF₁ mice. Hapten-hemocyanin (TNP-KLH) or hapten conjugates of B. abortus organisms (DNP-BA) induced both 19S and 7S primary responses and memory to the hapten. Spleen cells from mice immunized with TNP-KLH or DNP-BA did not give adoptive memory responses upon challenge with hapten-SIII and, in fact, were inhibited from responding to their homologous hapten conjugates by simultaneous injection of hapten-SIII. Incubation of TNP-KLH-primed spleen cells for as short as 5 min at 0 °C with 10 μg of TNP-SIII per milliliter virtually abolished their ability to give 19S and 7S memory responses to TNP-KLH upon transfer into irradiated recipients. It is suggested that a difference in avidity and/or number of anti-TNP receptors per cell between virgin and primed B cells may be an important factor in determining whether the cells will be stimulated or inhibited by exposure to hapten-SIII. Another factor may be a difference between virgin and memory cells in their requirement for T-cell help.     

Functional evidence for abnormal maturation within a B-cell subpopulation of NZB mice

NZB mice develop a systemic autoimmune disease and have a subpopulation of B lymphocytes that spontaneously produce excessive amounts of IgM. These abnormal B cells reside within a specific B-cell subset that is affected by the CBA/N defect. In normal mice, this B-cell subset acquires in vitro responsiveness to certain thymus-independent antigens (TI-2) relatively late in ontogeny. We compared the functional development of neonatal B cells from NZB mice to that of normal mice of the same H-2 type. The acquisition of in vitro responsiveness to the TI-1 antigen, TNP-LPS and the TI-2 antigens, TNP-Dextran, TNP-Ficoll, and FITC-Ficoll was examined. TNP-LPS could elicit a response from both normal and NZB neonates. In contrast, responses to the TI-2 antigens were elicited early in life (<1 week) only from or at a higher level from NZB neonates. However, an accelerated appearance of B-cell differentiation antigens was not detected in NZB neonates compared to normal strains. We conclude, therefore, that a maturation or triggering defect occurs in a small B-cell subpopulation of NZB mice very early in life.     

TNP-LPS induces an IgG anti-TNP immune response in mice.

The trinitrophenylated derivatives of lipopolysaccharide (TNP-LPS) elicit a specific anti-TNP, thymus-independent immune response in mice. After a single injection of antigen, anti-TNP antibodies of IgM and IgG isotypes are detected at the cellular and at the humoral levels, in athymic nude mice as well as in conventional (C57B1/6 × DBA/2)F₁ mice. The immune sera were resolved into IgM and IgG molecules by gel filtration; both fractions showed an anti-TNP activity, thus confirming the data obtained by the cellular analysis.     

Physiology of IgD. V. Enhancement of antibody responses in vivo by allo anti-IgD is due primarily to an indirect effect on B cells

Although responses of BALB/c mice to TNP-Ficoll or TNP-Brucella abortus are usually decreased by injection of allo anti-IgD (anti-Igh-5a) given 1 day before antigen, increased responses are obtained if a lymphokine mixture (SN) containing IL 2 is also injected. Simultaneous injection of anti-IgD and SN 4 days after priming with TNP-KLH induces an increase in antibody production similar to that induced by a second antigen injection. Injected together with a second injection of TNP-KLH at that time, anti-IgD and SN cause a synergistic enhancement of the secondary response. In allotype heterozygous (BALB/c X SJL)F1 mice injected with anti-IgD directed against one allotype, this enhancement of the secondary response is seen predominantly in the alternate allotype, because the IgG response of linked allotype specificity is slightly suppressed by the anti-IgD alone and is less enhanced than the alternate allotype by anti-IgD plus SN. Cells from unprimed heterozygous mice, incubated with anti-Igh-5a in vitro and transferred, together with antigen, to TNP-KLH-primed recipients, cause a much greater enhancement of the IgG responses of the Igb than of the Iga allotype in recipients. If, however, SN is also injected into the recipients, the anti-TNP response of both IgG allotypes is greatly enhanced.     

