Expression of GAT-715 idiotype by GAT-specific plaque-forming cells from various strains of mice

The splenic plaque-forming-cell (PFC) response of mice to immunization with pneumococcal capsular polysaccharide (SSS-III), coupled with T-cell activation by phytohemagglutinin (PHA), is characterized by enhanced numbers of IgG-producing cells, largely restricted to the IgG2a and IgG2b subclasses. In contrast, immunization with SSS-III alone results in low numbers of IgG-producing cells, fairly evenly distributed among the subclasses IgG1, IgG2a, IgG2b, and IgG3. The enhanced IgG response and a concomitantly enhanced IgM response are T-cell dependent and occur only if PHA is given 2 days after SSS-III immunization. The absence of immunologic memory to SSS-III in mice previously immunized and treated with PHA implies that enhanced IgG production results from the activation of amplifier T cells and not the helper T cells which are required for memory.     

Rapid changes in the regulatory potential of autologous anti-idiotopic T cells during an antigen-driven primary response

The antibody response of C57BL/6 strain mice to Streptococcus pneumoniae R36a (Pn) is dominated by the T15 idiotype, but the responding cells appear to be idiotypically heterogeneous, in that individual antibody plaque-forming cells (PFC) may express some but not all idiotopes (Id) of the T15 complex. The presence of these distinct Id on the PFC was detected by a plaque-inhibition assay with three different monoclonal anti-Id antibodies, designated AB1-2, MaId5-4, and B36-82. A periodic change in the expression of AB1-2 and MaId5-4 Id was observed during primary (IgM) antibody response to Pn in the spleen. Those two Id were poorly expressed in the log phase of the response between day 2 and day 4 after immunization (few PFC in the spleen bore the Id), but they became detectable on the majority of PFC at the peak of the response, day 5 to day 7. The proportion of the Id-(AB1-2 or MaId5-4) positive PFC declined, again at day 10 after immunization. In contrast, the B36-82 Id was expressed on greater than or equal to 80% PFC throughout the entire primary response. The possibility that the apparent changes in the Pn-reactive cell populations are regulated by autologous anti-Id T cells was tested in vitro. Normal, unimmunized B cells were cultured with Pn, either alone or in the presence of syngeneic T cells isolated from the spleen of mice at the appropriate intervals after immunization: day 2 (T2), day 5 (T5), and days 10 to 14 (T10 to T14); T cells from unimmunized donors (T0) served as a control. The specific response after 4 days in culture was determined in regard to the total PFC as well as the proportion of PFC expressing the Id. Pn-stimulated B cells, alone or with the control T0 cells, produced moderate, variable levels of AB1-2+ and MaId5-4+ PFC. The expression of these two Id in the assay cultures was suppressed by addition of either T2 cells or T10-14 cells, but it was enhanced if T5 cells were added. However, these various T cell populations did not differ in their effect on the total PFC response. Also, the proportion of PFC bearing the third Id, B36-82 was high, and it was not consistently influenced by the added T cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immune dysfunction associated with graft-vs-host reaction in mice transplanted across minor histocompatibility barriers. II. Reversible defect in T-dependent antibody responses

B cell and Th cell functions were assessed in mice undergoing a graft-vs-host reaction (GvHR) in response to minor histocompatibility Ag by using the plaque-forming cell (PFC) response to the T-independent Ag TNP-Brucella abortus and the T-dependent Ag TNP-SRBC. Bone marrow plus spleen cells from B10.D2 mice were transplanted into lethally irradiated B10.D2 (syngeneic recipient) or H-2d-compatible BALB/c (allogeneic recipient) to produce a chronic form of GvHR. BALB/c recipients of an allogeneic transplant demonstrated a marked and proportional lymphoid depletion of the spleen with normal percentages of B cells, T cells, and CD4+ and CD8+ T cell subsets. Mice with GvHR made normal numbers of PFC/10(5) spleen cells in response to the T-independent Ag, but a significantly depressed number of PFC/10(5) spleen cells to the T-dependent Ag compared with normal B10.D2 mice and with irradiated B10.D2 recipients of syngeneic B10.D2 marrow plus spleen cells. Mice undergoing the minor Ag GvHR made significantly larger numbers of PFC/10(5) spleen cells after secondary immunization with TNP-SRBC compared with controls. In vitro assays demonstrated that B cells from mice with GvHR responded to T help from normal B10.D2 mice and that T cells from mice with GvHR provided help to normal B cells after in vivo immunization. These data demonstrate that radiation chimeras with GvHR in response to minor histocompatibility Ag have relatively normal B cell function and an apparent defect in T helper cell function that is reversible by immunization with appropriate Ag.     

