Phenotypic analysis of thymocytes that express homing receptors for peripheral lymph nodes

Thymocytes that express high levels of homing receptors for peripheral lymph nodes can be detected with the monoclonal antibody MEL-14. We have shown that in adult mice these rare MEL-14hi thymocytes a) are cortical in location and typically constitute 1 to 3% of the total thymocyte population, b) may be a major source of thymus emigrants, and c) contain a high frequency of precursors of alloreactive cytotoxic T lymphocytes. In this study we have analyzed the phenotype of the MEL-14hi thymocyte subset. Most normal adult MEL-14hi thymocytes are midsize and express the mature phenotype typical of thymus emigrants, medullary thymocytes, and peripheral T cells: they are predominantly PNAlo, H-2K+, Thy-1+, Ly-1hi, and either Lyt-2-/L3T4+ or Lyt-2+/L3T4-. These findings argue strongly for the presence of rare MEL-14hi immunocompetent cortical thymocytes that, aside from their homing receptor expression, are phenotypically indistinguishable from medullary thymocytes. However, a minority (20 to 30%) of MEL-14hi thymocytes are large and phenotypically nonmature: they express intermediate to high levels of PNA binding sites, and are H-2K- to H-2Klo, Thy-1hi, Ly-1+, and either Lyt-2+/L3T4+ or Lyt-2-/L3T4-. Through a technique that selectively labels outer cortical cells, phenotypically nonmature MEL-14hi thymocytes have been shown to be concentrated in the subcapsular blast region of the outer cortex. Although we have no direct evidence of a precursor-product relationship, we consider it likely that the phenotypically nonmature outer cortical MEL-14hi lymphoblasts give rise to phenotypically mature MEL-14hi cells located deeper in the cortex. These results are consistent with our previous proposal that MEL-14hi thymocytes are a major source of thymus emigrants, and indicate that expression of high levels of MEL-14-defined homing receptors may be closely linked to the intrathymic selection process.     

L3T4+, B2A2+ thymocytes from infant mice produce IL 2 after interaction with accessory cells expressing self class II antigens

The presence of a thymocyte population in infant (3 to 10 day old), but not adult mice, that produces IL 2 after self class II MHC antigen stimulation is described. The responding thymocyte expresses the antigenic phenotype: Thy-1+, Ly-1+, Ly-2-, L3T4+, B2A2+. Cell-cell mixing experiments and limiting dilution analysis were consistent with a loss of the self-Ia-reactive IL 2-producing thymocyte in the adult, with no evidence for active suppression found. Although thymocytes from adult animals failed to generate IL 2 after self class II stimulation, a similar frequency of IL 2-producing cells was demonstrated in both infant and adult after allo stimulation. These findings, taken with the recent demonstration of IL 2 receptors on neonatal thymocyte subpopulations, demonstrate a mechanism for IL 2 production in the thymus that may play a role in intrathymic differentiation of T cells.     

T cell antigen receptor expression by subsets of Ly-2-L3T4- (CD8-CD4-) thymocytes

The V beta 8-specific mAb F23.1 and KJ16 were used as fluorescent stains to test for TCR expression on the surface of subpopulations of early, CD4-CD8- (L3T4-Ly-2-) thymocytes from adult CBA mice. A surprisingly high proportion (27%) of Ly-2-L3T4- thymocytes were strongly F23.1 and KJ16 positive. No positive cells were detected among Ly-2-L3T4- thymocytes from V beta 8-negative SJL mice. In contrast to the adult thymus, Ly-2-L3T4- cells from embryonic CBA thymus lacked F23.1-positive cells. Subsets of adult CBA Ly-2-L3T4- thymocytes were separated to determine which expressed V beta 8. The major subset, Ly-1 low B2A2-M1/69+Thy-1+Pgp-1-, representing a phenotype similar to embryonic Ly-2-L3T4- thymocytes and the phenotype commonly isolated from adult thymocytes as Ly-1 "dull," lacked cells strongly positive for F23.1. In contrast, a series of subsets of adult CBA Ly-2-L3T4- thymocytes which were B2A2-M1/69- and Pgp-1+ all included strongly F23.1-positive cells. A minor subset, negative for most markers except Pgp-1 and presumed on the basis of this phenotype and some reconstitution studies to include the earliest intrathymic precursors, contained 28% F23.1-positive cells. However, no F.23.1-positive cells were detected in equivalent "prethymic" populations from bone marrow or from athymic mouse spleen. The subsets of Ly-2-L3T4- thymocytes which were Ly-1 high, B2A2-M1/69-, and Pgp-1+ all contained about 70% F23.1-positive cells, indicating a V beta 8 usage much higher than the mature T cell average. These results indicate that a series of distinct developmental events have occurred within these CD4-CD8- thymocytes previously considered as a single group of early precursor cells, and that some aspects of repertoire selection may be occurring amongst thymocytes which lack CD4 or CD8.     

