T(Iat)- and B(Iab)-cell alloantigens determined by theH-2 linkedI region in mice

The specificity of an antiserum directed againstI region associated (Ia) antigens is described. The serum was raised in (DBA/1×B10.D2)F₁ mice against lymphocytes of AQR mice, differing from the responder for theI region only. The serum reacts with Ia antigens expressed on B cells (Iab) as well as with Ia antigens expressed on T cells (Iat). Absorption studies indicate that B cells possess at least two Ia antigens, and one of these is shared by T cells. However, this shared antigen is not present on the surface of lymphocytes of thymectomized mice. Analysis of the strain distribution of Iab and Iat antigens revealed that the Iab antigens are present on lymphocytes of mice carrying theIA ^k subregion and that the Iat antigens are present on lymphocytes of mice carryingI region genes of theH-2 ^k haplotype located between theIA andIB subregions. This conclusion is based on the analysis of the antiserum's reactivity with T and B cells of the strains B10.A(2R), B10.A(4R) and B10.HTT: the serum reacts with B and T cells of B10.A(2R) but only with B cells of B10.A(4R) mice and only weakly with T cells of B10.HTT mice.Abbreviations ALG antimouse lymphocyte globulin from rabbits - B cells bone marrow derived lymphocytes - B10 C57BL/10Sn mice - D1D2F₁ (DBA/1×B10.D2)F₁ hybrid mice - GVHR graft-vs-host reaction - Ia I region associated antigen - Iab on B cells - Iat on T cells - MLR mixed lymphocyte reaction - T cells thymus-derived lymphocytes - Thy-1 thymus antigen 1, formerly called theta - Tx-Lyc lymphocytes of thymectomized, ALG treated, lethally irradiated and anti-Thy-1 treated bone marrow reconstituted mice - 2R B10.A(2R)/SgSn mice - 4R B10.A(4R) mice     

Role of nominal antigen and Ia antigen in the binding of antigen-specific T lymphocytes to macrophages.

We have previously demonstrated that when primed T lymphocytes were repeatedly incubated on monolayers of antigen-pulsed macrophages (M phi), the cells that failed to adhere to the monolayer demonstrated a marked depletion of their proliferative response that was specific both for the antigen used for pulsing the M phi and for Ia determinants on the M phi. In order to further analyze the contribution of the nominal antigen and Ia antigens to the physical binding of T lymphocytes to M phi, we have attempted to block the absorption of T lymphocytes to M phi with a large excess of soluble antigen and with anti-Ia sera. Our results demonstrate that anti-Ia sera inhibit but that soluble antigen augments the binding of specific T lymphocytes to M phi. The implications of these findings for "dual recognition" and "linked recognition" models of T lymphocyte receptors are discussed.     

The mouse primed lymphocyte typing (mPLT) test

A murine primed lymphocyte typing (mPLT) assay, based on the sequential selective isolation of specific immunocompetent, alloantigen-reactive T blast cells, has been utilized to define the H-2-associated lymphocyte-stimulating (LS) determinants. Data obtained using mPLT cells indicate that both the Ia molecules of the J region and the SD molecules of theK or D regions possess LS determinants. Isolated Ia molecules as well as isolated SD molecules induce mPLT cell proliferation irrespective of the genetic background, thus revealing that both classes of H-2 LS antigens function in an autonomous manner. Restimulation data of mPLT cells sensitized toI-region gene products indicate that the LS determinants of the Ia molecules are the Ia specificities. However, whereas subregionI-E (I-C) determines one stimulating moiety, ia.7, subregionI-A determines multiple stimulating Ia determinants associated with each allelic product. Genetic analysis, in combination with known serology, suggests that each allelic product of theK andD regions possesses a unique LS determinant. Based on specific cross-reactivities exhibited by mPLT cells sensitized against SD molecules, the recognition of the SD-associated LS determinant appears to be distinct from the recognition of SD specificities by antibody and recognition of the target moiety by cytotoxic T lymphocytes. Thus, this mPLT assay provides a positive approach to defining the H-2 LS determinants as well as a technique for isolating cells with functionally restricted, clonal responses. Furthermore, we propose here a nomenclature for the designation of mPLT-defined LS determinants.     

