Idiotype expression and fine specificity of Glu60Ala30Tyr10-specific T proliferating cells

The fine specificity of anti-Glu60Ala30Tyr10 (GAT) and anti-Glu60Ala40 (GA) proliferating cells was studied. T cells primed with GAT proliferate both to GAT and GA and GA-primed T cells proliferate also to GA and GAT. This cross-reactivity was unexpected given the results previously reported on the fine specificity of anti-GAT antibodies. The effect on the proliferation of BALB/c lymph node cells (LNC) of a syngeneic anti-idiotypic serum, prepared in BALB/c against anti-GAT antibodies, was studied. Two major points are made in this paper: (i) the in vitro addition of the anti-idiotypic serum in cultures containing GAT-primed LNC and GAT enhances the proliferation of GAT-specific T cells; (ii) the anti-idiotypic serum is effective in priming in vivo LNC which then acquire the capacity to proliferate specifically with GAT in vitro. These results further confirm the existence of idiotype-like determinants on T cells.     

Dissection of the poly(Glu60 Ala30 Tyr10) (GAT)-specific T-cell repertoire in H-2I k mice

Twenty-five allospecific monoclonal antibodies (mAb), produced in the A. TH. A.BY, or B10.S (7R) anti-A.TL combinations, were shown to recognize determinants organized in four spatially distinct polymorphic regions on the same I-Ak-encoded molecule(s). These reagents were used to assess the recognition of the class II major histocompatibility complex (MHC) determinants in a series of GAT-reactive A.TL T-cell clones exhibiting various restriction specificity or alloreactivity patterns. Of the proliferative responses of 13 cloned T cells, 12 responses were found to be inhibited similarly by the same set of mAbs.A hierarchy in the blocking effects of these reagents that could be correlated with the spatial organization of their determinants was observed. (i) All the mAbs defining the epitope region I (i.e., recognizing public Ia.1- or Ia.17-like determinants, presumably expressed on the A beta subunit) and some of those identifying new public determinants in the epitope region II profoundly inhibited these T-cell responses. (ii) Intermediate blocking was observed when mAbs recognizing public determinants in the epitope region III were used. (iii) Finally, among the mAbs that identified the epitope group IV, the Ia.19-specific mAb 39.J was inhibitory, whereas mAbs directed against private Ia.2-like determinants were not. By contrast, the GAT-specific proliferative response of the T-cell clone AT-20.1, which recognized its nominal antigen in an extensively cross-reactive MHC-restricted fashion, could only be inhibited by a subset of the mAbs recognizing epitopes in groups I and II, but not by those recognizing epitopes in groups III and IV. It was also shown that the same subset of I-Ak-and I-Au-reactive mAbs displayed similar blocking effects on the proliferation of two T-cell clones exhibiting dual specificity for I-Ak- and I-Au-restricting and/or I-Ak- and I-Au-alloactivating determinants. Finally, all the cloned T-cell responses examined were found to be inhibited by rat mAbs against the LFA.1 molecule or the murine equivalent of the human OKT4 differentiation antigen. These studies suggest that class II specific mAbs can impair proliferation of cloned T-cells by a mechanism(s) other than the masking of the T-cells' restriction determinants per se.     

Isolation and characterization of an I-A-restricted T cell clone with dual specificity for poly(Glu60Ala30Tyr10) (GAT) and Mlsa,dl