Origin of autoreactive T helper cells. I. Characterization of Thy-1+, Lyt-, L3T4- precursors in the spleen of normal mice

A new population of dull Thy-1+, Ly-1-, Lyt-2-, L3T4- PNA- cells, resistant to a double cytotoxic treatment by monoclonal antibodies to these T cell markers plus complement, has been isolated from the spleen of normal adult BALB/c and DBA/2 mice (Tkr cells). These cells exhibit no spontaneous autoreactivity or alloreactivity but can be activated with concanavalin A (Con A). Once activated, they differentiate into bright Thy-1+, Ly-1+, Lyt-2-, L3T4+ PNA- T lymphocytes. Con A-activated Tkr cells also strongly proliferate in the presence of allogeneic or syngeneic dendritic cells in secondary cultures. Moreover, contrary to other Con A-stimulated T cell populations, they induce B lymphocytes to proliferate and to differentiate into Ig-secreting cells at a very high level. Con A-activated Tkr cells are therefore very potent polyclonal B cell activators. Restimulated of Tkr cells by syngeneic dendritic cells can be inhibited by anti-L3T4 or anti-class II monoclonal antibodies. The results suggest that Tkr cells are the precursors of class II-specific autoreactive T helper cells. Tkr cells are absent in the spleen of B6 animals. This indicates that their expression might be genetically controlled. It also suggests that Tkr cells may not be the unique splenic precursors of autoreactive T cells. Con A activation of Tkr cells in Click's medium is 2-mercaptoethanol dependent and highly sensitive to pCO2, like the response of thymocytes. Tkr cells are also absent in the spleen of nude mice. We conclude that Tkr cells represent splenic precursors of autoreactive T helper cells equivalent to Thy-1+, Ly-2-, L3T4- PNA- cortical thymocytes.     

Differentiation of thymocytes in fetal organ culture: analysis of phenotypic changes accompanying the appearance of cytolytic and interleukin 2-producing cells

At the 14th day of gestation, embryonic thymocytes+ are large, functionally incompetent cells with H-2K+ Thy-1+ B14- Ly-2- L3T4- phenotype, some of which express TL antigen. Differentiation of these cells in organ culture is characterized by: 1) appearance of cells expressing Ly-2 and L3T4 molecules, first among the population of large cells, after 2 days of culture; 2) appearance of small H-2K- Thy-1+TL+B14+Ly-2+L3T4+ and H-2K-Thy-1+TL+B14-Ly-2+ L3T4+ cells between days 2 and 4; 3) accumulation of small H-2K- Thy-1+ TL+ B14- Ly-2+ L3T4+ (but not H-2K- Thy-1+ TL+ B14+ Ly-2+ L3T4+) cells until day 5 of culture, and their subsequent gradual disappearance which is paralleled by an increase of the proportion of medium-sized H-2K+ Thy-1+ TL- B14- cells with various Ly-2 L3T4 phenotypes; 4) appearance and subsequent accumulation of cytolytic and IL 2-producing cells between days 4 and 6. Comparison of these results with the data from similar in vivo studies shows that differentiation of organ-cultured thymocytes rather closely follows the in vivo development only during the first week of culture and shows significant deviations thereafter. Precursors of cytolytic cells and cytolytic effector cells as well as IL 2-producing cells are found among both Ly-2+ and Ly-2- populations of thymocytes, indicating that there is no clear association between Ly-2 phenotype and the ability to kill or to secrete IL 2.     