Identification of Ia on a subpopulation of human T lymphocytes that stimulate in a mixed lymphocyte reaction

The delineation of discrete subpopulations of human T lymphocytes has permitted preliminary analyses of the complex cellular network regulating the immune response in man. We previously showed that a subset of T lymphocytes, designated as theophylline-sensitive because of their inability to bind sheep red blood cells in the presence of the drug, are responsible for antigen-specific suppression or regulation in an in vitro plaque-forming cell assay. We now show that 25 to 45% of these theophylline-sensitive T cells were Ia-positive by immunofluorescence with a rabbit antiserum raised against purified B lymphoblast surface antigenic material. These data suggested that 4 to 7% of peripheral blood T cells carry Ia determinants. The presence of Ia determinants on this T cell subset was confirmed by gel analysis of radioiodinated surface material. Furthermore, in mixed lymphocyte culture, the theophylline-sensitive cells demonstrated HLA-D determinants and were 10-fold more potent stimulators than equal numbers of B lymphocytes. The presence of Ia determinants on these T cells indicates the expression of major histocompatibility complex-related regulatory gene products on a specific human T lymphocyte subpopulation.     

Suppression of anti-hapten antibody responses by hapten-specific cytolytic T lymphocytes: role of I-A-associated antigen on target B lymphocytes

Cytolytic T lymphocytes (CTL) specific for 2,4,6-trinitrophenyl (TNP) determinants suppress the effector phase of a secondary anti-TNP antibody responses of murine syngeneic spleen cells in vitro. The cells mediating this suppression are hapten-specific, H-2-restricted, and possess properties typical of CTL. Moreover, the targets of the suppression appear to be antigen-primed B lymphocytes that are recognized by CTL via soluble antigen bound noncovalently to their Ig receptors. The effect of the CTL can be blocked by the addition of monoclonal antibodies directed against I-A molecules but not I-E or H-EK-encoded molecules on the target B cells, even in strain combinations in which the CTL-B cell interaction is restricted only by the H-2K and I regions of the MHC. This result suggests that B lymphocyte-bound antigen tends to associate preferentially with I-A rather than H-2K/D-encoded determinants, and that the suppressive effect of the CTL population is attributable to the minor subset that recognizes hapten-modified Ia antigens. These findings are also discussed in terms of the possible immunoregulatory function of Ia-restricted CTL.     

Murine thymocyte and splenocyte Ia antigens are indistinguishable by two-dimensional gel electrophoresis

Ia antigens have been found on the surface of B lymphocytes, macrophages, epidermal Langerhans cells and on certain transformed cells. Ia antigens have also been detected on the surface of thymocytes but the biosynthesis of these antigens by thymocytes has been difficult to demonstrate. We describe the labeling of murine thymocytes with 35S-methionine and the subsequent analysis of Ia antigens by two-dimensional polyacrylamide gel electrophoresis. Cell elimination experiments demonstrated that the Ia antigens detected were not of B cell origin and were synthesized by a Thy-1-positive thymocyte. Ia antigens from thymocytes were found to be indistinguishable from spleen Ia preparations. Since T cell I region determinants have been postulated to be involved in cellular recognition phenomena, models addressing this recognition must allow for the observation that T and B cell I region molecules detected by antisera such as A. TH anti-A. TL are indistinguishable by two-dimensional gel analysis and are thus unlikely to be involved in the generation of specificity in recognition.     

The immunobiology of T cell responses to Mls-locus-disparate stimulator cells. II. Effects of Mls-locus-disparate stimulator cells on cloned, protein antigen-specific, Ia-restricted T cell lines

Cloned, protein antigen-specific, Ia-restricted T cell lines frequently (approximately 20%) also respond strongly to stimulator cells from strains expressing stimulatory alleles at the chromosome 1-encoded Mls-locus. Furthermore, such responses are blocked by monoclonal antibodies specific for Ia antigens expressed by the stimulator rather than the responder cells. However, such responses show no specificity for polymorphic determinants on Ia molecules, although in such responses, as in primary and secondary T cell responses to stimulating Mls-locus alleles, I-E molecules appear to play a central role. These results, combined with the unique immunobiology of the primary T cell proliferative response to Mls-locus-disparate stimulator cells, suggest to us that this response involves the interaction of the receptor on T cells for antigen:self Ia with a relatively nonpolymorphic region of Ia glycoproteins. This hypothesis is supported by the observation that a monoclonal antibody to the T cell receptor will inhibit both responses, although the response to Mls-locus-disparate stimulators appears to be more sensitive to these antibodies. We propose that the interaction of the T cell receptor with Ia is stabilized by a cell interaction molecule encoded or regulated by the Mls-locus gene product permitting the T cell receptor:Ia glycoprotein interaction to lead to T cell activation.     

