Thymic stromal cells in culture. 2. Binding of normal thymocytes to a cloned thymic stromal cell line.

Thymic stromal cell line TS-9 was found to selectively bind a subpopulation of normal murine thymocytes. Selective binding allowed the isolation and phenotypic characterization of the adherent and nonadherent subpopulations of thymocytes. Flow cytometric analysis of fluorescently labeled thymocytes revealed that the adherent and nonadherent populations differ in maturity, with the adherent population enriched in immature thymocytes of the PNAhi, Thy-1hi, CD3-/lo, and CD4+/CD8+ double positive surface phenotype. A quantitative microwell assay was developed to measure the binding of thymocytes to TS-9. Thymocytes labeled with vital DNA stain Hoechst 33342 were allowed to bind to TS-9 in microwells and the intense fluorescence of this label was readily detected with a scanning fluorometer. The binding was trypsin-sensitive and hyaluronidase and PI-PLC resistant. The binding was also temperature dependent and sensitive to cytochalasin B. A panel of monoclonal antibodies to cell surface antigens including CD2, LFA-I/ICAM-I, and Thy-1 was screened in a quantitative binding assay for their ability to inhibit the binding of thymocytes to TS-9. The binding was partially inhibited by the C3C12 monoclonal antibody which recognizes the recently identified and apparently unique gp23,gp45 complex expressed on murine stromal cells.     

Cell surface molecular changes on the activation of human thymocytes

The changes in the expression of antigen molecules on the cell surface membranes of uncultured (nonactivated) and activated human thymocytes have been studied by flow cytometry and immunoprecipitation techniques. Nonactivated thymocytes do not have the phenotypic profile of a resting population because they express cell proliferation molecules such as the transferrin receptor and the 4F2 antigens (mainly the 100,000 dalton subunit). After activation with IL 2-containing supernatants, mature T3+, T6- thymocytes proliferate and are able to nonspecifically kill different target cells. The activated thymocytes are T3+, T11+, T6-, OKM1- and bear T4 or T8 antigens in mutually exclusive cell subpopulations. They also "de novo" express the IL 2 receptor, and the 210.000/130.000 molecular complex defined by the TS2/7 MAb. Activated human thymocytes express higher amounts of class I and class II MHC antigens, equal T3 and LFA-1, and lower quantities of T11 and T4 molecules than nonactivated thymocytes. Furthermore, activated thymocytes only express the T8 34,000 dalton polypeptide subunit, whereas the nonactivated thymocyte population expressed the T8 34,000 dalton associated with a 46,000 glycoprotein. We have demonstrated that this structural change in the T8 molecule from a complex of two polypeptide subunits of 46,000 and 32,000 does not indeed occur in the activation process but rather in the maturation from T6+ to T6- thymocytes.     

Gamma-interferon enhances expression of Class I MHC antigens in the weakly HLA+ human choriocarcinoma cell line BeWo, but does not induce MHC expression in the HLA- choriocarcinoma cell line Jar

PHA-activated lymphocyte supernatants and high doses of affinity-purified human gamma-interferon enhance the expression of apparently normal Class I histocompatibility antigens in a malignant human trophoblast cell line that expresses low amounts of these antigens under normal culture conditions. Another human choriocarcinoma cell line, Jar, which is normally HLA-, did not respond to this treatment. This system provides a model in which to study further the regulation and effects of MHC antigen expression in cells of trophoblastic origin.     

Anti-tumor activity of class II MHC antigen-restricted cloned autoreactive T cells. I. Destruction of B16 melanoma cells mediated by bystander cytolysis in vitro

