Expression and function of the UM4D4 antigen in human thymus

UM4D4 is a newly identified T cell surface molecule, distinct from the Ag receptor and CD2, which is expressed on 25% of peripheral blood T cells, resting or activated. Monoclonal anti-UM4D4 is mitogenic for T cells and T cell clones. Since alternative activation pathways independent of Ag/MHC recognition may be important in thymic differentiation, the expression and function of UM4D4 was examined in human thymus. UM4D4 was found on the surface of 6% of thymocytes. All thymocyte subsets contained UM4D4+ cells but expression was greatest on thymocytes that were CD1- (12%), CD3+ (11%) and especially CD4-CD8- (18%). CD3+CD4- CD8- cells, most of which bear the gamma delta-receptor, were greater than or equal to 50% + for UM4D4. Moreover, anti-UM4D4 was comitogenic for thymocytes together with PMA or IL-2. Anti-UM4D4 also reacted strongly with a subset of thymic epithelial cells in both cortex and medulla. Dual color fluorescence microscopy, with anti-UM4D4 and antibodies to other thymic epithelial Ag, showed UM4D4 expression on neuroendocrine thymic epithelium but not on thymic fibrous stroma. Thus, UM4D4 is expressed on, and represents an activation pathway for, a subset of thymic T cells. In addition, this determinant, initially identified as a novel T cell activating molecule, is broadly expressed by neuroendocrine thymic epithelium. Although the function of UM4D4 on the thymic epithelial cells is not yet clear, it is possible that UM4D4 represents a pathway for the functional activation of a subset of the thymic epithelium as well as a subset of thymocytes, thus playing a dual role in T cell differentiation.     

Monoclonal antibodies reactive with subsets of mouse and human thymic epithelial cells

We describe monoclonal antibodies (MAB) reactive with subsets of mouse and human thymic epithelial cells. Rat MAb CDR1 reacts with mouse but not human cortical epithelial cells. Immunologic staining of thymic nurse cells in suspension indicates the CDR1 antigen is located on the cell surface. Mouse MAb CDR2 reacts with human but not mouse cortical thymic epithelial cells. Rat MAb MD1 and MD2 detect different determinants expressed by most medullary epithelial cells in mouse thymus but fewer such cells in human thymus. In addition, MD1 detects flattened subcapsular cells rarely in mouse thymus but frequently in human thymus. Two-color stains using an anti-keratin antiserum demonstrate the epithelial nature of the cells reactive with these antibodies. The antigens detected by CDR1 and MD1 first appear during the neonatal period, achieving adult distribution by postnatal days 14 and 4, respectively. The extra-thymic staining of these MAb is described. On the basis of their intra- and extra-thymic reactivities, these MAb differ from those previously reported and may permit dissection of the thymic microenvironment.     

Heterogeneity of thymic epithelial cell (TEC) keratins--immunohistochemical and biochemical evidence for a subset of highly differentiated TEC in the mouse

The mouse thymic epithelial network was studied using three different anti-keratin antibodies. One of these antibodies, KL1, exclusively recognized a small subset of medullary epithelial cells characterized by its content of a high molecular weight keratin (63 kD). Since epithelial differentiation is known to be associated with the acquisition of high molecular weight keratins, KL1-positive cells, which express the Ia antigen and secrete thymulin, may represent a subset of highly differentiated cells among mouse thymic epithelial cells (TEC). These data reflect the heterogeneity of the thymic epithelium and support the concept that distinct TEC subsets might provide the thymus with different microenvironments.     

