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.     

Regulation of the autoimmune plaque-forming cell response to single-strand DNA (sDNA) in vitro.

We have shown that young autoimmune and normal strain mice possess autoantigen-sensitive cells potentially capable of producing anti-sDNA autoantibody in the absence of normal regulatory mechanisms in vitro. In certain strains such as B/W mice, these regulatory mechanisms presumably break down with increasing age, and autoimmunity develops. These regulatory mechanisms might consist of sDNA, T cells, or some combination of these since both of these agents suppressed the anti-sDNA PFC response in vitro. The sDNA may have inhibited PFC development by a receptor blockade mechanism since i) spleen cells pulsed with sDNA for short periods and then washed were suppressed after 5 days of culture; ii) treatment of these blocked cells with trypsin and DNase I restored the anti-sDNA response; iii) the PFC remaining in partially blocked cultures were of lower avidity than PFC in unblocked cultures; and iv) the target of sDNA may be a B cell. Thymocytes and splenic T cells suppressed the anti-sDNA response but not the anti-SRBC response in vitro in a dose-dependent manner. The suppressive capacity of thymus cells did not decline with age in B/W mice. In addition, thymus cells activated by competing foreign antigens could also suppress the anti-sDNA response. The relationship between these modes of regulating autoreactivity remains to be investigated.     

LPS-induced autoantibody response. I. Ontogenic development of PFC response to bromelain-treated syngeneic erythrocytes

Normal adult mice have been shown to contain a large number of cells secreting antibodies against bromelain-treated syngeneic erythrocytes (Br.MRBC) and the numbers remarkably increase by the stimulation with LPS. In this report development of the anti-Br.MRBC response during ontogeny was examined and it was shown that on the injection of LPS suckling mice responded little to generate splenic plaque-forming cells (PFC) against Br.MRBC in vivo and in vitro. The responsiveness of suckling mice to produce anti-Br.MRBC was shown to be less developed than the anti-TNP response or the mitotic response to LPS. The low responsiveness of suckling mice was analyzed in terms of suppressor activity in the spleen cell population, proliferative capacities of the precursors of anti-Br.MRBC PFC, and their frequencies in the spleen. In the coculture experiment of suckling and adult spleen cells or culture of anti-brain-associated Thy 1-treated, macrophage-depleted spleen cell population, no evidence was obtained to show that suckling spleen cells contained suppressor cells. Kinetic profiles studied in vitro showed that anti-Br.MRBC PFC in the suckling spleen did not increase during the culture as those in the adult spleen. Studies on the precursor frequencies revealed that spleen cells of 15-day-old mice contained precursors of anti-Br.MRBC PFC amounting to 20.5% of the adult precursors whereas the PFC response in vitro by the former was only 4% of the latter. From these experimental data, it was concluded that the low responsiveness of suckling mice was partly due to the low frequency of the precursors in the spleen and, in addition, to the defective nature of the precursors in proliferating to differentiate into PFC.     

Effect of bacterial lipopolysaccharides on anti-trinitrophenyl antibody-producing cells. Nonspecific modification of the affinity at the cellular level.

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Polyclonal Antibody Production in Murine Spleen Cells Induced by Staphylococcus

