Immune response to the p-azobenzenearsonate (ABA)-GAT conjugate. II. Hapten-specific T cells induced with ABA-GAT in GAT responder X nonresponder F1 hybrids are restricted to the nonresponder haplotype

Immunization of mice with the ABA-GAT conjugate stimulates GAT-specific T helper cells in GAT-responder animals and ABA-specific helpers in nonresponders. Unexpectedly, immunization of (responder X nonresponder) F1 mice, which have the GAT-responder phenotype, leads to the recruitment of both ABA- and GAT-specific clones of T helper lymphocytes. The GAT-reactive population is restricted to the haplotype of the responder parent (Iak), whereas ABA-specific T cells are mostly restricted to the nonresponder one (Ias). This is demonstrated by the ability of monoclonal antibodies to parental la antigens to inhibit T cell proliferation to GAT or ABA-Tyr in vitro. Consistently, ABA-GAT-primed F1 T cells can only activate nonresponder B cells to proliferate in the presence of ABA-Tyr and responder B lymphocytes in the presence of GAT. Furthermore, F1 T cells seem to recognize both ABA and GAT epitopes only in association with molecules encoded by the I-A subregion. Analysis of ABA-specific F1 T cell lines generated by in vitro stimulation with ABA-Tyr or ABA-GAT demonstrates a competition between GAT- and ABA-specific T cells present in the hybrid T cell repertoire and restricted to the same parental I-Ak molecule. The results indicate that F1 macrophages can present both ABA and GAT epitopes to T cells in association with the two parental and hybrid Ia determinants. It seems unlikely that the absence of GAT-specific T cells restricted to the nonresponder I-A in the F1 is due to suppressor T cells. Thus, the competition model that we propose, to explain the selective F1 T cell response to ABA-GAT, leads us to believe that GAT nonresponder animals may lack clones capable of recognizing, with a high affinity, I-As + GAT.     

ABA-specific responses are I region restricted by the carriers used for immunization

Immunization of mice with ABA coupled to carriers to which they are nonresponders gives rise to ABA-specific proliferative responses in lymph node cells. When C3H/HeN and CBA/J nonresponder mice are immunized with ABA on (T,G)-A-L (an I-A-restricted carrier in responder mice), the responses to ABA-tyr and ABA coupled to a variety of unrelated carriers are solely I-A restricted as determined by inhibition with anti-IA and anti-I-E sera. When ABA on GLT (an I-E-restricted carrier in responder mice) is used for immunization, the responses are both I-A and I-E restricted. Thus, ABA-specific responses in nonresponder mice appear in part to be restricted by the carrier used for immunization. B10.S mice, lacking functional I-E molecules, channel their ABA-specific responses entirely through I-A when immunized with ABA-GLT. These results support the hypothesis that the failure in nonresponders lies in a functional deficit in the T cell repertoire rather than an inability of accessory cells to present antigen.     

T cell subsets in (responder x nonresponder)F1 mice regulating antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine (GAT)

Immune responses to GAT are controlled by H-2-linked Ir genes; soluble GAT stimulates antibody responses in responder mice (H-2b) but not in nonresponder mice (H-2q). In nonresponder mice, soluble GAT stimulates suppressor T cells that preempt function of helper T cells. After immunization with soluble GAT, spleen cells from (responder x nonresponder: H-2b X H-2q)F1 mice develop antibody responses to responder H-2b GAT-M phi but not to nonresponder H-2q GAT-M phi. This failure of immune F1 spleen cells to respond is due to an active suppressor T cell mechanism that is activated by H-2q, but not H-2b, GAT-M phi and involves two regulatory T cell subsets. Suppressor-inducer T cells are immune radiosensitive Lyt-1 +2-, I-A-, I-J+, Qa-1+ cells. Suppressor-effector T cells can be derived from virgin or immune spleens and are radiosensitive Lyt-1-2+, I-A-, I-J+, Qa-1+ cells. This suppressor mechanism can suppress responses of virgin or immune F1 helper T cells and B cells. Helper T cells specific for H-2b GAT-M phi are easily detected in F1 mice after immunization with soluble GAT; helper T cells specific for H-2q GAT-M phi are demonstrated after elimination of the suppressor-inducer and -effector cells. These helper T cells are radioresistant Lyt-1+2-, I-A+, I-J-, Qa-1- cells. These data indicate that the Ir gene defect in responses to GAT is not due to a failure of nonresponder M phi to present GAT and most likely is not due to a defective T cell repertoire, because the relevant helper T cells are primed in F1 mice by soluble GAT and can be demonstrated when suppressor cells are removed. These data are discussed in the context of mechanisms for expression of Ir gene function in responses to GAT, especially the balance between stimulation of helper vs suppressor T cells.     