Developmental studies on expression of monoclonal antibody-defined cytokeratins by thymic epithelial cells from normal and autoimmune mice

A major component of the thymic microenvironment is a network of thymic epithelial cells (TEC) which are able to express class II major histocompatibility complex products and to secrete thymic hormones. In the present investigation, we used a panel of anti-cytokeratin (CK) antibodies to establish distinct cytokeratin-defined TEC subsets. Four subpopulations were identified. One, in the cortex, is defined by anti-CK8 and anti-CK18 monoclonal antibodies (MAb). The other three subsets are medullary, two minor ones respectively reactive with anti-CK19 and KL1 monoclonal antibodies (the latter being specific for CK3 and 10), and a major one characterized by negative reaction with the above-mentioned MAb but strongly positive after labeling with a polyclonal (and polyspecific) anti-keratin immunoserum. Ontogenetic studies revealed that the CK8+/18+ TEC subset is the first to be detected in fetal life. Moreover, the numbers of CK3/10+ cells and CK19+ cells decrease in aging normal mice, a phenomenon that seems to occur early in autoimmune mice. We also observed that these two medullary TEC subsets are sensitive to high-dose in vivo treatment with hydrocortisone, which stimulates a dramatic increase in CK3/10+ cells and a certain decrease in CK19+ cells. Our results indicate that a number of mouse TEC subsets can be distinguished by cytokeratin expression. Such a strategy can be applied to analyze TEC sensitivity to drugs and might also be useful to further understanding of differential TEC function regarding intrathymic T-cell differentiation.     

Developmental expression of regionally specific cell surface antigens in the Xenopus gastrula

Molecular markers for specific cell lineages would be useful in studies of cellular differentiation. To isolate such markers monoclonal antibodies (MoABs) were raised against plasma membranes isolated from gastrulating Xenopus embryos. Those antibodies that recognized subsets of cells within the embryo were selected by indirect immunofluorescence. The analysis of eight such MoAbs is presented. Western blot analysis showed that all but one MoAb recognized a complex pattern of glycoconjugates associated with glycoproteins. All the antigens recognized by the MoAbs were maternal in origin and displayed similar spatial patterns of pregastrular expression. This pattern of immunoreactivity at the apical surface was inherited passively during cleavage by the resulting superficial blastomeres suggesting that ectodermal specific markers of maternal origin are pre-localized to the cortical ooplasm in mature oocytes. We suggest that these maternal components may be specific glycosyl transferases. Three different patterns of expression were observed during gastrulation as exemplified by MoAbs 1F10C1, 3A4D1, and 6F10B6. MoAb 6F10B6 was specific for both neural and non-neural epithelium. MoAb 3A4D1 was specific for non-neural epidermis. MoAb 1F10C1 appeared to recognize a protein epitope on an extracellular component expressed by the superficial and involuting epithelial cells. The pattern of expression for the 1F10C1 antigen suggests that it may play a role in facilitating the movement of the involuting cells during gastrulation.     

Medullary epithelial cell lines from murine thymus constitutively secrete IL-1 and hematopoietic growth factors and express class II antigens in response to recombinant interferon-gamma

In this report, we describe the generation of two cloned epithelial cell lines, TE-71 and TE-75, from murine thymus. These cell lines resemble medullary thymic epithelium by a number of criteria, including reactivity with the monoclonal antibodies A2B5 and ER-TR5, the fucose-specific lectin derived from Ulex europeus, and the expression of keratins normally expressed by medullary thymic epithelial cells in situ. Constitutive Class II antigen expression by these cells is not detectable at the light or electron microscopic level or with flow cytometry. Following exposure to recombinant interferon-gamma or supernatants from mitogen-stimulated spleen cells, expression of Class II antigens by these thymic epithelial cell lines is increased, although less than the levels expressed by spleen cells. Medium conditioned by TE-71 and TE-75 cells exhibited colony-stimulating activity for bone marrow cells. In addition, TE-71-conditioned medium exhibited IL-1-like activity which could be neutralized with anti-IL-1 antibodies.     

