Post-thymic selection of peripheral CD4+ T-lymphocytes on class II major histocompatibility antigen-bearing cells.

Following positive and negative selection in the thymus, mature CD4+ T-cells emigrate into peripheral lymphoid organs. Whether resting T-cells require periodic stimulation to remain viable in the absence of antigen is important for understanding peripheral T-cell homeostasis. A prerequisite for T-cell receptor (TCR)-mediated signals in maintaining peripheral CD4+ T-cell longevity has been demonstrated. Here, we show in mice expressing a mutant I-Abeta transgene on an I-Abeta knockout background that na?ve CD4+ T-cells also require engagement of their CD4 coreceptors by peripheral, class II MHC-bearing cells for their survival. The transgene's product combines with endogenous Aalpha, but this mutant AalphaAbeta heterodimer cannot interact with CD4 molecules, although it efficiently presents antigens to TCRs. Resting CD4+ T-lymphocytes from mutant Abeta transgenic mice die by apoptosis at a much higher rate than do CD4+ T-cells from normal mice. Apoptosis of CD4+ T-cells in mutant Abeta transgenic mice is partially mediated by Fas. Adoptive transfer experiments revealed that the increase in apoptosis is due to a lack of interactions with mutant MHC class II rather than to an intrinsic defect in the CD4+ T-cells selected on mutant Abeta-expressing thymic epithelial cells. Thus, interactions between CD4 and MHC class II molecules contribute to the regulation of homeostasis in the peripheral immune system. Our results further suggest that thymic emigrant cells are continuously retested in the periphery for appropriate coreceptor interactions. Peripheral selection may be important in eliminating potentially autoreactive T-cells.     

Thymocyte antigens do not induce tolerance in the CD4+ T cell compartment.

Thymocytes fail to tolerize the developing T cell repertoire to self MHC class I (MHC I) Ags because transgenic (CD2Kb) mice expressing H-2Kb solely in lymphoid cell lineages reject skin grafts mismatched only for H-2Kb. In this study, we examined why thymocytes fail to tolerize the T cell repertoire to self MHC I Ags. The ability of CD2Kb mice to reject H-2Kb skin grafts was age dependent because CD2Kb mice older than 20 wk accepted skin grafts. T cells from younger CD2Kb mice proliferated, but did not develop cytotoxic functions in vitro in response to H-2Kb. Proliferative responses were dominated by H-2Kb-specific, CD4+ T cells rather than CD8+ T cells. Representative CD4+ T cell clones from CD2Kb mice were MHC II restricted and recognized processed H-2Kb. TCR transgenic mice were generated from one CD4+ T cell clone (361) to monitor development of H-2Kb-specific immature thymocytes when all thymic cells or lymphoid cell lineages only expressed H-2Kb. Thymocyte precursors were not eliminated and mice were not tolerant to H-2Kb when Tg361 TCR transgenic mice were intercrossed with CD2Kb mice. In contrast, all thymocyte precursors were eliminated efficiently in thymic microenvironments in which all cells expressed H-2Kb. We conclude that self MHC I Ags expressed exclusively in thymocytes do not induce T cell tolerance because presentation of processed self MHC I Ags on self MHC II molecules fails to induce negative selection of CD4+ T cell precursors. This suggests that some self Ags are effectively compartmentalized and cannot induce self-tolerance in the T cell repertoire.     

CD8 is needed for development of cytotoxic T cells but not helper T cells.

A mutant mouse strain without CD8 (Lyt-2 and Lyt-3) expression on the cell surface has been generated by disrupting the Lyt-2 gene using embryonic stem cell technology. In these mice, CD8+ T lymphocytes are not present in peripheral lymphoid organs, but the CD4+ T lymphocyte population seems to be unaltered. Cytotoxic response of T lymphocytes from these mice against alloantigens and viral antigens is dramatically decreased. Proliferative response against alloantigens and in vivo help to B lymphocytes, however, are not affected. These data suggest that CD8 is necessary for the maturation and positive selection of class I MHC restricted cytotoxic T lymphocytes but is not required on any of the intermediate thymocyte populations (CD8+CD4-TcR- or CD4+CD8+TcRlow) during the development of functional class II MHC restricted helper T cells.     