Polyclonal plaque-forming cell (PFC) responses in murine spleen cells induced by Staphylococcus aureus and S. epidermidis were studied. Injection of Balb/c mice with S. aureus strain 248βH resulted in the generation of anti-trinitrophenyl (TNP) and anti-sheep red blood cell PFC in their spleens. Cultures of Balb/c spleen cells in the presence of S. aureus 248βH, Cowan I, or a protein A-deficient mutant yielded many anti-TNP PFC. The larger the number of organisms that were added to the cultures, the better was the PFC response. Both living and killed organisms, were capable of inducing the response, but an excess of living 248βH organisms in the cultures abrogated the response. All of the organisms (12 strains of S. aureus and 11 strains of S. epidermidis) freshly isolated from patients had the ability to induce the polyclonal PFC response in cell cultures. These organisms stimulated cultured C3H/HeJ mouse spleen cells, which were unresponsive to bacterial lipopolysaccharide (LPS). Cultured cells from the spleens of athymic nu/nu mice also responded to these organisms, and the number of PFC in nu/nu cell cultures was always greater than that in nu/+ cells prepared from a haired litter mate. Moreover, the responses of nu/nu spleen cell cultures to which nylon wool column-filtered splenic nu/+ T cells were added were lower than expected. These findings suggest that the polyclonal PFC response to staphylococci is thymus independent, but that the magnitude of the response is regulated by mature T cells. Cultures of macrophage-depleted spleen cells responded to the organisms to an extent similar to that of the control. The 248βH organisms were less capable of stimulating spleen cells of 2-week-old mice (i.e., early maturing B cells) than LPS. However, spleen cells from adult (7-week-old) and aged (9-month-old) mice responded well to both the organisms and LPS. Previous sensitization with the organisms in vivo did not affect any polyclonal responses of spleen cells in vitro to either the organisms or LPS. The role of staphylococcal protein A in the polyclonal PFC response to staphylococci is discussed.     

Effect of Bacterial Lipopolysaccharides on Anti-Trinitrophenyl Antibody-Producing Cells

The effect of lipopolysaccharide (LPS) on anti-trinitrophenyl (TNP) direct plaque-forming cells (PFC) in the spleen of mice and the affinity of antibodies produced by these PFC were examined. Simultaneous injection of bacterial LPS and TNP-coupled sheep red blood cells(SRBC) induced an obvious increase in anti-TNP PFC numbers and heightened the antibody affinity at cellular levels. The higher the doses of LPS, the greater the effects. Concomitant injection of LPS in TNP-coupled homologous mouse red blood cells (MRBC) also elicited good anti-TNP PFC response and slightly heightened the affinity. Priming with LPS and SRBC together 7 days prior to immunization did not enhance the anti-TNP PFC response and it was difficult to alter the affinity. Preinjection with small amounts of TNP-MRBC or -rabbit red blood cells and LPS simultaneously did not induce any significant increase in anti-TNP PFC secondary response after reimmunization with TNP-SRBC, but obviously heightened the antibody affinity. Injection of LPS simultaneously with the secondary immunization was effective for both the anti-TNP PFC response and the alteration of antibody affinity. These results suggest that LPS affects the control mechanisms of anti-TNP antibody affinity via the non-thymus-derived helper cell function, and the adjuvant action and alteration of antibody affinity induced by LPS are regulated by different mechanisms.     

Immunorestoration of old mice by injection of thymus extract: Enhancement of T cell-T cell cooperation in the in vitro antibody response

The effect of injecting a thymus extract (TP-1 or Thy-5) into immunodeficient old mice on the in vitro antibody response of their spleen cells was investigated by techniques suitable for dissecting out T- and B-cell reactivities. The anti-TNP antibody response of HRBC-primed spleen cells from old mice uninjected or injected with TP-1 or Thy-5 was elicited in vitro by TNP-HRBC or TNP-Ficoll. Treatment with TP-1 or Thy-5 was found to induce only a slight increase in the anti-TNP antibody response to both immunogens. The helper activity of HRBC-primed spleen cells from untreated or treated old mice was titrated by adding graded numbers of these primed cells to cultures containing a constant number of normal spleen cells from young mice and the immunogen TNP-HRBC. Under these conditions it was found that both thymus extracts are very effective in restoring T cell-T cell cooperation in the generation of helper cell activity.     

Dissociation between proliferation and antibody formation by old mouse spleen cells in response to LPS stimulation.

Both lipopolysaccharide (LPS)-induced proliferation and antibody formation by C57B1/6 spleen cells from old mice were studied by measuring thymidine incorporation and plaque-forming cells (PFCs) to the 2,4-dinitrophenyl group (DNP). There was no significant difference in the proliferative response of spleen cells from young or old mice. Anti-DNP antibody formation by spleen cells from the old mice was greatly reduced. The reduced PFC response could not explained by a shift in kinetics of the responding cells. A similar dissociation could be obtained with LPS-stimulated spleen cells from young mice by using an anti-μ serum or a low concentration of hydroxyurea in the culture medium.     