Two Lyt-1+, L3T4a+ autoreactive T cell clones specific for self-class II major histocompatibility complex (MHC) gene products were established from lymph node cells and spleen cells of C57BL/6J mice, respectively, by different methods. They were stimulated to proliferate in culture in response to I-Ab antigen-bearing syngeneic spleen cells in a class II MHC-restricted manner. This stimulation was inhibited completely by the addition of anti-L3T4a (GK1.5) or anti-I-Ab (3JP) monoclonal antibodies. The autoreactive T cell clones lysed syngeneic I-Ab+ target cells such as lipopolysaccharide (LPS) blasts. They also lysed I-A- bystander cells such as Cloudman and B16 melanoma and lymphoid tumor cells in the presence of I-Ab+ stimulator cells but not I-Ad+ cells. This bystander killing was most likely mediated by soluble factors released from the autoreactive T cells in response to I-Ab antigens, because culture supernatants from activated autoreactive T cells inhibited the proliferation of B16 melanoma cells in vitro and also had significant cytolytic activity. Both lymphotoxin and interferon-gamma were released from activated autoreactive T cells, suggesting that these cytotoxic lymphokines were responsible for autoreactive T cell-mediated cytolysis. The finding that the two clones, established independently and by different methods, show self-class II MHC antigen-restricted cytolysis, and bystander cytolysis suggests that these properties are not restricted to a unique population of autoreactive T cells. These results favor the concept that in vivo, autoreactive T cells may express not only regulatory activity in regard to antibody responses, but also anti-tumor activity via bystander cytolysis.     

Immunohistology of thymic nurse cells

The demonstration of thymic nurse cells (TNC), complexes between stromal cells and thymocytes, in cell suspensions of murine thymuses, prompted us to investigate (1) the relationship of TNC to other thymic stromal cell types defined in situ, and (2) the maturation stage of the enclosed thymocytes. To this purpose we incubated frozen sections of TNC suspensions with various monoclonal antisera directed to T cells and stromal cell types, using immunohistology. This approach enabled us to study antigen expression on the "nursing" cell itself and to analyze the phenotype of the enclosed lymphocytes in cross sections of TNC. The results show that lymphocytes enveloped by TNC express high levels of Thy-1, moderate levels of T200, and variable amounts of Lyt-1. Due to enzymatic degradation Lyt-2 expression could not be studied. The enveloped cells also bear PNA receptors, but no detectable I-A/E antigens. Expression of H-2K antigens on enclosed thymocytes varied from weak to absent. The "nursing" cells react with ER-TR4, a monoclonal antibody which detects cortical epithelial-reticular cells. In addition TNC express I-A/E and H-2K antigens. In contrast, TNC do not react with ER-TR 5 and 7, monoclonal antibodies, which detect medullary epithelial cells and reticular fibroblasts, respectively. TNC do not express the macrophage antigens Mac-1 and Mac-2. We conclude that TNC in vitro represent the in vivo association of epithelial-reticular cells with cortical thymocytes. However, the enclosed thymocytes do not constitute a phenotypically distinct subset of subcapsular or outer cortical cells.     

Human lymphocyte differentiation antigens HB-10 and HB-11. I. Ontogeny of antigen expression

T, B, and NK cells appear to represent separate lymphocyte lineages, but indirect evidence suggests that they may be related via a common lymphoid precursor cell. We have produced two monoclonal antibodies, HB-10 (IgM) and HB-11 (IgG1), by fusing spleen cells from mice immunized with the human B cell line SB, and have shown that both antibodies react with lymphocyte-specific cell surface antigens present on T, B, and NK cells, but not on other types of blood cells. The antibodies were reactive with most cell lines and malignancies of B cell origin and with some of T and NK cell lineage. Although the populations of cells expressing these two antigens were virtually identical, the HB-10 and HB-11 antibodies identified separate protease-sensitive determinants on the cell surface. The HB-11 antigenic determinant was also sensitive to neuraminidase and periodate treatments, but the HB-10 determinant was not. Antigen expression by lymphocytes from fetal, newborn, and adult tissues was examined. Within the B cell lineage, these antigens were expressed by most pre-B cells in bone marrow (88% +/- 5) and almost all B cells, but were not expressed by mature plasma cells. Virtually all of the granular lymphocytes in blood marked by the Leu-7 and Leu-11 (anti-Fc receptor) antibodies were HB-10+ and 11+. Among T lineage cells, the HB-10 and 11 antigens were expressed by a subset of relatively mature T3+ thymocytes and by greater than 90% of the T cells in newborn blood. In adults, however, only 65% of blood T cells and 24 to 30% of splenic or tonsillar T cells expressed the HB-10 and HB-11 antigens. The postnatal emergence of T cells which, like plasma cells, do not express these antigens suggests that post-thymic T lymphocyte maturation occurs and may be an activation-dependent process.     