Development of the CD4 and CD8 lineage of T cells: instruction versus selection

T cells bearing the alpha beta T cell receptor (TCR) can be divided into CD4+8- and CD4-8+ subsets which develop in the thymus from CD4+8+ precursors. The commitment to the CD4 and CD8 lineage depends on the binding of the alpha beta TCR to thymic major histocompatibility complex (MHC) coded class II and class I molecules, respectively. In an instructive model of lineage commitment, the binding of the alpha beta TCR, for instance to class I MHC molecules, would generate a specific signal instructing the CD4+8+ precursors to switch off the expression of the CD4 gene. In a selective model, the initial commitment, i.e. switching off the expression of either the CD4 or the CD8 gene would be a stochastic event which is then followed by a selective step rescuing only CD4+ class II and CD8+ class I specific T cells while CD4+ class I and CD8+ class II specific cells would have a very short lifespan. The selective model predicts that a CD8 transgene which is expressed in all immature and mature T cells should rescue CD4+ class I MHC specific T cells from cell death. We have performed experiments in CD8 transgenic mice which fail to support a selective model and we present data which show that the binding of the alpha beta TCR to thymic class I MHC molecules results in up-regulation of the TCR in the CD4+8+ population. Therefore, these experiments are consistent with an instructive model of lineage commitment.     

Comparative contribution of CD1 on the development of CD4+ and CD8+ T cell compartments

CD1 molecules are MHC class I-like glycoproteins whose expression is essential for the development of a unique subset of T cells, the NK T cells. To evaluate to what extent CD1 contributes to the development of CD4+ and CD8+ T cells, we generated CD1oIIo and CD1oTAPo mice and compared the generation of T cells in these double-mutant mice and IIo or TAPo mice. FACS analysis showed that the number of CD4+ T cells in CD1oIIo mice was reduced significantly compared with the corresponding population in IIo mice. Both CD4+ NK1.1+ and the CD4+ NK1.1- population were reduced in CD1oIIo mice, suggesting that CD1 can select not only CD4+ NK1.1+ T cells but also some NK1.1- CD4+ T cells. Functional analysis showed that the residual CD4+ cells in CD1oIIo can secrete large amounts of IFN-gamma and a significant amount of IL-4 during primary stimulation with anti-CD3, suggesting that this population may be enriched for NK T cells restricted by other class I molecules. In contrast to the CD4+ population, no significant differences in the CD8+ T cell compartment can be detected between TAPo and CD1oTAPo mice in all lymphoid tissues tested, including intestinal intraepithelial lymphocytes. Our data suggest that, unlike other MHC class I molecules, CD1 does not contribute in a major way to the development of CD8+ T cells.     

Altered selection of CD4+ T cells by class II MHC bound with dominant and low abundance self-peptides

We have investigated the development of CD4(+) T cells in mice expressing low levels of transgenic class II MHC molecules (A(b)) preoccupied with covalent peptide (Ep), which in the presence of invariant chain (Ii) is extensively cleaved and replaced with self-derived peptides. In these mice, the transgenic A(b) molecules, bound with predominant peptide (Ep) and with multiple self-peptides, selected more CD4(+) T cells than A(b)/self-peptide complexes expressed in wild-type mice. The enhanced outcome of thymic selection was a result of impaired negative selection, rather than more efficient positive selection by an overall lowered abundance of self-derived A(b)/peptide complexes. Peripheral CD4(+) T cells in the A(b)EpIi(+) mice had memory phenotype, often followed by polyclonal activation of B cells. The A(b)EpIi(+) mice preserved their good health and had a normal life span despite the profound number of activated CD4(+) T cells and B cells in peripheral lymphoid organs, moderate hypergammaglobulinemia, and deposited complexes in the kidneys. We propose that CD4(+) T cells positively selected due to low avidity for high abundant A(b)Ep complex avoid negative selection on A(b) molecules loaded with low abundant peptides and become self-reactive in the peripheral lymphoid organs.     

