T cell tolerance by clonal elimination in the thymus

Positive selection of CD4-CD8+ T cells in the thymus of normal mice

The diversification of the repertoire of T-cell antigen receptor (TCR) specificities is influenced by at least two selection processes which occur in the thymus. One of these, termed 'negative selection', is required to install a state of tolerance to self-antigens in the T-cell repertoire and is often achieved by clonal deletion. The second type of selection operating in the thymus results in preferential differentiation of T cells that have restriction specificity for thymic major histocompatibility complex glycoproteins, but the mechanisms leading to this selective process are not yet clear. One model used to describe this 'positive selection' proposes that only those T cells with sufficient avidity for the MHC glycoproteins expressed in the thymus are allowed to acquire functional competence. Here we directly investigate the generation of TCR specificities by following the fate of developing V beta 17+ CD4-CD8+ T cells under conditions where one of the main class I-MHC molecules, either H-2K or H-2D, was specifically blocked by in vitro monoclonal antibody treatment. The results show that development of V beta 17+ CD4-CD8+ T cells in the SJL H-2s mouse strain is selectively abrogated by blocking class I-Ks molecules but is unaffected by blocking class I-Ds molecules. These data directly demonstrate that generation of CD4-CD8+ T cells expressing a particular TCR V beta segment can be correlated with the expression of a particular class I-MHC molecule, thereby providing evidence for positive selection.

A murine early thymocyte developmental sequence is marked by transient expression of the interleukin 2 receptor

Precursors of all T-lineage cells are found in the population of thymocytes that lacks the CD4 and CD8 surface markers. These "double-negative" thymocytes are heterogeneous and can be divided into discrete subpopulations based on their expression of other surface markers. We have determined the relative maturity of these subpopulations based on the extent of rearrangement and expression of their T-cell receptor genes, their cell cycle status, and their thymus reconstitution capacity. Within the subpopulation of double negatives expressing high levels of the heat-stable antigen, the additional markers phagocytic glycoprotein 1 (Pgp-1) and interleukin 2 receptor (IL-2R) can be used to define the sequence IL-2R- Pgp-1+----IL-2R+ Pgp-1-----IL-2R- Pgp-1-, which occurs before the expression of CD4 and CD8. Transient expression of the IL-2R marks an important developmental point in the sequence just prior to a burst of cell proliferation and a loss of thymus reconstitution ability. The earliest cells in this sequence are already partially rearranged for genes in the C beta 1 region. IL-2R expression marks a second wave of T-cell antigen receptor of beta-chain gene rearrangement and the initiation of T-cell antigen receptor alpha- and beta-chain gene expression.

Alternative T cell receptor gene usage induced by self tolerance

Ab-restricted, H-Y-specific T cell clones from C57BL/6 mice were found to use predominantly V beta 6 T cell receptor genes, conferring Mls-1a reactivity. However, the expression of Mls-1a as a self antigen in (DBA/2 x C57BL/6)F1 mice did not turn these mice into nonresponders to H-Y. Instead of V beta 6, they used other T cell receptor genes in this response. Thus, self tolerance appears to bias the repertoire of T cell receptor genes used in response to foreign antigens, without necessarily impairing the immune responsiveness to these antigens.

Tolerance to class I major histocompatibility complex antigens in chicken B cell chimeras. Effect of B cell depletion on transferability of tolerance

