The high background immune reactivity of mice to polymorphic determinants on xenogeneic erythrocytes: theoretical and practical implications

Background responses have been assessed by fusing lipopolysaccharide- (LPS) stimulated spleen cells from unimmunized mice with MOPC 315.43 myeloma cells and screening the hybrids for the production of antibody against chicken red blood cells (CRBC). Clones specific for CRBC represented about 1% of total hybrid clones (1000 to 5000 clones were obtained per mouse). The majority of the anti-CRBC clones (greater than 95%) secreted antibody against polymorphic CRBC determinants (present on CRBC from some but not all chickens) rather than species-specific determinants present on all CRBC. Some of the polymorphic determinants were linked to the B locus (the MHC of the chicken) and some were non-B antigens. The relative amount of these 2 categories varied slightly according to the mouse strain. These results agree well with the specificities of natural mouse antibody and rosette-forming spleen cells. The response of immunized mice against CRBC and human RBC was also selective for polymorphic determinants. These results have considerable importance for the use of xenogeneic RBC as "standard" antigens, and are interpreted in terms of a model for the advantages of genetic polymorphism as a protection against antigen mimicry by parasites.     

Development of self-tolerance in normal mice. Appearance of suppressor cells that maintain adult self-tolerance follows the neonatal autoantibody response

T cell populations from BALB/c mice at different ages were analyzed to determine when in development Ts cells specific for the anti-mouse RBC (MRBC) autoantibody response become activated. Previous studies have shown that adult CD8+ T cells actively suppress this autoimmune response and adult spleen cells depleted of CD8+ cells can generate an anti-MRBC response in culture with MRBC. The present results demonstrate that T cells from mice less than 1 wk of age do not suppress the in vitro anti-MRBC response of adult spleen cell populations depleted of CD8+ Ts cells. By 2 wk of age Ts cells are detectable in this anti-self response and reach adult levels by 3 wk of age. Non-specific "natural suppressor" cells normally present in neonatal spleen cell populations are unable to suppress this autoantibody response, although they are active in suppressing anti-SRBC responses in the same cultures. Before the appearance of Ts cells active in the anti-MRBC response, neonatal spleen cell populations can generate anti-MRBC antibody-forming cells, both spontaneously in vivo and in vitro. The in vitro anti-MRBC response of neonatal spleen cells was shown to be Ag driven and Ag specific. The ability of unfractionated spleen cells to generate this response in vitro declines with age and is relatively low by 3 wk. This decline in responsiveness occurs simultaneously with the appearance of suppression specific for the anti-MRBC response, suggesting that the two events may be causally related.     

Experimental erythrocyte autoantibodies. V. Induction and suppression of red blood cell autoantibodies in mice injected with rat bromelain-treated red blood cells

Mice injected with rat red blood cells (RBC), or rat bromelain-treated (brom) RBC, produce RBC autoantibodies and suppressor cells that specifically inhibit the autoimmune response without inhibiting the net production of antibodies against rat RBC. It has been investigated whether suppressor cells induced by injections of rat RBC are effective in preventing autoantibody production induced by rat brom RBC and vice versa. Autoantibodies were induced in C3H mice by weekly ip injections, each 0.2 ml, of a 6% suspension of rat RBC or rat brom RBC. Autoantibody production was assayed using Coombs' test. Suppressor cells were present in the spleens of mice positive in Coombs' tests and were shown by intravenous injections of 40 X 10(6) viable cells per mouse into untreated syngeneic mice 18 hr before the first injection of rat RBC or rat brom RBC. Autoantibodies eluted from mice positive in Coombs' tests after injections of rat RBC or brom RBC were absorbed by either type of rat RBC but not by RBC from sheep. This suggests that rat RBC and rat brom RBC display antigens that are similar, if not identical, to autoantigens on the mouse RBC. Spleen cells from mice injected with rat RBC suppressed autoantibodies induced by both rat RBC and rat brom RBC. In contrast, spleen cells from mice injected with rat brom RBC suppressed autoantibodies induced by rat brom RBC but not those induced by unmodified rat RBC. This differential suppression may be due to the removal from rat RBC, by bromelain, of a suppressor site and/or autoantigens of some specificities. Thus rat brom RBC may not induce the total range of specificities of autoantibodies, and of suppressor cells, induced by rat RBC.     