The functional helper T cell repertoire specific for L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)

Experiments have been carried out to examine the potential helper T cell repertoire specific for the random terpolymer GAT on responder, nonresponder, and (responder x nonresponder)F1 murine strains. The ability of GAT-MBSA immunized T cells to collaborate with DNP-specific primary and secondary B lymphocytes of each strain in response to the antigen DNP-GAT was tested with the splenic fragment culture system. The results of these experiments show that there are GAT-specific T lymphocytes in the responder, nonresponder, and F1 strains but that these 3 GAT-specific T cell populations differ in their collaborative potential. In sum, these findings present new evidence that the nonresponder status to the terpolymer GAT is due, in part, to a functional deletion of helper T cells capable of recognizing the antigen in the context of the nonresponder haplotype. Further, a new responsive phenotype is evidenced when F1 secondary B cells are stimulated in nonresponder GAT-MBSA-primed recipients. In this case, rather than the IgG1 responses observed in such strain combinations to other antigens such as DNP-Hy or DNP-Gl phi 9, only IgM responses were obtained. This new phenotype may be the result of GAT-specific suppression of isotype switching by B cells bearing the nonresponder cell surface alloantigens.     

TTGG-A-L-specific memory B cells induced in low responder strains

The immune response to TTGG-A--L, a defined-sequence, branched-chain polypeptide, is regulated by MHC-linked Ir genes. TTGG-A--L-specific B cells can be demonstrated in low responder strains by activation to specific antibody secretion after immunization with TTGGAA-F gamma G, a conjugate of the hexapeptide TTGGAA and the immunogenic carrier fowl gamma-globulin. It is shown that immunization with TTGG-A--L induces specific memory B cells with equal efficiency in low and high responder strains. This finding demonstrates that memory formation in a B cell subpopulation represented by TTGG-A--L-specific precursors is independent of carrier-specific, MHC-restricted helper T cells. This conclusion is further supported by the demonstration in an adoptive transfer model that immunization with TTGG-A--L induces equivalent levels of TTGG-A--L-specific memory B cells in T cell-deficient nude mice and their normal heterozygous littermates.     

Anti-idiotypic treatment of BALB/c mice induces CRIa-bearing suppressor cells with altered Igh-restricted function

The ABA-specific antibody response of A/J mice (Igh Ie) is dominated by the CRIa idiotype. In contrast, BALB/c mice (Igh Ia) do not produce CRIa-bearing anti-ABA antibodies after antigenic challenge. We have shown previously that treatment with rabbit anti-CRIa (R-anti-CRIa) induces the expression of "CRIa-like" anti-arsonate antibodies in BALB/c mice. In the present report, we demonstrate that R-anti-CRIa treatment enables BALB/c mice to respond to A/J ABA-specific first-order suppressor molecules (TsF1). Manipulated BALB/c also produced CRIa bearing ABA-specific immune response. Thus, R-anti-CRIa treatment induces a change in the characteristic Igh restriction pattern typically seen in this system. These data suggest that Igh restriction in the ABA-specific T suppressor cell pathway is the result of CRIa+ dominance in the T suppressor cell response of A/J mice. The effectiveness of idiotypic manipulation in inducing the expression of a given idiotype at both the B cell and T suppressor cell levels is discussed.     

