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.     

Expression of an unusual T cell receptor (TCR)-V beta repertoire by Ly-6C+ subpopulations of CD4+ and/or CD8+ thymocytes. Evidence for a developmental relationship between Ly-6C+ thymocytes and CD4-CD8-TCR-alpha beta+ thymocytes.

A novel thymocyte subpopulation expressing an unusual TCR repertoire was identified by high surface expression of the Ly-6C Ag. Ly-6C+ thymocytes were distributed among all four CD4/CD8 thymocyte subsets, and represented a readily identifiable subpopulation within each one. Ly-6C+ thymocytes express TCR-alpha beta, arise late in ontogeny, and appear in the CD4/CD8 developmental pathway after birth in a sequence that resembles that followed by conventional Ly-6C- cells during fetal ontogeny. Most interestingly, adult Ly-6C+ thymocytes express an unusual TCR-V beta repertoire that is identical to that expressed by CD4-CD8-TCR-alpha beta+ thymocytes in its overexpression of TCR-V beta 8 and in its expression of some potentially autoreactive TCR-V beta specificities. This unusual TCR-V beta repertoire was even expressed by Ly-6C+ thymocytes contained within the CD4+ CD8- 'single positive' thymocyte subset. Thus, expression of this unusual TCR-V beta repertoire is not limited to CD4-CD8-thymocytes, and is unlikely to be a consequence of their double negative phenotype. Rather, we think that Ly-6C+TCR-alpha beta+ thymocytes and CD4-CD8-TCR-alpha beta+ are developmentally interrelated, a conclusion supported by several lines of evidence including the selective failure of both Ly-6C+ and CD4-CD8-TCR-alpha beta+ thymocyte subsets to appear in TCR-beta transgenic mice. In contrast, peripheral Ly-6C+ T cells are developmentally distinct from Ly-6C+ thymocytes in that peripheral Ly-6C+ T cells expressed a conventional TCR-V beta repertoire and developed normally in TCR-beta transgenic mice in which Ly-6C+ thymocytes failed to arise. We conclude that: 1) expression of a skewed TCR-V beta repertoire is a characteristic of Ly-6C+TCR-alpha beta+ thymocytes as well as CD4-CD8-TCR-alpha beta+ thymocytes, and is not unique to thymocytes expressing neither CD4 nor CD8 accessory molecules; and 2) Ly-6C+ thymocytes are developmentally linked to CD4-CD8-TCR-alpha beta+ thymocytes, but not to Ly-6C+ peripheral T cells. We suggest that Ly-6C+TCR-alpha beta+ thymocytes are not the developmental precursors of Ly-6C+ peripheral T cells, but rather may be the developmental precursors of CD4-CD8-TCR-alpha beta+ thymocytes.     

Developmental potential of CD4-8- thymocytes. Peripheral progeny include mature CD4-8- T cells bearing alpha beta T cell receptor

We have used the intra-thymic transfer system to investigate the population dynamics of thymocyte and mature T cell subsets in the absence of continuing precursor input from the bone marrow. We have followed the development and life span of CD4+ and CD8+ thymocyte subsets and mature peripheral T cells from intra-thymically injected adult or fetal CD4-8- thymic precursors. Both precursor types proliferated, differentiated, and exported to peripheral lymphoid tissues alpha beta-TCR+CD4+8- and CD4-8+ progeny which formed a stable, long-lived component of the peripheral T cell pool. The production of phenotypically mature thymocytes and peripheral T cells occurred more rapidly from fetal CD4-8- precursors. CD4+8-:CD4-8+ ratios among peripheral progeny of intra-thymically-injected CD4-8- precursors were initially normal, but they steadily declined among progeny of the fetal precursors. Thus, there appear to be differences in the life span and/or proliferative capacity of mature T cells derived from embryonic vs adult progenitors. In addition to the predominant CD4+8- and CD4-8+ subsets of peripheral T cells, a minor (1 to 20%) population of Thy-1+CD3+4-8- T cells was identified among peripheral progeny of intra-thymically-injected CD4-8- thymocytes, as well as in lymph nodes of unmanipulated animals. A total of 20 to 34% of this subset expressed V beta 8+ TCR and the majority were CD5hi, Pgp-1+, and J11d-. The function and specificity of this newly identified population of thymically derived peripheral T cells remains to be investigated.     