Subpopulations of early thymocytes. A cross-correlation flow cytometric analysis of adult mouse Ly-2-L3T4-(CD8-CD4-) thymocytes using eight different surface markers

Putative early thymocytes, the Ly-2-L3T4-(CD8-CD4-) cells representing 3 to 4% of adult CBA mouse thymic lymphocytes, were isolated in high purity (99.5%). They were then stained by using mAb and analyzed by flow cytometry for the expression of six additional surface antigenic markers. Cross-correlation of the data obtained from a complete series of successive two-parameter analyses revealed the existence of about 11 discrete subsets, falling into four-main groups, within the Ly-2-L3T4- population. All subsets consisted of relatively large lymphoid cells. The most numerous group of Ly-2-L3T4- cells was Ly-1 low B2A2-M1/69 high Thy-1 high Pgp-1 low and by these markers resembled Ly-2+L3T4+ cortical blasts. Many of the cells in this group were positive for the IL-2R and/or for MEL-14. A second major group of Ly-2-L3T4- cells was Ly-1 high B2A2-M1/69 low Pgp-1 high, and resembled in some respects activated mature T cells. This group had previously been shown to be absent from the embryonic thymus. The group could be divided into Thy-1 high and Thy-1 low subsets. None of the cells in this group were positive for the IL-2R and very few expressed MEL-14. A third group, 13% of the Ly-2-L3T4- population, was Ly-1 low B2A2-M1/69 low Pgp-1 high, and could also be divided into Thy-1 high and Thy-1 low subsets. A final minor group, 9% of the Ly-2-L3T4- population, was Ly-1 high B2A2-M1/69 high Pgp-1 low Thy-1 high. The particular pattern of markers on these subsets, combined with subsequent information on their properties, makes it unlikely that they all represent sequential steps in one continuous developmental stream, and indicates that complex developmental steps have occurred, even at this supposedly early stage of T cell differentiation.     

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.     

Phenotype and localization of thymocytes expressing the homing receptor-associated antigen MEL-14: arguments for the view that most mature thymocytes are located in the medulla

The monoclonal antibody MEL-14 recognizes a lymphocyte surface structure (the MEL-14 antigen) involved in migration of lymphocytes into lymph nodes. Its use as a maturation marker for T cells within the thymus led to the view that a small population (1 to 2%) of MEL-14high thymocytes located in the inner cortex represented fully mature cells about to exit as thymus emigrants. The medulla, in this view, contained only the phenotypically mature but MEL-14low cells, and was not the source of thymus emigrants. The data we present, derived from flow-cytometric analysis of suspension-stained CBA mouse thymocytes, is not in accordance with this view. A high proportion (approximately 20%) of thymocytes express relatively high levels of MEL-14; these include some immature Ly-2- L3T4- and nonmature Ly-2+ L3T4+ thymocytes. Among the 12 to 14% thymocytes of mature phenotype (PNAlow or H-2Khigh or Ly-2+ L3T4- and Ly-2- L3T4+), more than half express relatively high levels of MEL-14. The mature phenotype and MEL-14moderate-to-high cells (8% of thymocytes) appear too numerous to account for the few percent MEL-14high cells seen in the cortex in frozen sections, and the mature phenotype but MEL-14low cells (2 to 3% of thymocytes) too few to fill the medulla; however, both together account numerically for the medullary population. By section staining, the medulla contains Ly-2- L3T4+ and Ly-2+ L3T4- cells in a characteristic 2:1 ratio; by suspension staining this ratio agrees with that of the total mature phenotype population, but not with that of the MEL-14low subset previously claimed to represent medullary cells. Another paradox is apparent when suspension staining and section staining are compared: suspension staining reveals that many mature phenotype cells coexpress high levels of both MEL-14 and H-2K, yet section staining reveals H-2Khigh cells in the medulla but not in the inner cortex, and reveals scattered MEL-14high cells throughout the cortex but not in the medulla. We suggest that section staining for MEL-14 fails to locate the mature cells that stain for MEL-14 in suspension; the few MEL-14high cells localized in both the inner and the outer cortex on section staining are predominantly immature Ly-2- L3T4- and nonmature Ly-2+ L3T4+ thymocytes; the majority of thymocytes of mature phenotype, whether MEL-14high or MEL-14low on suspension staining, are of medullary location; the medulla is the most likely immediate source of thymic emigrants.     