Analysis of the cellular interactions involved in the regulation of induced erythrocyte autoantibodies

When normal mice are immunised with rat red blood cells (RBC) they produce autoantibodies against their own red blood cells as well as antibodies against determinants on rat RBC non-cross-reacting with self-RBC. Spleen cells from mice primed with rat RBC specifically suppress the subsequent induction of autoantibody in normal mice. The response to non-cross-reacting determinants on rat RBC is not affected. The results presented here indicate that either T cells or a thymus have to be present in the recipient for suppression to be manifest. It may therefore be the case that suppression is in fact induced in the recipient by the primed T cells.     

Expression and regulation of a recurrent anti-erythrocyte autoantibody idiotype in spleen cells from neonatal and adult BALB/c mice.

BALB/c spleen cells depleted of CD8+ T cells generate an autoantibody response to mouse RBC (MRBC) when cultured 5 days in the presence of syngeneic RBC. More than 80% of the cells secreting anti-MRBC antibody are blocked by an antiidiotypic mAb that recognizes the G8 Id. This G8 Id was originally identified in an autoimmune NZB mouse derived anti-MRBC mAb and later characterized as a dominant Id in NZB anti-MRBC autoantibodies. Furthermore, the CD8+ regulatory T cells that control this autoimmune response in BALB/c mice are specifically eliminated by cytotoxic treatment with the G8 mAb + C, suggesting that the regulatory cells recognize the G8 Id. Spleen cells from neonatal BALB/c mice, which lack those regulatory cells can generate an in vitro antibody response to MRBC without depletion of CD8+ cells. More than 80% of these AFC were also found to express the G8 Id. We propose that Id determinants on autoantibodies that are produced neonatally induce Id-specific regulatory cells that maintain peripheral tolerance to self-RBC throughout the life of normal animals.     

I-J restriction of T cells that suppress in vivo antibody responses to Thy-1

The contact-sensitizing haptens dinitrophenyl (DNP) and oxazalone (Ox) act as helper determinants for antibody responses to Thy-1 when conjugated to donor thymus cells. The helper effect is transferrable from primed to naive mice with spleen cells, producing specific augmentation of in vivo PFC responses to Thy-1. The helper cells are hapten-specific and require associative recognition of hapten and Thy-1, excluding a role for nonspecific B cell activation. The phenotype of the helper cells is Thy-1+ and Lyt-1+2-. Antigen-specific suppression could be readily generated by using an inoculum of DNP-modified syngeneic RBC. T cells from these suppressed donors (Ts) were shown to abolish the helper effects of TH in adoptive transfer experiments in vivo. These Ts were characterized as Thy-1+ and Lyt-1-2+. A requirement for MHC compatibility at the I-J subregion was necessary between the Ts and the recipient to obtain a transfer of suppression.     

Transfer Agent of Immunity

Antibody formation in vitro was studied using erythrocytes (RBC) as antigen and immunocytoadhesion as the technique for detection of antibody-forming cells. Spleen cells (SPC) of nonimmune mice gained the ability to produce antibody after treatment with ribonucleic acid (RNA) preparation extracted from allogeneic mice immunized with xenogeneic or allogeneic RBC. It was also found that a small proportion of SPC from individual mice of certain strains formed antibody against autologous RBC when the cells were treated in vitro with RNA preparation obtained from the spleen of an allogeneic mouse immunized with RBC of that individual. No converting ability was observed in the RNA preparation from spleen of nonimmune autologous or allogeneic mice. The converting activity of immune RNA preparation was shown to be sensitive to ribonuclease treatment. These evidences exclude the possible contribution of antigen or fragments thereof in the RNA preparation to the induction of antibody formation in RNA recipient cells.     