Immune responses to T-dependent and T-independent antigens during visceral leishmaniasis in mice: evidence for altered T-cell regulation of immune responses to non-parasite antigens

Antibody responses to T-dependent and T-"independent" antigens were studied in disease-susceptible (BALB/c and C57BL/10) and disease-resistant (A/J) mice infected with Leishmania donovani chagasi. Disease-susceptible mice but not disease-resistant mice showed a transient decrease in PFC responses to TNP on a T-dependent carrier (BGG) during the period of 4-8 weeks after infection. Infected disease-susceptible animals also showed increased responses to TNP on a type II T-independent carrier (Ficoll), which persisted until at least 14 weeks after infection. The increased responses were associated with a significant increase in anti-TNP antibody of the IgG2b subclass. When T-enriched spleen cells from infected mice and B-enriched spleen cells from uninfected mice were transferred to irradiated recipients immunized with TNP-Ficoll, increased anti-TNP PFC were observed over numbers seen in irradiated recipients which received both B and T cells from uninfected mice. Increased responses to TNP-Ficoll were also induced by prior administration of soluble leishmania extract in CFA. Infected mice immunized with TNP-LPS, a T-independent type I antigen, also had increased anti-TNP antibody responses, but had normal anti-LPS antibody responses. The elevated antibody production which occurred in response to the T-"independent" antigens could not be attributed to the relatively low polyclonal response which occurred in both disease-resistant and disease-susceptible mice infected with L. donovani chagasi. The observations are consistent with leishmania induced, transient alterations in some T-cell functions including response to haptens on T-dependent carriers, and a lack of down regulation of T-"independent" responses. Subtle lesions in immunoregulation may be important correlates of successful protozoal infection and may be responsible for some of the immunologic manifestations of the disease.     

Expression of IgG memory response in vitro to thymus-dependent and thymus-independent antigens

A model is described in which expression of IgG secondary antihapten responses of large magnitude can be initiated in vitro without resorting to in vivo boosting prior to culture. The number of IgG plaque-forming cells (PFC) is frequently as much as 100-fold greater than that of IgM PFC. Spleen cells from mice primed with trinitrophenylated keyhole limpet hemocyanin (TNP-KLH) several months earlier are stimulated in vitro to produce an anti-TNP plaque-forming cell response 7–10 days later. The in vitro IgG response can be elicited with either a thymus-dependent antigen (TNP-KLH) or thymus-independent antigens (TNP-T₄ bacteriophage or DNP-dextran). The kinetics of the responses to these two forms of antigen differ in that the thymus-independent response peaks two days earlier. The IgG response to both forms of antigen requires the presence of 2-mercaptoethanol (2-ME) even though macrophages are not depleted prior to culture. In the absence of the reducing agent both thymus-dependent and thymus-independent IgG responses were diminished ≥90%. The magnitude of the response to thymus-independent antigens emphasizes the ability of these materials to elicit IgG expression in memory B cells provided optimal conditions for memory development and in vitro expression exist.     

The early postnatal development of the primary immune response in rat popliteal lymph node,stimulated with thymus-independent type-1 and type-2 antigens

Summary To examine the development of the postnatal immune response to thymus-independent type-1 (TI-type 1) and TI type-2 antigens, respectively, trinitrophenyl-lipopolysaccharide (TNP-LPS) or TNP-Ficoll was injected subcutaneously into the hind footpads of young rats of various ages. After 5 days the popliteal lymph nodes (PLNs) were removed and the localization pattern of specific anti-TNP antibody-containing cells was studied. The first specific antibody-containing cells elicited in rats by TNP-LPS appeared in animals at day 19 after birth. The results suggest that the development of these cells from lymphocyte to plasma cell occurs while they migrate from cortex to medulla. An unexpected finding was the low response to TNP-Ficoll in PLN; from 6 weeks after birth only very few specific antibody-containing cells were found. However, in the spleen numerous anti-TNP antibody-containing cells were found in the periarteriolar lymphocyte sheaths. To test the exclusive role of the spleen in the appearance of anti-TNP antibody-containing cells in lymph node after subcutaneous administration of TNP-Ficoll, the experiment was repeated in rats that had been splenectomized. Evidence from these experiments suggests that the spleen plays a major role in the appearance of the above-mentioned cells in lymph nodes.Abbreviations KLH keyhole-limpet haemocyanin - LPS lipopolysaccharide - PBS phosphate-buffered saline - PLN popliteal lymph node - TD thymus-dependent - TI thymus-independent - TNP trinitrophenyl     