B cells from bursa of Fabricius of newly hatched chickens are able to reconstitute the B cell compartment of chemically bursectomized chickens. The resulting B cell chimerism can be detected with monoclonal antibodies against donor B cell alloantigen. Chimeric chickens accept donor-type skin grafts and are unresponsive to donor major histocompatibility complex (MHC) antigens in graft-vs.-host splenomegaly assay and mixed lymphocyte reaction. To study the capability of B cells to induce tolerance to selected MHC antigens, we transplanted class I or total MHC-incompatible bursa cells into cyclophosphamide-treated recipients. The recipients of class I or total MHC-incompatible bursa cells were equally tolerant of donor-MHC antigens. To further analyze the mechanisms of tolerance to class I antigens vs. total MHC, spleen cells from tolerant chickens were transferred to irradiated, histocompatible secondary hosts. The secondary recipients were also unresponsive to bursa cell donor-strain MHC antigens. However, if the chimeric B cells were depleted before the spleen cell transfer, the transfer of tolerance to total MHC was severely inhibited. Instead, most recipients of B cell-depleted spleen cells tolerant of class I antigens were still tolerant of bursa cell donor MHC. Our results indicate differences in the transferability of tolerance to class I antigens vs. entire MHC, although in primary recipients of bursa cells the tolerance is similar. These data suggest that a mechanism that is not dependent on the presence of donor cell chimerism contributes to the maintenance of tolerance to donor class I antigens. The transfer of tolerance to total MHC disparity requires the presence of chimeric cells indicating that donor alloantigen expression is needed for induction of tolerance in the secondary hosts.

Clonal deletion of B lymphocytes in a transgenic mouse bearing anti-MHC class I antibody genes

B lymphocytes can be rendered specifically unresponsive to antigen by experimental manipulation in vivo and in vitro, but it remains unclear whether or not natural tolerance involves B-cell tolerance because B cells are controlled by T lymphocytes, and in their absence respond poorly to antigen (reviewed in ref. 7). In addition, autoantibody-producing cells can be found in normal mice and their formation is enhanced by B-cell mitogens such as lipopolysaccharides. We have studied B-cell tolerance in transgenic mice using genes for IgM anti-H-2k MHC class I antibody. In H-2d transgenic mice about 25-50% of the splenic B cells bear membrane immunoglobulin of this specificity, and abundant serum IgM encoded by the transgenes is produced. In contrast, H-2k x H-2d (H-2-d/k) transgenic mice lack B cells bearing the anti-H-2k idiotype and contain no detectable serum anti-H-2k antibody, suggesting that very large numbers of autospecific B cells can be controlled by clonal deletion.

Analysis of T-cell receptor usage in activated T-cell clones from Hashimoto's thyroiditis and Graves' disease

Rearrangements to the T-cell receptor (TcR) beta and gamma gene loci were studied in T cells derived from the thyroid glands of a patient with Hashimoto's (HT) and another with Graves' (GD) autoimmune thyroiditis. The cells studied were freshly isolated mononuclear cells, T-cell lines grown in the presence of anti-CD3 and IL-2 and T-cell clones. Numerous different rearrangements to the constant regions of TcR beta and TcR gamma and in the variable gene region of TcR beta were observed. These findings indicate that the T-cell response in autoimmune thyroiditis is multiclonal and may have implications for the epitopes recognized by autoreactive T cells and for the mechanisms of the disease.

Mouse thymic virus (MTLV). A mammalian herpesvirus cytolytic for CD4+ (L3T4+) T lymphocytes

Mouse thymic virus (MTLV; ICTV designation murid herpesvirus 3) infects developing T lymphocytes of neonatal mice, causing thymic necrosis and acute immunosuppression. Infected animals shed virus indefinitely. In the present report, two-color flow cytometric analysis of T lymphocyte subpopulations defined by the markers CD4 (L3T4) and CD8 (Lyt-2) was used to determine whether MTLV was lytic for a specific thymocyte population. At peak necrosis (8-11 d after infection), numbers of CD4+8+ cells in the thymus were reduced by 80% or more as compared with controls, and CD4+8- cells were reduced by greater than 98%. The major survivors were CD4-8+ and CD4-8- lymphocytes. These data indicate that the CD4 bearing lymphocyte is a primary target for cytolysis during MTLV infection. Possible parallels between MTLV and a newly described lymphotropic human herpesvirus, human herpesvirus 6 (HHV-6/HBLV), are also suggested.

Immunological tolerance: new approaches using transgenic mice

Transgenic technology allows the introduction into the germline of an animal of a known gene coding for a normally foreign antigen, and by means of a specific promoter, the direction of its expression to specific tissues. The antigen is therefore synthesized by the animal as an authentic self molecule, at a particular stage in development, and in a particular site. In this review, J.F.A.P. Miller and colleagues discuss this radically new approach to the investigation of the mechanism of acquired immunological tolerance to self components.