Cytotoxic activity toward mouse melanoma following immunization of mice with transfected cells expressing a human melanoma-associated antigen

Summary B78H1 is a mouse melanoma cell line that is weakly antigenic in syngeneic mice. In an attempt to augment their immunogenicity, B78H1 cells were transfected with genomic DNA from a line of human melanoma cells expressing a 96-kDa melanoma-associated antigen (ICAM-1). A selective co-amplification procedure was employed that generated a population of transfected cells (Ui11) that expressed fivefold higher quantities of the melanoma-associated antigen than the cells from which the DNA was obtained. To test the transfected cells' relative capacity to generate a cellular immune response against B78H1 cells, Ui11 cells and B78H1 cells were administered (in parallel) to syngeneic C57BL/6 mice, susceptible to the growth of the melanoma. Each cell line (lethally iradiated beforehand) was injected intraperitoneally at weekly intervals into the mice. After two or three injections, a standard chromium-release assay was employed to detect the presence of cellular immunity toward B78H1 cells. The population of spleen cells from mice immunized with the transfected melanoma cells exhibited higher levels of cytotoxicity toward B78H1 cells than spleen cells from mice immunized with equivalent numbers of nontransfected cells. This observation is consistent with the notion that the transfected human melanoma-associated antigen acted as a second antigen capable of potentiating cellular immune responses against the weakly immunogenic determinants of the mouse melanoma cells. The introduction of genes for foreign antigens into weakly antigenic tumor cells may generate immunogens that can lead to augmented anti-tumor cellular immune responses.     

The frequency and fine specificity of B cells responsive to (4-hydroxy-3-nitrophenyl)acetyl in aged mice

The B-cell response to NP-Hy of two murine strains has been analyzed in order to evaluate the affects of aging on B-cell repertoire expression. The results indicate that for both BALB/c mice (Igha) and B10.D2 mice (Ighb) the frequency of (4-hydroxy-3-nitrophenyl)acetyl (NP)-responsive splenic B cells is approximately twofold lower, on a per B cell basis, in aged mice as compared to young adults. However, as with previous assessments of the response to DNP-Hy in aged mice, the frequency of newly generated surface immunoglobulin negative bone marrow precursor cells specific for NP in aged BALB/c mice is the same as in young mice. The decrease in frequency of responsive splenic B cells is not accompanied by a measurable decrease in repertoire diversity or changes in clonotype distribution as assessed by representation of kappa vs lambda light chain-bearing antibodies, binding of monoclonal antibodies to a panel of analogues of NP, and the proportionate representation of B10.D2 monoclonal antibodies that bear NPb idiotypic determinants. By these criteria it appears that down-regulation of B cells as they mature and emerge from the bone marrow of aged mice is pan-specific and does not disproportionately affect B cells of a predominant clonotype family. Consistent with other investigations which have demonstrated differences in secreted antibodies of immunized aged vs young mice, we have observed that 4 weeks after immunization of B10.D2 mice with NP-BSA, the frequency of newly generated secondary B cells is lower in aged than in young mice and the generation of lambda-bearing secondary precursor cells is particularly low. Thus, clonotype-specific down-regulation may play a role in shaping the B-cell repertoire subsequent to immunization of aged mice.     

A synthetic decapeptide of influenza virus hemagglutinin elicits helper T cells with the same fine recognition specificities as occur in response to whole virus

The immunogenicity of an isolated murine helper T cell determinant was studied. Mice were immunized with a synthetic peptide corresponding to amino acid residues 111-120 of the influenza PR8 hemagglutinin (HA) heavy chain, a region previously identified as a major target of the helper T cell response to the HA molecule in virus-primed BALB/c mice. Lymph node T cells from these mice were fused with BW 5147 cells to produce T hybrids for clonal analysis of their recognition specificities. Three T cell hybridoma clones, obtained from two different mice, responded to the immunizing peptide when presented by syngeneic antigen-presenting cells. All of these clones responded also to antigen provided as intact wild-type PR8 virus. The fine specificity of the peptide-induced T cell hybridomas, in response to a panel of mutant and variant influenza viruses, was indistinguishable from the fine specificities of T cells to the corresponding region of the HA1 chain of the HA molecule which had been generated by priming of mice with intact wild-type virus. These results suggest that an immunogenic determinant is contained within the 111-120 sequence that is able to elicit anti-influenza virus T cells with a similar repertoire to those elicited by immunization with whole virus.     

