Strong T cell tolerance in parent----F1 bone marrow chimeras prepared with supralethal irradiation. Evidence for clonal deletion and anergy.

T cell tolerance induction was examined in long-term H-2-heterozygous parent----F1 chimeras prepared with supralethal irradiation (1,300 rad). Although these chimeras appeared to be devoid of host-type APC, the donor T cells developing in the chimeras showed marked tolerance to host-type H-2 determinants. Tolerance to the host appeared to be virtually complete in four assay systems: (a) primary mixed lymphocyte reactions (MLR) of purified lymph node (LN) CD8+ cells (+/- IL-2); (b) primary MLR of CD4+ (CD8-) thymocytes; (c) skin graft rejection; and (d) induction of lethal graft-vs.-host disease by CD4+ cells. Similar tolerance was observed in chimeras given double irradiation. The only assay in which the chimera T cells failed to show near-total tolerance to the host was the primary MLR of post-thymic CD4+ cells. In this assay, LN CD4+ cells regularly gave a significant antihost MLR. The magnitude of this response was two- to fourfold less than the response of normal parental strain CD4+ cells and, in I-E(-)----I-E+ chimeras, was paralleled by approximately 70% deletion of V beta 11+ cells. Since marked tolerance was evident at the level of mature thymocytes, tolerance induction in the chimeras presumably occurred in the thymus itself. The failure to detect host APC in the thymus implies that tolerance reflected contact with thymic epithelial cells (and/or other non-BM-derived cells in the thymus). To account for the residual host reactivity of LN CD4+ cells and the incomplete deletion of V beta 11+ cells, it is suggested that T cell contact with thymic epithelial cells induced clonal deletion of most of the host-reactive T cells but spared a proportion of these cells (possibly low affinity cells). Since these latter cells appeared to be functionally inert in the thymus (in contrast to LN), we suggest that the thymic epithelial cells induced a temporary form of anergy in the remaining host-reactive thymocytes. This anergic state disappeared when the T cells left the thymus and reached LN.

Capacity of unprimed CD4+ and CD8+ T cells expressing V beta 11 receptors to respond to I-E alloantigens in vivo.

Self tolerance induction in the thymus is known to delete T cells expressing certain V beta TCR molecules. In particular, V beta 17a+ and V beta 11+ T cells are selectively deleted in mice expressing H-2 I-E molecules. Although this finding implies that V beta 17a+ and V beta 11+ T cells have specificity for self I-E molecules, studies with V beta 11+ hybridomas prepared from mature lymphocytes taken from I-E- mice have shown that the vast majority of these hybridomas do not display I-E alloreactivity, at least in vitro. To examine whether V beta 11+ T cells are capable of reacting to I-E antigens in vivo, normal unprimed T cells from I-E- B10.A(4R) mice were transferred to irradiated I-E+ B10.A(2R) hosts and harvested from thoracic duct lymph of the recipients at various intervals. The donor T cells recovered in early lymph collections showed no reactivity to the I-E antigens of the host in vitro, presumably as a reflection of selective sequestration of the host-reactive cells in the lymphoid organs. Significantly, the disappearance of functional host-reactive cells from TDL was paralleled by a 90-95% reduction of V beta 11+ CD4+ cells. Blast cells were rare in early lymph collections but accounted for nearly all of the lymph-borne cells by day 3 after transfer. These blast cell populations contained a surprisingly high proportion of V beta 11+ cells, i.e., up to 25% in some experiments. Interestingly, the enrichment for V beta 11+ cells in the blast populations applied to CD8+ cells as well as to CD4+ cells. Collectively, the data suggest that in marked contrast to the failure of V beta 11+ cells to respond to I-E antigens in vitro, a high proportion of normal resting V beta 11+ cells are capable of reacting to I-E alloantigens in vivo.

Role of T cell subsets in lethal graft-versus-host disease (GVHD) directed to class I versus class II H-2 differences. I. L3T4+ cells can either augment or retard GVHD elicited by Lyt-2+ cells in class I different hosts.

Detailed information was sought on the capacity of purified Lyt-2+ cells to mediate lethal graft-versus-host disease (GVHD) directed to class I H-2 differences. When B6 Lyt-2+ cells were transferred to irradiated class I-different (B6 x bm 1)F1 mice, three different patterns of lethal GVHD were observed. First, rapid death from hematopoietic failure occurred when Lyt-2+ cells were transferred together with host-type marrow cells; this form of GVHD probably reflected direct destruction of stem cells by Lyt-2+ cytotoxic cells. Second, a pattern of late-onset, chronic GVHD resulting in death only after 4-6 wk occurred when Lyt-2+ cells were supplemented with donor marrow. This syndrome developed in the apparent absence of L3T4+ cells and was observed with either high or low doses of Lyt-2+ cells and with either light or heavy irradiation of the host. Third, an acute form of GVHD resulted when Lyt-2+ cells plus donor marrow cells were supplemented with exogenous help, i.e., by adding small doses of donor L3T4+ cells or injecting the hosts with rIL-2. Although L3T4+ cells potentiated GVHD when injected in small doses, supplementing Lyt-2+ cells with large doses of L3T4+ cells paradoxically led to marked protection; symptoms of GVHD were mild and no deaths occurred.