Phenotypic and functional analysis of murine CD3+,CD4-,CD8- TCR-gamma delta-expressing peripheral T cells

Murine CD3+,CD4-,CD8- peripheral T cells, which express various forms of the TCR-gamma delta on their cell surface, have been characterized in terms of their cell-surface phenotype, proliferative and lytic potential, and lymphokine-producing capabilities. Three-color flow cytofluorometric analysis demonstrated that freshly isolated CD3+,CD4-, CD8- TCR-gamma delta lymph node cells were predominantly Thy-1+,CD5dull,IL-2R-,HSA-,B220-, and approximately 70% Ly-6C+ and 70% Pgp-1+. After CD3+,CD4-,CD8-splenocytes were expanded for 7 days in vitro with anti-CD3-epsilon mAb (145-2C11) and IL-2, the majority of the TCR-gamma delta cells expressed B220 and IL-2R, and 10 to 20% were CD8+. In comparison to CD8+ TCR-alpha beta T cells, the population of CD8+ TCR-gamma delta-bearing T cells exhibited reduced levels of CD8, and about 70% of the CD8+ TCR-gamma delta cells did not express Lyt-3 on the cell surface. Functional studies demonstrated that splenic TCR-gamma delta cells proliferated when stimulated with mAb directed against CD3-epsilon, Thy-1, and Ly-6C, but not when incubated with an anti-TCR V beta 8 mAb, consistent with the lack of TCR-alpha beta expression. In addition, activated CD3+,CD4-,CD8- peripheral murine TCR-gamma delta cells were capable of lysing syngeneic FcR-bearing targets in the presence of anti-CD3-epsilon mAb and the NK-sensitive cell line, YAC-1, in the absence of anti-CD3-epsilon mAb. Finally, activated CD3+, CD4-,CD8-,TCR-gamma delta+ splenocytes were also capable of producing IL-2, IL-3, IFN-gamma, and TNF when stimulated in vitro with anti-CD3-epsilon mAb.     

Clonal deletion of self-reactive T cells at the early stage of T cell development in thymus of radiation bone marrow chimeras

Sequential appearance of T cell subpopulations occurs in the thymocytes of irradiated C3H/He mice (H-2k, Mls-1b2a, Thy-1.2) after transplantation with bone marrow cells of AKR/J mice (H-2k, Mls-1a2b, Thy-1.1) (AKR----C3H chimeras). The donor-derived thymocytes of AKR----C3H chimeras on day 14 after bone marrow transplantation (BMT) contained a large number of blastlike CD4+CD8+ cells which represent relatively immature thymocytes, whereas those on day 21 after BMT consisted of small sized CD4+,CD8+ cells which represent a great part in normal thymocytes. To define the developmental stage at which clonal deletion of self-reactive T cells occurs in adult thymus, we followed the fate of V beta 6- or V beta 11-bearing T cells in the donor-derived thymocytes at the early stage of AKR----C3H chimeras. Mature thymocytes expressing high intensity of V beta 6 or V beta 11, which are involved in recognition of Mls-1a or MHC I-E gene products, respectively, were deleted from the donor-derived thymocytes on day 21. Immature thymocytes expressing low intensity of V beta 6 in CD3low thymocyte fraction decreased in proportion, whereas those expressing low intensity of V beta 11 rather increased in proportion in the donor-derived thymocytes of AKR----C3H chimeras from day 14 to day 21 after BMT. These results suggest that the clonal deletion of V beta 6-positive cells occurs just at the stage of immature CD3lowCD4+CD8+ cells, whereas the clonal deletion of V beta 11-positive cells may begin at the transitional stage from CD3lowCD4+CD8+ cells to CD3high single positive cells. Timing of negative selection of thymocytes may vary in distinct T cells capable of recognizing different self-Ag.     

Responsiveness of fetal and adult CD4-, CD8- thymocytes to T cell activation

Day-14 fetal CD4-, CD8- thymocytes showed a greater proliferative response to PMA + IL-4 than did adult double-negative thymocytes. In contrast, adult double-negative thymocytes were more responsive to PMA + IL-1 + IL-2 or to IL-1 + IL-2 alone. The adult double-negative thymocytes showed significantly greater proliferation than fetal thymocytes after stimulation via anti-CD3 or anti-Thy-1 in the presence or absence of interleukins (IL-1 + IL-2 or IL-4). Adult CD4-, CD8- thymocytes also exhibited greater calcium mobilization following anti-CD3 stimulation IL-2-dependent activation with anti-Thy-1 or IL-1 + IL-2 in the absence of PMA resulted in marked expansion of CD 3+, F23.1+, CD4-, CD8- thymocytes, a population absent in fetal thymocytes but constituting 4% of pre-cultured CD4-, CD8- adult thymocytes. IL-4 + PMA failed to expand this CD 3+ population. It is hypothesized that before expression of functional TCR, T cell development may be more dependent on activation pathways not using IL-2; after TCR expression, IL-2-dependent pathways, including Thy-1-mediated stimulation, become functional.     