Dual immunofluorescence studies of cortisone-induced thymic involution: evidence for a major cortical component to cortisone-resistant thymocytes

Cortisone-resistant thymocytes (CRT) have been used as the experimental equivalent of medullary thymocytes for the past 15 yr. Studies with CRT have provided evidence that the medullary population is similar to mature T cells in phenotype and function and may therefore be the major source of thymus emigrants. However, we have recently demonstrated that CRT differ from medullary thymocytes in their expression of the homing receptor molecule recognized by the monoclonal antibody MEL-14. Thus, many CRT express high levels of the MEL-14-defined homing receptor, whereas medullary thymocytes are MEL-14- to MEL-14lo. In normal adult mice, only 1 to 3% of thymocytes are MEL-14hi; these cells are located exclusively in the cortex and many are phenotypically and functionally mature. In this study we have used dual immunofluorescence techniques to further characterize those thymocytes resistant to cortisone treatment. Aside from being of mature phenotype with respect to expression of peanut agglutinin binding sites and the cell surface molecules H-2K, Ly-1, Lyt-2, and L3T4, CRT can be divided into MEL-14lo and MEL-14hi subpopulations, suggesting that they may actually be derived from both the medullary and the MEL-14hi cortical thymocyte subsets.     

In vivo thymocyte maturation. BUdR labeling of cycling thymocytes and phenotypic analysis of their progeny support the single lineage model

Spontaneously cycling thymocytes have been labeled in vitro and in vivo by bromodeoxyuridine (BUdR), a non-reutilized precursor of DNA that is detectable by a monoclonal antibody. Studies of BUdR-labeled cells have included the determination of their anatomical location, size, and nuclear aspects and of their cell surface phenotype. Dividing blasts were initially located in the cortex (mainly but not exclusively in the subcapsular region) and expressed the double-negative (Lyt-2- L3T4-) and double-positive (Lyt-2+ L3T4+) phenotypes. The fate of these cells have been determined in days after BUdR administration, and we observed an initial double-negative to double-positive transition that was followed by the death of the majority of labeled cells in the cortex. As of day 3, the few surviving cells acquired a mature helper phenotype (Lyt-2- L3T4+) and began migrating into the thymic medulla. The exclusive medullary location of blast cell progeny was observed between days 5 and 10 post-BUdR administration. These results suggest a direct precursor-product relationship between dividing cortical cells and mature medullary thymocytes, and therefore support the single lineage model of intrathymic differentiation.     

Phenotypic characterization of thymic prelymphoma cells of B10 mice treated with split-dose irradiation

Using an intrathymic injection assay on B10 Thy-1 congenic mice, it was demonstrated that thymic prelymphoma cells first developed within the thymuses from 4 to 8 days after split-dose irradiation and were detected in more than 63% of the test donor thymuses when examined at 21 and 31 days after irradiation. Moreover, some mice (25%) at 2 mo after split-dose irradiation had already developed thymic lymphomas in their thymuses. To characterize these thymic prelymphoma cells, the thymocytes from B10 Thy-1.1 mice 1 mo after irradiation were stained with anti-CD4 and anti-CD8 mAb and were sorted into four subpopulations. These fractionated cells were injected into the recipient thymuses to examine which subpopulation contained thymic prelymphoma cells. The results indicated that thymic prelymphoma cells existed mainly in CD4- CD8- and CD4- CD8+ thymocyte subpopulations and also in CD4+ CD8+ subpopulation. T cell lymphomas derived from CD4- CD8- prelymphoma cells had mainly CD4- CD8- or CD4- CD8+ phenotypes. T cell lymphomas developed from CD4- CD8+ prelymphoma cells mainly expressed CD4- CD8+ or CD4+ CD8+ phenotype. T cell lymphomas originating from CD4+ CD8+ prelymphoma cells were mainly CD4+ CD8+ but some CD4- CD8+ or CD4+ CD8- cells were also present. These thymic prelymphoma cells were further characterized phenotypically in relation to their expression of the marker defined by the mAb against J11d marker and TL-2 (thymus-leukemia) Ag, which is not expressed on normal thymocytes of B10.Thy-1.2 or B10.Thy-1.1 strain, but appears on the thymocytes of lymphomagenic irradiated mice. The results indicated that the prelymphoma cells existed in J11d+, TL-2+ cells.     