Mice deficient in CD4 T cells have only transiently diminished levels of IFN-gamma, yet succumb to tuberculosis

CD4 T cells are important in the protective immune response against tuberculosis. Two mouse models deficient in CD4 T cells were used to examine the mechanism by which these cells participate in protection against Mycobacterium tuberculosis challenge. Transgenic mice deficient in either MHC class II or CD4 molecules demonstrated increased susceptibility to M. tuberculosis, compared with wild-type mice. MHC class II-/- mice were more susceptible than CD4-/- mice, as measured by survival following M. tuberculosis challenge, but the relative resistance of CD4-/- mice did not appear to be due to increased numbers of CD4-8- (double-negative) T cells. Analysis of in vivo IFN-gamma production in the lungs of infected mice revealed that both mutant mouse strains were only transiently impaired in their ability to produce IFN-gamma following infection. At 2 wk postinfection, IFN-gamma production, assessed by RT-PCR and intracellular cytokine staining, in the mutant mice was reduced by >50% compared with that in wild-type mice. However, by 4 wk postinfection, both mutant and wild-type mice had similar levels of IFN-gamma mRNA and protein production. In CD4 T cell-deficient mice, IFN-gamma production was due to CD8 T cells. Thus, the importance of IFN-gamma production by CD4 T cells appears to be early in infection, lending support to the hypothesis that early events in M. tuberculosis infection are crucial determinants of the course of infection.     

T cell receptor-independent CD4 signalling: CD4-MHC class II interactions regulate intracellular calcium and cyclic AMP

CD4 is a coreceptor on T helper (Th) cells that interacts with MHC class II molecules (MHCII). The mechanisms mediating the effects of CD4 on responses by T helper cells to stimulation of the antigen-specific T cell receptor (TCR) are still poorly understood. Here, we demonstrate T cell costimulation via CD4 signalling independent of T cell receptor-mediated signals. Incubation of T helper cells with peptide mimetics of the CD4-binding region on the MHC class II beta2 domain caused intracellular calcium mobilization in the absence of antigen or other T cell receptor stimuli. Engagement of CD4 by peptide mimetics or wild-type MHC class II, but not by mutant MHC class II molecules incapable of engaging CD4, inhibited the T cell receptor-mediated increase in cyclic AMP (cAMP) concentrations in T helper cells. CD4-mediated signals activated cyclic AMP phosphodiesterases (PDEs) and inhibited adenylyl cyclase. Full activation and clonal expansion of antigen-stimulated T helper cells required the CD4-mediated regulation of cyclic AMP. Our results suggest a costimulatory mechanism of CD4 function that acts on the second messengers, calcium and cyclic AMP.     

CD4+CD25+ regulatory T cell repertoire formation shaped by differential presentation of peptides from a self-antigen

We have used TCR transgenic mice directed to different MHC class II-restricted determinants from the influenza virus hemagglutinin (HA) to analyze how specificity for self-peptides can shape CD4+CD25+ regulatory T (Treg) cell formation. We show that substantial increases in the number of CD4+CD25+ Treg cells can occur when an autoreactive TCR directed to a major I-E(d)-restricted determinant from HA develops in mice expressing HA as a self-Ag, and that the efficiency of this process is largely unaffected by the ability to coexpress additional TCR alpha-chains. This increased formation of CD4+CD25+ Treg cells in the presence of the self-peptide argues against models that postulate selective survival rather than induced formation as mechanisms of CD4+CD25+ Treg cell formation. In contrast, T cells bearing a TCR directed to a major I-A(d)-restricted determinant from HA underwent little or no selection to become CD4+CD25+ Treg cells in mice expressing HA as a self-Ag, correlating with inefficient processing and presentation of the peptide from the neo-self-HA polypeptide. These findings show that interactions with a self-peptide can induce thymocytes to differentiate along a pathway to become CD4+CD25+ Treg cells, and that peptide editing by DM molecules may help bias the CD4+CD25+ Treg cell repertoire away from self-peptides that associate weakly with MHC class II molecules.     