Normal thymic cortical epithelial cells developmentally regulate the expression of a B-lineage transformation-associated antigen

Nonlymphoid, stromal cells in the mouse thymus are believed to be important in T cell maturation and have been proposed to play a central role in the acquisition of major histocompatibility complex (MHC) restriction and self-tolerance by maturing thymocytes. Both cortical and medullary epithelial cells in the thymus express high levels of class II (A) major histocompatibility antigens (MHC Ags). We show here that a specific subset of these A^– epithelial cells express a transformation-associated antigen (6C3Ag) found previously on the surfaces of Abelson murine leukemia virus-transformed pre-B cells and on those bone marrow-derived stromal cell clones which support normal and preneoplastic pre-B cell proliferation. Among solid lymphoid organs, only the thymus contains 6C3Ag¹ cells and within the thymus, this antigen is found exclusively on A^– epithelial cells in cortical regions. It is striking that the expression of the 6C3Ag on thymic epithelium is developmentally regulated, suggesting a role for this lymphostromal antigen in the maturation of the thymic microenvironment.     

Thymic nurse cells exclusively bind and internalize CD4+CD8+ thymocytes.

Thymic nurse cells (TNC) contain 20-200 thymocytes within specialized vacuoles in their cytoplasm. The purpose of the uptake of thymocytes by TNCs is unknown. TNCs also have the capacity to present self-antigens, which implies that they may serve a function in the process of thymic education. We have recently reported the development of thymic nurse cell lines that have the ability to bind and internalize T cells. Here, we use one of these TNC lines to identify the thymocyte subpopulation(s) involved in this internalization process. TNCs exposed to freshly isolated thymocytes bind and internalize CD4 and CD8 expressing thymocytes (CD4+CD8+ or double positives) exclusively. More specifically, a subset of the double-positive thymocyte population displayed binding capacity. These double-positive cells express cell surface alpha beta type T cell antigen receptor (TCR), as well as CD3 epsilon. Binding was not inhibited in the presence of antibodies against CD3, CD4, CD8, Class I antigens, or Class II antigens. These results describe two significant events in T cell development. First, TNCs exclusively bind and internalize a subset of alpha beta TCR expressing double-positive T cells. Also, binding is facilitated through a mechanism other than TCR recognition of major histocompatibility complex antigens. This suggests that thymocyte internalization may be independent of the process used by TNCs to present self-antigen.     

Cloned endothelium derived from autoimmune vascular disease retain structural and functional characteristics of normal endothelial cells.

MRL/1pr mice demonstrate anatomic specificity in their development of vasculitis including the small- and medium-sized muscular arteries of the mesentery. To define the functional role of endothelium in vasculitis, we have cloned endothelial cells derived from inflamed small- and medium-sized arteries. Primary cells were derived by enzymatic dispersement and endothelial cells were selected by utilizing a combination of specific culture conditions. Cloned endothelium were developed utilizing limiting dilution cultures supplemented by endothelial cell growth factor. The cloned endothelial cells express many structural features of mature endothelial cells including Factor VIII-RA, non-muscle-specific actin, and Weibel-Palade bodies. Functionally, the clones express functional receptors for the scavenger pathway for LDL metabolism. The cells do not express Class I MHC antigens; however, IFN-beta and IFN-gamma stimulate Class I MHC expression after 24 h, which induces lysis of virus-infected cloned endothelium by Class I-restricted virus-primed T cells. In direct contrast to site-identical vascular smooth muscle cells (VSMCs), endothelial cells do not spontaneously express Class II MHC antigens, nor do they secrete biologically relevant levels of IL-1 unless triggered by lipopolysaccharide. The availability of site-specific cloned endothelium along with cloned VSMCs from autoimmune mice should resolve major experimental controversies involving the pathophysiology of inflammatory vascular disease.     