Evidence for the existence of distinct heterogeneity among the peripheral CD4-CD8- T cells from MRL-lpr/lpr mice based on the expression of the J11d marker, activation requirements, and functional properties

Autoimmune-susceptible, MRL-lpr/lpr (lpr) mice develop a profound lymphadenopathy resulting from the accumulation of CD4-CD8- (double-negative, DN) cells in peripheral lymphoid organs. The source and the mechanism of this abnormal accumulation of cells is still unknown. Recently, we reported that a significant number (approximately 35%) of the CD4-CD8- cells expressed J11d, a marker expressed by immature thymocytes but not by mature functional peripheral T cells. In the present study, we investigated the phenotype, growth requirements, and functional properties of purified J11d+ and J11d- subpopulations. Using the mAb, F23.1, which recognizes a TCR determinant encoded by the V beta 8 gene family, it was observed that approximately 30% of the J11d+ and J11d- DN cells expressed this determinant. Further studies on the thymus revealed that J11d+ DN cells from lpr thymus also contained F23.1+ cells (approximately 25%), whereas, similar cells from normal MRL(-)+/+mice were all F23.1-, consistent with earlier reports in other normal strains. Further phenotypic studies revealed that the peripheral J11d+ and J11d- cells from lpr mice were similar in expressing CD3, Ly-5 (B220), and Ly-24 (Pgp-1) determinants. When stimulated with phorbol myristic acetate (PMA) and recombinant IL-2 (rIL-2), only J11d- cells but not J11d+ cells responded by proliferation. However, in the presence of calcium ionophore (A23187) and PMA, both J11d+ and J11d- subpopulations proliferated by producing and responding to endogenous IL-2 but not IL-4. The lymph node T cells from 1-month-old MRL-lpr/lpr mice responded strongly when stimulated with PMA + rIL-4 or PMA + rIL-6. In contrast both J11d+ and J11d- subpopulations failed to respond when similarly stimulated. The J11d+ but not J11d- cells demonstrated spontaneous cytotoxic activity against the NK-sensitive YAC-1 tumor targets. The J11d- cells did not exhibit cytotoxic potential in spite of culture with PMA + rIL-2. Even after repeated culture in vitro with PMA + A23187 or PMA + rIL-2, both J11d+ and J11d- subpopulations failed to express the mature phenotype bearing CD4 and/or CD8 antigens. The present study demonstrates the expansion of unique J11d+, alpha beta-TCR+, DN T cells with cytotoxic potential in lpr mice and further suggests the existence of phenotypic and functional heterogeneity among the abnormal lpr DN cells.     

Cytokine production by mature and immature CD4-CD8- T cells. Alpha beta-T cell receptor+ CD4-CD8- T cells produce IL-4.

This study follows our previous investigation describing the production of four cytokines (IL-2, IL-4, IFN-gamma, and TNF-alpha) by subsets of thymocytes defined by the expression of CD3, 4, 8, and 25. Here we investigate in greater detail subpopulations of CD4-CD8- double negative (DN) thymocytes. First we divided immature CD25-CD4-CD8-CD3- (CD25- triple negative) (TN) thymocytes into CD44+ and CD44- subsets. The CD44+ population includes very immature precursor T cells and produced high titers of IL-2, TNF-alpha, and IFN-gamma upon activation with calcium ionophore and phorbol ester. In contrast, the CD44- subset of CD25- TN thymocytes did not produce any of the cytokines studied under similar activation conditions. This observation indicates that the latter subset, which differentiates spontaneously in vitro into CD4+CD8+, already resembles CD4+CD8+ thymocytes (which do not produce any of the tested cytokines). We also subdivided the more mature CD3+ DN thymocytes into TCR-alpha beta- and TCR-gamma delta-bearing subsets. These cells produced cytokines upon activation with solid phase anti-CD3 mAb. gamma delta TCR+ DN thymocytes produced IL-2, IFN-gamma and TNF-alpha, whereas alpha beta TCR+ DN thymocytes produced IL-4, IFN-gamma, and TNF-alpha but not IL-2. We then studied alpha beta TCR+ DN T cells isolated from the spleen and found a similar cytokine production profile. Furthermore, splenic alpha beta TCR+ DN cells showed a TCR V beta gene expression profile reminiscent of alpha beta TCR+ DN thymocytes (predominant use of V beta 8.2). These observations suggest that at least some alpha beta TCR+ DN splenocytes are derived from alpha beta TCR+ DN thymocytes and also raises the possibility that these cells may play a role in the development of Th2 responses through their production of IL-4.     