Detection of HLA-DRw (Ia-like) antigens on human T lymphocytes grown in tissue culture.

Human T lymphocytes that proliferate in the presence of conditioned medium from PHA-stimulated allogeneic peripheral blood cells were shown to express IPA antigens after the 8th culture day. Ia antigens as detected by xenogeneic antisera were present on 80 to 90% of the cultured cells which were also strongly reactive with xenogeneic antisera defining a human T cell antigen and formed E rosettes. Control cultures with PHA or no conditioned medium expressed T cell but not Ia antigens. These cultured T cells also express the same HLA-DRw determinants as the B cells of the donor they were derived from. Absorption of xenogeneic Ia, and HLA-DRw alloantisera with cultured T cells completely removed the reactivity of these sera for enriched peripheral blood B lymphocytes from normal donors.     

The fine specificity of antigen and Ia determinant recognition by T cell hybridoma clones specific for pigeon cytochrome c

The activation of proliferative T lymphocytes normally involves the simultaneous recognition of a particular foreign antigen and a particular Ia molecule on the surface of antigen-presenting cells, the phenomenon of major histocompatibility complex (MHC) restriction. An analysis of T cell clones specific for pigeon cytochrome c, from B10.A and B10.S(9R) strains of mice, revealed the unusual finding that several of the clones could respond to antigen in association with Ia molecules from either strain. Using these cross-reactive clones, we performed experiments which demonstrated that both the Ia molecule and the T cell receptor contribute to the specificity of antigen recognition; however, MHC-linked low responsiveness to tuna cytochrome c (an immune response gene defect) could not be attributed solely to the efficacy with which the Ia molecules associated with the antigen. These results imply that antigen and Ia molecules are not recognized independently, but must interact at least during the process of T cell activation.     

Receptor specificity of Ia-restricted T lymphoblasts activated against trinitrobenzene sulfonate-coupled spleen cells: recognition of distinct trinitrophenyl and Ia moieties

The receptor specificity of H-2-restricted T lymphoblasts activated against trinitrobenzene sulfonate (TNBS)-coupled spleen cells was examined using an antigen binding assay. A population of Lyt-1+,2-T lymphoblasts acquired syngeneic Ia determinants during 4 days of primary culture with hapten-coupled stimulator cells. Syngeneic Ia was not reexpressed after trypsin treatment of the T cells, but was found after incubation with soluble Ia shed from lipopolysaccharide-activated blasts. Self-Ia binding was specific in that Lyt-1+,2- but not Lyt-1-,2+ cells acquired the antigen, and in that self-Ia bound more effectively than allogeneic Ia material. To determine the relationship of self-Ia binding to the recognition of foreign antigen, the binding of trinitrophenyl (TNP)-coupled plasma membrane vesicles by TNP-specific T cells was studied. TNP-vesicle binding occurred via TNP and H-2(Ia) molecules on the vesicles in that binding was inhibited with antibodies against TNP or H-2(Ia) molecules but not non-major histocompatibility complex (e.g., Ly-6.2) molecules on the vesicles. Complete inhibition of TNP-vesicle binding by an Iak-restricted TNP-specific T-cell line occurred with soluble TNP-lysine, but not an unrelated hapten, N-iodoacetyl-N-(5-sulfonic-1-naphthyl)ethylenediamine (I-AED)-cysteine. Conversely, I-AED-cysteine, but not TNP-lysine, inhibited binding of I-AED-coupled B6 vesicles by B6 anti-I-AED T cells. Significant, but weak inhibition of TNP-vesicle binding by the anti-TNP line was observed with glycoprotein preparations containing partially purified self-Ia molecules. However, inhibition was specific for I-Ak molecules, in that inhibition was lost after removal of I-Ak molecules from the glycoprotein preparation, and very little inhibition occurred with soluble glycoproteins prepared from thymocytes which contained very little Ia material or from LPS blasts of an unrelated H-2 haplotype. These results suggest a recognition model in which TNP and Ia determinants are recognized by neighboring receptor combining sites.     