Induction of T lymphocyte responses to a small molecular weight antigen. I. Failure to induce tolerance in azobenzenearsonate (ABA)-specific T cells in guinea pigs with an ABA conjugate of A copolymer of D-glutamic acid and D-lysine (D-GL).

2,4-Dinitrophenyl (DNP) coupled to the copolymer D-glutamic acid and D-lysine (D-GL) induces B cell tolerance but not T cell tolerance. This implies either a lack of DNP determinant recognition by T cells or a substantial difference in tolerance mechanisms for the two cell types. In the present study D-GL was conjugated with the well-defined determinant azobenzenearsonate (ABA) coupled to single amino acids shown here and previously by others to trigger effectively T lymphocytes. The experiments presented here demonstrate that these ABA conjugates of D-GL, although capable of diminishing anti-ABA antibody production, completely fail to render ABA-specific T lymphocytes tolerant thus drawing us to conclude that there are significant operational differences in the mechanisms of tolerance induction in T and B lymphocytes, respectively.     

Identification of suppressor T cells in virgin non-responder spleen cells responsible for primary unresponsiveness to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)

T cell subsets that regulate antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) in mice that are Ir gene non-responders have been further characterized. We previously defined several T cell subsets in GAT-primed non-responder mice. The Lyt-2+ suppressor-effector T cells suppress responses to GAT and GAT complexed to methylated BSA (GAT-MBSA). The Lyt-1+ cell population is complex and can be separated into I-J- Th cells, which support responses to GAT and GAT-MBSA. After priming, the Lyt-1+, I-J+ cell population contains suppressor-inducer cells that activate precursors of suppressor-effector cells to suppress responses to GAT and GAT-MBSA as well as Ts cells that directly inhibit responses to GAT but not GAT-MBSA. By contrast, the Lyt-1+ cells from virgin mice contain only cells that directly suppress responses to GAT but not GAT-MBSA. The major question addressed in the present studies was whether the Lyt-1+, I-J+ Ts cells in virgin and primed mice and the suppressor-inducer cells in GAT-primed mice were functionally and serologically distinct subsets. The studies used mAb and panning procedures to separate cell populations and inhibition of PFC cell responses to functionally define the activity of the cell populations. We used the following two mAb that were raised by immunizing rats with GAT-specific suppressor factors: 1248A4.10 (known to react with suppressor-inducer cells) and 1248A4.3, another reagent from the same fusion. Lyt-1+ cells from virgin spleens contained Ts cells that were A4.10-, A4.3+ and no suppressor-inducer T cells, whereas Lyt-1+ cells from GAT-primed spleens contained Ts cells that were A4.10-, A4.3+ as well as A4.10+, A4.3- suppressor-inducer cells. Thus, the Lyt1+, I-J+ cell subset can be divided into two functionally and serologically distinct subsets, direct Ts cells (1248A4.3+), which suppress responses to GAT but not GAT-MBSA, and GAT-primed suppressor-inducer T cells (1248A4.10+).     

Hapten-specific IgE antibody responses in mice. VII. Conversion of IgE "non-responder" strains to IgE "responders" by elimination of suppressor T cell activity.