Phenotypic and functional characterization of human thymic stromal cell lines.

To establish new tools for studying human thymic stromal cells, we transfected adherent cells from a human postnatal thymus using a plasmid encoding SV40 large T antigen. Among the cell lines obtained, we characterized four epithelial cell lines (LT-TEC1 to LT-TEC4) and one thymic myoid cell line (MITC). Several morphological, functional and phenotypic differences were observed between these 2 cell types. Epithelial cells were heterogeneous and larger than myoid cells. Untreated LT-TEC lines expressed MHC class I, ICAM-1 and LFA-3 antigens and not MHC class II antigens, similarly to primary thymic epithelial cells (PTEC), while MITC line expressed only class I and LFA-3 antigens. After IFN-gamma treatment, MHC class II and ICAM-1 antigens were markedly upregulated in LT-TEC lines but not in MITC, indicating the absence or a dysfunction of regulatory factors in MITC line. Myoid cells expressed mRNA for all the subunits of the acetylcholine receptor (AChR) while epithelial cells expressed only the alpha, beta and epsilon subunits. Strikingly, LT-TEC produced much more C-C chemokines and IL-6 than MITC cells, while these latter produced higher levels of IL-8 and TNF-alpha. Altogether, these results reveal phenotypic and functional differences between these two stromal cell types, suggesting a potential involvement of myoid cells in the thymic function.     

Complex interplay of activating and inhibitory signals received by Vgamma9Vdelta2 T cells revealed by target cell beta2-microglobulin knockdown

Tumor cells often escape immunosurveillance by down-regulating MHC class I molecule expression. For human Vgamma9Vdelta2 T cells, a major peripheral blood T cell subset with broad antitumor reactivity, this down-regulation can affect signals transmitted by both the inhibitory and the activating MHC class I and Ib-specific NK receptors (NKRs) that these lymphocytes frequently express. To assess the overall impact of MHC down-regulation on Vgamma9Vdelta2 T cell activation, we used stable beta(2)-microglobulin knockdown to generate tumor cells with a approximately 10-fold down-modulation of all MHC class I molecules. This down-modulation had little effect on T cell proliferation or cytokine production, but modified tumor cell killing efficiency. Ab-blocking studies identified ILT2 as an important inhibitor of tumor cell killing by Vgamma9Vdelta2 T cells. Down-modulation of MHC class I and Ib molecules severely reduced ILT2 inhibitory signaling, but still allowed signaling by activating CD94-based receptors. It also unveiled a frequent enhancing effect of NKG2D on tumor killing by Vgamma9Vdelta2 T cells. Current models suggest that activating NKRs have less affinity for their MHC ligands than homologous inhibitory NKRs. Our results show that, despite this, activating NKRs recognizing MHC class I molecules play an important role in the increased killing by Vgamma9Vdelta2 T cells of tumor cells with down-regulated MHC class I molecule expression, and suggest that these T cells will best lyse tumor cells combining MHC class I molecule expression down-regulation with up-regulated NKG2D ligand expression.     

Diabetes and tolerance in transgenic mice expressing class II MHC molecules in pancreatic beta cells

Insulin-dependent diabetes is caused by the loss of insulin-producing beta cells in pancreatic islets. It has been proposed that aberrant expression of Class II Major Histocompatibility Complex (MHC) molecules on beta cells stimulates an autoimmune attack against beta cell antigens. To test this hypothesis, we generated transgenic mice that express Class II MHC molecules (E alpha d/E beta b, or I-Eb) on beta cells. Diabetes was found in 100% of transgenic progeny from three expressing transgenic mouse lines, but without evidence for lymphocytic infiltrates. Furthermore, T lymphocytes appeared to be tolerant to the transgene I-Eb molecule, despite the absence of expression of I-Eb in the thymus or any other lymphoid tissue. The results suggest that novel expression of Class II MHC molecules on nonlymphoid cells is by itself insufficient to initiate autoimmune responses against tissue-specific antigens.     