We have isolated a BALB/c (H-2d, Mlsb) T cell clone (JTL-G12) specific for the synthetic polypeptide antigen poly(Glu60Ala30Tyr10) (GAT) in the context of self I-A determinants and for Mlsa,d antigens in the absence of GAT. JTL-G12 proliferation in response to GAT was mapped to the Kd, I-Ad subregions by using inbred H-2 congenic and recombinant strains. In addition, monoclonal antibody directed against I-Ad but not Kd or I-As determinants blocked JTL-G12 proliferation in response to GAT presented by syngeneic splenocytes, indicating I-A restriction. The Mls cross-reactivity of this clone was verified by using a panel of inbred strains bearing the Mlsa,b,c,d alleles and by using BXD recombinant inbred strains bearing the Mlsa allele or the Mlsb allele. All of the Mlsa BXD strains of the H-2d or H-2b haplotypes stimulated JTL-G12 in the absence of GAT, whereas all of the Mlsb BXD strains were nonstimulatory. This response pattern is in complete accordance with recognition of the Mlsa determinant encoded by Mls or closely linked loci on chromosome 1. JTL-G12 proliferation in response to GAT/I-Ad and Mlsa,d determinants could be blocked with a monoclonal antibody (GK1.5) directed against L3T4, a structure involved in class II major histocompatibility complex antigen recognition. These results suggest that antigen/class II responsiveness, Mls reactivity, and expression of L3T4 can be properties of a single T cell population.     

Epitope-specific regulation in Ir gene systems. I. Conditions for the induction of epitope-specific suppressors to poly(Glu60Ala30Tyr10)

Injection of responder mice with poly(Glu60Ala30Tyr10) (GAT) followed by immunization with GAT-methylated bovine serum albumin (GATMBSA) selectively suppresses anti-MBSA plaque-forming cell (PFC) and delayed hypersensitivity (DTH) reactions. Conversely, MBSA injection followed by GATMBSA immunization suppresses anti-GAT PFC and DTH, while anti-MBSA responses remain intact. Suppression occurs for doses of antigen which are optimally immunogenic. The suppression is specific and does not act in a bystander fashion. These results demonstrate that epitope-specific regulation is reciprocal, is not limited to humoral responses, and is not limited to molecules of low molecular weight.     

Idiotypic analysis of hybridoma antibodies to branched synthetic polymer (Tyr, Glu)-Ala-Lys: idiotypic relationship with antibodies to linear random polymer (Glu60, Ala30, Tyr10)

The expression of three anti-GAT idiotypes, CGAT, Gte, and GA-1, on 17 C57BL/10 and four C3H.SW hybridoma anti-(T,G)-A--L antibodies was analyzed. These hybridoma anti-(T,G)-A--L antibodies exhibited two patterns of fine antigen binding specificity. The majority of the hybridoma antibodies bound the (T,G)-A--L, GT, and GAT polymers but not the GA polymer, and were designated as GT-reactive hybridoma antibodies. A minor population of hybridoma anti(T,G)-A--L antibodies bound to (T,G)-A--L but not to GT, GAT, or GA, i.e., (T,G)-A--L-specific. A complete correlation between fine antigen binding pattern and the expression of CGAT idiotype was demonstrated. None of the 21 hybridoma anti-(T,G)-A--L antibodies expressed the GA-1 idiotype. All of the GT-reactive and none of the GT-nonreactive hybridoma anti-(%,G)-A--L antibodies expressed the CGAT idiotype. Furthermore, the Gte idiotype was found on the majority of CGAT+-bearing C57BL/10 hybridoma anti-(T,G)-A--L antibodies. These results indicate that C57BL/10 anti-(T,G)-A--L antibody repertoire can be grouped into a minimum of three families; i.e., CGAT+ Gte+, CGAT+ Gte-, and CGAT- Gte- families, with the CGAT+ Gte+ family as the major compartment. This is confirmed by the high percentage idiotype binding of serum anti-(T,G)-A--L antibodies with anti-CGAT idiotypic antisera. Finally, anti-idiotypic antisera made against CGAT+ hybridoma anti-GAT or anti-(T,G)-A--L antibodies crossreact extensively with other CGAT+ hybridoma anti-GAT and anti-(T,G)-A--L antibodies. However, additional experiments demonstrated that CGAT+ hybridoma anti-(T,G)-A--L antibodies also possess private idiotypes.     