T cell contact with Ia antigens on nonhemopoietic cells in vivo can lead to immunity rather than tolerance.

Long-term H-2-heterozygous a----(a x b)F1 bone marrow (BM) chimeras prepared with supralethal irradiation (1,300 rad) are devoid of Ia+ host BM-derived antigen-presenting cells (APC), but show quite strong host Ia expression in germinal centers, probably on follicular dendritic cells (a class of nonhemopoietic stromal cells). To examine whether Ia expression on these non-BM-derived cells is capable of inducing post-thymic tolerance of T cells, thymectomized irradiated (a x b)F1 mice were reconstituted with parent alpha stem cells and then, 6 mo later, given parent alpha thymus grafts. As measured by primary mixed lymphocyte reactions and V beta expression, the CD4+ cells differentiating in the thymus-grafted mice showed no detectable tolerance to the H-2 (Ia) antigens of the host. To examine whether the thymus-grafted mice contained immunologically significant quantities of host Ia antigens, long-term alpha----(alpha x b)F1 chimeras were injected with normal strain alpha CD4+ cells; the donor cells were recovered from thoracic duct lymph of the chimeras and tested for host reactivity in vitro. The results showed that Ia expression in the chimeras was sufficient to cause selective trapping of a substantial proportion of host-Ia-reactive CD4+ cells soon after transfer and, at later stages, to induce strong priming. Tolerance was not seen. The data place constraints on the view that T cell recognition of antigen expressed on cells other than typical BM-derived APC leads to tolerance induction.

Two subsets of epithelial cells in the thymic medulla.

Information was sought on the features of epithelial cells in the murine thymic medulla. The expression of major histocompatibility complex (MHC) molecules on medullary epithelium was defined by light microscopy with the aid of bone marrow chimeras and MHC-transgenic mice. A proportion of medullary epithelial cells was found to show conspicuously high expression of conventional MHC (H-2) class I (K, D, L) and class II (I-A, I-E) molecules. These cells express a high density of the Y-Ae epitope, a complex of an E alpha peptide and I-Ab molecules found on typical bone marrow-derived cells. MHC+ medullary epithelial cells show limited expression of I-O molecules, a class of atypical nonpolymorphic MHC-encoded class II molecules present on B cells. Other medullary epithelial cells express a high density of I-O molecules but show little or no expression of typical MHC class I or II molecules. MHC and I-O expression thus appear to subdivide medullary epithelial cells into two phenotypically distinct subsets. This applies in adults. In the embryonic thymus most medullary epithelial cells express both types of molecules.

T cell reactivity to MHC molecules: immunity versus tolerance.

The specificity of mature CD8+ and CD4+ T lymphocytes is controlled by major histocompatibility complex (MHC) class I and class II molecules, respectively. The MHC class specificity of T cells is stringent in many assays, but is less evident when cells are supplemented with exogenous lymphokines. The repertoire of T cells is shaped through contact with MHC molecules in the thymus and involves a complex process of positive selection and negative selection (tolerance). Tolerance of immature T cells to MHC molecules can reflect either clonal deletion or anergy and results from intrathymic contact with several cell types, including epithelial cells and cells with antigen-presenting function. Unlike immature T cells, mature T cells are relatively resistant to tolerance induction. In certain situations partial unresponsiveness of mature T cells can be achieved by exposing T cells to foreign MHC molecules expressed on atypical antigen-presenting cells. Tolerance is rarely complete, however, and the precise requirements for tolerizing mature T cells are still unclear.

Intraocular viral replication after systemic murine cytomegalovirus infection requires immunosuppression.

PURPOSE: Human cytomegalovirus retinitis is the most common blinding complication of acquired immune deficiency syndrome. However, the pathogenesis of the disease is poorly understood. The authors sought to characterize intraocular viral replication after systemic murine cytomegalovirus (MCMV) infection in the normal and immunosuppressed Balb/c mouse. METHODS: Normal or immunosuppressed mice (400 rads radiation plus antilymphocyte serum) were infected intravenously with a recombinant MCMV (RM408) that carries an MCMV IE1 promoter--LacZ insert. In vivo MCMV replication and its tissue distribution were monitored by beta-gal activity with x-gal staining on frozen tissue sections of multiple organs harvested from infected mice at different time points after inoculation. RESULTS: MCMV replication within the eye can be detected in the immunosuppressed Balb/c mouse but not in the normal host. Intraocular viral replication was noted first, and most frequently, in the ciliary body and was mainly restricted to the uveal tract. Intraocular viral replication coincided with the peak of systemic viral replication; however, the neurosensory retina was spared. In contrast, supraciliary inoculation of MCMV in the immunosuppressed Balb/c mouse resulted in massive viral replication and destruction of the neurosensory retina. CONCLUSIONS: This study demonstrated that intraocular MCMV replication after systemic infection requires systemic immunosuppression. Furthermore, the ciliary body is the portal of entry for the virus within the eye. MCMV can replicate in the epithelium of the uvea and retinal pigment epithelium, but it does not replicate within the neurosensory retina. The absence of MCMV replication within the neurosensory retina is not caused by either a defect in the recombinant virus or the inability of the host tissue to support viral replication.