Resistance to experimental autoimmune encephalomyelitis induced by neonatal tolerization to myelin basic protein: clonal elimination vs. regulation of autoaggressive lymphocytes

The target autoantigen of experimental autoimmune encephalomyelitis (EAE), myelin basic protein (MBP), appears late in ontogeny. In the rat MBP is expressed first on days 2-3 post partum, at a development stage, when self tolerance to most other autoantigens has already developed. To shed light on the cellular mechanisms that lead to immunological self tolerance to MBP, we treated neonatal rats with high doses of MBP before ontogenetic appearance of this autoantigen. We found that high doses are required to confer MBP-specific tolerance lasting until the adult life. Neonatally tolerized, adult rats are completely resistant to induction of EAE by injection of MBP in complete Freund's adjuvant (CFA). Upon MBP CFA challenge, these animals develop a limited humoral response to MBP, but are completely unreactive to MBP on the T cell level. The function of antigen-presenting cells is unchanged by neonatal tolerization, and there is no evidence for the induction of suppressive mechanisms. Transfers of large numbers of tolerized lymphocytes to normal hosts fails to interfere with EAE inducibility. Moreover, neonatally tolerized lymphocytes do not reduce MBP reactivity of primed lymph node cells or T line cells in vitro. Finally, neonatally tolerized rats are susceptible to EAE transferred by activated primed lymphocytes or by in vitro-activated MBP-specific T line cells. The apparent deletion of MBP-specific T lymphocytes in neonatally tolerized rats is in striking contrast to the physiological self tolerance to MBP, which is characterized by the presence of MBP-specific clones in the normal immune repertoire.

The thymus selects the useful, neglects the useless and destroys the harmful

Although efficient at reacting to foreign antigen in the context of MHC, mature T cells do not normally react to self antigens presented by self MHC. In this review, Harald von Boehmer and colleagues describe the investigation of self MHC restriction and self-tolerance using TCR transgenic mice expressing a receptor for the male-specific minor histocompatibility antigen, H-Y, in the context of class I H-2Db MHC antigens, on many of their T cells. CD4-8+ T cells expressing the transgenic receptor were positively selected by the restricting H-2Db MHC antigens in female transgenic mice. In the male TCR transgenic mice, CD4+8+ thymocytes were deleted, and transgene-expressing T cells with high surface-density of CD8 were-absent from the periphery. The remaining T cells could not be activated by male H-Y stimulator cells, as they lacked or expressed only low levels of CD8 molecules.

Contingent genetic regulatory events in T lymphocyte activation

Interaction of antigen in the proper histocompatibility context with the T lymphocyte antigen receptor leads to an orderly series of events resulting in morphologic change, proliferation, and the acquisition of immunologic function. In most T lymphocytes two signals are required to initiate this process, one supplied by the antigen receptor and the other by accessory cells or agents that activate protein kinase C. Recently, DNA sequences have been identified that act as response elements for one or the other of the two signals, but do not respond to both signals. The fact that these sequences lie within the control regions of the same genes suggests that signals originating from separate cell membrane receptors are integrated at the level of the responsive gene. The view is put forth that these signals initiate a contingent series of gene activations that bring about proliferation and impart immunologic function.

The V beta-specific superantigen staphylococcal enterotoxin B: stimulation of mature T cells and clonal deletion in neonatal mice

Staphylococcal enterotoxin B is known to be a powerful T cell stimulant in mouse and man. In this paper we show that, for mice, this is because the protein in association with major histocompatibility complex class II molecules stimulates virtually all T cells bearing V beta 3 and V beta 8.1, 8.2, and 8.3, and few others. Neonatal mice given the enterotoxin eliminate all mature, and some immature, T cells bearing these V beta s, demonstrating that tolerance to exogenously administered antigen can be caused by clonal deletion of reactive T cells. The enterotoxin shares these "superantigenic" properties with known self-antigens in mice, Mls-1a and Mls-2a, and a B cell-derived product, a shared property that is unlikely to be coincidental or inconsequential.