Mice of the inbred strains SJL (H-2s) and AKR (H-2k) are "non-responders" and "low-responders," respectively, in terms of their capacity to develop antibody responses of the IgE class when immunized with conventional proteins and hapten-protein conjugates under conditions optimal for eliciting IgE responses in "high-responder" mice, such as BALB/c (H-2d), to these same antigens. For example, BALB/c mice preimmunized with ASC and then challenged 7 days later with DNP-ASC develop peak augmented primary IgE anti-DNP antibody responses of 320 PCA units, whereas SJL and AKR mice develop responses which are 16-fold and 4-fold lower, respectively. However, pretreatment of the latter two strains with appropriate doses of either x-irradiation (150 R), cyclophosphamide (100 mg/kg) or ALS (150 mul) before carrier-preimmunization strikingly enhances the magnitude of IgE antibody responses in such mice to levels as high as 64-fold above those of untreated control mice of the same strains. Evidence obtained in these experiments indicates that the capacity of such maneuvers to to convert poor IgE responders to high responder status reflects elimination of nonantigen-specific suppressor T lymphocytes which are naturally present and normally function to suppress or "dampen" the IgE antibody response in a relatively selective manner. It appears that these cells modulate IgE responses by acting at least at two distinct points: 1) The most effective activity seems to be at the level of induction of carrier-specific helper T cells; 2) A second locus of inhibitory activity is more distal in the response, either impeding helper T cell-B cell cooperative interactions or suppressing B cell differentiation and/or function directly. Taken collectively, these observations demonstrate that the state of poor responsiveness of the SJL and AKR strains for the IgE antibody class is not a reflection of a genetic inability to develop IgE responses but rather a manifestation of a genetic capability to actively inhibit IgE antibody synthesis.     

The effect of selection of both sire and dam on the response of F1 generation lambs to vaccination with irradiated Trichostrongylus colubriformis larvae

Windon R. G. and Dineen J. K. (1981). The effect of selection of both sire and dam on the response of F₁ generation lambs to vaccination with irradiated Trichostrongylus colubriformis larvae. International Journal for Parasitology11: 11–18. Rams and ewes, tested for responsiveness to vaccination with irradiated T. colubriformis larvae at an early age, were mated on the basis of responder × responder and non-responder × non-responder. Progeny were vaccinated at 8 and 12 weeks of age with 20,000 irradiated larvae, treated with anthelmintic at 16 weeks and challenged with 20,000 normal larvae at 17 weeks. Faecal egg counts of progeny from responder matings were significantly lower than progeny from non-responders, and within each mating type, ewe lambs had markedly lower egg counts than ram lambs. The level of circulating complement-fixing antibodies to T. colubriformis larval extract were inversely related to egg counts. Thus, ewe progeny from responder matings had the highest serum antibody levels, non-responder ram progeny had the lowest levels and responder rams and non-responder ewes had similar intermediate levels. In vitro responses of cells stimulated with T. colubriformis L₃ antigen were greater in progeny from responder matings, whereas responses to bacterial lipopolysaccharide were higher in progeny from non-responder matings. The results confirm that the response to vaccination at an early age is genetically determined, and show that the response of progeny is most vigorously expressed when both sires and dams have been selected.     

ABA-specific helper T cells in A/J mice bear the major cross-reactive idiotype

Attempts were made to induce azobenzenearsonate (ABA)-specific helper cell responses in A/J mice. These were measured by an increase in TNP plaque-forming cells following administration of the double hapten conjugate ABA-bovine serum albumin-TNP. Immunization with ABA coupled homologous immunoglobulin or spleen cells produced ABA-specific help only when the same carrier was used to boost. Hapten-specific help was achieved by two injections of ABA-N-acetyltyrosine in complete Freund's adjuvant 5 weeks apart. This help was passively transferable by T cells as shown by its elimination with anti-Thy 1.2 serum and complement treatment. The presence of the major ABA cross-reactive idiotype (CRI) on these T helper cells could be similarly shown by the elimination of help when the cells were treated with rabbit anti-CRI antibody and complement prior to passive transfer. The same treatment did not effect ABA-specific helper activity of CBA/J mice.     

T cell subsets regulating antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) in virgin and immunized nonresponder mice

