Antigen presentation by hapten-specific B lymphocytes. I. Role of surface immunoglobulin receptors.

The present study examines the ability of hapten-specific murine splenic B lymphocytes to present hapten-proteins to carrier-specific T cell hybridomas. BALB/cB cells specific for 2,4,6-trinitrophenyl (TNP) were isolated from spleens of immune mice by elution from TNP-gelatin-coated dishes. Such cells presented the TNP-modified terpolymer, GL phi, at concentrations as low as 0.1 microgram/ml, to a GL phi-specific, I-Ed-restricted, interleukin 2-producing T cell hybridoma. In contrast, the same B lymphocytes required 1,000-fold higher concentrations of unmodified GL phi to stimulate the same T cell hybridoma. The presentation of low concentrations of TNP-GL phi by TNP-specific B lymphocytes was significantly or completely blocked by anti-Ig antibody or TNP-proteins, indicating that surface Ig receptors were critically involved in this phenomenon. Finally, binding of TNP-proteins did not alter the ability of the B cells to present unrelated, unhaptenated proteins or to stimulate alloreactive T cells. These results suggest that surface Ig receptors serve to focus antigens onto specific B lymphocytes and that such cells are highly efficient at presenting linked antigenic determinants to T cells. The implications of these findings for the mechanisms of physiologic, histocompatibility-restricted T-B collaboration are discussed

Inhibition of T-lymphocyte-mediated tumor-specific lysis by alloantisera directed against the H-2 serological specificities of the tumor

After appropriate in vivo or in vitro immunization, cytotoxic T lymphocytes (CTL) are generated which efficiently kill cells bearing particular membrane antigens in common with the immunizing cell (reviewed in reference 1). Such CTL have been most thoroughly studied in mice, employing alloimmunization with cells differing at the major histocompatibility locus, H-2. in such cases, the predominant cell surface antigens recognized by the CTL appear to be the molecules carrying the serologically defined H-2 specificities, coded for by the K and D regions of the H-2 complex (2). In other syngeneic models of cell-mediated specific cytolysis, involving lymphocyte chariomeningitis (LCM) virus- or ectromelia virus-infected cells or TNP-modified lymphoid cells, thymus-derived cells also constitute the main effector cell type. The CTL generated in these latter systems function most efficiently when virus-infected or TNP-modified target cells share identitites at the H-2K or H-2D loci with the effector CTL and stimulator cells (3-5). Another set of experimental systems in which CTL are generated and play a significant biological role is that of immunity to tumor-associated antigens (TAA) (6). The nature of the TAA which the CTL recognize is only beginning to be understood. Several recent reports indicated the existence of physiochemical and/or antigenic relationships between TAA and H-2 antigens (7,8). These relationships, together with the genetic restrictions cited above in the generation of CTL involving products of the H-2K or H-2D loci suggested the possibility that in certain tumor systems, the TAA which are able to most effectively stimulate CTL responses might be structurally similar to, or linked with, the H-2K or H- 2D molecules on the tumor surface. It has been previously demonstrated in allogenic models that antisera specific for the appropriate H-2K or H-2D products present on a target cell could specifically block CTL-mediated lysis (1,9). This report demonstrates that certain anti-H-2 alloantisera specific for the target tumor cells can block lysis of those target cells mediated by syngeneic tumor-specific CTL effector cells

Cytotoxic T lymphocytes induced against allogeneic I-region determinants react with Ia molecules on trinitrophenyl-conjugated syngeneic target cells

The major histocompatibility complex codes for determinants which are recognized by and serve as targets for cytolytic T lymphocytes (CTL) (1). Antigens coded for by the K and D loci of the H-2 complex can activate xenogeneic or allogeneic CTL (2,3). In addition, the H-2K or H-2D gene products function as those molecules against which syngeneic CTL responses specific for chemical, viral, and minor H antigens are directed (4-8). It has recently been shown that Ia determinants can also serve as target antigens for distinct but weaker CTL responses (9-13). Those clones which recognize Ia antigens see them independently of K- or D- coded antigens as shown in genetic studies and by antisera-blocking experiments (12,13). We have proposed that the existence of clones of CTL specific for I-region-coded determinants is not fortuitous; rather these clones specifically recognize Ia determinants and may have an immunoregulatory role. These CTL may affect those immune functions which are at least partially dependent on or controlled by I-region-coded molecules. Two predictions can be made and tested concerning the role of Ia determinants in cytolytic systems and the role, if any, of I-region- specific CTL in regulating the immune response: (a) that if as we and others have shown, certain Ia specificities can serve as a third series of major histocompatibility antigens, then Ia antigens should be susceptible to the same types of antigenic modifications as H-2K- or H-2D-coded structures and thus serve as targets for CTL directed against modified-self in selected systems; and (b) that allogeneically induced I-region-specific CTL should demonstrate cross-reactivity with targets bearing modified syngeneic I-region-coded determinants. Data will be present which demonstrates that trinitrophenyl (TNP)-modified syngeneic I-region determinants can serve as targets for CTL induced by allogeneic Ia antigens