Antibodies to CD3/T-cell receptor complex induce death by apoptosis in immature T cells in thymic cultures

The receptors found on most T lymphocytes bind to antigen presented on major histocompatibility complex proteins and consist of dimers of alpha- and beta-polypeptides associated with the invariant CD3 complex. A fully competent immune system requires a diverse array of T-cell antigen receptors (TCRs) with different specificities. This diversity is generated by rearrangement of TCR alpha- and beta-chain gene segments within the thymus where the receptors are first expressed. Any cells carrying self-reactive receptors must be eliminated, suppressed or inactivated so that destructive autoimmunity is avoided. Recently, compelling evidence has shown that one process involved in producing such self-tolerance is clonal deletion of autoreactive cells within the thymus by an as-yet-undefined mechanism. Here we show that engaging the CD3/TCR complex of immature mouse thymocytes with anti-CD3 antibodies produces DNA degradation and cell death through the endogenous pathway of apoptosis. Activation of this process in immature T cells by the binding of the TCR to self-antigens may therefore be the mechanism which produces clonal deletion and consequently self-tolerance.

Transplantation tolerance correlates with high levels of T- and B-lymphocyte activity

Mice tolerized (treated to make them tolerant) at birth to transplantation antigens by injection of semiallogeneic cells contain very high numbers of activated T and B lymphocytes in their spleen. Lymphoid hyperactivity correlates with the tolerant state: it is present only in animals accepting skin allografts. Tolerized mice that reject the allogeneic skin graft have approximately the same numbers of total and activated lymphocytes as normal mice. The high level of lymphocyte activation in tolerant mice persists for up to 1 year of age, although it declines with age, and is markedly increased by a secondary allograft. The magnitudes of both primary and secondary tolerant responses are significantly higher than the immunological response of a normal mouse rejecting the same type of allograft. These observations contradict concepts of clonal deletion or anergy as the basis of neonatally induced transplantation tolerance and may contribute additional approaches to experimentation and control of transplantation reactions.

T cell immunity or tolerance as a consequence of self antigen presentation

In this study we investigated the basis for immunity or tolerance to a mouse serum protein, the fifth component of complement (C5). In C5-deficient mice this protein is absent from serum and therefore they are not tolerized. Immunization of C5-deficient mice with C5-sufficient serum generates CD4+ T cells, which recognize C5 presented in the context of class II. No C5-specific responses were observed in T cells from C5-sufficient mice. We show that this self protein is processed and presented with class II by cells from C5-sufficient tolerant mice and can be recognized by C5-specific T cell clones and hybrids in the absence of exogenously added antigen. The stimulation of C5-specific T cells by C5-sufficient antigen-presenting cells is not a consequence of C5 secretion and subsequent processing in vitro but rather employs C5 peptide/class II complexes generated in vivo. We conclude that this self antigen is presented in normal mice in a form recognizable by T cells to induce and maintain immunological tolerance.

A monoclonal antibody to a constant determinant of the rat T cell antigen receptor that induces T cell activation. Differential reactivity with subsets of immature and mature T lymphocytes

mAb R73 detects a T cell-specific surface molecule consisting of two disulfide-linked subunits of 40 and 46 kD, respectively, on 97% of peripheral rat T cells, as defined by the OX-52 marker. Of the few OX-52+ R73- cells, none are CD4+ but many express the CD8 antigen known to be present on rat NK cells. mAb R73 is mitogenic for unseparated spleen cells and for purified T cells. In the absence of non-T "accessory cells", stimulation by R73 requires artificial crosslinking of the mAb and is largely dependent on exogenous IL-2. Overnight incubation of purified T cells with crosslinked R73 mAb induces blastoid transformation, IL-2-R expression, and modulation of the R73 antigen. In the rat thymus, mature medullary cells express the R73 determinant at the same level as peripheral T cells, whereas 94% of CD4-CD8- thymocytes are R73-. The major CD4+8+ thymocyte population contains 25% R73- and 70% R73low cells. Thymocytes of the CD4-CD8+OX-44- subpopulation that are the direct precursors of CD4+CD8+ cells display a continuum of R73 antigen density from undetectable to very low levels. We conclude that R73 is most likely directed at a constant determinant of the rat alpha/beta heterodimeric TCR and suggest that CD8+ immature thymocytes are the first cells in the T cell differentiation pathway to express this molecule at their surface.

