Developmental regulation of alpha beta T cell antigen receptor expression results from differential stability of nascent TCR alpha proteins within the endoplasmic reticulum of immature and mature T cells.

The alpha beta T cell antigen receptor (TCR) that is expressed on most T lymphocytes is a multisubunit transmembrane complex composed of at least six different proteins (alpha, beta, gamma, delta, epsilon and zeta) that are assembled in the endoplasmic reticulum (ER) and then transported to the plasma membrane. Expression of the TCR complex is quantitatively regulated during T cell development, with immature CD4+CD8+ thymocytes expressing only 10% of the number of surface alpha beta TCR complexes that are expressed on mature T cells. However, the molecular basis for low TCR expression in developing alpha beta T cells is unknown. In the present study we report the unexpected finding that assembly of nascent component chains into complete TCR alpha beta complexes is severely impaired in immature CD4+CD8+ thymocytes relative to their mature T cell progeny. In particular, the initial association of TCR alpha with TCR beta proteins, which occurs relatively efficiently in mature T cells, is markedly inefficient in immature CD4+CD8+ thymocytes, even for a matched pair of transgenic TCR alpha and TCR beta proteins. Inefficient formation of TCR alpha beta heterodimers in immature CD4+CD8+ thymocytes was found to result from the unique instability of nascent TCR alpha proteins within the ER of immature CD4+CD8+ thymocytes, with nascent TCR alpha proteins having a median survival time of only 15 min in CD4+CD8+ thymocytes, but > 75 min in mature T cells. Thus, these data demonstrate that stability of TCR alpha proteins within the ER is developmentally regulated and provide a molecular basis for quantitative differences in alpha beta TCR expression on immature and mature T cells. In addition, these results provide the first example of a receptor complex whose expression is quantitatively regulated during development by post-translational limitations on receptor assembly.

Differential effects of zeta and eta transgenes on early alpha/beta T cell development.

The zeta-family dimers (zeta, eta, and gamma) are a group of structurally and functionally related proteins that are expressed in developing thymocytes and function as signal transducing subunits of the T cell antigen receptor (TCR) and certain Ig Fc receptors. Zeta, eta, and gamma each contain one or more copies of a conserved tyrosine-based activation motif (TAM) that is known to be required for signal transduction. To examine the developmental importance of multiple or individual TAM elements we generated transgenic mice that express: (a) full-length (FL) zeta-chain (3 TAMs); (b) eta-chain, a naturally occurring variant of zeta that is derived from alternative splicing (2 TAMs); or (c) truncated zeta-chain (CT108; 1 TAM), under the control of the human CD2 promoter and regulatory elements. Unexpectedly, we found that overexpression of the FL zeta chain caused premature termination of RAG-1 and RAG-2 expression, prevented productive rearrangement of the TCR-alpha and TCR-beta genes and blocked entry of thymocytes into the CD4/CD8 developmental pathway. In contrast, we found that overexpression of eta or CT108 had no effect on normal thymocyte maturation. These results suggest that an early signaling pathway exists in precursor TCR- thymocytes that can regulate RAG-1 and RAG-2 expression and is differentially responsive to individual members of the zeta-family dimers.

Decreased signaling competence as a result of receptor overexpression: overexpression of CD4 reduces its ability to activate p56lck tyrosine kinase and to regulate T-cell antigen receptor expression in immature CD4+CD8+ thymocytes.

Thymic selection of the developing T-cell repertoire occurs in immature CD4+CD8+ thymocytes, with the fate of individual thymocytes determined by the specificity of T-cell antigen receptor they express. However, T-cell antigen receptor expression in immature CD4+CD8+ thymocytes is actively down-regulated in CD4+CD8+ thymocytes by CD4-mediated tyrosine kinase signals that are generated in the thymus as a result of CD4 engagement by intrathymic ligands. In the present study we have examined the effect of CD4 overexpression in CD4+CD8+ thymocytes on activation of CD4-associated p56lck tyrosine kinase and regulation of T-cell antigen receptor expression. Augmented CD4 expression in CD4+CD8+ thymocytes did not result in commensurate increases in associated p56lck molecules, so that CD4 expression was quantitatively disproportionate to that of its associated signaling molecule p56lck. Interestingly, we found that CD4 overexpression significantly interfered with the ability of CD4 crosslinking to activate associated p56lck molecules and significantly interfered with the ability of CD4 to regulate T-cell antigen receptor expression. Thus, this study provides an example in which receptor overexpression leads to decreased receptor signaling competence.