Mature CD4+ T cells perceive a positively selecting class II MHC/peptide complex in the periphery

A repertoire of TCRs is selected in the thymus by interactions with MHC bound to self-derived peptides. Whether self peptides bound to MHC influence the survival of mature T cells in the periphery remains enigmatic. In this study, we show that the number of naive CD4+ T cells that developed in mice with class II MHC bound with endogenous peptides (Abwt) diminished when transferred into mice with Ab covalently bound with a single peptide (AbEp). Moreover, transfer of a mixture of naive CD4+ T cells derived from Abwt and from AbEp mice into AbEp mice resulted in the expansion of the latter and decline of the former. In contrast, when wild-type activated CD4+ T cells were transferred into AbEp or Abwt mice, these cells survived in both recipients for more than 4 wk, but further expanded in the Abwt host. We conclude that to survive, naive CD4+ T cells favor peripheral expression of the class II MHC/peptide complex(es) involved in their thymic selection, whereas some of activated CD4+ T cells may require them only for expansion.     

The recognition of abnormal forms of HLA-B27 by CD4+ T cells

The MHC class I molecule, HLA-B27 can be expressed as a number of non-conventional forms, in addition to conventional HLA-B27 heterodimers presenting peptide. This has lead to new avenues of research to explain the association of this molecule with SpA. Surprisingly, HLA-B27 transgenic animal models implicated CD4+ T cells, which conventionally interact with MHC class II molecules, not MHC class I molecules, in the pathogenesis of SpA. One hypothesis to explain these finding is that non-conventional forms of HLA-B27, specifically HLA-B27 homodimers, might mimic MHC class II molecules and be recognised by CD4+ T cells. We investigated whether CD4+ T cells from AS patients can interact with HLA-B27, discovering that indeed CD4+ T cells can interact with various forms of HLA-B27. Here we discuss how such interactions between HLA-B27 and CD4+ T cells could occur in vivo and potential contributions of such interactions to the pathogenesis of SpA.     

Tumor-specific CD4+ T cells are activated by "cross-dressed" dendritic cells presenting peptide-MHC class II complexes acquired from cell-based cancer vaccines

Tumor cells that constitutively express MHC class I molecules and are genetically modified to express MHC class II (MHC II) and costimulatory molecules are immunogenic and have therapeutic efficacy against established primary and metastatic cancers in syngeneic mice and activate tumor-specific human CD4+ T lymphocytes. Previous studies have indicated that these MHC II vaccines enhance immunity by directly activating tumor-specific CD4+ T cells during the immunization process. Because dendritic cells (DCs) are considered to be the most efficient APCs, we have now examined the role of DCs in CD4+ T cell activation by the MHC II vaccines. Surprisingly, we find that DCs are essential for MHC II vaccine immunogenicity; however, they mediate their effect through "cross-dressing." Cross-dressing, or peptide-MHC (pMHC) transfer, involves the generation of pMHC complexes within the vaccine cells, and their subsequent transfer to DCs, which then present the intact, unprocessed complexes to CD4+ T lymphocytes. The net result is that DCs are the functional APCs; however, the immunogenic pMHC complexes are generated by the tumor cells. Because MHC II vaccine cells do not express the MHC II accessory molecules invariant chain and DM, they are likely to load additional tumor Ag epitopes onto MHC II molecules and therefore activate a different repertoire of T cells than DCs. These data further the concept that transfer of cellular material to DCs is important in Ag presentation, and they have direct implications for the design of cancer vaccines.     