Ontogeny of murine T lymphocytes: I. Maturation of thymocytes induced in vitro by tumor necrosis factor-positive serum (TNF+)

One question which is unresolved in developmental immunology is whether cortical thymocytes are the precursor cells which give rise to medullary thymocytes and peripheral T cells. Cortical thymocytes display a characteristic surface antigen phenotype (high TL and Thy-1, low H-2, no Qa-2, no Qa-3), are agglutinated by peanut agglutinin (PNA), and are unresponsive to concanavalin A (Con-A). The functionally more mature medullary thymocytes express a surface phenotype more closely resembling peripheral T cells (no TL, low Thy-1, high H-2, and some Qa-2), are not agglutinated by PNA, and are responsive to Con-A. An in vitro induction system has been devised in which mouse thymocytes undergo quantitative changes in surface antigens in less than 24 hr and increase their mitogen response to Con-A. The phenotypic changes are characterized by a decrease of TL and Thy-1 and an increase in H-2, Qa-2, and Qa-3. Studies in which thymocytes were fractionated on BSA gradients and by PNA agglutination demonstrate that the inducible cells have the properties of cortical thymocytes. Our data show that a subpopulation of cortical thymocytes can acquire phenotypic characteristics similar to medullary thymocytes and peripheral T cells.     

Thymus cell migration: cells migrating from thymus to peripheral lymphoid organs have a "mature" phenotype

To gain information on the lineage relationship of cells leaving the thymus, we studied the phenotype of thymus emigrants within hours of their exit. The migrants were identified in the peripheral lymphoid organs by their fluorescence, 3 to 4 hr after intrathymic injection of a solution of fluorescein isothiocyanate, a technique that initially only labels thymocytes. Migrants identified in this way were analyzed with rhodamine-anti-Thy-1 or rhodamine peanut agglutinin (PNA). They were found to express Thy-1 antigen and PNA binding sites at levels very similar to those found on the majority of peripheral T cells or medullary thymocytes and quite different from cortical thymocytes. Taken together with our previous experiments on Lyt-1, Lyt-2, and H-2 levels, the data show that cells leaving the thymus are quite mature in phenotype and are indistinguishable from peripheral T cells by all the criteria examined.     

The cells responsible for murine natural cytotoxic (NC) activity: a multi-lineage system

Previous studies on the surface phenotype of natural cytotoxic (NC) cells defined by negative selection with antibodies and complement showed that most if not all NC activity is the property of "null" cells that did not express a variety of lymphoid markers, including some expressed by natural killer (NK) cells. In the present study we show that when murine C57BL/6 spleen cells were sorted by flow cytometry into fractions positive or negative for Qa-5, Ly-2.2, Thy-1.2, L3T4, or surface immunoglobulin (sIg) and for high or low expression of H-2Kb, the pattern of NC activities was quite different from the negative selection experiments with antibody and complement. Enrichment of NC activity tested against WEHI-164 targets was observed in the H-2Kb high, Qa-5+, Thy-1.2+, and Ly-2.2- fractions, and to a lesser extent in the L3T4+ and sIg- fractions. However, significant NC activity, although lower than in the unseparated cells, was also found in the H-2Kb low, Qa-5-, Thy-1.2-, L3T4-, Ly-2.2+, and sIg+. With the exception of the anti-Ig, all the reagents were monoclonal antibodies. By comparison, NK activity tested against YAC-1 targets was clearly enriched in the H-2Kb high, Ly-2.2-, sIg-, and to a lesser extent, Thy-1.2+ sorted fractions, whereas most of the NK activity was in the L3T4- fractions. These results indicate that NC activity against WEHI-164 targets is mediated by an heterogeneous population of effector cells, which includes cells with markers of both the T and the B lineages, as well as of NK cells. These studies also show that negative selection with antibodies and complement is not always a reliable method for defining the surface phenotype of effector cells.     