Defective helper T-cell activity in LPS-unresponsive C3H/HeJ mice

C3H/HeJ mice, unresponsive to LPS, exhibit a defective ability to mount antibody responses to T-dependent immunogens. The anti-TNP antibody response to TNP-HRBC, a T-dependent immunogen, was found to be lower in these mice as compared to LPS-responsive C3H/HeN mice, whereas the anti-TNP antibody response to TNP-Ficoll, a T-independent immunogen, was of the same magnitude in C3H/HeJ and C3H/HeN mice. An impaired helper activity of C3H/HeJ HRBC-primed spleen cells was demonstrated in a titration assay in which graded numbers of C3H/HeJ or C3H/HeN HRBC-primed spleen cells were added to cultures containing a constant number of unprimed spleen cells from either C3H/HeJ or C3H/HeN mice and the immunogen TNP-HRBC. The reduced helper T-cell activity of C3H/HeJ HRBC-primed spleen cells appears to be independent of macrophage defects, since C3H/HeJ and C3H/HeN macrophages were found equally effective in antigen presentation as evaluated by an in vitro antigen-specific T-cell proliferation assay. The difference in helper T-cell activity between these two substrains probably reflects a lower number and/or proliferation rate of antigen-responsive T cells in C3H/HeJ mice.     

B Cell Tolerance

The mechanisms of B cell tolerance were studied in an attempt to learn whether B cells rendered tolerant are present in the immune system in a potentially responsive form. The author tested the in vitro anti-trinitrophenyl (TNP) antibody-forming cell (anti-TNP AFC) response to TNP-immunogens and polyclonal B cell activators (PBA) of spleen cells taken from mice injected with a tolerogen, TNP-carboxymethylcellulose (TNP-CMC). Spleen cells from mice injected 5 days previously with 10 μg of TNP-CMC did not respond to TNP-sheep red blood cells (TNP-SRBC), T-dependent (TD) antigen or TNP-Ficoll, T-independent (TI) antigen. However, the same spleen cells responded to PBA, lipopolysaccharide (LPS) of Salmonella enteritidis and purified protein derivative (PPD) of BCG. The results indicate that B cells specific for TNP are present in a potentially responsive form. Spleen cells from mice injected with 500 μg of TNP-CMC did not respond to either TNP-immunogens or PBA. The state of unresponsiveness to PBA lasted for 12 days after the tolerogen injection. Responsiveness to PBA reappeared within the short period of 2 days, whereas unresponsiveness to TNP-immunogens lasted much longer. Unresponsiveness to PBA was relieved considerably by treating tolerant spleen cells with the proteolytic enzyme trypsin before in vitro stimulation. These results indicate that B cells rendered refractory are present in the immune system in a potentially responsive form.     