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.     

Effects of microwave exposure on the hamster immune system. IV. Spleen cell IgM hemolytic plaque formation

Microwave exposure has been reported to affect various components of the immune system. In this study, we examined the effect of a single whole-body exposure of hamsters to microwave (mw) energy (2.45 GHz; 5-25 mW/cm2; 1 h) on the IgM antibody (Ab) response of spleen cells to sheep red blood cells (SRBC). MW-exposed, sham-exposed, and cage-control hamsters were immunized with SRBC and plaque-forming cells (PFC) in spleens assayed using the direct hemolytic plaque assay. In cage-control hamsters the Ab response was highest between days 4 and 5, returning to baseline by day 9. MW exposure (25 mW/cm2 for 1 h) significantly augmented PFC response only on days 4 and 5 postimmunization, causing approximately a 4.3- and 3.5-fold increase over controls, respectively. Exposure to 15 mW/cm2 caused a lesser, but significant increase in PFC. Exposure to intensities below 15 mW/cm2 for 1 h did not produce any increase in Ab response. Immunization with different concentrations of SRBC following 1 h of 25 mW/cm2 MW exposure revealed a stimulation in PFC at all concentrations ranging from 5 X 10(7) to 5 X 10(8) SRBC. Pretreatment of hamsters with MW radiation prior to immunization showed that the animals retained an increased sensitivity to SRBC for as long as 4 days after MW exposure. In contrast, exposure of hamsters to MW energy on different days after immunization showed an effect of the PFC response only if given between 0 and 1 day after immunization. These results suggest that MW exposure augments the primary IgM response to SRBC by affecting some early event in the immune response process. The various possible explanations for this phenomenon are discussed.     

Complement-dependent and -independent pathways of T cell-B cell cooperation.

BDF1 mice treated with CoV had markedly reduced levels (less than 20%) of native serum C3 32 hr later, whereas the frequency of splenic CR+ cells was normal. CoV treatment before immunization reduced the IgM PFC response to a T-dependent antigen (TNP-SRBC) by more than 60%. Inclusion of highly specific anti-C3 antibody had no effect on the T-dependent IgM response of CR- B cells. The residual PFC responses in cultures of unfractionated spleen cells treated with anti-C3 could be largely or completely accounted for by CR- B cells in the cultures. The effect of anti-C3 antibody was not due to cytotoxicity. These data collectively indicate that the effect of CoV on T-dependent antibody responses is due to decreased C3 in serum rather than to interaction of C receptors directly with CoV or with C3 cleavage products. They suggest the existence of at least two distinct pathways of T-B cooperation, one in which C3 is an obligatory participant and another in which it may be uninvolved.     

In vivo immune response suppression by the supernatant from concanavalin A-activated spleen cells.

Supernatants from concanavalin A- (Con A) activated murine spleen cells have been shown to suppress the in vitro plaque-forming cell (PFC) response to sheep red blood cells (SRBC). The present study examined the effect of such Con A-activated spleen cell supernatants (herein termed CONS) on the in vivo immune response to SRBC in C57BL/6, BALB/c and CDF1 mice. CONS derived from BALB/c spleen cells suppressed direct PFC 4 and 8 days after immunization with 2 X 10(8) SRBC. CONS also suppressed indirect PFC 8 days after immunization, as well as serum hemagglutinins to SRBC. The PFC response of C57BL/6 (H-2b) mice was suppressed as much as that of BALB/c (H-2d) by CONS derived from BALB/c mice, indicating a lack of H-2 specificity of the CONS. In addition to suppression of the antibody response to SRBC, in vivo CONS administration resulted in reduction in spleen cell number. This reduction was not sufficient to explain the decreased PFC response. When the CONS was separated into less than 10,000 m.w. and greater than or equal to 10,000 m.w. fractions, the immunosuppressive activity was found in the less than 10,000 m.w. fraction. This observation suggests that intact interferon, SIRS, and MIF were not responsible for the results obtained.     