Expression of T cell antigen receptor beta-chains on subsets of mouse thymocytes. Analysis by three-color flow cytometry

The expression on adult mouse thymocytes of a T cell antigen receptor beta-chain epitope, recognized by the antibody F23.1, has been studied by three-color flow cytometry. Low density F23.1 staining was found mainly on CD4+8+ thymocytes. High density staining was mainly on CD4+8- and CD4-8+ cells. Variable proportions of CD4-8- cells were also F23.1+. Among CD4-8+ cells, F23.1 was expressed only on the J11d- subset with mature T cell function. We conclude that many subpopulations of thymocytes express antigen receptors and are candidates for the population subject to thymic selection, but at present no single subpopulation makes a convincing claim.     

Subpopulations of mature murine thymocytes: properties of CD4-CD8+ and CD4+CD8- thymocytes lacking the heat-stable antigen

The heat-stable antigen (HSA), recognized by the monoclonal antibodies M1/69, B2A2, and J11d, is low or absent on the surface of most murine peripheral T cells but present on all but 3% of thymocytes. The CD4-CD8+ and CD4+CD8- or "single positive" thymic populations may be divided into further subgroups based on surface HSA expression. One group, CD4-CD8+ and expressing very high levels of HSA (HSA++), is an immature, T cell antigen receptor (TcR) negative, outer cortical blast cell. However, a further subdivision of CD4-CD8+ and CD4+CD8- single positives may be made, into those negative to low for HSA (HSA-) and those expressing moderate amounts of HSA (HSA+). The proportion of HSA- single positives is low in the thymus of young mice, whereas the proportion of HSA+ single positives is similar to that of the adult. Both the HSA- and the HSA+ subsets of single positive thymocytes from adult mice are CD3+ and express the normal peripheral T cell incidence of V beta 8 determinants on the TcR. On stimulation with concanavalin A in limit-dilution culture both HSA- and HSA+ subsets of single positive thymocytes give a high frequency of proliferating clones, and the clones from both HSA- and HSA+ subsets of CD4-CD8+ thymocytes are cytotoxic. Thus both HSA- and HSA+ single positive thymocytes are functionally mature. The HSA- subsets of single positive thymocytes differ from the HSA+ subsets in being slightly larger in size, in expressing higher levels of MEL-14, in binding more peanut agglutinin, and in including a proportion of cells expressing high levels of the Pgp-1 glycoprotein. It is suggested that HSA- CD4-CD8+ and HSA- CD4+CD8- thymocytes are more mature than their HSA+ counterparts, and might represent a previously activated or "memory" thymic subpopulation.     

NK1.1+ thymocytes. Adult murine CD4-, CD8- thymocytes contain an NK1.1+, CD3+, CD5hi, CD44hi, TCR-V beta 8+ subset.

CD4-, CD8- thymocytes were purified from thymi obtained from normal C57BL/6 mice. By flow cytometry analysis, 5 to 10% of these double negative (DN) thymocytes were found to express NK1.1 on their surface. The NK1.1+ DN thymocytes were demonstrated, by two-color fluorescence, to be CD3lo, CD5hi, CD44hi, J11d-, B220-, MEL 14-, IL2R- with 60% expressing TCR-V beta 8 as determined by the mAb F23.1. In contrast, splenic and peripheral blood NK cells were NK1.1+, CD3-, CD5-, TCR-V beta 8- with 40 to 60% being MEL 14+. Unlike peripheral NK cells, fresh DN thymocytes enriched for NK1.1+ cells were unable to kill YAC-1, the classical murine NK cell target. However, these cells were able to mediate anti-CD3 redirected lysis even when they were assayed immediately after purification, i.e., with no culture or stimulation. These data demonstrate that adult murine thymocytes contain NK1.1+ cells which are distinct, both by function and phenotype, from peripheral NK cells. These data also raise the issue of a possible NK/T bipotential progenitor cell.     