Recessive T cell response to poly (Glu50Tyr50) possibly caused by self tolerance

The proliferative T cell response of inbred mouse strains to the random copolymer poly(Glu50Tyr50) (GT) was found to fall into two categories. Some strains responded only marginally (delta cpm values less than 10,000 and stimulation indices less than 3), whereas other strains mounted a substantial response (delta cpm 10,000 to 80,000, SI 3 to 30). The response is controlled by the A alpha and A beta loci of the major histocompatibility complex (MHC), as well as by genes not linked to the MHC. Because the response is selectively inhibited by monoclonal antibodies specific for the A alpha A beta molecule, we assume that its control by A loci is manifested as an A-restriction of the participating T (Ly-1high, Ly-2-) cells. It is of interest that the responsiveness is recessive in F1 hybrids of responder and nonresponder strains that are H-2-identical, but differ at their genetic background. Nonresponsiveness of these F1 mice is caused neither by a defect of antigen presentation, nor the result of immune suppression on priming or at the effector phase of the response. It is most likely the consequence of clonal deletion during the establishment of self-tolerance.     

Antigen-Specific T-cell factors in the immune response to poly(Tyr,Glu)-poly(Pro)-poly(Lys)

The production by T cells of an antigen-specific factor capable of replacing the T-cell function in specific antibody formation was used as a tool for studying the cellular aspects of the genetic control of immune responses. The ability of different T-cell populations to produce a cooperative signal and the ability of B-cell populations to react to this signal were studied in different mouse strains. The antigen used was the synthetic polypeptide poly(LTyr,LGlu)-poly-(LPro) —poly(lXys), (T,G)-Pro -L, the response to which was found not to beH-2-linked. It was found that the SWR strain of mice, a low responder to (T,G)-Pro -L, is not capable of producing a T-cell factor specific to this antigen, but its B cells react normally to an active factor produced in a high responder strain. In the DBA/1 strain, also a low responder to (T,G)-Pro -L, the bone marrow cells are not able to cooperate with an active T-cell factor to produce anti-(T,G)-Pro —L-specific antibodies, while their T cells do produce a (T,G)-Pro -L-specific factor. The SWR (low responder) B cells can be triggered by DBA/1 (low responder) T cells factor specific to (T,G)-Pro —L to produce an antibody response to this immunogen. These results suggest that the immune response to (T,G)-Pro -L is controlled by two genes which are expressed in different lymphocyte populations.     

Modulation of the helper activity of educated T cells to the synthetic polypeptide poly(Tyr,Glu)-poly(dlAla)-poly(Lys) by adherent cell-bound antigen

The effects of culturing in vivo- or in vitro-activated helper cells on antigen-pulsed splenic adherent cells were studied. In vivo T cells educated to the synthetic polypeptide (T,G)-A-L were obtained by the transfer of thymocytes into lethally irradiated mice. When the activation process was suboptimal, resulting in a low helper function of the cell preparation, incubation of the educated cells on (T,G)-A-L-pulsed splenic adherent cells for 24 hr potentiated their activity, and efficient helper cells were obtained. This process was found to be antigen specific, it did not involve de novo education of naive cells or selection of specific T lymphocytes, but rather completion of the education procedure, which had already started in vivo. It seems that a physical contact between the educated T cells and the antigen-presenting cells is essential for inducing the enhanced helper effect. It is also apparent that during this 24-hr culture on antigen-pulsed macrophages T cells did not proliferate, but rather differentiated into immunocompetent helper cells. On the contrary, when the initial education step was efficient the subsequent culture of the activated T cells on antigen-pulsed splenic adherent cells resulted in a marked decay in the helper function of the cells, while control monolayers were inert. Thus, macrophage-bound antigen differentially modulates the helper function of educated T cells, a procedure which is probably dependent on the degree of maturation or differentiation of the T lymphocyte.     