Immunohistology of lymphoid and non-lymphoid cells in the thymus in relation to T lymphocyte differentiation

The present paper reports the distribution of lymphoid and non-lymphoid cell types in the thymus of mice. To this purpose, we employed scanning electron microscopy and immunohistology. For immunohistology we used the immunoperoxidase method and incubated frozen sections of the thymus with 1) monoclonal antibodies detecting cell-surface-differentiation antigens on lymphoid cells, such as Thy-1, T-200, Lyt-1, Lyt-2, and MEL-14; 2) monoclonal antibodies detecting the major histocompatibility (MHC) antigens, H-2K, I-A, I-E, and H-2D; and 3) monoclonal antibodies directed against cell-surface antigens associated with cells of the mononuclear phagocyte system, such as Mac-1, Mac-2, and Mac-3. The results of this study indicate that subsets of T lymphocytes are not randomly distributed throughout the thymic parenchyma; rather they are localized in discrete domains. Two major and four minor subpopulations of thymocytes can be detected in frozen sections of the thymus: 1) the majority of cortical thymocytes are strongly Thy-1+ (positive), strongly T-200+, variable in Lyt-1 expression, and strongly Lyt-2+; 2) the majority of medullary thymocytes are weakly Thy-1+, strongly T-200+, strongly Lyt-1+, and Lyt-2- (negative); 3) a minority of medullary cells are weakly Thy-1+, T-200+, strongly Lyt-1+, and strongly Lyt-2+; 4) a small subpopulation of subcapsular lymphoblasts is Thy-1+, T-200+, and negative for the expression of Lyt-1 and Lyt-2 antigens; 5) a small subpopulation of subcapsular lymphoblasts is only Thy-1+ but T-200- and Lyt-; and 6) a small subpopulation of subcapsular lymphoblasts is negative for all antisera tested. Surprisingly, a few individual cells in the thymic cortex, but not in the medulla, react with antibodies directed to MEL-14, a receptor involved in the homing of lymphocytes in peripheral lymphoid organs. MHC antigens (I-A, I-E, H-2K) are mainly expressed on stromal cells in the thymus, as well as on medullary thymocytes. H-2D is also expressed at a low density on cortical thymocytes. In general, anti-MHC antibodies reveal epithelial-reticular cells in the thymic cortex, in a fine dendritic staining pattern. In the medulla, the labeling pattern is more confluent and most probably associated with bone-marrow-derived interdigitating reticular cells and medullary thymocytes. We discuss the distribution of the various lymphoid and non-lymphoid subpopulations within the thymic parenchyma in relation to recently published data on the differentiation of T lymphocytes.     

Differential expression and regulation of cyclooxygenase isozymes in thymic stromal cells

Prostaglandins (PGs) are lipid-derived mediators of rapid and localized cellular responses. Given the role of PG in supporting thymic T cell development, we investigated the expression of the PG synthases, also known as cyclooxygenases (COX)-1 and -2, in the biosynthesis of PGs in thymic stromal cell lines. The predominant isozyme expressed in cortical thymic epithelial cells was COX-1, while COX-2 predominated in the medulla. IFN-gamma up-regulated expression and activity of COX-2 in medullary cells, in which COX-2 was expressed constitutively. In contrast, IFN-gamma down-regulated COX-1 activity, but not expression, in cortical cells. Stromal cells support T cell development in the thymus, although the mediators of this effect are unknown. Selective inhibition of COX-2, but not COX-1, blocked the adhesion of CD4+CD8+ and CD4+CD8- thymocytes to medullary cell lines. No effect of the inhibitors was observed on the interactions of thymocytes with cortical epithelial lines. These data further support the differential regulation of COX-1 and COX-2 expression and function in thymic stromal cells. PGs produced by COX-2 in the medullary thymic stroma may regulate the development of thymocytes by modulating their interaction with stromal cells.     