Recognition of antigens by T lymphocytes

Summary The present review briefly summarizes our knowledge of antigen-specific B and T lymphocyte receptors. Antigen-specific receptors on mammalian B lymphocytes are mainly monomeric IgM and IgD consisting of conventional immunoglobulin heavy and light chains. The nature of the T lymphocyte receptor which can specifically recognize antigens is not yet fully defined. However, it seems that conventional light chains do not participate in the build up of this receptor, and that the receptor is made up of heavy chains of a new immunoglobulin class which has to be further characterized and which we call Tau-chain. The variable region of the T lymphocyte receptors share idiotypic determinants with the corresponding B lymphocyte receptors. The possible linkage between the T cell idiotypes present on the Tau-chains and molecules which are under the control of genes of the Major Histocompatibility Complex of the species are discussed.In the last part of the review two methods for the induction of specific transplantation tolerance in adult animals are described. These methods are based on the concept that T lymphocytes reactive against alloantigens bear idiotypic determinants against which a specific auto-immune response can be initiated.     

Influenza viruses as lymphocyte mitogens. II. Role of I-E molecules in B cell mitogenesis by influenza A viruses of the H2 and H6 subtypes

Influenza A viruses of the H2 and H6 subtypes behave as T cell-independent B cell mitogens for lymphocytes from strains of mice that express the class II MHC glycoprotein I-E (Ia.7+ haplotypes). We have examined the role of I-E molecules in mitogenesis by these viruses. Lymphocytes from (Ia.7+ X Ia.7-)F1 hybrid strains that express lower levels of I-E antigen than homozygous Ia.7+ strains showed a level of response to H2 and H6 influenza viruses that was intermediate between the high response of the Ia.7+ parent and the low response of the Ia.7- parent. The mitogenic response of H-2k lymphocytes to these viruses was completely inhibited by low concentrations of anti-I-Ek monoclonal antibody that had no effect on B cell proliferation induced by LPS or by influenza A virus of the H3 subtype. Furthermore, incubation of H-2k spleen cells with high concentrations of H2 (but not H3) influenza viruses substantially inhibited the binding of radio-labeled anti-I-Ek, but not anti-I-Ak, monoclonal antibody. Cell mixing experiments indicated that expression of I-E by the B cells was critical to the mitogenic response, whereas I-E expression by accessory cells may not be necessary. The data support a model in which B cell mitogenesis by these viruses results from direct binding of the viruses to I-E molecules on B lymphocytes.     

T-cell function in B-lymphocyte-deprived mice

Previous work has identified selective defect(s) in T cells in mice deprived of B lymphocytes by the chronic administration of anti-IgM antibody. Experiments described in the present communication revealed that anti-IgM-treated mice do not possess T cells with surface Ia and FcR, and, unlike T cells from normal animals, they also fail to bind these molecules in vitro. Functional assays disclosed that an anti-suppressor pathway which relies on Ia+ donor and acceptor T cells is interrupted in these mice at both levels. These observations may provide an insight to explain the selective failure of some T cells when B lymphocytes have been deleted.     

Adherent Ia+ murine cell lines with characteristics of dendritic cells. II. Characteristics of I region-restricted antigen presentation