Multigenic control of immune responses of inbred mice against the terpolymers poly(Glu57Lys38Ala5) and poly(Glu54Lys36Ala10) and linkage withH-2 haplotype

Results of immunizations of recombinant inbred and congenic strains of mice with the random polymers poly(glu⁵⁷ lys³⁸ala⁵) or GLA⁵ and poly(glu⁵⁴lys³⁶ala¹⁰) or GLA¹⁰ indicate that there is an association of the responsiveness with theH-2 haplotype. Although the C57BL/6J mice (H-2 ^b haplotype) are “non responders”, the C57BL/6By originally derived from mice of the same haplotype are responders. The immune response pattern of recombinant strains carrying haplotypes derived by crossing over within theH-2 complex indicate that the responsiveness is under control of anIr gene which maps to the left of theIB subregion. Studies with the backcross mice indicated multigenic control of the responsiveness, with one locus beingH-2 linked and another locus segregating independently ofH-2.     

Idiotypic analysis of anti-GAT antibodies. VII. Common idiotype on hybridoma antibodies to poly(Glu60 Ala40)

A single DBA/2 mouse, immunized with L-glutamic acid60-L-alanine40 (GA), was used to produce hybridoma cell lines. Seven hybridoma anti-GA antibodies were obtained for idiotypic analyses. Two hybridoma anti-L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) antibodies, preferentially reactive to GA, were studied in parallel. Anti-idiotypic antisera to purified anti-GAT and anti-GA serum antibodies and to hybridoma anti-GA antibodies were analyzed by idiotype binding and inhibition of idiotype binding assays. Five of the nine hybridoma antibodies exhibited common GA-1 idiotypic specificities previously demonstrated on the majority of anti-GA antibodies of inbred mouse strains of differing immunoglobulin heavy chain linkage groups; these hybridoma antibodies also possessed private idiotypic determinants. Two GA-1 negative hybridoma anti-GA antibodies appeared identical by immunochemical criteria, arguing that somatic hybridization does not artifactually generate private idiotypic determinants. The results demonstrate that the common GA-1 idiotype system is associated with a family of nonidentical but idiotypically related antibody molecules present in a single DBA/2 mouse, and these antibodies are part of the "GA-1 idiotypic family".     

L3T4 (CD4+) cells that mediate contact sensitivity to trinitrochlorobenzene express I-A determinants

The present study has further characterized the T cell-mediated inflammatory response of contact sensitivity (CS) to the hapten trinitrochlorobenzene (TNCB) in mice. A discernible CS response was found to be induced as early as 2 days after epicutaneous application of TNCB. The response peaked on Days 4 to 5 and it then declined to a nearly undetectable level by Days 10 to 11. Examination of the draining lymph nodes demonstrated that development of CS coincided with an increase in cellular proliferation and in the total number of cells present. Despite a severalfold increase in the cellular contents of the draining lymph nodes of sensitized mice, the relative percentages of most subsets of T cells remained unchanged. Flow cytometric studies revealed that the subpopulation of T cells characterized as Thy 1.2+ L3T4+ I-A+ increased substantially in comparison to its presence in unsensitized mice. Whether the Thy 1.2+ L3T4+ I-A+ cells that increased following sensitization represented the effector population that mediates CS was then examined. Four-day immune lymph node T cells or L3T4 cells positively selected from them were capable of adoptively transferring CS to normal mice. However, these cells, after treatment with anti-Ia antibody or anti-I-A monoclonal antibody and complement, were unable to transfer CS. These findings imply that expression of I-A determinants may indicate antigen-induced T cell activation in vivo and that L3T4 cells that mediate CS are I-A positive.     

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+).     

Suppressor T cells regulate the cytolytic T lymphocyte response to syngeneic tumors induced by murine sarcoma virus (MSV) in the mouse.

Studies were designed to analyze the immune activities of spleen cells from mice previously injected with murine sarcoma virus (MSV) and undergoing the processes of MSV tumor growth and rejection. Fractionation of MSV-primed spleen cells according to cell size by velocity sedimentation at unit gravity showed that MSV-specific cytolytic T lymphocytes (CTL) generated in vivo underwent an apparent transition in size from large to small cells as the tumor regressed. The majority of CTL precursors, however, were invariably recovered among small to medium-sized MSV-immune cells, as revealed to CTL generation in vitro in secondary mixed leukocyte-tumor cell cultures (MLTC). Evidence was obtained for the existence in MSV-immune spleens of two suppressor cell populations capable of inhibiting CTL generation in vitro: one population probably consisted of macrophages and could be removed by treatment with carbonyl iron; the second population was comprised of T cells and inhibited the differentiation of tumor-immune CTL precursors in a selective manner. These results provide a preliminary overview of the mechanisms regulating the generation, differentiation, and activity of tumor-specific CTL in a syngeneic model system.     