In vitro immune response of cells of various lymphoid tissues in (NZB X NZW)F1 mice: evidence for abnormality of the mesenteric lymph node cells

Autoimmune-prone (NZB X NZW)F1 (B/W) mice have been shown to have a variety of immunologic perturbations. However, most studies have been performed with spleen cells. By using the Mishell-Dutton culture system, we examined the in vitro immune response of the various lymphoid tissue to determine whether an imbalance at a selective lymphoid site may exist in B/W mice. It was shown that the ability of mesenteric lymph node (MLN) cells of B/W mice to generate plaque-forming cells (PFC) in response to sheep red blood cells was consistently less than that of the spleen cells. This relationship held true in the aged mice. In contrast, the ability of the MLN cells of other strains not prone to develop autoimmunity to generate PFC was higher than that of the spleen cells. No significant difference in the mitogenic response of the lymphoid cells from various lymphoid tissue in the young B/W mice was seen, as compared with normal lymphoid cells from control mice. However, it was demonstrated that a relative decrease of B cells and immunoregulatory Lyt-123+ cells in the MLN in the B/W mice occurred early in life, and it was concluded that this abnormality may account for the low PFC response observed.     

Nude mice--a model system for studying the cellular basis of the humoral immune response

Mice homozygous for the nu gene fail to develop a thymus. In comparison to spleen cells from +/nu mice spleen cells from nu/nu mice have a deficient 19S PFC response to SRBC when tested in culture or in vivo. This deficiency is due to a lack of “helper” T cells in nu/nu spleen; A cells and B cells appear to be normal. The capacity of nu/nu spleen cells to produce a PFC response in culture can be corrected by the addition of T cells obtained from either the thymuses or the spleens of +/nu mice. In contrast to “helper” T cells obtained from the spleen, “helper” T cells obtained from the thymus appear to require the capacity for proliferation during the response to SRBC.     

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.     

T cells and the anti-trinitrophenyl antibody response to fetal calf serum and 2-mercaptoethanol

Unprimed murine lymphocytes maintained in culture medium containing fetal calf serum (FCS) and 2-mercaptoethanol (2-ME) developed very high levels of anti-trinitrophenyl (TNP) plaque forming cells (PFC). Both FCS and 2-ME contributed to the response. The development of anti-TNP PFC during culture was accompanied by a 10-fold expansion in the number of immunoglobulin-secreting cells, indicating polyclonal stimulation. However, the number of anti-TNP PFC was disproportionately high and not accompanied by a similar increase in plaques specific for sheep red blood cells. The TNP-specific plaques were not artifacts of the plaque assay since they were 98% inhibited by specific antigen. The in vitro induction of anti-TNP PFC by FCS and 2-ME was common to a number of mouse strains, although some genetic variation occurred. Nylon-wool-separated B cells, nude mouse spleen cells, and bone marrow cells all produced high levels of anti-TNP after culture with medium containing FCS and 2-ME. The addition of T cells to B-cell cultures increased the numbers of anti-TNP PFC by 1.5- to 2.5-fold. The presence of a TNP-cross-reacting antigen in FCS probably contributed to the unexpectedly high anti-TNP response. The response to the antigen in FCS was potentiated by the enhancing activity of 2-ME.     

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.     