Differential expression of guinea pig class II major histocompatibility complex antigens on vascular endothelial cells in vitro and in experimental allergic encephalomyelitis

Previous studies have shown that vascular endothelial cells do not normally express major histocompatibility complex (MHC) Class II antigens either in vivo or in vitro. In this investigation it was found that endothelial in the central nervous system (CNS) of normal guinea pigs constitutively express MHC Class II antigens recognized by the monoclonal antibodies HLA-DR, 27E7, and MSgp8. This phenotype is retained when these CNS-derived endothelial cells are propagated in tissue culture. Furthermore, examination of CNS tissue taken from animals in the acute phase of chronic relapsing experimental allergic encephalomyelitis shows that additional epitopes of the MHC Class II antigen, detected by the monoclonal antibodies CI.13.1 and 22C4, are present during the diseased state. This study not only demonstrates constitutive expression of certain MHC Class II determinants by guinea pig endothelial cells, but also shows that other Class II determinants can be differentially expressed in certain disease states.     

Primitive endothelial cell lines from the porcine embryonic yolk sac

Endothelial cell lines have been established from cells that were isolated from porcine yolk sacs from day 18 and day 22 embryos and propagated in vitro under various growth conditions. After expansion in vitro, the general properties of the cells proved similar for the different media used. The endothelial cells expressed cell surface receptors for acetylated low-density lipoprotein and also expressed cell surface-associated angiotensin-converting enzyme. The cells showed a characteristically high level of binding for Bandeiraea simplicifolia lectin I and Dolichos biflorus agglutinin but did not bind significant amounts of Ulex europaeus lectin I. The cells expressed low but serologically detectable levels of Class I major histocompatibility complex (MHC) antigens but failed to bind antibodies directed against Class II MHC antigens. Alpha5beta1 integrins were weakly expressed, whereas vascular cell adhesion molecule-1 (CD106) and alphavbeta3 integrins were not detected. Three-dimensional tube formation was readily observed in cultures grown on Matrigel and occurred even in uncoated plastic dishes in the absence of Matrigel. In contrast to most of the adult porcine endothelial cells, yolk sac-derived endothelial cells did not possess serologically detectable receptors for porcine growth hormone (GH), an observation consistent with the finding that GH did not increase the proliferative rate of these cells. Electron microscopic examination demonstrated the presence of Weibel-Palade bodies, tight endothelial cell junctions, and typical rough endoplasmic reticulum. Exposure of the cells to either concanavalin-A-stimulated porcine splenocyte culture supernatants or to human tumor necrosis factor alpha did not cause upregulation of VCAM-1 or Class II MHC antigens. Addition of porcine interferon-gamma led to an increase in the level of expression of Class I MHC. Yolk sac endothelial cells from day 22 embryos showed a low but detectable level of expression of Class II MHC antigens, whereas the endothelial cells from day 18 embryos showed no expression of Class II antigens after interferon-gamma stimulation. The cells maintained competence to develop vascular structures in vitro and could do so after coinjection with murine tumor cells into adult, immunocompromised mice.     

Immunological profiling of a panel of human ovarian cancer cell lines

Purpose The efficient identification of peptide antigens recognized by ovarian cancer-specific cytotoxic T lymphocytes (CTL) requires the use of well-characterized ovarian cancer cell lines. To develop such a panel of cell lines, 11 ovarian cancer cell lines were characterized for the expression of class I and class II major histocompatibility complex (MHC)-encoded molecules, 15 tumor antigens, and immunosuppressive cytokines [transforming growth factor β (TGF-β) and IL-10]. Methods Class I MHC gene expression was determined by polymerase chain reaction (PCR), and class I and class II MHC protein expression was determined by flow cytometry. Tumor antigen expression was determined by a combination of polymerase chain reaction (PCR) and flow cytometry. Cytokine expression was determined by ELISA. Results Each of the ovarian cancer cell lines expresses cytokeratins, although each cell line does not express the same cytokeratins. One of the lines expresses CD90, which is associated with a fibroblast lineage. Each of the cell lines expresses low to moderate amounts of class I MHC molecules, and several of them express low to moderate amounts of class II MHC molecules. Using a combination of PCR and flow cytometry, it was determined that each cell line expressed between six and thirteen of fifteen antigens tested. Little to no TGF-β3 was produced by any of the cell lines, TGF-β1 was produced by three of the cell lines, TGF-β2 was produced by all of the cell lines, with four of the cell lines producing large amounts of the latent form of the molecule, and IL-10 was produced by one of the cell lines. Conclusions Each of the 11 ovarian cancer lines is characterized by a unique expression pattern of epithelial/fibroblast markers, MHC molecules, tumor antigens, and immunosuppressive cytokines. Knowledge of these unique expression patterns will increase the usefulness of these cell lines in identifying the antigens recognized by ovarian cancer-specific CTL.     