Antigen-specific B cells are required as APCs and autoantibody-producing cells for induction of severe autoimmune arthritis

B cells play an important role in rheumatoid arthritis, but whether they are required as autoantibody-producing cells as well as APCs has not been determined. We assessed B cell autoantibody and APC functions in a murine model of autoimmune arthritis, proteoglycan (PG)-induced arthritis, using both B cell-deficient mice and Ig-deficient mice (mIgM) mice that express an H chain transgene encoding for membrane-bound, but not secreted, IgM. The IgH transgene, when paired with endogenous lambda L chain, recognizes the hapten 4-hydroxy-3-nitro-phenyl acetyl and is expressed on 1-4% of B cells. B cell-deficient and mIgM mice do not develop arthritis after immunization with PG. In adoptive transfer of PG-induced arthritis into SCID mice, T cells from mIgM mice immunized with PG were unable to transfer disease even when B cells from PG-immunized wild-type mice were provided, suggesting that the T cells were not adequately primed and that Ag-specific B cells may be required. In fact, when PG was directly targeted to the B cell Ig receptor through a conjugate of 4-hydroxy-3-nitrophenyl acetyl-PG, T cells in mIgM mice were activated and competent to transfer arthritis. Such T cells caused mild arthritis in the absence of autoantibody, demonstrating a direct pathogenic role for T cells activated by Ag-specific B cells. Transfer of arthritic serum alone induced only mild and transient arthritis. However, both autoreactive T cells and autoantibody are required to cause severe arthritis, indicating that both B cell-mediated effector pathways contribute synergistically to autoimmune disease.     

Characterization of anti-idiotypic suppressor T cells (Tsid) induced after antigen priming

The induction and fine specificity of idiotype-specific suppressor T cells (Tsid) were studied. Spleen cells from C57BL/6 mice, immunized 4 wk previously with NP-KLH, failed to express NPb3 idiotype-bearing PFC when challenged in vitro with NP-Ficoll or NP-Brucella abortus. After treatment of NP-primed responder cultures with anti-Thy-1.2 anti-serum + C, NPb idiotype-bearing B cells could be detected. This B cell subset was preferentially suppressed by the addition of T cells from NP-primed mice. With this reconstitution protocol, it was determined that suppression of the NPb idiotype-bearing portion of the B cell response was mediated by a specifically induced T cell population (Tsid) that directly suppressed NPb-bearing B cells. As with a previously described suppressor population induced with hapten-modified syngeneic spleen cells (Ts2), the Tsid population bound and was lysed by NPb idiotype-bearing serum antibodies. However, the Tsid could be distinguished from the Ts2 population because it lacked I-J determinants and functioned as an effector T cell, not an intermediary suppressor cell. Furthermore, fine specificity studies with monoclonal NP-specific antibodies expressing various levels of serologically detectable NPb idiotypic determinants indicated that unlike the Ts2, the Tsid population reacts with conventional, serologically detected members of the NPb family. The combined idiotype binding studies for the Tsid and Ts2 populations demonstrate that the fine specificity of suppressor T cell populations reflects their independent mechanisms of regulation.     

Differences in the repertoire expressed by peritoneal and splenic Ly-1 (CD5)+ B cells.

Purified populations of B cells expressing the Ly-1 and/or Mac-1 surface Ag were isolated from normal unmanipulated mice by cell sorting. The number of lymphocytes in each population secreting antibodies reactive with DNA, bromelain-treated mouse RBC, phosphorylcholine and TNP-keyhole limpet hemocyanin was quantitated by ELISA spot assay. The proportion of B cells secreting Ig in vivo and the repertoire of antibodies they produced varied as a function of B cell phenotype and location. Among peritoneal lymphocytes, those that were Ly-1+ or Ly-1- Mac-1+ secreted Ig 10 times more frequently that Mac-1- Ly-1- B cells from the same location. In addition, the former populations expressed repertoires that were significantly skewed toward the production of antibodies reactive with bromelain-treated mouse RBC (p less than 0.001). In contrast, splenic B cells expressing the Ly-1 surface Ag did not differ significantly from splenic Ly-1- B cells in their expressed repertoire or frequency of Ig production. B cells isolated from the spleen and peritoneum tended to differ in antibody specificity from bone marrow and lymph node-derived lymphocytes. For example, B cells from the spleen secreted anti-DNA antibodies two to four times more frequently than B cells from other organs. These results demonstrate that phenotype and microenvironment influence the repertoire of antibodies expressed by B cells in vivo.     