The ability of an adherent Ia+, interleukin 1+ (IL-1) tumor cell line (P388AD) to present turkey gamma-globulin (TGG) to primed T lymphocytes was demonstrated and compared with normal antigen-presenting cells (APC) found in mouse spleen. P388AD tumor cells presented TGG to long-term cultures of TGG-reactive T cells (LTTC) and to lymph node-derived T cells which were enriched on nylon wool columns and subsequently depleted of endogenous antigen-presenting cells with anti-Ia antisera and complement. MHC-restricted antigen presentation by P388AD was observed when long-term cultures of TGG-reactive T cells were used as the responding T-cell population. Furthermore, antisera directed against I-region determinants expressed on the P388AD tumor cells inhibited TGG-specific T-cell proliferation in a dose-related fashion, suggesting a functional role for the tumor cell-associated Ia molecules. The kinetics of antigen presentation to LTTC by P388AD were similar to the kinetics observed for splenic APC, although the magnitude of the proliferative response to LTTC to TGG was generally lower when antigen (Ag) was presented by the tumor cells compared to splenic antigen-presenting cells (APC). However, the magnitude of T-cell proliferation of immune lymph node (LN) T cells was comparable when Ag was presented on tumor cells or splenic APC. Several experiments suggested that Ag uptake and/or processing may be less effective in P388AD tumor cells as compared to normal splenic APC. A nonadherent Ia+, IL-1- tumor cell line (P388NA), which was isolated from the same parental tumor as P388AD, was also tested for the ability to present Ag to primed T lymphocytes and Ag-reactive LTTC. In contrast, to P388AD, the nonadherent tumor cell failed to present TGG under identical culture conditions even though Ia molecules were expressed on the tumor cells and Ag uptake had occurred. However, the defect in Ag presentation by P388NA could be corrected if an exogenous source of purified interleukin 1 was supplied to the cultures. A unique opportunity thus exists with both the P388AD and P388NA tumor cell lines to decipher some of the molecular interactions leading to T-cell proliferation during antigen presentation.     

Inhibition of secondary mouse mixed lymphocyte reaction by anti-Ia sera

Secondary mixed lymphocyte reaction (MLR-II) was studied in A.TH anti A.TL and A.TL anti-A.TH combinations in which stimulation was mainly due to H-21-region differences. In both cases of MLR-II was specifically inhibited by the responder anti-stimulator Ia serum. The level of inhibition was dependent on the ratio of the amount of immune serum to the number of stimulating cells. The inhibitory activity and Ia antibodies were specifically absorbed and eluted together. The results confirm that the lymphocyte-activating determinants of the MLR-II (1) are carried by the Ia molecules and (2) are identical to the serologically defined Ia determinants. - Anti-Ia sera directed against private and public specificities of the stimulating cell induced a higher level of inhibition than anti-Ia sera directed only against public specificities, indicating that both private and public Ia specificities are involved in re-stimulation during MLR-II. - These results, in connection with others, suggest that the receptor of the proliferating T cell recognizes the same Ia determinant as the combining site of the Ia-recognizing antibody.     

Antigenic properties of T cell antigen-specific receptors isolated from the surface of rabbit and mouse spleen and lymph node cells

The presence ofa allotypic determinants was tested in fractions obtained by gel filtration of antigen-specific receptors isolated by immunoadsorption from lymphoid cells of antigen-stimulateda3-3 rabbits. This technique, as well as the inhibition of the reaction of isolated receptors with anti-T cell receptor antisera (anti R) by anti-a3 antibodies failed to demonstrate the presence of a allotypie determinants. The inhibitory effect of antigen-specific receptors isolated from the lymphoid cells of stimulated A/J mice on the cytotoxic effect of anti-Ia antibodies on mouse spleen cells in the presence of rabbit complement was tested. All preparations inhibited the cytotoxic reaction with the average effectivity of 60%. In order to confirm the presence of Ia determinants on the rabbit and mouse T cell receptor molecules it was shown that the reactions of three anti-R antisera with 12 different receptor preparations were inhibited by anti-la antibodies. SDS-PAGE analyses of¹²⁵I-labelled mouse specific receptors and the precipitate obtained by anti-R antisera showed that T cell receptors were present in fractions with molar mass 100 and 85 kg/mol. The molar mass of the former fraction after reduction and alkylation was 45 kg/mol.     