In vitro studies of the rabbit immune system: I. Hemolytic plaque-forming response of dissociated spleen cells from normal and primed rabbits

The conditions for the in vitro generation of primary and secondary immune responses by rabbit spleen cells to sheep red blood cell (SRBC) antigen have been examined. Spleen cells from many normal and all previously immunized rabbits are capable of producing in vitro plaque-forming cell (PFC) responses when cultured as dissociated cell suspensions in the presence of antigen. Primed spleen cells generate approximately 100 times the number of PFCs obtained in normal cultures with a shorter lag period. Both types of cultures demonstrate a period of exponential increase in PFCs during which the doubling time is 12–14 hr. This increase occurs after 1 day of culture of spleen cells from primed rabbits and after 4 days of culture of spleen cells from unprimed rabbits. The PFCs which arise in cultures of primed cells appear not to be the progeny of those generated in vivo but to be derived from an increased number of PFC precursors. Repeated immunization of the spleen cell donor is required to produce significant numbers of indirect (IgG) PFC or indirect precursors; most of the PFC found after a single immunization in vivo or in vitro are direct (IgM). There is no evidence for conversion of IgM to IgG PFC in vitro. This system should provide a means for further identification of the cellular interactions involved in the immune response of the rabbit.     

Cellular requirements for the expression of IgM. Immunological memory in vitro

In vitro culture techniques have been used to compare the direct (IgM) plaqueforming cell (PFC) response to heterologous erythrocytes (RBC) by normal mouse spleen cells and spleen cells from mice injected intravenously with 5 × 10⁴ RBC ten days previously [low dose primed (LDP)]. Although LDP mice fail to undergo a significant primary PFC response, their spleen cells are capable of a secondary or enhanced PFC response in vitro. The secondary PFC response is shown to be a function of: (A) an increase in the frequency of immunocompetent cells or units (IU) due to in vivo priming, and (B) an increased number of PFC generated per IU subsequent to in vitro stimulation. The latter increase is shown to be mediated through a shorter PFC doubling-time during logarithmic expansion of the PFC population. Analysis of nonadherent spleen cell dose response experiments indicate that two nonadherent cell types interact in the secondary response. Subsequent cocultivation experiments suggested that both of these cell types must be “primed” to allow induction of a secondary response. Although adherent cells are required for the secondary response, normal splenic adherent cells serve as equivalent substitutes for LDP adherent cells.     

Modification of immune response in nude mice infected with mouse hepatitis virus.

In nude mice experimentally infected with mouse hepatitis virus (MHV), the numbers of early and later plaque forming cells (PFC) to sheep red blood cells (SRBC) generated in the spleen were 7 to 20 times and 2 to 163 times, respectively, greater than those in non-infected nude mice, when SRBC were given at day 0 to day 21 postinfection. Splenic theta-positive lymphocytes in infected nude mice were shown to increase only at day 10 or more postinfection. PFC response to bacterial lipopolysaccharide, a T cell-independent antigen, was not modified in MHV-infected nude mice.     

Immune response in malnutrition. Differential effect of dietary protein restriction on the IgM and IgG response to alloantigens

The capacity for humoral immune response was evaluated in C57BL/6 mice fed diets with low (8%) or normal (27%) protein content upon primary and secondary stimulation with allogeneic cells from the DBA/2 strain. Primary antibody response was assessed by titration of serum hemagglutinins and by quantitation of direct plaque forming cells (PFC) in immune spleen suspensions, with lymphoma cells L5178Y of the DBA/2 strain as target. Secondary antibody response was assessed by titration of serum hemagglutinins. The following results were obtained: 1) Significant decrease in the total number of spleen cells was observed in protein deficient animals while the numbers of IgM PFC/spleen did show small reduction. 2) The number of direct alloantibody PFC/10⁷ spleen cells was increased in the protein deficient animals in comparison to the normally fed controls. 3) The above effect was observed even after short periods (1 week) of protein depletion. 4) Titers of serum hemagglutinins in protein deficient mice were similar or higher than in normal mice during the primary response but markedly depressed during the secondary response. 5) The synthesis of IgG hemagglutinins was depressed in protein deficient mice during both the primary and secondary responses. The results indicated that cells producing IgM alloantibodies are not affected by protein deficiency starting during the fourth week of age, while one or more of the cell populations interacting in the IgG response to alloantigens is markedly depressed by similar protein restriction. It was suggested also that protein deficient animals present a failure in the regulatory mechanism(s) of the IgM response to alloantigens.     