Impaired clonal expansion in athymic nude CD8+CD4- T cells

A comparative study of the phenotype and immune functions of highly purified CD8+CD4- T cells obtained from the spleen and thymus of normal mice and from the spleen of athymic nude mice was conducted. Of seven individual normal and nude mice examined, the range of V beta 8+ cells among CD8+ T cells was a heterogeneous 4.3 to 30.5% for athymic nude mice and a much more uniform spread from 14.7 to 18.5% for normal mice. In six of the seven nude mice examined, the fraction of V beta 8+ cells was below the lower limit of the V beta 8 distribution in normal mice. However, one of the seven nude mice contained nearly twice the percentage of normal V beta 8+ cells. A reduction in the density of V beta 8 as well as CD3 Ag expression was also observed in athymic CD8+CD4- cells although an Ly-6-linked Ag, B4B2 displayed a highly increased expression. Considering the battery of Ag analyzed in entirety, athymic CD8+CD4- T cells were clearly distinct from their "counterpart" CD8+CD4- T cells isolated from either thymus or spleen of normal (euthymic) mice. Anti-CD3-mediated triggering of the TCR:CD3 complex caused extensive clonal proliferation in cultures to which single responding CD8+ T cells had been deposited. Under identical conditions, however, anti-CD3 caused little, if any clonal expansion in CD8+ cells from athymic nude mice. Highly purified athymic CD8+CD4- cells produced readily detectable IL-2R expression and IL-2 synthesis and secretion upon stimulation by anti-CD3 and by Con A. Production of IL-2 by purified athymic CD8+CD4- cells was due to CD8+CD4- cells and not due to a minor population of contaminating CD8- cells as anti-CD8 + C treatment completely abrogated the ability of athymic CD8+CD4- cells to produce IL-2. Despite IL-2 production and IL-2R expression by athymic nude CD8+CD4- T cells in response to anti-CD3 and to Con A, an impaired proliferative response followed.     

Expression of T cell receptors by thymocytes: in situ staining and biochemical analysis.

We have examined the in situ expression of T cell receptor (TCR) V beta 8 protein in murine thymus during ontogeny using the monoclonal antibody F23.1. Positive cells were first detected at day 15 of gestation (0.6%). By day 16 the frequency of positive cells increased dramatically (4.18%). From day 16 to day 17 positive cells doubled (8.17%). The first clusters of F23.1 positive cells were seen at day 17. In the cortex, positive cells decreased from 14% in the newborn mice to 9.8% in 8-week-old mice, whereas in the medulla the frequency remained unchanged at 20%. The antibody F23.1, as well as an antiserum raised against the constant region of the beta chain, immunoprecipitated receptor dimers from highly purified Lyt2+, L3T4+ thymocytes and from two thymic lymphomas of cortical phenotype which express full size alpha and beta mRNA. The receptor dimer could not be precipitated from Lyt2-, L3T4- thymocytes. The results are discussed with regard to intrathymic T cell repertoire selection.     

Characterization and differentiation of CD4-, CD8- thymocytes sorted with the Ly-24 marker

Heterogeneity within the CD4-, CD8- thymocyte population was explored by flow microfluorometry on thymocytes from 6-wk-old female C57BL/6 mice. Double negative cells were obtained by twice killing thymocytes with anti-CD4 and anti-CD8 antibodies. The resultant population lacked CD4, CD8, and Ig on cell surfaces; it contained cells bearing Ly-24 (27%), Ly-6C (6%), and Ly-5 (B220) detected by 6B2 (6%). These markers are the same as those characteristic of lpr/lpr T cells; they also are found on bone marrow cells. In order to investigate the maturational pathway of CD4-, CD8- thymocytes, such cells were cultured in vitro for 6 days with phorbol myristate acetate + calcium ionophore. There was a marked increase in cells bearing Ly-24 with time; by 6 days essentially all bore Ly-24. A lesser increase (to 15%) in 6B2 + Thy-1 positive cells was observed. Small numbers of cells bearing CD4 and/or CD8 also were found after 6 days in vitro. In additional studies, CD4-, CD8- cells were first sorted with respect to Ly-24 and then cultured with phorbol myristate acetate + calcium ionophore. Ly-24+ cells proliferated vigorously and formed clusters whereas Ly-24- cells did not. The former gave rise to large numbers of CD4+, CD8+ cells; the latter exhibited little differentiation. These studies demonstrate substantial heterogeneity within the CD4-, CD8- thymocyte population. Use of the markers Ly-24, Ly6C, and 6B2 allows a subdivision of such progenitor thymocytes. Different stages of maturation as well as possible lineages of cells may be investigated by combining such hemopoietic cell surface markers with in vitro culture.     