The human thymic microenvironment: cortical thymic epithelium is an antigenically distinct region of the thymic microenvironment

The thymic microenvironment is a complex tissue essential for normal T cell maturation. Prothymocytes in the subcapsular cortical (SCC) region of the thymus undergo cell division and migrate to the inner cortex. The majority of cortical thymocytes cease dividing and die, but a minority are exported to the periphery. We have previously shown thymic hormones in SCC and medullary thymic epithelium and have identified a monoclonal antibody (TE-4) that defines human endocrine thymic epithelium. However, no marker that selectively defines cortical thymic epithelium has been available. In this study, we have produced two monoclonal antibodies, TE-3A and TE-3B, raised against human thymic stroma that bind to an intracellular antigen in cortical but not medullary thymic epithelium. In double immunofluorescence assays in which we used anti-keratin, anti-thymosin alpha 1, and anti-endocrine thymic epithelium antibodies (TE-4, A2B5), TE-3+ SCC epithelium was TE-4+ and contained keratin and thymosin. alpha 1. In contrast, TE-3+ inner cortical epithelium was TE-4/A2B5 nonreactive and did not contain thymosin alpha 1. An ontogeny study of seven fetal and five neonatal thymuses demonstrated that expression of the TE-3 antigen was acquired at 10 wk fetal gestation. Using TE-3 antibody, we observed sequential stages of separation of cortical and medullary epithelium from 12 to 20 wk fetal gestation. In dysplastic (severe combined immunodeficiency disease) thymuses, strands of TE-3+ nonendocrine cells encircled nests of TE-4+ endocrine epithelium. Thus, human cortical thymic epithelium is antigenically distinct from endocrine medullary epithelium. Antibodies against the TE-3 antigen define an intracellular molecule that may reflect a specialized function of cortical thymic epithelium.     

Immunohistochemical characterization of nurse cells in normal human thymus.

Lymphoepithelial complexes known as thymic "nurse" cells (TNC) have been isolated and described in the thymus of several animal species including man. Most of the investigations on TNC have been carried out in enzymatically digested thymuses in which TNC were isolated by differential sedimentation. In the present study we demonstrate TNC in immunohistochemically stained sections of human thymus as ring-shaped cells completely enclosing thymocytes and localized not only in the cortex, but also at the corticomedullary junction where they have not been previously described. TNC expressed epithelial markers [low and high molecular weight keratins identified by 35 beta H11 and 34 beta E12 monoclonal antibodies, a cortical antigen shared with neuroectodermal neoplasms recognized by the GE2 monoclonal antibody, and tissue polypeptide antigen (TPA:B1)], class II histocompatibility antigens (HLA-DR), and thymosin alpha 1. Double staining experiments with the nuclear proliferation-associated antigen Ki-67 and the cortical epithelium marker GE2 showed that most thymocytes enclosed in these cortical TNC were not proliferating. The antigens expressed by TNC indicate that not only cortical, but also medullary epithelial cells are part of the TNC system. The possible role of TNC in the education and maturation of thymocytes is discussed.     

Culture and characterization of thymic epithelium from autoimmune NZB and NZB/W mice

Autoimmune NZB and NZB/W mice display early abnormalities in thymus histology, T cell development, and mature T cell function. Abnormalities in the subcapsular/medullary thymic epithelium (TE) can also be inferred from the early disappearance of thymulin from NZB. It has also been reported that NZB thymic epithelial cells do not grow in culture conditions that support the growth of these cells from other strains of mice. In order to study the contribution of TE to the abnormal T cell development and function in NZB and NZB/W mice, we have devised a culture system which supports the growth of TE cells from these mice. The method involves the use of culture vessels coated with extracellular matrix produced by a rat thymic epithelial cell line. TEA3A1, and selective low-calcium, low-serum medium. In addition TEA3A1 cells have been used as an antigen to generate monoclonal antibodies specific for subcapsular/medullary TE. These antibodies, as well as others already available, have been used to show that the culture conditions described here select for cells displaying subcapsular/medullary TE markers, whereas markers for cortical TE and macrophages are absent.     

The thymic insulin-like growth factor axis: involvement in physiology and disease.