Antibody formation in mouse bone marrow. IX. Peripheral lymphoid organs are involved in the initiation of bone marrow antibody formation.

Mouse bone marrow is barely capable of plaque-forming cell (PFC) activity during the primary response to sheep red blood cells (SRBC). However, during secondary-type responses, it becomes the major organ, containing IgM, IgG, and IgA PFC. In the present paper, the influence of splenectomy (Sx) upon the secondary bone marrow PFC response to SRBC was investigated. When previously primed mice were splenectomized just before the second intravenous (iv) injection of SRBC, the effect of Sx upon the height of the bone marrow PFC response was dependent on the booster dose. Sx just before a booster of 10⁶ SRBC iv almost completely prevented bone marrow PFC activity, whereas an iv booster dose of 4 × 10⁸ SRBC evoked a normal IgM, IgG, and IgA PFC response in Sx mice. Apparently low doses of iv administered antigen require the spleen in order to evoke antibody formation in the bone marrow. Experiments with parabiotic mice, consisting of Sx and sham-Sx mice, showed that this facilitating influence of the spleen upon bone marrow antibody formation occurs via the blood stream. In a subsequent study, it was investigated whether the spleen is required throughout the bone marrow PFC response or only during the few days of the initiation phase. Therefore, mice were splenectomized at different intervals after a booster injection of 10⁶ SRBC iv. It appeared that Sx 2 days after the booster injection could still prevent the normal bone marrow PFC activity, whereas Sx at Day 4 could no longer do so. Apparently, after an iv booster injection, the spleen is only required for initiation of the bone marrow PFC response and not for the maintenance of this PFC activity thereafter.     

Kinetics of the antibody response to type III pneumococcal polysaccharide. II. Factors influencing the serum antibody levels after immunization with an optimally immunogenic dose of antigen.

When the number of PFC present in the spleen was measured at 24-hr intervals after immunizing with an optimally immunogenic dose of type III pneumococcal polysaccharide (SSS-III), maximal numbers of PFC were attained 4 days after immunization; thereafter, the number of PFC decreased rapidly. By contrast, serum antibody levels, which were measured in the same mice using a Farr test, reached peak values 5 days after immunization and then declined much more slowly than did the number of PFC. Two factors were found to contribute to this disparity. First, experiments conducted with splenectomized mice showed that extrasplenic antibody synthesis, which began between days 3 and 4 after immunization and peaked on days 6 to 7, accounted for nearly one-third of the total amount of serum antibody produced. Second, the average rate of antibody synthesis by PFC increased through day 6 after immunization and then declined. Antigen-antibody dissociation tests showed that the avidity of the serum antibody obtained 4 to 7 days after immunization was the same. Moreover, during the same interval, all the antibody detected by the Farr test was of the IgM class. Thus, a change in avidity or class of immunoglobulin after day 5 did not account for the disparity observed. The clearance rate of antibody injected i.v. into nonimmune and immunized mice was studied. The data obtained indicated that accelerated clearance of antibody was occurring prior to day 3 after immunization; however, after day 3 the antibody clearance rate was constant and was the same as that found when antibody was injected into nonimmune mice. These findings affirmed the results of previous studies showing that treadmill neutralization was not important in determining the serum antibody levels present after immunization with an optimally immunogenic dose of SSS-III.     