Unilateral T cell maturation arrest in the thymus of CBA/H mice as a long-term effect after neutron irradiation

Thymuses of CBA/H mice were investigated up to 570 days after whole-body irradiation with 2.5 Gy fast fission neutrons or 6.0 Gy X rays. A number of these thymuses, observed 220-270 days after neutron irradiation, have two equal sized lobes, one of which has an abnormal T cell distribution. The present paper reports on the distribution of lymphoid and stromal cell types in these thymuses. For this purpose, we employed immunohistology using the indirect immunoperoxidase method. We incubated frozen sections of these aberrant thymuses with monoclonal antibodies directed to cell surface differentiation antigens on lymphoid cells, such as Thy-1, T-200, MT-4, Lyt-1, Lyt-2, and MEL-14; monoclonal antibodies directed to major histocompatibility complex (MHC) antigens, such as I-A and H-2K; and monoclonal antibodies directed to determinants in various thymic stromal cell types. The results of this study show a T cell differentiation arrest in only one of the two thymic lobes. T cells in the aberrant lobe express Thy-1, T-200, and MEL-14 antigens but are MT-4- and Lyt-1-. In some lobes, a weak Lyt-2 expression was observed. The observed T cell maturation arrest is mainly restricted to the cortex since in the medulla, in addition to cells with an aberrant cortical phenotype, normal T cell phenotypes are observed. This indicates that cortex and medulla have independent generation kinetics in T cell maturation. The stromal cell composition in these abnormal lobes is not different from that in the normal lobe, but the size of the medulla tends to be smaller. Furthermore, the I-A expression on the cortical epithelial cells does not reveal the characteristic reticular staining pattern that is observed in the normal lobe, since the I-A determinants are not strictly confined to the epithelial cells. In addition, cortical lymphoid and stromal cells in these lobes are slightly H-2K+. These alterations in MHC expression in the cortex are discussed in relation to the observed T cell maturation arrest.     

Establishment of a mouse thymic epithelial cell line, IT-76MHC and a brief review on cultured thymic epithelial cells.

Interactions between thymocytes and thymic stromal cells are essential for thymocyte differentiation, but little evidence has been presented to directly show in vivo functions or interactions of the stromal cells. Among the stromal cells, the thymic epithelial cell has been considered to have profound effect on thymocyte differentiation and maturation. The calcium-depleted medium, originally developed for the culture of mouse epidermal cells, was applied for the culture of the mouse thymic epithelial cells, and successfully, an epithelial cell line, IT-76MHC was obtained from the mouse thymus. IT-76MHC cells were identified as distinct mouse thymic epithelial cells by 1/ mosaic-like arrangement, 2/ presence of well-developed desmosome and 3/ tonofilaments, 4/ positivity for cytokeratin, and 5/ induced expression of MHC class I and II by IFN-gamma treatment. IGF-1, IGF-2, oxytocin and vasopressin were also detected immunohistochemically in IT-76MHC cells. Furthermore, the IT-76MHC thymic epithelial cells, when injected intrathymically in the allogeneic mouse, prolonged the survival of skin graft from the same donor strain that IT-76MHC cells were derived. These results demonstrate that the thymic epithelial cell line IT-76MHC produces modest thymocyte survival factors as well as a growth suppressor, and that IT-76MHC cells have the ability to induce transplantation tolerance probably through their expression of MHC class I and II molecules. Taken altogether, the IT-76MHC thymic epithelial cells have been proved to be useful tools to better understand the in vivo functions of thymic epithelial cells, and to gain a deep insight into their involvement in the critical selection process of thymocytes which still remains obscure. Finally and additionally, literatures so far reported on thymic epithelial cells in culture, especially lines and clones, are reviewed and their identity as well as their functions are discussed.     