Alloreactive cytotoxic T lymphocytes recognize epitopes determined by both the alpha helices and beta sheets of the class I peptide binding site.

A chimeric class I glycoprotein was created to investigate the functional contribution of the alpha helices and the beta-pleated sheets in forming the antigen recognition site (ARS) of antigen-presenting molecules. This novel molecule was generated by replacing the DNA sequences encoding the alpha helices of the Ld gene with the corresponding sequences from the Kb gene. Serologic analysis of transfected L cells that expressed the chimeric molecule (Kb alpha Ld beta) revealed that the engineered class I glycoprotein retains two conformational epitopes associated with the alpha helices of Kb, as defined by monoclonal antibodies K10.56 and 28-13-3. These results demonstrate that the alpha helices of Kb can associate with the beta-pleated sheets of Ld to form a stable structure, which is expressed on the cell surface. To address the role of the alpha helices of the ARS in determining T cell crossreactivity, alloreactive cytotoxic T lymphocytes (CTL) were used to analyze L cells expressing Kb alpha Ld beta. CTL raised against Kb or Ld as alloantigens showed little, if any, ability to lyse L cells expressing Kb alpha Ld beta. Thus, alloreactive CTL did not recognize structures determined by the alpha helices alone or by the beta sheets of the ARS alone. However, bulk and cloned alloreactive CTL that were generated against the mutant Kb glycoprotein Kbm8 reacted strongly with Kb alpha Ld beta. In addition to the Kb alpha helices, the Kbm8 ARS shares a single polymorphic amino acid at position 24 with Kb alpha Ld beta. Amino acid 24 is located on the beta 2 strand that forms part of the floor of the ARS and has been identified as a component of pocket B in the HLA class I ARS. The substitution of Glu to Ser at this position was shown previously to be the central determinant of the Kbm8 mutant alloantigenicity. The functional significance of this position in determining crossreactivity between bm8 and Kb alpha Ld beta identifies pocket B as a strong anchor for allogenic self-peptides. These findings demonstrate that determinants recognized by CTL on class I alloantigens are formed by interactions involving both the alpha helices and beta sheets of the ARS. These interactions are best explained by the influence of the alpha helices and beta sheets on the peptide-binding properties of these antigen-presenting molecules.

Ligand-stimulated signaling events in immature CD4+CD8+ thymocytes expressing competent T-cell receptor complexes.

During thymic selection of the developing T-cell repertoire, the fate of individual CD4+CD8+ thymocytes is determined by the specificity of the T-cell antigen receptors (TCRs) they express. Paradoxically, most CD4+CD8+ thymocytes express few TCR molecules, and those they express are essentially incapable of transducing intracellular signals as measured by intracellular calcium mobilization. However, both TCR number and calcium-signaling capability are significantly induced in CD4+CD8+ thymocytes when the cells are released from intrathymic inhibitory signals that are mediated by their CD4 molecules. Here, the response to ligand engagement of TCR on "induced" CD4+CD8+ thymocytes that have been released from CD4-mediated inhibition was examined and was found to result in internalization of surface TCR complexes and rephosphorylation of zeta chains of the TCR complex. In addition, a proportion of induced CD4+CD8+ thymocytes were found to fragment their DNA upon ligand engagement. Thus, this study describes early events in immature CD4+CD8+ thymocytes resulting from TCR-mediated signals.

Cellular basis of skin allograft rejection across a class I major histocompatibility barrier in mice depleted of CD8+ T cells in vivo.

The present study was undertaken to define the cellular mechanisms involved in the rejection of major histocompatibility complex (MHC) class I disparate skin grafts by mice depleted of CD8+ T cells in vivo. Mice were effectively depleted of CD8+ T cells by adult thymectomy followed by in vivo administration of anti-CD8 monoclonal antibody (mAb) and then engrafted with allogeneic skin. We found that CD8 depleted mice did reject MHC class I disparate skin grafts, but only when the grafts also expressed additional alloantigens. Despite the marked depletion of CD8+ T cells in these mice, we found that their rejection of MHC class I disparate grafts was mediated by CD8+ cytolytic T lymphocyte (CTL) effectors that had escaped depletion. These CD8+ CTL effectors were unique in that: (a) their generation was dependent upon the injected anti-CD8 mAb and upon exposure to class I MHC alloantigens expressed on the engrafted skin, and (b) their effector function was resistant to blockade by anti-CD8 mAb. We observed that the additional alloantigens coexpressed on MHC class I disparate grafts that triggered graft rejection in CD8-depleted mice could be MHC-linked or not and that they functioned in these rejection responses to activate third party specific CD4+ T helper (Th) cells to provide helper signals for the generation of CD8+ anti-CD8 resistant CTL effector cells. Thus, mice depleted of CD8+ T cells by thymectomy and in vivo administration of anti-CD8 mAb harbor a unique population of anti-CD8 resistant, CD8+ effector cells that mediate anti-MHC class I responses in vivo and in vitro, but require help from third party specific Th cells to do so.