Molecular genetic analysis of 178 I-Abm12-reactive T cells

We have studied the genetic diversity of the TCR repertoire to the murine alloantigen I-Abm12 by generating a panel of 178 C57BL/10-derived I-Abm12-reactive T cell hybridomas. The expression of V alpha and V beta gene families was examined in this panel and the frequency of expression of V beta, but not ofV alpha, gene families differed significantly from that observed in a companion panel of random C57BL/10-derived hybridomas. The V beta 5 gene family was expressed significantly less frequently while the V beta 14, V beta 15, and V beta 16 genes were expressed significantly more frequently in the panel of I-Abm12-reactive than in the panel of random hybridomas. The junctional regions (VJ alpha and VDJ beta) of TCR V alpha and V beta genes from selected I-Abm12-specific hybridomas were amplified using the polymerase chain reaction, and directly sequenced. Surprisingly, no conserved J alpha, D beta, J beta, or N region-encoded sequences among these selected I-Abm12-reactive TCRs were identified. Thus, the T cell response to an I-A alloantigen that differs by only three amino acid residues from the I-A molecule of the responding strain is genetically complex but nonrandom. We have estimated that the repertoire to this alloantigen is comprised of at least 37 different TCRs.

Peripheral self-tolerance and autoimmunity: the protective role of expression of class II major histocompatibility antigens on non-lymphoid cells

Immunologic self-tolerance is achieved mainly during development by clonal deletion in the thymus of T lymphocytes with receptors specific for self-antigens and with associated T-cell markers CD4/CD8. However, T cells expressing a low level of these markers are allowed into the periphery still bearing their autospecific receptors. Such clonal deletion, induced by cells bearing the class II antigens coded for by major histocompatibility complex (MHC) in the thymus, does not remove all autoreactive T cells specific for antigens of differentiated tissue expressed extrathymically. However, these autoreactive T cells are silent in the periphery. Peripheral non-lymphoid cells (e.g., endocrine cells) can induce antigen-specific unresponsiveness in T cells and can specifically suppress production of autoantibody against their antigens when the non-lymphoid cells express class II MHC antigens on their surface. This class II MHC expression is induced by interferon-gamma produced by T cells as a result of various immune responses, such as autoimmune reaction. Thus, the expression of class II MHC antigens on non-lymphoid cells may serve as a peripheral mechanism for the induction and maintenance of self-tolerance in autoreactive T cells that escape negative selection in the thymus or that are specific for extrathymic tissue antigens, in a fail-safe mechanism against autoimmunity. Some autoimmune diseases, especially organ-specific ones, might be caused by a defect in this fail-safe mechanism.

Growth of fetal thymocytes in organ culture: effect of recombinant lymphokines on thymocyte maturation

Interleukin 2 (IL2) has a dose-dependent inhibitory effect on the growth and phenotypic maturation of thymocyte populations grown in fetal thymus organ culture. Addition of IL2 (100 U/ml) to 14-day fetal thymus organ cultures induces the appearance of a population of lymphokine-activated killer (LAK) cells which lyse allogeneic, syngeneic, and syngeneic tumor cell targets. The addition of the monoclonal antibody, PC-61, blocks the IL2-dependent growth and activation of LAK cells but does not influence the maturation of CD4+ CD8+ fetal thymocytes. These data imply that IL2 is not a major regulator of normal fetal thymocyte maturation. The effects of a range of recombinant lymphokines (IL1 alpha, IL1 beta, IL3, IL4, GM-CSF, G-CSF, M-CSF) on the proliferation and phenotypic maturation of fetal 14-day thymocytes in organ culture has been analysed. Two significant changes were seen. First, IL1 alpha and IL1 beta inhibited growth and the expression of the CD4 and CD8 antigens in organ culture, and second, GM-CSF increased the expression of Mac-1+ cells. IL4, which has known T cell growth-promoting activity, IL3, G-CSF, and M-CSF did not alter either normal growth or surface antigen expression in fetal thymocytes. While some of these lymphokines may function as accessory molecules in fetal thymocyte development, our experiments suggest that they do not have a significant influence on thymocyte maturation when used alone.