A repertoire of neuroendocrine-related genes is transcribed in the non-lymphoid compartment of the thymus, transposing the dual physiological role of this organ at the molecular level in T-cell development towards the establishment of central T-cell self-tolerance. The "neuroendocrine self" has been defined as a series of antigen sequences processed from precursors predominantly expressed in the thymus and first encountered by differentiating T-lymphocytes in their early life. All the members of the insulin gene family are expressed in the thymus according to a precise hierarchy and cellular topography, whereby IGF-II (epithelium of the subcapsular cortex and medulla) exceeds IGF-I (macrophages), which in turn far exceeds INS (rare subsets of medullary epithelial cells). This hierarchy in the degree of their respective thymic expression explains why IGF-II is more tolerated than IGF-I, and much more so than insulin. Evidence has been found for significant regulatory/tolerogenic properties in the IGF-II B:11 - 25 sequence after analysis of the cytokine secretion profile in peripheral blood mononuclear cells isolated from ten DQ8+ type 1 diabetic adolescents. In the thymus, IGF ligands and receptors also intervene in the control of T-cell proliferation and differentiation. Here, we also discuss how a disturbance in the intrathymic IGF-mediated signaling could contribute to the pathogenesis of T-cell leukemia.     

Total lymphoid irradiation leads to transient depletion of the mouse thymic medulla and persistent abnormalities among medullary stromal cells

Mice given multiple doses of sublethal irradiation to both the thymus and the peripheral lymphoid tissues showed major transient, and some persistent disruptions in general thymic architecture and in thymic stromal components. At 2 wk after total lymphoid irradiation (TLI), the thymus lacked identifiable medullary regions by immunohistochemical analyses. Medullary stromal cells expression MHC Ag or a medullary epithelial cell Ag, as well as medullary macrophages, were undetectable. Instead, the processes of cortical epithelial cells were observed throughout the entire thymus. Strikingly, thymocyte subsets with mature phenotypes (CD4+CD8- and CD4-CD8+) were present in the apparent absence of a medulla. This early, gross effect was rapidly reversed such that by 1 to 2 mo after TLI, medullary areas with MHC Ag-positive cells were evident. However, abnormalities in a subset of medullary stromal cells appeared to be more persistent. Medullary epithelial cells, identified by the MD1 mAb, were greatly reduced in number and abnormally organized for at least 4 mo after TLI. In addition, macrophages containing endogenous peroxidase activity, normally abundant in medullary regions, were undetectable at all times examined after TLI. Therefore, this irradiation regimen induced both transient and long term effects in the thymus, primarily in medullary regions. These results suggest that TLI may be used as an experimental tool for studying the impact of selective depletion of medullary stromal cells on the development of specific T cell functions.     

Spectrum of reactivity of monoclonal antibodies against specific T-suppressors

Monoclonal antibodies (MoAb) against specific T-suppressors CI and C4 are characterized by their reactivity with normal lymphoid cells and some tumour cell lines cultivated in vitro. MoAb CI and C4 react with T and B cells from spleen and lymph nodes. The amount of CI and C4 T and B subsets are equal in the spleen (25-29%), while lymph node T-lymphocytes contain twice as much CI and C4 cells than B-lymphocytes (40 and 20%, respectively). In the thymus CI is expressed mostly on immature (cortical) thymocytes and C4--on the mature (medullary) thymocytes. CI is expressed on some T-lymphoma cell lines (BW 5147, EL4, LBRM33), but not on thymoma RDM4 and mastocytoma P815. C4 is not found on the above cell lines but is expressed on the intermediate filament of mouse and quail fibroblasts and in lymphoid cells. This cross-reactivity may result from the existance of similar determinants in cytoskeleton proteins and lymphocyte membranes or from the intermediate filament expression on T-suppressor cellular membranes, but not on other functional T subsets.     

Biochemical and functional characterization of a molecule expressed by a subset of thymic medullary epithelial cells.