Inhibition of T cell receptor expression and function in immature CD4+CD8+ cells by CD4.

Most immature CD4+CD8+ thymocytes express only a small number of T cell receptor (TCR) molecules on their surface, and the TCR molecules they do express are only marginally capable of transducing intracellular signals. TCR expression and function was not intrinsically low in immature CD4+CD8+ thymocytes, but was found to be actively inhibited by CD4-mediated signals. Indeed, release of CD4+CD8+ thymocytes from CD4-mediated signals resulted in significant increases in both TCR expression and signaling function. These results suggest that, in CD4+CD8+ cells developing in the thymus, increased TCR expression and function requires release from CD4-mediated inhibition.

In vivo induction of antigen-specific transplantation tolerance to Qa1a by exposure to alloantigen in the absence of T-cell help.

A goal of transplantation immunology is to be able to induce antigen-specific tolerance in transplant recipients. In the present study we describe an in vivo model of antigen-specific transplantation tolerance to skin allografts using mice congenic at Qa1, a ubiquitously expressed class I-like molecule encoded to the right of H-2D. B6 mice are deficient in Qa1a-specific T-helper cells and only reject Qa1a disparate tail skin grafts when a second graft expressing additional helper determinants is also present. We report that animals initially engrafted with Qa1a disparate skin, in the absence of any source of additional help, are rendered tolerant to Qa1a disparate skin allografts despite the subsequent presence of inducer skin grafts expressing additional helper allodeterminants. The nonresponsive state is Qa1a-specific, because HY-bearing inducer grafts are rejected normally. In vitro, Qa1a-tolerant animals are specifically unable to generate anti-Qa1a T-killer cells, which provides the cellular basis for their failure in vivo to reject Qa1a skin allografts. Thus, initial exposure to Qa1a allodeterminants, in the absence of T-cell help, leads to a state of Qa1a-specific transplantation tolerance. This study suggests that antigen-specific transplantation tolerance may be induced by exposing naive T-killer cells to tissue alloantigens under conditions in which T-cell help is not generated.

Recognition requirements for the activation, differentiation and function of T-helper cells specific for class I MHC alloantigens.

The present review has focused on the specificity of the T-helper cell populations initiating MHC class I alloreactions. In contrast to conventional immune responses against soluble antigens, responses against membrane-bound class I alloantigens are initiated by two distinct antigen-specific T-helper cell populations that can be distinguished by their Lyt phenotype, MHC restriction specificity, antigen specificity, and requirement for thymically determined self-recognition. Alloresponses were shown to be a composite consisting of two distinct components: one mediated by L3T4+ Th cells and very similar to conventional self + X responses; and one mediated by Lyt2+ Th cells and unique to alloresponses against MHC class I antigens. As would befit an unusual Th cell population, the recognition/response spectrum of Lyt2+ Th cells was highly unusual and was found to be the basis for much of the uniqueness we attribute to immune alloreactions, including rapid rejection of tissue allografts in vivo.

Differential helper and effector responses of Lyt-2+ T cells to H-2Kb mutant (Kbm) determinants and the appearance of thymic influence on anti-Kbm CTL responsiveness.