Prevention of lymphadenopathy in MRL-lpr/lpr mice by blocking peripheral lymph node homing with Mel-14 in vivo

MRL-lpr/lpr mice develop massive lymphadenopathy and autoimmunity. There is evidence that both migration and local proliferation contribute to the accumulation of Ly-2-, L3T4-, 6B2+ T cells in the peripheral lymph node (PLN). Mel-14 is an antibody which binds to the lymphocyte lymph node homing receptor (gp90Mel-14) and can block migration of lymphocytes to the PLN. Treatment of mice from birth to 11 wk of age with Mel-14 and another rat IgG2a mAb, 6B2, resulted in reduction (10- to 20-fold) in lymphadenopathy. Mel-14, but not 6B2, preferentially reduced the percentages of Thy-1+, 6B2+ lymphocytes in the lymph node. Treatment with a third antibody, anti-Ly-1, had no effect on lymphadenopathy. Mel-14 treatment resulted in diversion of the Ly-2-, L3T4-, 6B2+, gp90Mel-14 cells to the spleen and consequently induced marked splenomegaly. Thymocytes from MRL-lpr/lpr and MRL-+/+ mice were analyzed by two-color flow cytometry analysis after depletion of Ly-2+ and L3T4+ T cells. There was no difference in the percent of Ly-2-, L3T4-, 6B2+, gp90Mel-14 positive thymocytes comparing these two strains. Mel-14 treatment did not alter Ig levels or autoantibody production. These studies suggest Mel-14 reduced lymphadenopathy by interfering with homing to PLN, whereas 6B2 may have interfered with marrow production of precursor cells or killed 6B2+ cells after they exited the marrow. The data are consistent with the idea that lymphadenopathy occurs in MRL-lpr/lpr mice due to increased homing gp90-Mel-14 T cells to the PLN and that gp90Mel-14 is a necessary receptor for the abnormal 6B2+ T cells.     

The murine IL 2 receptor. III. Cellular requirements for the induction of IL 2 receptor expression on T cell subpopulations

The accessory cell requirements for the induction of the IL 2 receptor by the lectin Con A on murine T cell subsets were directly assayed with anti-IL 2 receptor monoclonal antibodies. Substantial levels of IL 2 receptor expression were induced on T lymphocytes of the MHC class I-restricted, suppressor/cytotoxic phenotype (L3T4-, Ly-2+) in the presence and absence of accessory cells. In contrast, high levels of IL 2 receptor expression could only be induced on T cells of the MHC class II-restricted, helper/inducer phenotype (L3T4+, LY-2-) in the presence, but not in the absence, of accessory cells. Ia- cells such as the P388D1 macrophage line or cultured fibroblasts (DAP X 3) were as efficient as the Ia+ B cell hybridoma LB in providing accessory cell function for the L3T4+, Ly-2- subset. PMA, but not purified human IL 1, could substitute for accessory cells for both IL 2 receptor expression and IL 2 secretion by the L3T4+, Ly-2- subset. These data suggest that IL 2 receptor induction on the L3T4+, Ly-2- subset is complex, possibly requiring a T cell-accessory cell interaction, whereas the lectin may directly trigger IL 2 receptor expression on L3T4-, Ly-2+ T cells.     

Selection of CD4+CD8+ thymocytes by complex formation with medulla-derived epithelial cells

The role of lymphostromal complexes in T-cell differentiation is far from elucidated, mainly because a clear association of a particular stromal cell type with a distinct thymocyte subset has never been identified. Using an in vitro system, detecting the adherence of thymocytes to a thymic medullary epithelial cell line (E-5), we showed that the phenotype of these thymocytes was that of cortical type: Thy-1hi, LFA-1+, PNAhi, CD4+CD8+, MEL-14-/lo, IL-2R-, CD3-/lo, and TcR V beta 8-/lo. They were enriched in cells in G2/M at the time of complex formation, showed a higher basal proliferation in culture, and did not respond to PHA, IL-2 and only marginally to Con A. These data show that complex formation with mouse thymic medullary epithelium selects for CD4+CD8+ thymocytes, as shown by the marked decrease in CD4+CD8-/CD4-CD8+ thymocytes, and the incapacity of CD4-CD8- thymocytes to adhere.     