A monoclonal antibody (mAb), named TE-4F 10, was produced by fusing P3X-Ag8 myeloma cells with splenocytes of BALB/c mice immunized with a rat medullary thymic epithelial cell (TEC) line, (TE-R 2.5), previously established in our Institute. Flow cytometry showed that 85-95% TE-R 2.5 cells expressed the TE-4F10 antigen. The mAb immunoprecipitated a 29 kDa molecule from the TE-R2.5 cell lysate. Immunohistochemical analysis using single and double staining of the thymus with anti-cytokeratin (CK) mAb, showed that TE- 4F10 mAb selectively stains a subpopulation of medullary TEC. Hematopoietic and lymphoid cells were negative. The expression of the TE-4F10 antigen on TE-R 2.5 cells in vitro was significantly upregulated by interleukin 1 (IL-1) and tumor necrosis factor (TNFalpha). Other cytokines IL-4, IL-6, IL-10 and granulocyte - macrophage colony stimulating factor (GM-CSF) showed lesser stimulation on its expression, whereas interferon gamma (IFN) and dexamethasone were without significant effect. The TE-R 2.5 cell line strongly bound and induced apoptosis of a rat / mouse thymocyte heterohybridoma (BWRT8), phenotypically alphabetaTCRhiCD4hiCD8lo. TE-4F10 mAb significantly inhibited binding (40-50%) of both BWRT8 cells and the BWRT8 - MDP.1 subclone to TE-R 2.5 cells. The inhibition was enhanced when TEC were stimulated with IL-1 + TNFalpha. The mAb also significantly blocked apoptosis of BWRT8 but did not modulate cell death of the BWRT8 - MDP.1 subclone, which was resistant to TEC-induced apoptosis. These findings indicate that the TE-4F10 antigen might be selectively involved in adhesion and selection processes in the medullary thymic microenvironment. The mAb of the same characteristics has not been described so far.     

Thymic shared antigen-1. A novel thymocyte marker discriminating immature from mature thymocyte subsets.

In a previous study, we raised a mAb (MTS 35) reacting with a plasma membrane Ag expressed on both cortical thymocytes and a subset of thymic medullary epithelial cells. In view of the shared expression of this molecule, we have defined it as thymic shared Ag-1 (TSA-1). Considering its selective reactivity with cortical, but not medullary thymocytes, the relevance of TSA-1 as a marker of immature T cells was investigated in detail in this study, using multicolor flow cytometric analysis. TSA-1 was found on all immature thymocyte subsets (CD3-4-8-, CD3-4+8-, CD3-4-8+, CD3-4+8+, CD3low4+8+). Conversely, CD3high4+8- and CD3high4-8+ thymocytes, early thymic migrants and peripheral T cells were TSA-1-. More refined gating and analysis of the transitional CD3intermediate/high4+8+ thymocytes, proposed candidates for negative selection, demonstrated that approximately one half were TSA-1-. In fact, there was a directly inverse relationship between TSA-1 and CD3 expression on thymocytes. In the periphery, TSA-1 was detected on B lymphocytes. TSA-1 is PI-linked and has a molecular mass of 17 kDa nonreduced, or 12 to 13 kDa reduced. Through cross-correlation analysis, this molecule was distinct from H-2K, PNA-R, CD5, CD11a/18, Thy-1, HSA, Ly6A/E, Ly6C, ThB, CD25, CD44. Hence TSA-1 appears to be a unique marker which exquisitely separates mature from immature thymocytes.     

Expression of MHC antigens by mouse thymic dendritic cells.

Thymic epithelial cells express MHC antigens in several different patterns. I-A is present throughout the thymic cortex on dendritic cells. The remainder of the I region and H-2K/D are expressed on dendritic cells apparently only variably in the cortex (at least in some haplotypes). All MHC antigens tested are present in the medulla on epithelial cells; expression on medullary lymphocytes cannot be evaluated. Monoclonal anti-MHC antibodies confirm these results. The significance of these findings to T cell maturation is discussed.     