Studies on the clonality of the response to an epitope of a protein antigen. Randomness of activation of epitope-recognizing clones and the development of clonal dominance

Syngeneic mice immunized with tobacco mosaic virus protein (TMVP) can differ with respect to their ability to produce antibodies that bind a decapeptide epitope representing residues 103 to 112 of TMVP, and with respect to the fine specificity of the decapeptide binding antibodies as determined by their ability to bind several synthetic analogues of the decapeptide. To elucidate the mechanism responsible for the differences between the syngeneic animals in their ability to make anti-decapeptide antibodies, spleen cells from a large number of naive CSW mice were pooled, and aliquots were transferred (either including or excluding resident T cells) into naive recipients that were subsequently immunized with TMVP. Examination of the frequency and fine specificity of anti-decapeptide antibodies revealed that the recipients exhibited various clonalities of decapeptide binding antibody responses similar to those seen in a normal population of CSW mice. Moreover, the response of each individual mouse was of a restricted clonality despite the availability of a more extensive repertoire of decapeptide-recognizing clones. The results indicate that the selection of the clonality of the antibody response was not determined by the presence (or absence) of particular clones of B or T cells and that the mechanism responsible for generating differences between mice must have acted, subsequent to introduction of the Ag, by activation of a limited number of clones randomly selected by Ag and/or by Ag-driven mutation. The long term nature of the antibody response to the decapeptide epitope was also investigated. The response was shown to be "locked-in" for the life of the immunized individual. Thus, individuals that responded to TMVP but that did not produce antibodies to the decapeptide after the first set of immunizations with TMVP maintained their non-responsiveness to the decapeptide after the second set of immunizations with the protein. However, individuals that responded to an initial set of immunizations with TMVP by producing antibodies to the decapeptide epitope continue to produce antibodies to the decapeptide after a second set of immunizations with TMVP. The fine specificity of the decapeptide-binding antibodies also appeared to be "locked in" throughout the life of the immunized individual. The long term maintenance of the clonability of the antibody response does not appear to be influenced by Ag-specific T cells and is strictly a function of memory B cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of the murine IgE antibody response. I. Characterization of suppressor cells regulating both persistent and transient responses and their sensitivity to low doses of X-irradiation.

Anti-ovalbumin (OA) IgE antibody responses were measured in B6D2F1 mice as a function of time and antigen dose. One hundred to 200 microgram of OA in Al(OH)3 elicited transient responses, whereas 1 to 10 microgram of OA in Al(OH)3 elicited persistent anti-OA IgE responses of high titer. T cells isolated from the spleens of mice mounting either a persistent or a transient response strongly suppressed primary anti-DNP IgE responses in unirradiated recipient mice that were immunized with DNP-OA in Al(OH)3; it was, therefore, concluded that suppressor T cells (Ts cells) were activated during both the persistent and transient IgE responses. Nevertheless, in the present study it was not possible to completely rule out the contention that IgG antibodies may also have been suppressing the IgE response. With a modified adoptive transfer system, it was shown that these Ts cells were sensitive to low doses (250 R) of x-irradiation. The suppressive activity of long-term OA primed cells was also shown to be markedly enhanced when cultured for 24 hr with soluble OA; this finding was interpreted to indicate the presence of memory suppressor cells.     