Phenotypic, functional, and molecular genetic comparisons of the abnormal lymphoid cells of C3H-lpr/lpr and C3H-gld/gld mice

Lymph node cells from C3H mice homozygous for lpr and gld were compared for expression of cell surface antigens, lectin-binding sites, functional characteristics, expression of ecotropic MuLV, and organization of Ig and T cell receptor (TcR) beta-chain genes. The abnormal cells (Ly-2-/L3T4-) populating nodes of both mutant strains were specifically purified by using plate separation techniques. The purified abnormal cells were shown to express the beta-chain of the TcR, to exhibit rearrangements of the beta-chain genes, and to express TcR beta and alpha gene mRNA, demonstrating the T cell origin of these populations. FMF analyses of the separated abnormal cells showed them to be Thy-1+, Ly-1+, Ly-2-, L3T4-, Ly-5(B220)+, Ly-6+, Ly-22+, Ly-24+, sIg-, ThB-, Ia-, HSA-/+, and PC.1+ and to bind at high levels lectins that normally bind preferentially to B cells. These cells did not proliferate or generate CTL in response to stimulation with alloantigens, and supernatants of cells stimulated with Con A were devoid of IL 2. These characteristics do not correspond to those of any known immature or mature population of normal T cells. The findings that the abnormal T cells of lpr and gld homozygotes are indistinguishable for each parameter examined support the suggestion that these mutations may affect different enzymes in a common metabolic pathway of major importance to T cell differentiation and function.     

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.     

Qualitative and quantitative heterogeneity in Pgp-1 expression among murine thymocytes

A proportion of Pgp-1+ cells in the thymus have been shown to have progenitor activity. In adult AKR/Cum mice the total Pgp-1+ population in the thymus differs from that of the bulk of thymocytes and is antigenically heterogeneous when examined by flow cytometry. Pgp-1+ thymocytes are enriched for several minor cell populations compared to total thymocytes: B2A2-, interleukin-2-receptor+ (IL-2R+), and Lyt-2-, L3T4-. However, these subsets are still a minor proportion of the Pgp-1+ cells, the majority being Lyt-2+ and/or L3T4+ and B2A2+. Pgp-1+ thymocytes also differ from the bulk of thymocytes in having lower amounts of Thy-1 and in showing a higher proportion of single positive (Lyt-2+, L3T4- or Lyt-2-, L3T4+) cells. Populations of adult thymocytes that are enriched in progenitor cells can be isolated by cytotoxic depletion using either anti-Thy-1 antibody (Thy-1 depletion) or anti-Lyt-2 and anti-L3T4 antibody (Lyt-2, L3T4 depletion). Pgp-1+ cells in progenitor cell-enriched populations are also phenotypically heterogeneous. Pgp-1+ cells in both populations may be IL-2R+ or IL-2R- and B2A2+ or B2A2-. The population of Pgp-1+ cells in progenitor cell-enriched populations in the adult differs from that of the fetus at 14 days of gestation in that in the 14-day fetus, most Pgp-1+ cells are IL-2R+. By Day 15 of gestation, distinct populations of Pgp-1+, IL-2R-; Pgp-1+, IL-2R+; and Pgp-1-, IL-2R+ cells are observed. In the 15-day fetus, as in the adult, many Pgp-1+ thymocytes express low to moderate levels of Thy-1. The total percentage of Pgp-1+ cells in the thymus varies among different mouse strains, ranging from 4 to 35% in the thymus of young adult mice. Pgp 1.1 strains contain more detectably Pgp-1+ thymocytes than Pgp 1.2 strains; however, there is variability in the proportion of Pgp-1+ cells, even among Pgp 1.2 strains. In contrast to AKR/Cum mice, the Pgp-1+ thymocyte population in BALB/c mice, which contain a high proportion of Pgp-1+ thymocytes, closely resembles the total thymocyte population.