Functional differentiation in the genetic control of murine T lymphocyte responses to human fibrinopeptide B

The ability to generate proliferative and helper T lymphocyte responses in mice was compared by using the 14 amino acid peptide, human fibrinopeptide B (hFPB). Lymph node or peritoneal exudate T cells from mice immunized with hFPB were assessed for in vitro proliferation to soluble hFPB as determined by the uptake of 3H-thymidine. The T cell proliferative response to hFPB was found to be under MHC-linked Ir gene control; mice possessing the H-2a,k haplotypes were responders, whereas H-2b,d,q,s mice were nonresponders. The influence of non-H-2 genes on these responses was not investigated, so exclusive regulation by H-2 is provisional. The absence of a detectable lymph node and peritoneal exudate T cell proliferative response persisted in H-2b,d,q,s mice after immunization and boosting with several doses of hFPB. In addition, the capacity to produce a T cell proliferative response was inherited in an autosomal dominant manner and gene(s) controlling responsiveness to hFPB mapped to the I-A subregion of the H-2 complex. To measure peptide-specific helper T cell activity, an in vitro microculture assay in which hFPB-primed lymph node T cells and normal spleen B cells and macrophages were used was developed measuring anti-fluorescein isothiocyanate (FITC) IgM and IgG plaque-forming cell (PFC) responses after culture with FITC-conjugated peptide. Immunization of B10.BR, C57BL/10, B10.D2, and B6AF mice with hFPB primed for significant helper T cell activity as assessed by the ability to augment a primary in vitro IgM response to FITC. The normal B cell IgM responses were completely dependent on hFPB-primed T cells and required that hapten (FITC) and carrier (peptide) be linked. In addition, immunization with FITC-conjugated peptide elicited positive in vivo PFC responses to FITC in B10.BR and C57BL/10 mice, indicating similar genetic control of helper activity in both the intact animals and the in vitro microcultures. Thus, B10.BR mice show both T help and T proliferative responses to hFPB, whereas C57BL/10 mice show only T help and no T proliferative responses. In contrast to B10.BR mice, C3H and CBA mice immunized with hFPB were completely unresponsive when assayed for helper T cell activity in vitro despite their ability to generate positive lymph node T cell proliferative responses. These results indicate responsiveness to hFPB by T helper and proliferating cells is different and is under separate genetic control.     

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.     

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.     

Corticosteroids and the humoral immune response of mice. II. Enhancement of bone marrow antibody formation to lipopolysaccharide by high doses of corticosteroids.

The effect of injection of the synthetic corticosteroid dexamethasone sodium phosphate upon the primary response to Escherichia coli lipopolysaccharide (LPS) was studied in mouse spleen and bone marrow. Daily corticosteroid injections, starting 1 day before immunization with LPS, could suppress the anti-LPS plaque-forming cell (PFC) response in the spleen. The higher the dose of corticosteroids, the more the splenic PFC response was suppressed. On the other hand, the bone marrow PFC response showed a dose-dependent enhancement after corticosteroid injections. This effect was maximal when tested 7 days after antigen injection, and constituted a 3- to 15-fold increase after daily injection of 16 mg dexamethasone/kg body wt. The same effect was found in genetically athymic nude mice, showing that the corticosteroid-mediated enhancement of the anti-LPS PFC response in the bone marrow is not due to elimination of T suppressor cells. Probably the differential effect of corticosteroids upon antibody formation in spleen and bone marrow is due to a redistribution of B-lineage cells, with a resulting accumulation in the bone marrow.     

The origin of antibody-forming cells detected in the bone marrow after thymus-independent antigen-stimulation and abnormality in migration of B cells of X-linked immunodeficient CBA/N mice

The anti-TNP IgM plaque-forming cells (PFC) were generated in the spleen and bone marrow of non-immunodeficient normal mice after intraperitoneal administration of TNP-LPS. Irradiation of normal mice while shielding bone marrow completely abrogated the generation of bone marrow PFC, indicating that they are derived from extramedullary sites. The bone marrow PFC, response to TNP-LPS was low in X-linked immunodeficient CBA/N strain mice, while the spleen response was comparable to that seen in the normal mice. To further study the basis of the deficient bone marrow PFC response in CBA/N mice, spleen cells were adoptively transferred to irradiated syngeneic mice stimulated with TNP-LPS. While spleen cells from normal mice generated high numbers of PFC in recipient bone marrow and spleen, those from CBA/N strain mice could not generate bone marrow PFC. This result was obtained regardless of whether normal or CBA/N recipients were used. These results indicate that TNP-LPS administration normally results in the migration of B lymphocytes from the periphery into the bone marrow and that B cells from immunodeficient CBA/N strain mice bear an inherent defect in this migratory function. This migratory defect was shown to be X-linked, as are the other previously reported B cell defects in this inbred mouse strain. The possible relationship between this migratory defect and the maturational defects of B cell lineage as reported previously in CBA/N strain mice is discussed.     