Hormonal modulation of responses to thymus-independent and thymus-dependent antigens in autoimmune NZB/W mice

Previous work suggested that gonadal steroids influence immunity through the thymus, but the mechanisms were unclear. To investigate the effects of these hormones on immune responses to T1 and TD antigens in autoimmune mice, we studied hybrid NZB/W mice and the nonautoimmune DBA/2 strain. Mice castrated at 14 days of age were implanted with Silastic capsules releasing, in adults, physiologic levels of E2 in males or Te in females. Sham-operated controls received empty capsules. Splenic PFC were quantified 4 to 5 days after challenge with the TI2 antigen TNP-Ficoll, the TI1 antigen TNP-LPS, or the TD antigen SRBC. Young castrated NZB/W males implanted with E2 had striking enhancement of IgM responses to TNP-Ficoll when compared to castrated Te-treated females and comparable sham-operated controls of both sexes. E2 also stimulated responses to TNP-LPS. In response to challenge with SRBC, young E2-treated NZB/W males had a consistent trend to increased IgM PFC, and the stimulatory effect of E2 on IgG plaques was variable. Physiologic doses of Te had no consistent effect on responses in young mice. In old female NZB/W mice, Te caused PFC response after immunization with TNP-Ficoll to resemble age-matched NZB/W males. As sham-operated NZB/W females grew older, PFC responses to SRBC fell. This age-related phenomenon was delayed, however, in female castrates implanted with Te. In contrast, Te clearly suppressed responses to TNP-LPS. Implantation of E2 did not alter responses to TNP-Ficoll, TNP-LPS, or SRBC in nonautoimmune DBA/2 males. This finding suggested that exogenous E2 given in physiologic doses did not influence immunologic responsiveness in a normal strain to the degree seen in hormone-sensitive NZB/W mice. It was concluded that E2 enhanced responses to a variety of exogenous antigens in autoimmune NZB/W mice. The most consistent E2-induced increase in PFC response was observed with TI antigens, suggesting that E2 exerted its effects on B cells or Ts.     

A general interactive model for B cell activation

The general interactive model described in the previous paper was subjected to experimental testing. We examined the high affinity anti-TNP? plaqueforming cell response of cultures of murine lymphocytes exposed to lipopolysaccharide and trinitrophenylated lipopolysaccharide (TNP-LPS). From our model we predicted the effects of the addition of free LPS on the dose response to TNP-LPS, the effect of the addition of Polymyxin B to cultures stimulated with TNP-LPS, and the effect on the response to TNP-LPS preparations with different haptenation ratios. The results obtained were consistent with the predictions of the general interactive model.     

LPS regulation of the immune response: suppression of immune responses to orally administered T-independent antigen

The regulation of immune responses to gastrically administered TI antigens has been investigated, and the characterization of a regulatory cell population has been performed. Intragastric administration of TNP-haptenated homologous erythrocytes (TNP-MRBC) induced splenic IgM anti-TNP PFC responses in LPS nonresponsive C3H/HeJ mice that were higher than those in LPS-responsive C3H/HeN mice and similar to those noted in athymic (nu/nu) C3H/HeN animals. The simultaneous intragastric administration of LPS with TNP-MRBC augmented immune responses in a manner similar to that previously reported for parenterally administered LPS and antigen. Further, LPS-induced augmentation of TNP-MRBC responses was greater in athymic mice. These findings were substantiated using in vitro spleen cultures. Intragastric challenge with a 2nd TI antigen, TNP-LPS, induced approximately 8-fold higher splenic anti-TNP PFC responses in athymic C3H/HeN mice compared with those in euthymic littermates. By admixture of B and T cell populations, it was demonstrated that the host responsiveness to TNP-LPS was negatively regulated by suppressor cells. Suppressive activity resided in a Thy 1.2-bearing, irradiation-resistant, nylon wool-nonadherent cell population. These cells could be demonstrated in spleen and Peyer's patches from young or old LPS-responsive C3H/HeN mice, but not in tissues from LPS nonresponsive C3H/HeJ mice. The specificity of the regulator cells was not limited to TNP-LPS responses, since immune responsiveness to another TI antigen, TNP-dextran, was also under the control of this cell population. These studies confirm the TI nature of TNP-MRBC and indicate that immune responses to gastrically administered antigens such as TNP-LPS, TNP-dextran, and possibly TNP-MRBC are negatively regulated by a suppressor T cell population. A role for endogenous LPS in the generation of regulator cells and the effect of these cells on host responses to gut-derived antigens is discussed.