The goal of this study was to assess and compare the allorecognition requirements for eliciting Lyt-2+ helper and effector functions from primary T cell populations. By using interleukin 2 (IL 2) secretion as a measure of T helper (Th) function, and cytolytic T lymphocyte (CTL) generation as a measure of effector function, this study compared the responses of Lyt-2+ T cells from wild-type B6 mice against a series of H-2Kb mutant determinants. Although all Kbm determinants stimulated B6 Lyt-2+ T cells to become cytolytic effector cells, the various Kbm determinants differed dramatically in their ability to stimulate Lyt-2+ T cells to function as IL 2-secreting helper cells. For example, in contrast to Kbm1 determinants that stimulated both helper and effector functions, Kbm6 determinants only stimulated B6 Lyt-2+ T cells to become cytolytic and failed to stimulate them to secrete IL 2. The distinct functional responses of Lyt-2+ T cells to Kbm6 determinants was documented by precursor frequency determinations, and was not due to an inability of the Kbm6 molecule to stimulate Lyt-2+ Th cells to secrete IL 2. Rather, it was the specific recognition and response of Lyt-2+ T cells to novel mutant epitopes on the Kbm6 molecule that was defective, such that anti-Kbm6 Lyt-2+ T cells only functioned as CTL effectors and did not function as IL 2-secreting Th cells. The failure of Lyt-2+ anti-Kbm6 T cells to function as IL 2-secreting Th cells was a characteristic of all Lyt-2+ T cell populations examined in which the response to novel mutant epitopes could be distinguished from the response to other epitopes expressed on the Kbm6 molecule. The absence of significant numbers of anti-Kbm6 Th cells in Lyt-2+ T cell populations was examined for its functional consequences on anti-Kbm6 CTL responsiveness. It was found that primary anti-Kbm6 CTL responses could be readily generated in vitro, but unlike responses to most class I alloantigens that can be mediated by Lyt-2+ Th cells, anti-Kbm6 CTL responses were strictly dependent upon self-Ia-restricted L3T4+ Th cells. Because the restriction specificity of L3T4+ Th cells is determined by the thymus, in which their precursors had differentiated, anti-Kbm6 CTL responsiveness, unlike responsiveness to most class I alloantigens, was significantly influenced by the Ia phenotype of the thymus in which the responder cells had differentiated.(ABSTRACT TRUNCATED AT 400 WORDS)

T-cell recognition of a chimaeric class II/class I MHC molecule and the role of L3T4.

In addition to expressing clonally distributed antigen-specific and major histocompatibility complex (MHC)-restricted receptors, T cells also express non-clonally distributed surface molecules that are involved in T-cell function. Among the most intriguing of the latter are L3T4 and Lyt 2, which are expressed on individual T lymphocytes in striking, though not absolute, concordance with their restriction by either class II or class I MHC determinants, and which are thought to contribute to the overall avidity of T-cell interactions by binding to monomorphic determinants on class II and class I MHC molecules, respectively. To examine the ability of T cells to recognize a single class II domain in the absence of the remainder of the Ia molecule, as well as to evaluate the structural basis for the putative interaction of L3T4 with Ia, a recombinant class II/class I murine MHC gene was constructed and introduced into mouse L cells. Here we demonstrate that a subset of class II allospecific cytotoxic T lymphocytes (CTL) can specifically recognize and lyse L-cell transfectants expressing an isolated polymorphic A beta 1 domain, and that anti-L3T4 antibody can block such killing, a result inconsistent with the highly conserved membrane-proximal domains of Ia acting as unique target sites for L3T4 binding.

Characterization of antigen-specific, Ia-restricted, L3T4+ cytolytic T lymphocytes and assessment of thymic influence on their self specificity.

The goals of the present study were: (a) to generate antigen-specific L3T4+ cytolytic T lymphocytes (CTL), (b) to determine their major histocompatibility complex (MHC) restriction specificity, and (c) to assess the influence of thymic MHC determinants on their self specificity. We found that L3T4+ CTL specific for either trinitrophenyl (TNP)-modified self determinants or minor histocompatibility antigens could be generated from Lyt-2- responder T cells provided that the response cultures were supplemented with supernatants rich in helper factors. Such antigen-specific L3T4+ CTL were Ia-restricted by the criteria that they lysed only Ia+ target cells and that their lysis of Ia+ target cells was specifically inhibited by anti-Ia monoclonal antibodies. The relative frequency of L3T4+ pCTL was found to be only 5-10% of the total anti-TNP pCTL present in the spleens of normal mice. Finally, we utilized radiation bone marrow chimeras to assess the influence of the thymic haplotype on the self-Ia specificity of L3T4+ CTL. Both bulk culture and limiting dilution experiments revealed that the self-Ia specificity of L3T4+ anti-TNP CTL from F1----parent and A----B allogeneic chimeras was not markedly skewed toward the haplotype of the chimeric thymus. These results contrast with those obtained previously for L3T4+ anti-TNP Th cells and demonstrate that in the radiation bone marrow chimera model of T cell differentiation, the self specificity of Th cells but not pCTL is markedly influenced by the haplotype of the chimeric thymus.