Some cloned murine CD4+ T cells recognize H-2Ld class I MHC determinants directly. Other cloned CD4+ T cells recognize H-2Ld class I MHC determinants in the context of class II MHC molecules.

Murine T lymphocytes recognize nominal Ag presented by class I or class II MHC molecules. Most CD8+ T cells recognize Ag presented in the context of class I molecules, whereas most CD4+ cells recognize Ag associated with class II molecules. However, it has been shown that a proportion of T cells recognizing class I alloantigens express CD4 surface molecules. Furthermore, CD4+ T cells are sufficient for the rejection of H-2Kbm10 and H-2Kbm11 class I disparate skin grafts. It has been suggested that the CD4 component of an anti-class I response can be ascribed to T cells recognizing class I determinants in the context of class II MHC products. To examine the specificity and effector functions of class I-specific HTL, CD4+ T cells were stimulated with APC that differed from them at a class I locus. Specifically, a MLC was prepared involving an allogeneic difference only at the Ld region. CD4+ clones were derived by limiting dilution of bulk MLC cells. Two clones have been studied in detail. The CD4+ clone 46.2 produced IL-2, IL-3, and IFN-gamma when stimulated with anti-CD3 mAb, whereas the CD4+ clone 93.1 secreted IL-4 in addition to IL-2, IL-3, and IFN-gamma. Cloned 46.2 cells recognized H-2Ld directly, whereas recognition of Ld by 93.1 apparently was restricted by class II MHC molecules. Furthermore, cytolysis by both clones 46.2 and 93.1 was inhibited by the anti-CD4 mAb GK1.5. These results demonstrate that CD4+ T cells can respond to a class I difference and that a proportion of CD4+ T cells can recognize class I MHC determinants directly as well as in the context of class II MHC molecules.     

Genetic approaches for the induction of a CD4+ T cell response in cancer immunotherapy

Recently, it has become more and more obvious that not only CD8+ cytotoxic T lymphocytes, but also CD4+ T helper cells are required for the induction of an optimal, long-lasting anti-tumor immune response. CD4+ T helper cells, and in particular IFN-gamma-secreting type 1 T helper cells, have been shown to fulfill a critical function in the mounting of a cancer-specific response. Consequently, targeting antigens into MHC class II molecules would greatly enhance the efficacy of an anti-cancer vaccine. The dissection of the MHC class II presentation pathway has paved the way for rational approaches to achieve this goal: novel systems have been developed to genetically manipulate the MHC class II presentation pathway. First, different genetic approaches have been used for the delivery of known epitopes into the MHC class II processing pathway or directly onto the peptide-binding groove of the MHC molecules. Second, several strategies exist for the targeting of whole tumor antigens, containing both MHC class I and class II restricted epitopes, to the MHC class II processing pathway. We review these data and describe how this knowledge is currently applied in vaccine development.     

Antigen processing for presentation to CD4+ T cells.

The immune system surveys the organism for the presence of foreign or abnormal structures. An important role in the immune response is assumed by T lymphocytes that recognize foreign antigen while tolerating self-proteins. T lymphocytes can recognize only peptide fragments that are presented to them by molecules of the major histocompatibility complex (MHC). Antigen processing for presentation to T cells involves distinct cellular compartments where peptides and MHC molecules interact. Whereas class I MHC molecules (recognized by CD8+ cytotoxic T cells) acquire peptides in an early biosynthetic compartment, class II molecules (recognized by CD4+ helper T cells) acquire peptides most efficiently in an endocytic compartment. It has emerged recently that the class II processing compartment can be fed not only from the outside with exogenous antigen but also from endogenous sources, including membrane-associated and cytosolic proteins. The potential sources of proteins that can trigger a helper T cell response during viral infections and that can induce self-tolerance are thus much wider than previously anticipated.     