Immunosuppressive factor(s) specific for L-glutamic acid(50)-L- tyrosine(50) (GT). II. Presence of I-J determinants on the GT-suppressive factor

The responses to the synthetic antigens, L-glutamic acid(60)-L- alanine(30)-L-tyrosine(10) (GAT) and L-glutamic acid(50)-L-tyrosine(50) (GT) are controlled by genes in the I region of the mouse H-2 complex (1-3). Preimmunization of the mice bearing the H-2(p,q,s) nonresponder haplotypes with GAT stimulates the development of suppressor T cells that inhibit in vivo or in vitro antibody responses to GAT complexed to the immunogenic carrier, methylated bovine serum albumin (GAT-MBSA) (4). The copolymer GT is not immunogenic in any inbred mouse strain tested, and has a suppressive effect on the antibody responses to GT-MBSA in mouse strains bearing the H-2(d,f,k,s) haplotypes; suppressor T cells have been demonstrated to be responsible for specific GT suppression (3). We have obtained specific suppressive extracts from thymus and spleen cells of GAT-or GT-primed suppressor strains (5,6). The specific suppressive T-cell factors in the active extracts have been characterized (6,7) and appear similar to the carrier-specific suppressor factor described by Tada and Taniguchi (8). These products belong to a family of newly identified molecules coded for by the I region of the H-2 complex with affinity for antigen and helper (9,10) or suppressive (5-8) regulatory activity on the immune response. Recently, Tada et al. have reported that the keyhole limpet hemocyanin (KLH)-specific suppressor factor is coded for by the I-J subregion of the H-2 complex (11). We now demonstrate also that a GT-specific suppressor factor extracted from the spleens and thymuses of B10.BR (H-2(k)) mice bears determinants controlled by the I-J subregion of the H-2 complex

Cytotoxic T lymphocytes specific for I region determinants do not require interactions with H-2K or D gene products

Gene products coded for by the major hisocompatibility complex (MHC) can serve as target antigens for cytotoxic T lymphocytes (CTL) (1). A variety of test systems are available which have yielded information consistently reinforcing the importance of this complex of genes in the generation and effector phases of the cytotoxic immune response. Originally, it was shown that allogeneically-induced CTL had specificity primarily for the products of the K and D loci of the mouse H-2 complex (2). More recently this has also been found to be the case for xenogeneic immunizations (3,4). Additional examples of T cell-mediated lysis have been reported involving viral-infected or chemically- modified syngeneic stimulating and target cells in which homology at H-2K or H-2D was required between the responding and target cells for appreciable lysis to occur (5-7). Moreover, CTL specific for minor histocompatability antigens are able to lyse only target cells bearing these membrane antigens and sharing a common H-2K or H2-D gene product with the effector (8,9). Two hypotheses have been proposed to explain the requirement for H-2 identity between effector and targets in these systems. CTL may recognize new antigenic determinants created by the interaction of the modifier with syngeneic K and D gene products. Alternately, a dual recognition system my exist, requiring an antigen-specific receptor as well as a second receptor with specificity for homologous H-2K or H-2D determinants (5). Neither model can be excluded at this time. The I region also contains genes coding for histocompatibility loci since animals differing at the I-A or I-C regions of the H-2 complex reject skin grafts (10-12), though less rapidly than mice differing at the H-2K or H-2D regions, Also CTL can be generated to I region determinants but less efficiently than CTL specific for H-2K or H-2D gene products (12-14). The question can therefore be raised, whether the I region minor histocompatibility loci function independently from the H-2K or H-2D loci or whether I region-specific cytolysis requires the participation of H-2K or H-2D gene products of the target cell. This communication illustrates the generation of CTL showing specificity for I region determinants in primary mixed lymphocyte cultures. Further, we demonstrate by genetic analysis and byt eh use of speficit alloantisera that CTL directed to Ia determinants (a) do not see these antigens as modifications of H-2K or H-2D gene products but as independent gene products coded for by the I region, and (b) they do not require interaction with target cells bearing the same H-2K or H-2D gene product as the effect CTL

Cell interactions between histoincompatible T and B lymphocytes. VII. Cooperative responses between lymphocytes are controlled by genes in the I region of the H-2 complex

The results of this study provide compelling evidence for the existence of the gene or genes controlling optimal T-B-cell cooperative interactions in the designated I region of the H-2 gene complex. Previously, we have speculated that the relevant gene(s) involved may well be located in this region based on several observations from our earlier work in this area (3, 5, 6). Thus, in the preceding paper, we showed that T and B cells from B10.BR and A strain mice developed effective cooperative interactions in vitro to DNP-KLH in a system identical to the one reported herein. Since these mice differ for genes in the S and D regions of H-2 but are identical for K and I region genes, we were able to localize the critical genes to the K-end of H-2