LPS regulation of the immune response: Bacteroides endotoxin induces mitogenic, polyclonal, and antibody responses in classical LPS responsive but not C3H/HeJ mice

Recent studies have suggested that lipopolysaccharide (LPS) derived from gram-negative organisms such as Bacteroides, which are not members of the Enterobacteriaceae, stimulate B cells from the classic LPS-hyporesponsive C3H/HeJ mouse. In the present study, purified, phenol-water-extracted LPS from Bacteroides fragilis ATCC 25285 (B-LPS) was tested for its ability to induce in vivo and in vitro responses in classic LPS-responsive C3H/HeN, LPS-hyporesponsive C3H/HeJ, and (C3H/HeN X C3H/HeJ)F1 hybrid mice. B-LPS induced mitogenic responses in both C3H/HeN and C3H/HeJ spleen cell cultures when cells were cultured under standard conditions, i.e., 8 X 10(5) cells/well. Interestingly, when lower spleen cell numbers were tested with B-LPS, a typical responsive-nonresponsive pattern developed in which good mitogenic responses were induced by B-LPS in C3H/HeN cultures and in which low responses in C3H/HeJ spleen cell cultures were evident. In vivo immunization of mice with B-LPS resulted in high antibody responses in C3H/HeN, intermediate responses in F1, and low responses in C3H/HeJ mice. When purified splenic B cells were incubated with B-LPS, both mitogenic responses and polyclonal immunoglobulin M (IgM) synthesis occurred in C3H/HeN cultures, whereas intermediate responses were noted in F1 cultures and no response was seen in B cell cultures from C3H/HeJ mice. Furthermore, in vitro TNP-B-LPS responses were induced in C3H/HeN spleen cells or purified B cell cultures, and intermediate anti-TNP PFC responses occurred in F1 spleen cells or purified B cell cultures. The toxicity of B-LPS was tested in galactosamine-sensitized mice. The LD50 values for B-LPS in classic LPS-responsive C3H/HeN and C57BL/6J mice were 0.6 microgram and 1.1 microgram, respectively; F1 hybrid mice were approximately 15-fold more resistant, whereas C3H/HeJ mice gave an LD50 of 1650 micrograms. This study shows that phenol-water preparations of B-LPS are biologically active and induce responses in the classic LPS-responsive but not in the LPS-hyporesponsive C3H/HeJ mouse strain.     

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.     

Production of auto-anti-idiotype antibody during the normal immune response. X. Response to TNP-Ficoll in the chicken

The spontaneous production of auto-anti-idiotype (Id) was demonstrated after injection of chickens with trinitrophenylated Ficoll (TNP-F) by: (a) the presence of hapten-augmentable plaque-forming cells (PFC), (b) the ability of serum and of hapten eluates from immune spleen cells to cause hapten-reversible inhibition of anti-TNP plaque formation, and (c) an enzyme-linked immunosorbent assay (ELISA). Tests for anti-Id using the ELISA and hapten-reversible inhibition of PFC correlated very well. As in the mouse, the incidence of hapten-augmentable PFC was reduced by thymectomy and increased by the transfer of TNP-F-immune spleen cells. Hapten-augmentable PFC were also observed during the immune response of chickens to p-azobenzene arsonate-conjugated Brucella abortus.     

Measurement and comparison of the proliferative and antibody response of neonatal, immature and adult murine spleen cells to T-dependent and T-independent antigens.

Mouse spleen cell antigenic responses to the thymic-dependent antigen sheep red blood cells (SRBC), and the thymic-independent antigens, E. Coli lipopolysaccharide (LPS) and pneumococcal polysaccharides Type I and II (SI, SII) were studied as as a function of age, employing both in vitro spleen cell stimulation and plaque-forming cell (PFC) assay systems. Primary spleen cell proliferative and PFC responses to SRBC, were either absent or meager in comparison to adult (8–12 weeks) values for the first 3 weeks of life. Thereafter responses rose achieving adult values between 4 and 8 weeks of age. The inability of young mice to respond to SRBC was not because of a different immunizing dose requirement for SRBC, since immunization with SRBC over a 200-fold range did not enhance their capability to respond. Also, addition of adherent cells or macrophages from adult mice did not enhance the immune responses of young mice. Furthermore, immunization of 2–4 week old mice with SRBC inhibited the secondary response to SRBC. In contrast, young murine spleen cell proliferative and PFC responses to SI, SII, and LPS were approximately the same as the adult by 7–14 days of life. These data suggest that B-cell immunologic activity, as measured by immunologic assays utilized in this study, develops much earlier than does T-cell responsiveness.     