T cell tolerance after bone marrow transplantation in mice.

This article provides a brief overview of T cell tolerance induction in the thymus, using parent----F1 bone marrow (BM) chimeras as a model. Although intrathymic tolerance is controlled largely by BM-derived cells, experiments with BM chimeras suggest that thymic epithelial cells can make a major contribution to tolerance induction, especially for high-affinity T cells. Whether extrathymic mechanisms contribute to tolerance induction remains controversial: evidence against this possibility is provided by the finding that transferring normal parental strain T cells to parent----F1 chimeras leads to immunogenicity rather than tolerogenicity. Breakdown of self tolerance is discussed in terms of the phenomenon of "auto-GVHD".

Intrathymic and extrathymic tolerance in bone marrow chimeras.

Parent-->F1 bone marrow (BM) chimeras provide a useful model for studying self tolerance induction. When prepared with supralethal irradiation (1300 cGy) and conditioned with anti-T cell antibodies, parent-->F1 BM chimeras are devoid of host BM-derived cells; host H-2 expression is apparent in both the intrathymic and extrathymic environments but is limited to non BM-derived cells. When parent-->F1 chimeras are injected with T cells from normal parental strain mice, the expression of host H-2 antigens on nonprofessional APC might be expected to induce tolerance through induction of clonal anergy. In practice, this does not occur. Instead, a small proportion of the injected T cells is induced to proliferate and differentiate into effector cells. Tolerance is not seen. Similarly, tolerance is not apparent when thymectomized parent-->F1 chimeras are given parental strain thymus grafts. These findings suggest that the expression of host H-2 antigens in the post-thymic environment of chimeras is not intrinsically tolerogenic for mature T cells or recent thymic emigrants. Interestingly, post-thymic tolerance does occur when parental strain T cells differentiate in the endogenous thymus of chimeras. Thus, when mature CD8+ cells are prepared from thymus vs lymph nodes (LN) of parent-->F1 chimeras, tolerance to host class I antigens is more marked in LN than thymus; this applies to cytotoxic T lymphocyte (CTL) precursors, generated by limiting dilution analysis. It would appear therefore that many of the host-reactive CTL precursors generated in the thymus of chimeras undergo tolerance induction (deletion or irreversible inactivation) in the post-thymic environment. We suggest that such tolerance is a reflection of a covert form of tolerance induced in the thymus: intrathymic contact with host antigens on thymic epithelial cells (TEC) in chimeras does not delete typical CTL precursors, but these cells are rendered "semi-tolerant". When cultured in vitro in the presence of lymphokines, the cells are able to recover and differentiate into CTL. In vivo, however, the cells recognize antigen in the periphery in the relative absence of lymphokines and the cells die. Although host class I expression on TEC in chimeras deletes only a small proportion of CTL precursors, contact with TEC induces strong tolerance of CD8+ cells in terms of helper-independent proliferative responses in vitro and induction of lethal graft-versus-host disease in vivo. We postulate that these latter responses are controlled by high-affinity T cells, whereas typical CTL generated in LDA are predominantly low-affinity cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Abnormal differentiation of thymocytes in mice treated with cyclosporin A.

Cyclosporin A (CsA) acts as a powerful immunosuppressive agent, and also, when given in repeated doses, can cause T-cell-dependent graft-versus-host disease and organ-specific autoimmune disease in rodents. This suggests that CsA interferes with the processes governing self-tolerance, either by nullifying the activity of T suppressor cells or by preventing the deletion of autoreactive T cells during ontogeny in the thymus. We report here that irradiated mice given repeated injections of CsA show striking dysfunction of the thymus. There are two different effects, the first of which is that CsA seems to block the differentiation of immature CD4+CD8+ thymocytes into mature CD4+CD8- and CD4-CD8+ cells expressing a high density of T-cell receptors and CD3 molecules. Second, CsA-treated mice show incomplete deletion of T cells expressing T-cell receptor molecules reactive to self H-2 I-E molecules.

T-cell selection in the thymus.

Differentiation of early thymocytes into mature T cells depends upon intrathymic T cell contact with major histocompatibility complex (MHC) molecules, i.e., H-2 molecules in mice. T cell recognition of H-2 molecules in the thymus has two consequences. First, some T cells undergo a process of positive selection which leads specifically-reactive immature thymocytes to survive and differentiate into mature functional T cells. Second, T cells with high affinity for H-2 molecules undergo negative selection (tolerance). We and others have argued that positive selection is controlled by thymic epithelial cells, especially cortical epithelium, whereas negative selection reflects contact with bone-marrow (BM) derived cells. This scheme appears to be an oversimplication because we have recently found evidence that a non-BM-derived component of the thymus, presumably epithelial cells, is highly tolerogenic for CD4+ cells. Whether tolerance of CD4+ cells is controlled by cortical epithelium or medullary epithelium is unclear. In this respect it is of interest that chronic injection of mice with cyclosporine A results in selective destruction of medullary epithelial cells and impaired induction of self tolerance.