The cell surface of mouse dendritic cells: FACS analyses of dendritic cells from different tissues including thymus

The surface of dendritic cells from mouse spleen, thymus, and epidermis has been compared with a panel of monoclonal antibodies and the FACS. A method was first developed to isolate populations of large, adherent, thymic dendritic cells that were greater than 90% pure. These were released by collagenase digestion and separated from adherent macrophages after overnight culture. Enrichment was based on the facts that most macrophages remained plastic adherent and rosetted strongly with antibody-coated erythrocytes. As in spleen, thymic dendritic cells were stellate in shape, had abundant class I and II MHC products, lacked many standard macrophage and lymphocyte markers, and actively stimulated the mixed leukocyte reaction. Most spleen and thymic dendritic cells could be lysed by the 7D4 mAb, to the low-affinity IL-2 receptor, and complement but the levels of 7D4 by FACS were low and sometimes not above background. Differences among dendritic cells from different tissues were noted with other mAb. Adherent dendritic cells from thymus all expressed the J11d "B cell" antigen and the NL145 interdigitating cell marker, but lacked the 33D1 spleen dendritic cell antigen. Eighty to ninety percent of spleen dendritic cells were J11d-, NL145-, 33D1+ but the remainder expressed the J11d+, NL145+, 33D1- thymic phenotype. The latter phenotype also was identical to that of epidermal Langerhans' cells. We postulate that the major 33D1+ cell in spleen represents a migratory stage in which dendritic cells are moving from tissues to lymphoid organs.     

Neuroendocrinology of the thymus

The neuropeptides oxytocin (OT) and vasopressin (VP) are synthesized in the human thymus in a similar way as in the hypothalamo-neurophypophyseal system. Immunocytochemistry with polyclonal and monoclonal antibodies revealed that immunoreactive OT- and VP-producing cells are localized in the subcapsular cortex and medulla of human and murine thymuses. The epithelial nature of the neuroendocrine thymic cells is demonstrated by their immunostaining with a monoclonal antibody against cytokeratin. An original example of a neuroendocrine-immune microenvironment is given by the thymic nurse cells which are composed of a large neuroendocrine epithelial cell enclosing numerous mitotic immature thymocytes. These observations and the previously reported mitogenic and immunomodulatory properties of VP and OT upon mature T cells and thymocytes strongly support the existence of a neuroendocrine thymo-lymphoid axis and an active role of thymic VP and OT in T cell differentiation and activation.     

A role for accessibility to self-peptide-self-MHC complexes in intrathymic negative selection

Whether intrathymic-positive and -negative selection of conventional alpha beta T cells occur in anatomically distinct sites is a matter of debate. By using a system composed of two distinct immune receptors, the Y-Ae mAb and the 1H3.1 (V alpha 1/V beta 6) TCR, both directed against the 52--68 fragment of the I-E alpha-chain (E alpha 52--68) bound to I-A(b), we examined the occurrence of negative selection imposed in vivo by a self-peptide-self-MHC class II complex with differential tissue expression. 1H3.1 TCR-transgenic (Tg) mice were bred to mice having an I-E alpha transgene with expression directed to all MHC class II-positive cells, restricted to thymic epithelial cells, or restricted to B cells, dendritic cells, and medullary thymic epithelial cells. All 1H3.1 TCR/I-E alpha double-Tg mice revealed a severely diminished thymic cellularity. Their lymph node cells were depleted of V beta 6(+)CD4(+) cells and were unresponsive to E alpha 52--68 in vitro. The absolute number of CD4(+)CD8(+) thymocytes was drastically reduced in all combinations, indicating that negative selection caused by an endogenously expressed self-determinant can effectively occur in the thymic cortex in vivo. Moreover, both cortical epithelial cells and, interestingly, the few cortical dendritic cells were able to support negative selection of CD4(+)CD8(+) thymocytes, albeit with a distinct efficiency. Collectively, these observations support a model where, in addition to the avidity of the thymocyte/stromal cell interaction, in vivo negative selection of autoreactive TCR-Tg T cells is determined by accessibility to self-peptide-self-MHC complexes regardless of the anatomical site.