Role of the thymus in natural tolerance to an autologous protein antigen

C5-deficient mice grafted with thymus from C5-sufficient donors and immunized with C5 failed to make humoral antibody to C5, suggesting that the transfer of thymus had induced tolerance. Irradiated C5-deficient hosts repopulated with lymphoid cells from thymectomized C5-deficient mice grafted with C5-sufficient thymus also failed to respond to immunization with C5, thus showing that the state of tolerance can be adoptively transferred. These results demonstrate that natural tolerance to self-protein antigen is "learned" in the thymus.

Peripheral tolerance mechanisms prevent the development of autoreactive T cells in chimeras grafted with two minor incompatible thymuses

The thymus has been shown to play an important role in the generation of T cell tolerance to self antigens. Developing T cells are readily tolerized to antigens which are expressed in the thymus, and it is generally thought that such thymic tolerance occurs by a mechanism of clonal deletion. We sought to examine whether T cells which initially encountered a "self antigen" post-thymically would be rendered tolerant of that antigen, and if so whether the mechanism of tolerance induction would differ from that found for thymic antigens. We constructed bone marrow radiation chimeras which were grafted with two thymus lobes differing in minor histocompatibility antigens. T cells which matured in one thymus would be tolerized to the minor histocompatibility antigens expressed in that thymus but would not encounter, and would therefore have no early opportunity of being tolerized to the minor histocompatibility antigens expressed by the other thymus. The initial encounter with the minor antigens on the second thymus would occur post-thymically. Would these T cells be tolerant or responsive to those minor histocompatibility antigens? We found that tolerance was dominant in these chimeras. The data further suggest that the mechanism responsible for tolerance induction in the periphery may differ from that which operates in the thymus.

Tolerization during pregnancy: impact on the development of antigen-specific help and suppression

Analysis of splenic B cells in the offspring of BALB/c mice which were treated with 2,4,6-trinitrobenzenesulfonic acid (TNBS) throughout the gestational period revealed that reduced responsiveness was predominantly reflecting changes in regulatory cells. Since development of T cells takes place in the thymus, postnatal maturation of helper (Th) and suppressor (Ts) T cells was evaluated in the thymus as well as in the spleen. To elaborate the impact of prenatal TNBS-treatment on the trinitrophenyl (TNP) repertoire, TNP-sheep red blood cell- and fluorescein isothiocyanate-specific regulatory elements were determined in parallel. It was found that the thymus contained activated helper and suppressor cells during the first 2 weeks of postnatal life, the majority of which appeared to be self-specific. Self reactivity in thymus and periphery disappeared within 3 weeks. Prenatally TNBS-treated mice differed inasmuch as they apparently recognized TNP-self as a self component, TNP-self reactivity being down-regulated similar to self reactivity in prenatally untreated mice. This explains why prenatally TNBS-treated mice responded poorly to stimulation with conventional T-dependent TNP-carrier conjugates. Yet, they responded transiently to TNP-anti-TNP conjugates. It could be shown that this was due to down-regulation of putatively idiotype-specific Ts, which were highly increased in prenatally TNBS-treated mice. Data are interpreted in the sense that the establishment of self tolerance is preceded by activation of self-reactive Th, which become partially eliminated. Remaining autoreactivity is controlled by the establishment on an equilibrium between idiotypic and anti-idiotypic elements.

An analysis of T-cell receptor variable region gene expression in major histocompatibility complex disparate mice

To define the impact of major histocompatibility complex (MHC)-encoded glycoproteins on the selection of the T-cell receptor repertoire, we have determined the frequency with which T-cell receptor variable region (V alpha and V beta) genes are expressed in T cells from MHC disparate mice. Approximately 500 T-cell hybridomas were generated from each of three strains of MHC congenic mice [B10 (H-2b), B10.BR (H-2k), and B10.Q (H-2q)] by fusing mitogen-stimulated lymph node T cells with the thymoma BW5147. RNA was prepared from 1629 individual hybridomas and analyzed for the expression of 10 V alpha and 16 V beta gene families. These experiments reveal significant differences in the relative contributions of 1 V alpha gene family (V alpha 3) and several V beta gene segments (V beta 5.1, -5.2, -11, and -12) to the T-cell receptor repertoire of MHC disparate mice.