Heterogeneity in cellular antigen retention structures

The mechanism of presentation of foreign antigens to helper T lymphocytes and the nature of the structures involved in this process are not totally understood. It is well documented that this event is carried out by antigen-presenting cells (APC) (e.g., macrophages, dendritic cells, and B lymphocytes) that internalize the antigen, process it, reexpress it on their membrane surface, and present it to the T cell in the context of major histocompatibility complex class II (Ia) molecules. Recent evidence supports the hypothesis that peptide antigens associate directly with Ia molecules on the APC surface membrane. However, the characteristics of other APC membrane structures potentially involved in antigen presentation are not entirely clear. Previous studies in our laboratories identified a guinea pig macrophage membrane-bound, non-Ia-containing antigenic complex (peak A) formed upon incubation of APC with the octapeptide antigen angiotensin (AII). This complex was capable of stimulating AII-immune guinea pig T cells and thus appeared to contain the immunologically relevant form of the antigen. For this reason it was important to establish whether such complex formation with peptides occurs with other cell types and with other peptide antigens. In the present study we found that other types of cells are also capable of forming such a membrane complex with antigen (peak A) and that this event is not unique to AII. Two other peptides, alpha-melanocyte-stimulating hormone and human fibrinopeptide B, both of which are antigenic in mice, were found to form peak A with a number of murine cell lines. As in our earlier studies with guinea pig macrophages, there was no evidence from these experiments for a role for major histocompatibility complex Ia antigens in the peptide binding observed. Differences in both the amount of peak A formation and the pattern of peptide antigen degradation were found from cell line to cell line for a given peptide, and from peptide to peptide for a given cell line, suggesting cellular heterogeneity in peptide processing and retention. In addition, cross-inhibition studies indicated that there was peptide specificity in the formation of peak A perhaps suggestive of molecular heterogeneity in the structure of peak A. These results indicate that there may be several types of cell surface molecules that specifically bind and retain peptide antigens.(ABSTRACT TRUNCATED AT 400 WORDS)     

Distinct roles for L3T4 in T cell activation

The mutually exclusive expression of L3T4 and Lyt-2 on murine T cells and the correlation of their expression to the major histocompatibility complex (MHC) restriction of the T cell antigen receptor (Ti) have led to the hypothesis that these surface molecules are related to recognition of class II and class I MHC antigens, respectively. It has been suggested that these T cell surface molecules interact with nonpolymorphic determinants on MHC antigens. We have studied the role of L3T4 in activation of an H-2Dd-specific T cell hybridoma. This novel hybridoma allowed the separate evaluation of the specificities of Ti and L3T4 and the examination of their roles in T cell activation. Antibody-blocking experiments have demonstrated that L3T4 was involved in triggering this T cell hybridoma only if the antigen-bearing cell expressed Ia. The apparent requirement for an L3T4-Ia interaction reflected the amount of available H-2Dd antigen. It appears that the L3T4-Ia interaction influences T cell activation during suboptimal antigenic stimulation. We have begun to examine the role of L3T4 in lectin and anti-Ti monoclonal antibody stimulation of the same T cell hybridoma. These experiments have suggested a distinct role for L3T4 in the absence of Ia, as a mediator of a negative signal for activation.     

Representation of heavy but not light chain Ig idiotypes on T cell receptors for alloantigens.

We have analyzed idiotypic determinants on B and T lymphocytes reactive against the same antigenic determinants by the use of different anti-idiotypic antibodies. Such antisera were produced in (Lewis X DA) F1 rats against Lewis anti-DA alloantibodies (= B cell product) and Lewis T lymphocyte receptors with the same specificity. We found that B lymphocytes bear unique idiotypic determinants which are not present on the corresponding T lymphocytes. T cell unique (not shared by B lymphocytes) idiotypes were so far not detected. T cells idiotypic determinants which are present on heavy but not light chains of the corresponding alloantibodies.     

Helper cells in the autologous mixed lymphocyte reaction. I. Generation of cytotoxic T cells recognizing modified self H-2

The autologous mixed lymphocyte reaction (AMLR) in mice measures the proliferative response of T cells to determinants on syngeneic non-T spleen cells. Normally, cytotoxic T lymphocytes (CTL) are not generated in this reaction. However, the addition of trinitrophenyl-modified mitomycin C-treated syngeneic T cells (TNP-Tm) to the AMLR results in the generation of TNP-specific CTL but does not alter the proliferative response. Significant cytotoxic activity is not detectable against TNP in association with Ia unless TNP is present on cells bearing those determinants. Thus, if unselected spleen cells are TNP-modified and used as stimulators in the AMLR, the proliferative response is enhanced and CTL are generated that recognize TNP in association with K, D, and I region-encoded determinants. The CTL generated in the AMLR are H-2 restricted and dependent on the presence of adherent cells in the sensitization cultures. The experiments presented here suggest that the AMLR can provide the help necessary for generating cytotoxic T cells in vitro.