T cell subsets from virgin and immunized mice, which are Ir gene controlled nonresponders to GAT, which regulate antibody responses to GAT have been characterized. Virgin nonresponder B10.Q B cells develop GAT-specific antibody responses to GAT, B10.Q GAT-M phi, and GAT-MBSA when cultured with virgin or GAT-primed Lyt-1+, I-J-, Qa1- B10.Q helper T cells. Virgin T cells are radiosensitive, whereas immune T cells are radioresistant (750 R); qualitatively identical helper activity is obtained with T cells from mice immunized with soluble GAT, B10.Q GAT-M phi, and GAT-MBSA. Responses to GAT and GAT-M phi are not observed when virgin or GAT-primed Lyt-1+, I-J+, Qal+ T cells are added to culture of virgin or GAT-primed Lyt-1+, I-J-, Qa1- helper T cells and virgin B cells; the GAT-specific response to GAT-MBSA is intact. The Lyt-1+, I-J+, Qa1+ T cells from mice primed with GAT, GAT-M phi, and GAT-MBSA were qualitatively identical in mediating this suppression. Virgin Lyt-2+ T cells have no suppressive activity alone or with virgin Lyt-1+, I-J+, Qa1+ T cells, whereas responses to GAT, GAT-M phi, and GAT-MBSA are suppressed in cultures of GAT-primed helper T cells containing GAT-primed Lyt-2+ T cells (with or without GAT-primed Lyt-1+, I-J+, Qa1+ T cells). Suppression of responses to GAT-MBSA in cultures of GAT-M phi-primed helper T cells requires both GAT-M phi-primed Lyt-1+, I-J+, Qa1+ T cells and Lyt-2+ T cells; the Lyt-1+, I-J+, Qa1+ T cells appear to function as inducer cells in this case. In cultures containing GAT-MBSA-primed helper T cells, either GAT-MBSA-primed Lyt-1+, I-J+, Qa1+ or Lyt-2+ T cells suppress responses to GAT and GAT-M phi; under no circumstances are responses to GAT-MBSA suppressed by GAT-MBSA-primed regulatory T cells. This regulation of antibody responses to GAT by suppressor T cells is discussed in the context of the involvement of suppressor T cells in responses to antigens under Ir control, and of the evidence that nonresponsiveness to GAT is not due to a defect in the T cell repertoire, but rather is due to an imbalance in the activation of suppressor vs helper T cells.     

Antigen-specific suppressor T cell interactions. I. Induction of an MHC-restricted suppressor factor specific for L-glutamic acid50-L-tyrosine50

The synthetic polymers L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) and L-glutamic acid50-L-tyrosine50 (GT) stimulate specific suppressor T cells in certain strains of mice. Extracts from these T cells contain factors (TsF) that inhibit GAT- or GT-specific antibody responses by normal spleen cells or proliferative responses by primed T cells. We constructed T cell hybridomas that constitutively produce GAT-TsF or GT-TsF, which functionally and serologically are identical to factors extracted from suppressor T cells. In this report we demonstrate that monoclonal GT-TsF can induce specific unresponsiveness in vivo or in vitro and that this unresponsiveness is due to development of second-order antigen-specific suppressor T cells. T cell hybridomas were constructed by fusion of BW5147 with GT-TsF1 induced second-order suppressor T cells and clones that produced suppressor factor (GT-TsF2) were isolated and characterized. GT-TsF2 differs from the GT-TsF1 used to induce it in that GT-TsF1 acts across allogeneic barriers whereas GT-TsF2 does not. This restriction is controlled by genes in the H-2 gene complex and maps to the I-J subregion. GT-TsF2 is antigen-specific in suppressive activity and also in its antigen-binding site(s). Thus, GT-TsF2 closely resembles the carrier-specific, I-J+, genetically restricted factor described by Tada and his colleagues. Because GT-TsF2 was induced by GT-TsF1, we suggest cells producing GT-TsF1 are an early cell in the pathway of suppression, and that this cell is required for the activation of antigen-specific, MHC-restricted TsF.     