T-cell receptor-specific monoclonal antibodies against a V beta 11-positive mouse T-cell clone

Two monoclonal antibodies specific for the mouse T-cell receptor (Tcr) have been established by immunization with a V beta 11+ T-cell clone, clone C6. One is a rat antibody, KT11 (IgG2b, k), specific for the V beta chain of C6, V beta 11. This was demonstrated by the fact that the strain distribution pattern of KT11+ cells was similar to that of V beta 5, 8, 9, 11, 12, and 13 and that the gene that encodes the molecule detected by KT11 was closely linked to V beta 8 in (B10 X SJL)F1 X SJL backcross mice. Furthermore, V beta of C6 has been cloned from a lambda gt10 cDNA library and was demonstrated to be identical to the V beta 11 published sequences. All strains of mice that do not express major histocompatibility complex class II E molecules had higher numbers of KT11+ cells than E+ strains. The KT11+ population in A strain mice and its H-2 congenic strains, however, was not affected by the presence or absence of E molecules. The other is a mouse antibody, KTL2 (IgM), specific for the idiotope of the Tcr expressed on the clone C6. Both antibodies were mitogenic and induced cytotoxicity. Expression of epitopes detected by KT11 or KTL2 was down-modulated by a T3 epsilon-specific antibody 145-2C11.

Cross-linking of the T cell antigen receptor interferes with the generation of CD4+8+ thymocytes from their immediate CD4-8+ precursors

The majority of thymocytes are immature cells co-expressing the surface markers CD4 and CD8. About two thirds of these cells also express the T cell antigen receptor (TcR), though at a level distinctly lower than found on mature T cells. The direct precursors of these "double-positive" thymocytes are cycling cortical blast cells of the CD4-8+ phenotype. Using a new monoclonal antibody to a constant determinant of the rat TcR alpha/beta, it is shown here that (a) about 50% of these CD8 "single-positive" committed precursor cells already express the TcR alpha/beta, though at very low levels, (b) during short-term suspension culture in medium supplemented only with fetal calf serum they not only acquire CD4 but also TcR alpha/beta levels characteristic of CD4,8 "double-positive" thymocytes, and (c) cross-linking of the TcR during culture inhibits the acquisition of the CD4 antigen in the majority of these cells.

Positive selection of CD4+ thymocytes controlled by MHC class II gene products

The mature T-cell antigen receptor repertoire is characterized by lack of reactivity to self-components as well as by preferential reactivity to foreign antigens in the context of polymorphic self-proteins encoded within the major histocompatibility complex. Whereas the former characteristic (referred to as negative selection or tolerance) is associated with intrathymic deletion of T cells expressing T-cell antigen receptor beta-chain variable (V beta) domains, which confer a preferential reactivity to self antigens, the existence of the latter (referred to as positive selection or MHC restriction) has so far only been inferred indirectly from functional studies. We show here that intrathymic deletion of V+beta 6 T cells (reactive with a self-antigen encoded by the Mlsa locus) is controlled by polymorphic MHC class II determinants. Furthermore, in mice lacking expression of Mlsa, the same class II MHC loci control the frequency of occurrence of V+beta 6 cells among mature CD4+ T lymphocytes. These data are direct evidence for positive selection by MHC determinants in the thymus in unmanipulated animals.

Macrophages phagocytose thymic lymphocytes with productively rearranged T cell receptor alpha and beta genes

The thymus gland is important for the formation of competent T lymphocytes. However, there is long-standing evidence that greater than 95% of newly formed thymocytes do not emigrate to peripheral lymphoid tissues but instead die locally. We have identified a rapid and selective pathway for thymocyte turnover in vitro. The mechanism entails binding, uptake, and digestion by macrophages. The susceptible cells are a subpopulation of double-positive thymocytes. These thymocytes can be enriched by virtue of their high buoyant density in Percoll and prove to have low levels of surface CD3 and little or no surface TCR. However TCR-alpha and -beta genes have undergone rearrangement, and full length alpha and beta transcripts are abundant. Therefore many double-positive cells rearrange and express TCR genes but do not have normal levels of TCR on the cell surface. We propose that thymocytes that undergo high turnover in situ are unable to form receptors that can be selected by MHC molecules in the thymus, and that these cells are recognized and cleared by the macrophage.