Acquisition of humoral transplantation tolerance upon de novo emergence of B lymphocytes

A major obstacle to transplantation tolerance is humoral immunity. In this paper, we demonstrate that the intrinsic developmental propensity of the B lymphocyte compartment for acquisition of self-tolerance can be harnessed to induce humoral unresponsiveness to transplanted alloantigens. In the current study, when transitional B cells developed in the presence of donor lymphoid cells, the mature B lymphocyte compartment failed to mount a donor-specific alloantibody response to an organ transplant--despite unrestrained acute T cell-mediated allograft rejection. Specifically, we generated an experimental system wherein a B6 strain B cell compartment developed de novo in the presence of F1 (B6xBALB/c) lymphoid cells and in a T cell-deficient setting. Following establishment of a steady-state B cell compartment, these B6 mice were transplanted with heterotopic cardiac allografts from allogeneic BALB/c donors. The mice were then inoculated with purified syngeneic B6 T cells. As expected, all cardiac allografts were acutely rejected. However, the B lymphocyte compartment of these mice was completely inert in its capacity to form a BALB/c-specific alloantibody response. Using an alloantigen-specific Ig transgenic system, we demonstrated that this profound degree of humoral tolerance was caused by clonal deletion of alloreactive specificities from the primary B cell repertoire. Thus, de novo B cell compartment development at the time of transplantation is of critical importance in recipient repertoire "remodeling" to a humoral tolerant state.     

Anti-P autoantibody production requires P1/P2 as immunogens but is not driven by exogenous self-antigen in MRL mice

Considerable evidence supports the idea that autoantibody production in human and murine SLE is Ag driven. To determine whether Ag (the ribosomal P proteins) could initiate autoantibody production in lupus mice, 34 MRL/lpr mice were immunized with mouse riboosomal proteins in Freund's adjuvant. Neither intact ribosomes, denatured total mouse ribosomal proteins, nor the purified mouse ribosomal proteins, P1 and P2, induced the production of anti-P autoantibodies in the MRL/lpr mice. In contrast to these negative findings, MRL/lpr mice immunized with Artemia salina ribosomes produced anti-P antibodies as well as anti-P autoantibodies. Although the induced anti-P autoantibodies bound exclusively to the carboxyl terminus, these anti-P antibodies differed from spontaneously occurring anti-P autoantibodies in their predominant binding to mouse P0 on immunoblots and their preferential reactivity against A. salina synthetic peptides by ELISA. Induction of anti-P antibodies required the presence of P1 and P2 on the ribosome because ribosomal cores devoid of P1 and P2 dimers did not induce anti-P. Despite the presence of approximately 80 ribosomal proteins, autoantibodies to other mouse ribosomal proteins were rarely observed. Immunization of MRL/+ mice and a normal H-2-matched strain of mice, C3H, also resulted in anti-P antibodies reactive with the A. salina P proteins and mouse P0. Whereas anti-P levels gradually declined in C3H mice, anti-P levels either remained elevated (MRL/lpr) or showed a secondary rise (MRL/+) at the onset of autoimmunity. These observations indicate that: i) high levels of autologous Ag are not sufficient to drive antiribosomal autoantibody production in MRL mice, ii) multivalency of the P proteins may explain their potent immunogenicity and ability to break tolerance, and iii) immunized MRL mice show an abnormal persistence of high level anti-P production presumably reflecting T cell activation of presensitized B cells.     

Suppression in murine experimental autoimmune thyroiditis: in vivo inhibition of CD4+ T cell-mediated resistance by a nondepleting rat CD4 monoclonal antibody.

Genetically susceptible mice become resistant to experimental autoimmune thyroiditis (EAT) induction with mouse thyroglobulin (MTg) and lipopolysaccharide after pretreatment with deaggregated MTg (dMTg). Recent work showed this suppression to be mediated by CD4+ suppressor T cells (Ts). To study Ts action in vivo, we used a rat IgG2a monoclonal antibody (mAb), YTS 177.9, which modulates CD4 antigen in vivo without depleting CD4+ cells. Initial studies showed that after two 1-mg doses of mAb 7 days apart, extensive CD4 antigen modulation of peripheral blood leukocytes occurred within 4 days. Mice given CD4 mAb 24 hr before dMTg (2 doses, 7 days apart) were resistant to EAT induction when immunized with MTg and LPS 20 days later. Also, anti-rat IgG2a titers were reduced following challenge with heat-aggregated rat IgG2a compared to controls. Subsequent analysis of serum in CD4 mAb-treated animals revealed that mAb was present in the circulation for 14 days. Moreover, mice given CD4 mAb and dMTg, then challenged after only 10 days, when CD4 mAb was still circulating, developed a significantly higher incidence of thyroid damage than controls. These findings suggest that modulation of CD4 antigen does not interfere with Ts activation, but the presence of CD4 mAb, at the time of autoantigenic challenge, can interfere with tolerance to EAT induction. Thus, the direct relationship between the presence of CD4 mAb and inhibition of EAT suppression implicates a role for CD4 molecules in the mediation of suppression.     