Stearoyl-CoA desaturase gene expression in lymphocytes.

B lymphocytes from the spleens of normal (BALB/c) and autoimmune (MRL/lpr) strains of mice express the SCD-2 form of stearoyl-CoA desaturase as opposed to the SCD-1 form of the gene which is expressed in liver. However, whereas BALB/c T cells did not express SCD-1 or SCD-2, both BALB/c thymocytes and MRL/lpr T cells expressed SCD-2, suggesting a developmental down-regulation of SCD-2 within the T cell lineage. Northern analyses also revealed the expression of SCD-2 in the T cell lines BW5147, CTLL-2 and HT-2 and in BCL1, a B cell line. SCD-1 expression was not detected in any of the lymphoid cells tested. Finally, we show that SCD-2 gene expression is inhibited by arachidonic acid (20:4). These results demonstrate the complexity of SCD-2 regulation in lymphoid cells.     

Thymus and autoimmunity: production of CD25+CD4+ naturally anergic and suppressive T cells as a key function of the thymus in maintaining immunologic self-tolerance

This study shows that the normal thymus produces immunoregulatory CD25+4+8- thymocytes capable of controlling self-reactive T cells. Transfer of thymocyte suspensions depleted of CD25+4+8- thymocytes, which constitute approximately 5% of steroid-resistant mature CD4+8- thymocytes in normal naive mice, produces various autoimmune diseases in syngeneic athymic nude mice. These CD25+4+8- thymocytes are nonproliferative (anergic) to TCR stimulation in vitro, but potently suppress the proliferation of other CD4+8- or CD4-8+ thymocytes; breakage of their anergic state in vitro by high doses of IL-2 or anti-CD28 Ab simultaneously abrogates their suppressive activity; and transfer of such suppression-abrogated thymocyte suspensions produces autoimmune disease in nude mice. These immunoregulatory CD25+4+8- thymocytes/T cells are functionally distinct from activated CD25+4+ T cells derived from CD25-4+ thymocytes/T cells in that the latter scarcely exhibits suppressive activity in vitro, although both CD25+4+ populations express a similar profile of cell surface markers. Furthermore, the CD25+4+8- thymocytes appear to acquire their anergic and suppressive property through the thymic selection process, since TCR transgenic mice develop similar anergic/suppressive CD25+4+8- thymocytes and CD25+4+ T cells that predominantly express TCRs utilizing endogenous alpha-chains, but RAG-2-deficient TCR transgenic mice do not. These results taken together indicate that anergic/suppressive CD25+4+8- thymocytes and peripheral T cells in normal naive mice may constitute a common T cell lineage functionally and developmentally distinct from other T cells, and that production of this unique immunoregulatory T cell population can be another key function of the thymus in maintaining immunologic self-tolerance.     

Noble metals strip peptides from class II MHC proteins

Class II major histocompatibility complex (MHC) proteins are essential for normal immune system function but also drive many autoimmune responses. They bind peptide antigens in endosomes and present them on the cell surface for recognition by CD4(+) T cells. A small molecule could potentially block an autoimmune response by disrupting MHC-peptide interactions, but this has proven difficult because peptides bind tightly and dissociate slowly from MHC proteins. Using a high-throughput screening assay we discovered a class of noble metal complexes that strip peptides from human class II MHC proteins by an allosteric mechanism. Biochemical experiments indicate the metal-bound MHC protein adopts a 'peptide-empty' conformation that resembles the transition state of peptide loading. Furthermore, these metal inhibitors block the ability of antigen-presenting cells to activate T cells. This previously unknown allosteric mechanism may help resolve how gold(I) drugs affect the progress of rheumatoid arthritis and may provide a basis for developing a new class of anti-autoimmune drugs.