Deletion of potentially self-reactive T cell receptor specificities in L3T4-, Lyt-2- T cells of lpr mice

The current study examines the possibility that the TCR repertoire of L3T4-, Lyt-2- cells in lpr/lpr mice is enriched for self-reactive specificities. T cells utilizing V beta 17a and V beta 8.1 gene products have been shown to be clonally eliminated in nonautoimmune mice expressing I-Ek and Mlsa/H-2k, respectively, because of their potential self reactivity. We quantitated these V beta specificities in lymph nodes and spleens of lpr/lpr mice. The results indicate that lpr-dependent L3T4-/Lyt-2- T cells, similar to normal peripheral T cells, have undergone a repertoire modification such that potential self-reactive V beta specificities have been eliminated. Evidence for tolerance in this population provides insight into the development of these aberrant cells, and may also have important implications for normal T cell development in the thymus.

Postnatal B cell development: influence of trinitrobenzenesulfonic acid treatment during pregnancy

Prenatal treatment with a reactive hapten may be well suited for analyzing the establishment of self tolerance because the hapten binds ubiquitously to proteins and cells and persists for a long period in the developing organism. Based on this consideration, pregnant BALB/c mice were treated with 2,4,6-trinitrobenzenesulfonic acid (TNBS), searching for differences in 2,4,6-trinitrophenyl (TNP) responsiveness in their offspring as compared to litters of untreated mice. The frequency of TNP-specific T-independent B cells of litters from TNBS-treated mothers was very low at birth and remained below 10% of controls until the age of 42 days. On the contrary, in 8-day-old prenatally TNBS-treated litters, the frequency of TNP-specific T-dependent B cells was higher than in controls. Expansion of TNP-specific B cells after antigenic stimulation of control mice started at the age of 3-4 weeks and expansion rates increased with age, while in prenatally TNBS-treated mice, significant expansion rates were seen at the age of 2 weeks only. Yet, after restimulation with TNP-lipopolysaccharide or with a TNP-anti-TNP conjugate, but not after restimulation with TNP-ovalbumin, similar numbers of plaque-forming cells (PFC) were observed with spleen cells of prenatally untreated and TNBS-treated mice, the latter revealing an exceptional predominance of IgG PFC. Thus, TNP-specific B cells were not deleted, but prenatal TNBS treatment resulted in an altered composition of TNP-specific B cell subpopulations, their regulation differing qualitatively from the one observed in prenatally untreated mice.

Thymic selection process induced by hybrid antibodies

Thymus-derived (T) lymphocytes using the alpha beta T-cell antigen receptor (TCR) recognize fragmented antigen in conjunction with surface molecules encoded by genes of the major histocompatibility complex (MHC). Peripheral T lymphocytes preferentially see antigen presented by self rather than by foreign MHC molecules, and autoreactive T lymphocytes are deleted. Thus, the peripheral T-lymphocyte repertoire is skewed towards recognition of antigen in the context of self-MHC and towards tolerance to self-antigens. During T-lymphocyte development in the thymus, this repertoire is formed by the interaction of TCR with MHC molecules resulting in positive and negative selection phenomena. Hybrid antibodies (HAbs) that carry binding sites to the TCR and to a surface marker on another cell can engage all T lymphocytes regardless of their specificity. It should be possible to mimic selection processes in normal animals with HAb that specifically link members of a TCR family to MHC molecules on the thymic stroma. We have probed T-lymphocyte development with HAbs linking V beta 8-positive TCR to either class I or class II MHC products in thymic organ culture. Thymocytes exposed to either HAb in an early stage of maturation respond with a significant increase in the frequency of V beta 8-carrying cells. At a later stage of development V beta 8-positive thymocytes are depleted. These results illustrate the succession of positive and negative selection in the developing thymus of normal mice.