Role of t lymphocytes in the humoral immune response. II. T cell-mediated regulation of antibody avidity.

The effect of activated T lymphocytes (ATC) on the avidity distribution of PFC in the secondary response was studied in normal mice. The total PFC response was not significantly changed for either direct or indirect PFC by administration of ATC before secondary antigen challenge. However, marked suppression occurred of indirect PFC that secreted high avidity antibody; no suppression was seen of high avidity direct PFC. At the same time, significant stimulation was seen of relative and absolute frequencies of indirect PFC that secreted middle and low avidity antibody. These effects were dependent on Thy 1-bearing, nylon nonadherent cells which demonstrated carrier specificity. In further characterization of these effects, it was found that increasing the number of ATC transferred produced progressive loss of high avidity PFC and compensatory increase in lower avidity PFC. Moreover, in these experiments, suppression of the high avidity response was inducible with the administration of ATC 5 weeks before to 3 days after the secondary immunization. Thus, it is likely that the avidity-modifying effects are dependent on T lymphocytes which influence the late stages of B lymphocyte maturation.     

Production of auto-anti-idiotypic antibody during the normal immune response. XII. Enhanced auto-anti-idiotypic antibody production as a mechanism for apparent B-cell tolerance in rabbits after feeding antigen

Rabbits fed trinitrophenylated bovine serum albumin (TNP-BSA) generated fewer anti-TNP plaque-forming cells but greater numbers of hapten (TNP)-augmentable IgM and IgG PFC following immunization with TNP-Ficoll or TNP-Brucella abortus than did animals not previously fed antigen. Spleen and mesenteric and bronchial lymph nodes were similarly affected. In addition more auto-anti-idiotype (Id) antibody (anti-anti-TNP) was eluted by hapten from spleen cells of antigen-fed rabbits than from spleen cells of control rabbits not prefed antigen. Gel filtration studies ruled out the possibility that the Id binding activity in the eluates was due to immune complexes. The isotype of the anti-Id was IgG except in one rabbit where it was IgM. The results are consistent with the interpretation that the production of auto-anti-Id antibody is one of the factors responsible for the specific depression of the IgM and IgG immune responses which follows antigen feeding. In contrast the antigen feeding resulted in priming for an IgA anti-TNP response without detectable hapten-augmentable IgA PFC.     

Ability of chicken B cells from different compartments to respond to TNP-Ficoll

The responsiveness of chicken B cells from various compartments to T-independent antigens was studied by immune transfers of spleen and bursa cells into immunosuppressed recipients. Bursa cells from 8- to 10-wk-old donors failed to respond to trinitrophenylated Ficoll (TNP-F) even when thymus cells or splenic T cells were added. Spleen cells from the same donors transferred responses, as judged both by anti-TNP plaque-forming cells (PFC) per spleen and serum anti-TNP titers. In contrast, responses to TNP-Brucella abortus (TNP-BA) were transferred at least as well as by bursa as by spleen cells. Rabbit anti-chicken T cell serum plus complement treatment of the spleen cells reduced their ability to transfer responses to sheep erythrocytes, but either did not affect or enhanced serum antibody responses to TNP-BA and TNP-F. In intact animals, responsiveness to i.v. injected TNP-F was found to develop slowly after hatching in the chicken. At the age of 2 and 3 mo, PFC/spleen on day 4 after TNP-F injection were only 20% and 40%, respectively, of the adult response. Thymectomy at hatching further delayed this development, resulting in 12% and 45% of the adult control response at ages of 3 and 4 mo. It is concluded that responsiveness to the TI-2 antigen, TNP-F, develops slower than that to the TI-1 antigen, TNP-BA, and is restricted to the splenic B cell compartment. In addition, this development appears to be faster in the presence rather than in the absence of the thymus. In view of the previously shown effect of thymus on bursa development, these data suggest that the maturation of TI-1 antigen (TNP-F)-respondent chicken B cells requires residence in both the bursa and spleen before the development of responsiveness to such antigens.