Changes in the Ir gene controlled response phenotypes in mice of the Ap and Ak family of alleles expressing naturally occurring variant molecules

Several wild-derived H-2 haplotype mice were recently shown by serology and tryptic peptide fingerprinting to express I-region A molecules closely related to the Ap and Ak molecules of the laboratory strains. To determine if such naturally occurring minor structural variations in the A molecule alter Ir gene-controlled responsiveness, we examined the immune responses of these strains after primary immunizations to three synthetic polypeptide antigens: G60Phe40, GLPhe9, and GAT10. Inbred strains carrying the Ap (or Aq) allele are known to be high responders to G60Phe40 and GLPhe9 but low responders to GAT10. Strains expressing the Ak allele are classified as low responders to G60Phe40 and GLPhe9, but high responders to GAT10. Of seven strains examined belonging to the Ap family, one (B10.CAS2) failed to respond to either G60Phe40 or GLPhe9 as measured by antibody production and T cell proliferation. In addition, two strains (B10.STC90 and W12A) of the Ak family were found to be of responder phenotype to GLPhe9. Both GLPhe9 responses resulted from the introduction of new E beta genes into the I region through naturally occurring intergenic recombination between A beta A alpha and E beta. All strains of mice in the Ak family proved to be of the high responder phenotype in their responses toward GAT10. These results contrast strongly with known patterns of alloreactivity against the variant Ap and Ak molecules.     

Tolerance to azobenzenearsonate: idiotype-specific suppression, B cell dominance, and clonal elimination

Twenty to 70% of the antibody molecules produced by individual A/J mice in response to azobenzenearsonate (ABA) bear a particular idiotype termed the major cross-reactive idiotype (CRI). Mice that were made tolerant to ABA by injection of ABA coupled to human gamma-globulin show a decrease in production of ABA-specific antibody and a preferential loss of the major CRI. In the experiments reported here, we have used adoptive cell transfers and splenic fragment culture assays to study the mechanism(s) involved in the tolerance to ABA, with emphasis on the preferential loss of the CRI. These studies show that the decrease in total anti-ABA after the induction of tolerance is the result of a decrease in the number of ABA-responsive B cells independent of CRI expression. The preferential loss of the CRI is due to idiotype-specific T cell suppression and/or B cell dominance. In addition, it is demonstrated that immunization in the presence of idiotype-specific suppression converts a normally immunogenic stimulus into a tolerogenic signal, resulting in a decrease in the absolute number of CRI+ B cell precursors.     

Variation in resistance to haemonchosis: selection of female sheep resistant to Haemonchus contortus.

Seventy female lambs (6-7 months old) which were exposed to natural infections of Haemonchus contortus were designated as responders or non-responders on the basis of 10 weekly cumulative faecal egg counts. Selected responder and non-responder lambs were treated with ivermectin, housed separately and 6 weeks post-housing, seven lambs from each group were given a trickle infection of Haemonchus contortus at 1000 L3 daily for 5 days per week up to 2 weeks and examined weekly for 10 weeks after first infection. Analysis of data revealed significantly lower mean faecal egg counts and non-significantly less weight loss in responder than non-responder lambs. Mean values of haemoglobin, packed cell volume, total serum protein and peripheral eosinophil counts were significantly higher in responders than non-responders. In contrast, serum pepsinogen concentration was significantly less in responders than in non-responders. At 10 weeks post-infection, there were fewer pathological lesions and significantly lower worm burdens in responders than in non-responders. These results demonstrate a distinct resistance in responders to Haemonchus contortus infection.     

Suppressor cell induction in vitro. VI. Production of suppressor factors to synthetic polypeptides GAT and (T,G)-A--L from cells of responder and nonresponder mice.

The capacity of responder and nonresponder strains of mice to generate suppressor cells and factors to two antigens under MHC linked Ir gene control was investigated. Eight different H-2 types (H-2b,d,f,k,p,q,r,s) as well as seven independently derived strains (B10, BALB/c, CBA/Ca, A/St, DBA/2, P/J, SJL) were tested, and all yielded suppressor factor (SF) to (T,G)-A--L and GAT. This indicated that the genetic control of SF production was different from that of helper cell induction. Unlike previous reports of GAT suppressor extracts that GAT-specific supressor factors acted equally on both responder and nonresponder strains. As reported earlier with in vitro induced protein- (KLH) specific suppressor factors, GAT and (T,G)-A--L specific suppressor factors failed to show any genetic restriction in their function. The implications of these results for the general mechanism of Ir gene control are discussed.     