Peripheral murine CD3+, CD4-, CD8- T lymphocytes express novel T cell receptor gamma delta structures

A mAb directed against the CD3 molecule was used to identify a subset of CD3+, CD4-, CD8- T cells previously undefined in the peripheral lymphoid organs of the mouse. Biochemical analysis of CD3+, CD4-, CD8- splenocytes revealed that the vast majority of these cells express one of at least two distinct CD3-associated TCR gamma delta heterodimeric structures, but no detectable TCR alpha beta. One disulfide-linked heterodimer (77 kDa) is composed of two chains of 45 to 46 and 32 kDa. The latter chain was immunoprecipitated with an anti-TCR C gamma 1/C gamma 2 antiserum and was not glycosylated. An antiserum produced against a peptide corresponding to the C-terminal region of the predicted C gamma 4 gene product immunoprecipitated additional heterodimers (80 to 90 kDa). One heterodimer, composed of disulfide-linked 41- to 45-kDa protein (including a V gamma/C gamma 4 component), is expressed on a T cell hybridoma, DN-1.21, which was derived from fused splenic CD3+, CD4-, CD8- T cells. Another V gamma/C gamma 4-containing heterodimer is composed of disulfide-linked 46- to 47-kDa glycoproteins. These findings demonstrate that CD3+, CD4-, CD8- T cells present in the peripheral lymphoid organs express a variety of paired TCR gamma delta proteins. Unlike CD3+, CD4-, CD8- thymocytes, these cells express high levels of C gamma 4, but little, if any TCR alpha beta.     

Deviations in thymocyte development induced by divalent and monovalent ligation of the alpha/beta T cell receptor and by its cross-linking to CD8

Fetal thymic organ cultures (FTOC) were tested as a model system to induce, in a polyclonal fashion, negative and positive thymic selection events. By flow cytometry, thymocytes developed in FTOC differed in several parameters from their in vivo differentiated counterparts. In particular, no clear distinction was possible between CD4+CD8+ immature cells with low TCR expression and mature CD4+ or CD8+ cells with high TCR expression. Thymocyte development in FTOC was manipulated with three different antibody reagents: anti-V beta 8 (F23.1), anti-Lyt-2.2 (19/178) and the quadroma derived bifunctional antibody HPHT-2, carrying one binding site of each. This antibody served also as a monovalent anti-V beta 8 reagent in FTOC from Lyt-2.1 mouse strains. Antibody 19/178 suppressed the development of single positive CD8+ cells, but only at very high concentrations. F23.1 and HPHT-2 suppressed the development of CD4+V beta 8+ and CD8+V beta 8+ thymocytes at relatively low concentrations giving rise to V beta 8 occupancies from about 2% upwards. Suppression was equally pronounced in cells with low and high TCR densities. Moreover, V beta 8 suppression occurred upon divalent and monovalent V beta 8 binding and was not significantly influenced by V beta 8-CD8 cross-linking. This suggests that ligation of the TCR alone is sufficient for clonal deletion. The data do not exclude a role for CD8 as an accessory adhesion molecule but suggest that exogenous cross-linking of CD8 to the TCR is not essential in transmembrane signaling for clonal deletion. At lower antibody concentrations giving rise to V beta 8 occupancies below detection, V beta 8-CD8 cross-linking by HPHT-2, but no divalent and monovalent V beta 8 ligation, induced an increase of CD8+V beta 8+ cells at the expense of CD4+ V beta 8+ cells with no change in the proportion of total V beta 8+ thymocytes. The latter effect was quantitatively of borderline significance but reproducible. These latter results are compatible with the hypothesis that cross-linking of the alpha beta TCR and CD8 on the thymocyte surface provides a maturation signal resulting in loss of CD4 from CD4+ CD8+ double positive immature thymocytes.     