Administration of PLP139-151 primes T cells distinct from those spontaneously responsive in vitro to this antigen

We examined the TCR repertoire used by naive SJL mice in their in vitro spontaneous response to proteolipid protein (PLP) 139-151 by Vbeta-Jbeta spectratyping and compared it to that used after immunization with the peptide. T cells from immunized mice use the public rearrangement Vbeta10-Jbeta1.1, but naive mice do not; in contrast, TCR CDR3-beta rearrangements of Vbeta18-Jbeta1.2 and Vbeta19-Jbeta1.2 consistently are associated with the spontaneous response. T cells involved in spontaneous and induced responses can each recognize PLP(139-151) presented in vivo, but its s.c. administration has different consequences for the two repertoires. Four days after immunization, T cells associated with spontaneous responsiveness appear in the draining lymph nodes but disappear by day 10 and never appear elsewhere. Simultaneously, Vbeta10-Jbeta1.1 T cells are likewise activated in the lymph nodes by day 4 and spread to the spleen by day 10. Eight- to 10-wk-old naive mice use a narrower repertoire of TCRs than do immunized age-matched mice. Induced Vbeta10-Jbeta1.1 T cells home to the CNS during experimental autoimmune encephalomyelitis, whereas we failed to detect Vbeta18-Jbeta1.2 and Vbeta19-Jbeta1.2 TCR rearrangements in the CNS. Thus, we observe that administration of PLP(139-151) primes a T cell repertoire distinct from the one responsible for spontaneous responsiveness. This "immunized" repertoire substitutes for the naive one and becomes dominant at the time of disease onset.     

Idiotypic properties of the murine anti-arsonate antibody response: B- and T-cell influences

In a previous report characterizing the arsonate (ABA)-specific plaque-forming cell (PFC) responses of A/J mice induced by ABA-KLH, two interesting characteristics of the idiotypic (Id) profile were noted: (1) an apparent Id selectivity in the isotype switch since the earliest appearing IgG PFC in the primary response were significantly more "cross-reactive Id" (CRI)-dominant than the IgM PFC population, and, (2) a temporal waning of CRI dominance with time among IgG PFC, from 75-100% CRI+ PFC to about 25-45% CRI+ PFC in secondary responses. Experiments were performed to determine whether these effects are largely attributable to T or to B cells. Mice were immunized with a T-independent (TI) form of ABA (ABA-Brucella abortus) and apparent Id selectivity was observed; the earliest IgG PFC averaged 75% CRI+ while IgM PFC were only 39% CRI+. Due to the TI nature of the Ag, this provides suggestive, but not conclusive, evidence that the Id asymmetry in the isotype switch may be attributable to the direct interaction of Ag with B cells. Other studies addressed the temporal shift in CRI dominance. First, it was found that preexposure of mice to either KLH or to ABA (on an irrelevant carrier) resulted in diminished CRI dominance in subsequent "primary" responses to ABA-KLH. Secondly, adoptive transfer experiments with B and T cells from virgin mice (Bv, Tv) or ABA-KLH-primed mice (Bp, Tp) showed that recipients of Bv + Tp or Bp + Tv generated anti-ABA PFC responses with intermediate CRI levels. The Tv cells had some preferential tendency to activate CRI+ clones in the Bp population. The results demonstrate that CRI levels are jointly determined by the immune status of both B and T cells. A simple model is offered which accounts for early Id dominance and its gradual decline and has as its central postulate the assumption that CRI+ B cells in the virgin ABA-specific repertoire have an affinity advantage over CRI- clones.