Differential effects of poly (Glu60, Phe40) (GPhe) on murine TH1 and TH2 cells.

The random amino acid copolymer (Glu60, Phe40)n (GPhe) was previously shown to augment antigen-dependent proliferation of the murine TH2 cell lines DCL-2 and D10.G4.1. In the present study, the addition of GPhe to (Glu36, Lys24, Ala40)n (GLA)-primed BALB/c primary lymph node (1 degree LN) T cell cultures, the source of DCL-2, resulted in significant suppression of both the proliferative and lymphokine response to GLA. Suppression by GPhe of the 1 degree LN response was subsequently shown to be neither antigen- nor haplotype restricted, and was inhibitable by polyclonal anti-GPhe antibodies. Studies were extended to a GLA-reactive T cell hybridoma clone (DL.4G6.1). where significant suppression by GPhe of GLA-stimulated lymphokine production was observed as measured by markedly decreased HT-2 stimulatory activity of the collected supernatants. Subsequent antibody blocking experiments employing the monoclonal anti-murine IL-4 antibody 11B11 revealed that BALB/c GLA-reactive 1 degree LN T cells and DL.4G6.1 did not produce detectable levels of IL-4 in their culture fluids when stimulated by GLA, which suggested that these cells, unlike DCL-2, were TH1-like in nature. The addition of GPhe to the TH1 clones 5.2 and 5.9 resulted in significant suppression of proliferation to homologous antigen (ovalbumin), in contrast to the augmentation observed with the TH2 cell lines DCL-2 and D10.G4.1. It was concluded from these data, that the addition of GPhe to various T cell cultures lead to unusual suppressive and augmenting activities specific for TH1 and TH2 cells, respectively. Although the mechanism for these dichotomous effects of GPhe is as yet undetermined, several possibilities are considered.     

Dissection of the poly(glu60ala30tyr10) (GAT)-specific T-cell repertoire in H-21 k mice

We examined the antigen recognition of the class II major histocompatibility complex (MHC) of 45 poly(glu60 ala30 tyr10) (GAT)-reactive T-cell clones isolated by limiting dilution cloning of a pool of in vivo-primed and in vitro-restimulated A.TL lymph-node T cells. Each clone expressed the Thy-1.2+, Lyt-1+, Lyt-2-, LFA-1+, Ia-, and H-2Dd+ cell-surface phenotype and exhibited strict specificity for GAT on syngeneic antigen-presenting cells (APCs). The monitoring of the proliferative responses of these clones in the presence or absence of GAT, using APCs from strains with 11 independent H-2 haplotypes, revealed several distinct specificity patterns: (i) most (31 of 45, 73%) T-cell clones recognized GAT in a self-I-Ak-restricted manner; (ii) other alloreactive clones (5 of 45, 11%) were stimulated to proliferate, irrespective of the presence of GAT, in response to allodeterminants expressed on H-2s, H-2d, H-2f or H-2u spleen cells; (iii) a third T-cell clone subset (4 of 45, 9%) was activated by GAT in the context of not only self-I-Ak but also nonself restriction Ia determinants; and (iv) three clones (7%) exhibited a triple specificity, i.e., they recognized GAT in the context of self and nonself Ia determinants and were alloreactive. One of the latter clones responded to GAT in an apparently non-MHC-restricted manner and recognized an I-Ab allodeterminant. These data provide direct evidence that the antigen-specific and alloreactive T-cell repertoires overlap and that the self-MHC restriction of GAT-specific T-cell responses is not absolute in A.TL mice.