Activation of CD 4-, CD 8- thymocytes with IL 4 vs IL 1 + IL 2

Thymocytes from C57BL/6 mice were highly purified to obtain the CD 4-, CD 8- subpopulation which constitutes only 5% of all thymocytes. Substantial proliferation was induced in vitro with either IL-1 + IL-2 or with IL-4 in the presence of PMA. IL-1 and IL-2 synergized in inducing proliferation of these purified CD 4-, CD 8- thymocytes whereas neither synergized with IL-4. In order to determine whether stimulation with IL-1 + IL-2 acted via IL-4 or vice versa, cultures were treated reciprocally with affinity-purified anti-IL-2 or anti-IL-4 antibodies. Cultures with IL-4 were inhibited by anti-IL-4 but were unaffected by anti-IL-2. The CD 4-, CD 8- thymocytes cultured with IL-1 + IL-2 + anti-IL-2 were inhibited to baseline IL-1 stimulation. At low concentrations of IL-1 (1 U/ml) and IL-2 (100 U/ml), anti-IL-4 had no effect, whereas at higher levels of IL-1 (2 U/ml IL-1), and 100 or 200 U/ml IL-2, anti-IL-4 significantly reduced DNA synthesis. This result suggests that at higher concentrations the combination of IL-1 + IL-2 can induce cells to produce IL-4 which then contributes to overall proliferation. When CD 4-, CD 8- thymocytes were cultured with the low doses of IL-1 + IL-2 for 72 h, 62% expressed cell surface T3 complex (vs 11% at initiation) and 27% were F23.1+ (vs 5% at initiation). In contrast, culture with IL-4 led to no increase in numbers of T3+ cells and none were F23.1+; however, there was coexpression of Thy1 and 6B2 on 20% of cells at the end of culture (vs 4% at initiation). Thus, IL-1 + IL-2 causes expansion of a CD 4-, CD 8- thymocyte population expressing the alpha, beta-T cell receptor, whereas IL-4 induces cells to express a phenotype present in small numbers in the periphery of normal mice and in larger numbers in mice bearing the lpr gene.     

Participation of L3T4 in T cell activation in the absence of class II major histocompatibility complex antigens. Inhibition by anti-L3T4 antibodies is a function both of epitope density and mode of presentation of anti-receptor antibody

The recognition of many class II major histocompatibility complex (MHC)-associated antigens by T cells requires the participation of the L3T4 molecule. It has been proposed that this molecule acts to stabilize low affinity binding to antigen in association with MHC and thereby increases the avidity of T cell/antigen interactions. By using antibodies against the T cell antigen receptor (TCR) to activate T cells, thereby circumventing the requirement for antigen presenting cells and MHC-associated antigen, we have been able to study the function of L3T4 in the absence of class II MHC. We have used two monoclonal antibodies, KJ16-133.18 and F23.1, that recognize a determinant encoded by the T cell receptor V beta 8 gene family. These antibodies were used to select two clones of T cells with surface phenotype Thy-1.2+, L3T4+, Lyt-2-, KJ16-133.18+, F23.1+, IA-, IE-. One of these clones (E9.D4) was hapten-specific (anti-ABA + Iak), the other (4.35F2) was alloreactive (anti-Iak). Activation of these clones by antigen, concanavalin A (Con A) or by the F23.1 antibody was studied by assaying the production of interleukin 3 (IL 3). Both soluble and solid phase-coupled F23.1 induced T cell activation in the complete absence of class II MHC, immobilized antibody (either Sepharose-coupled or plastic-adsorbed) being more effective. The induction of IL 3 production by suboptimal doses of either Con A or plastic-adsorbed F23.1 was inhibited by the anti-L3T4 antibody GK1.5, as was the response to F23.1 coupled to Sepharose-4B beads. However, the responses to optimal or superoptimal doses of these stimuli were not inhibited. In contrast, weak responses to non-TCR cross-linking stimuli such as phorbol myristate acetate (PMA) or low concentrations of soluble F23.1 were not inhibited by GK1.5 (the latter response was usually slightly enhanced). These results show that anti-L3T4 antibodies are not inherently inhibitory, but require both ligation and cross-linking of the TCR for their effect. We propose a model whereby L3T4 interacts with the TCR during T cell activation. Anti-L3T4 antibodies sterically hinder the formation of TCR complexes and so prevent activation. However, by increasing the epitope density of the activating ligand, the avidity of the T cell/ligand interaction can be increased sufficiently to prevent this disruption.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.