Cross-positive selection of thymocytes expressing a single TCR by multiple major histocompatibility complex molecules of both classes: implications for CD4+ versus CD8+ lineage commitment

This study has investigated the cross-reactivity upon thymic selection of thymocytes expressing transgenic TCR derived from a murine CD8+ CTL clone. The Idhigh+ cells in this transgenic mouse had been previously shown to mature through positive selection by class I MHC, Dq or Lq molecule. By investigating on various strains, we found that the transgenic TCR cross-reacts with three different MHCs, resulting in positive or negative selection. Interestingly, in the TCR-transgenic mice of H-2q background, mature Idhigh+ T cells appeared among both CD4+ and CD8+ subsets in periphery, even in the absence of RAG-2 gene. When examined on beta2-microglobulin-/- background, CD4+, but not CD8+, Idhigh+ T cells developed, suggesting that maturation of CD8+ and CD4+ Idhigh+ cells was MHC class I (Dq/Lq) and class II (I-Aq) dependent, respectively. These results indicated that this TCR-transgenic mouse of H-2q background contains both classes of selecting MHC ligands for the transgenic TCR simultaneously. Further genetic analyses altering the gene dosage and combinations of selecting MHCs suggested novel asymmetric effects of class I and class II MHC on the positive selection of thymocytes. Implications of these observations in CD4+/CD8+ lineage commitment are discussed.     

Unexpected reactivities of T cells selected by a single MHC-peptide ligand.

In H2-DM mutant mice, most MHC class II molecules are bound by a single peptide, CLIP, derived from the class II-associated invariant chain. Previous studies showed that H2-DM- cells are defective in presenting synthetic peptides to class II-restricted T cells. In sharp contrast, however, the same peptides elicited strong CD4+ T cell responses in H2-DM- animals. We now provide an explanation for this apparent discrepancy. Peptide-specific CD4+ T cells from wild-type mice were efficiently stimulated by H2-DM+, but not by H2-DM- cells pulsed with the cognate peptide. In sharp contrast, CD4+ T cells from mutant animals specific for the same MHC-peptide combination recognized peptide-pulsed H2-DM+ and H2-DM- cells equally well. In addition, unlike Ag-specific T cells from wild-type animals, the reactivities of peptide-specific T cells from mutant animals could not be efficiently blocked by Abs specific for the cognate MHC class II-peptide combination. We further demonstrated that the distinct reactivities of CD4+ T cells from H2-DM+ and H2-DM- mice are due to differences in thymic selection. Collectively, these findings indicate that the CD4+ T cell repertoires of H2-DM+ and H2-DM- mice are remarkably different.     

A two-step model of acute CD4 T-cell mediated cardiac allograft rejection

CD4 T cells are both necessary and sufficient to mediate acute cardiac allograft rejection in mice. This process requires "direct" engagement of donor MHC class II molecules. That is, acute rejection by CD4+ T cells requires target MHC class II expression by the donor and not by the host. However, it is unclear whether CD4+ T cell rejection requires MHC class II expression on donor hemopoietic cells, nonhemopoietic cells, or both. To address this issue, bone marrow transplantation in mice was used to generate chimeric heart donors in which MHC class II was expressed either on somatic or on hemopoietic cells. We report that direct recognition of hemopoietic and nonhemopoietic cells are individually rate limiting for CD4+ T cell-mediated rejection in vivo. Importantly, active immunization with MHC class II(+) APCs triggered acute rejection of hearts expressing MHC class II only on the somatic compartment. Thus, donor somatic cells, including endothelial cells, are not sufficient to initiate acute rejection; but they are necessary as targets of direct alloreactive CD4 T cells. Taken together, results support a two-stage model in which donor passenger leukocytes are required to activate the CD4 response while direct interaction with the somatic compartment is necessary for the efferent phase of acute graft rejection.