Gentic control of the immune response to the Ea-2 alloantigen system of the mouse. I. The humoral antibody response.

The immunization of selected congenic strains and hybrids against the Ea-2.1 cellular alloantigen of the mouse demonstrated that the hammagglutinating antibody response to Ea-2.1 is regulated by a gene or genes associated with the H-2 gene complex. H-2r and H-2b are, respectively, responder and non-responder haplotypes.     

Accessory cell stimulation of T cell proliferation requires active antigen processing, Ia-restricted antigen presentation, and a separate nonspecific 2nd signal

The roles of Ia+ accessory cells in H-2-restricted stimulation of antigen-specific T cell proliferation were explored in an in vitro model. L-glutamic acid60-L-alanine30-L-tyrosine10-(GAT) primed BALB/c nylon wool-passed T cells were depleted of Ia+ antigen-presenting cells (APC) by treatment with monoclonal anti-Ia antibody plus complement. Such cells failed to respond to soluble GAT, or to soluble GAT in the presence of phorbol myristic acetate (PMA), which is known to stimulate production of, or replace, IL-1 in vitro. Addition of gamma-irradiated syngeneic spleen cells reconstituted the response to soluble GAT, but addition of ultraviolet (UV) light-irradiated spleen cells did not, even in the presence of PMA. Preincubation of cells with GAT for 24 hr, followed by washing, then gamma irradiation, generated a cell population able to stimulate GAT-primed T cells to proliferate. The same pulsed cells exposed to UV irradiation failed to stimulate T cell responses unless PMA was added to the cultures. The relevant cells in this UV-irradiated population are Ia+. It is concluded that a finite period of time for interaction of metabolically intact APC with antigen is required before creation of an appropriate (Ia + antigen) signal recognized by the T cell. In addition to such Ia-restricted antigen presentation, however, a 2nd nonspecific signal, again requiring metabolically active APC for elaboration, is necessary for detectable T cell activation. These studies thus define 3 separable activities of APC during the process of H-2 restricted T cell activation.     

Genetic regulation of the immune response to hepatitis B surface antigen (HBsAg). V. T cell proliferative response and cellular interactions

We previously demonstrated that in vivo antibody production to HBsAg in the mouse is regulated by at least two immune response (Ir) genes mapping in the I-A (HBs-Ir-1) and I-C (HBs-Ir-2) subregions of the H-2 locus. To confirm that H-2-linked Ir genes regulate the immune response to HBsAg at the T cell level and to determine if the same Ir genes function in T cell activation as in B cell activation, the HBsAg-specific T cell responses of H-2 congenic and intra-H-2 recombinant strains were analyzed. HBsAg-specific T cell proliferation, IL 2 production, and the surface marker phenotype of the proliferating T cells were evaluated. Additionally, T cell-antigen-presenting cell (APC) interactions were examined with respect to genetic restriction and the role of Ia molecules in HBsAg presentation. The HBsAg-specific T cell proliferative responses of H-2 congenic and intra-H-2 recombinant strains generally paralleled in vivo anti-HBs production in terms of the Ir genes involved, the hierarchy of responses status among H-2 haplotypes, antigen specificity, and kinetics. However, the correlation was not absolute in that several strains capable of producing group-specific anti-HBs in vivo did not demonstrate a group-specific T cell proliferative response to HBsAg. The proliferative responses to subtype- and group-specific determinants of HBsAg were mediated by Thy-1+, Lyt-1+2- T cells, and a possible suppressive role for Lyt-1-2+ T cells was observed. In addition to T cell proliferation, HBsAg-specific T cell activation could be measured in terms of IL 2 production, because anti-HBs responder but not nonresponder HBs-Ag-primed T cells quantitatively produced Il 2 in vitro. Finally, the T cell proliferative response to HBsAg was APC dependent and genetically restricted in that responder but not nonresponder parental APC could reconstitute the T cell response of (responder X nonresponder)F1 mice, and Ia molecules encoded in both the I-A and I-E subregion are involved in HBsAg-presenting cell function.