Regulation of T15 idiotype dominance. II. Genes unlinked to the Igh locus regulate T15 dominance of the secondary adoptive transfer response to phosphocholine

We have studied the idiotype and fine specificity of the secondary immune response to phosphocholine (PC) in C57BL (B10, B10.D2, and B.C8) and BALB (BALB/c, BAB-14, and C.B20) congenic strains of mice. In vivo IgM responses of mice from these two genetic backgrounds differed in their T15 idiotypic representation. BALB strains expressed the T15 idiotype on greater than 90% of their IgM, PC-specific plaque-forming cells (PFC), whereas C57BL strains expressed the T15 idiotype on approximately 50% of their IgM PFC. All strains examined expressed greater than 75% PC-inhibitable, VHPC idiotype-positive, IgM PFC. The IgG3 and IgA memory responses were similar to the IgM memory response; BALB strains produced a higher proportion of T15+ PFC than C57BL strains; however, the majority of IgG3 and IgA PFC in all strains were VHPC+, and PC-inhibitable. In contrast, the IgG1 memory response was not dominated by T15+, VHPC+, PC-inhibitable PFC in any of the strains tested. The IgG1 PFC required nitrophenylphosphocholine (NPPC) for efficient inhibition. The IgG2 memory response generally mimicked the IgG1 response with respect to idiotype and specificity. These data demonstrate that the representation of the T15 idiotype in the anti-PC immune response is determined by genes outside both the MHC and Igh genetic loci. Control of T15 expression in secondary IgM, IgG3, and IgA anti-PC responses was examined by using a cell-mixing protocol with primed T and B cells from BALB/c and B10.D2 mice. T15 representation in these responses was determined by the genotype of the B cell, not by the genotype of the helper T cell. Similarly, the B cell genotype was responsible for the idiotypic profile of a primary, in vitro, T-dependent, anti-PC response.     

Murine bone marrow IgA responses to orally administered sheep erythrocytes

Specific immunization protocols have been established for the induction of murine bone marrow IgA responses to the T cell-dependent (TD) antigen sheep red blood cells (SRBC). Systemic immunization, either i.p. or i.v., followed by a second injection, induced splenic IgM and IgG responses and a bone marrow IgM response. No significant IgA responses were observed in either lymphoid tissue compartment. Oral immunization with SRBC by gastric intubation for 2 days, followed 1 wk later by an i.p. injection of SRBC resulted in a splenic IgA plaque-forming cell (PFC) response, but did not elicit a bone marrow IgA response. Repeated daily gastric intubation of SRBC to C3H/HeN and C3H/HeJ mice led to the previously reported pattern of systemic unresponsiveness in C3H/HeN mice and good anamnestic type IgM, IgG, and IgA splenic anti-SRBC PFC responses in the C3H/HeJ strain upon parenteral challenge. Oral administration of SRBC for 14 days to C3H/HeN mice, followed by systemic SRBC challenge, resulted in diminished splenic PFC responses of all isotypes, whereas gastric intubation of SRBC for 28 days led to complete systemic unresponsiveness to antigen in C3H/HeN mice. Interestingly, the repeated oral administration of SRBC resulted in significant bone marrow IgA PFC responses upon i.p. challenge in both C3H/HeN and C3H/HeJ mouse strains. The bone marrow IgA responses were clearly dependent upon chronic oral exposure to SRBC, because gastric intubation with SRBC for 2 consecutive days/wk for 10 wk also induced bone marrow and splenic IgA anti-SRBC PFC responses in C3H/HeN mice. These results suggest that memory B cells reside in the bone marrow of orally immunized mice and can yield anamnestic-type responses to challenge with the inducing antigen. The memory cells may arise in the Peyer's patches of the gut and migrate to the bone marrow. The possibility that the bone marrow is a component of the common mucosal immune system in mammals is suggested by this study.