Existence of mature human CD4+ T cells with genuine class I restriction.

A human T cell receptor (TcR) alpha/beta CD4+CD8-T cell clone (R416) is reactive with the minor histocompatibility antigen H-Y in the context of major histocompatibility complex (MHC) class I and not class II molecules. Therewith clone R416 violates the so-called specificity association of mature TcR alpha/beta+ T cells. R416 displays H-Y-specific, HLA-A2-restricted proliferation as well as cytotoxicity in vitro. Its fine specificity is identical to that of a classical H-Y-reactive CD4-CD8+ MHC class I-restricted CTL clone, showing that CTL expressing either CD4 or CD8 can display identical antigenic specificities. Exploiting the MHC class I restriction of this CD4+ T cells clone, it was found that interaction of CD4 with non-TcR-bound MHC class II molecules does not contribute to antigen specific activation of these CD4+ T cells. This coreceptor-mismatched T cell clone was not generated in vitro but obtained by expansion of CD8-depleted peripheral blood mononuclear cells of a female who had been immunized against H-Y. The existence of such MHC class I-restricted mature TcR alpha/beta+ T cells expressing CD4 and not CD8 is relevant because it indicates that the generally accepted model for thymic selection, in which the TcR specificity alone determines CD4/CD8 expression of mature thymocytes, may not be absolute.     

Cross-linking of the T cell antigen receptor interferes with the generation of CD4+8+ thymocytes from their immediate CD4-8+ precursors

The majority of thymocytes are immature cells co-expressing the surface markers CD4 and CD8. About two thirds of these cells also express the T cell antigen receptor (TcR), though at a level distinctly lower than found on mature T cells. The direct precursors of these "double-positive" thymocytes are cycling cortical blast cells of the CD4-8+ phenotype. Using a new monoclonal antibody to a constant determinant of the rat TcR alpha/beta, it is shown here that (a) about 50% of these CD8 "single-positive" committed precursor cells already express the TcR alpha/beta, though at very low levels, (b) during short-term suspension culture in medium supplemented only with fetal calf serum they not only acquire CD4 but also TcR alpha/beta levels characteristic of CD4,8 "double-positive" thymocytes, and (c) cross-linking of the TcR during culture inhibits the acquisition of the CD4 antigen in the majority of these cells.     

Phenotypical and Functional Characterization of Small Intestinal TcRγδ+ T Cells in Coeliac Disease

Increased numbers of TcR gamma delta + T cells are present in the small intestinal epithelium of patients with coeliac disease (CoD). Their function, however, is unknown. In order to facilitate detailed functional studies, intestinal gamma delta T cells have been isolated from small intestinal biopsies of patients with CoD (n = 18) and controls (n = 14). As expected, increased numbers of V delta 1+ TcR gamma delta + T cells were detected in freshly isolated intraepithelial cell suspensions (IEL) from CoD patients. Also, in the in vitro expanded IEL T-cell populations from CoD patients the numbers of V delta 1+ TcR gamma delta + T cells were increased compared with similar cell cultures from control patients. From IEL cultures derived from six CoD patients, 107 T-cell clones were generated by limiting dilution and analysed. Sixty of these clones were either CD4 or CD8 positive TcR alpha beta + clones. The remaining 47 clones expressed the TcR gamma delta. Further phenotypical analysis of the gamma delta T-cell clones indicated that the TcR gamma delta + T-cell population in the small intestinal epithelium of CoD patients is heterogeneous: four TcR gamma delta phenotypes could be detected and, although the majority of the TcR gamma delta + T cells were CD4 CD8, gamma delta T-cell clones expressing either a CD8 alpha alpha homodimer, a CD8 alpha beta heterodimer or CD4 were also identified. In contrast to the TCR alpha beta + IEL, most TcR gamma delta + IEL were CD5 negative. Furthermore, biochemical analysis indicated that the increase in V delta 1+ gamma delta T cells in the small intestinal epithelium of CoD patients was not the result of a monoclonal expansion. The small intestinal epithelium-derived gamma delta T-cell clones were functional in vitro since the majority of these clones were able to lyse target cell lines such as K562. Molt4 and Daudi. These novel findings therefore indicate that the gamma delta T cells in the small intestine of CoD patients represent a heterogeneous population and that such cells are functional in vitro. The isolation and the in vitro propagation and cloning of these cells may open new avenues for the study of the putative immune mechanisms leading to coeliac disease.     

The organotin-induced thymus atrophy, characterized by depletion of CD4+ CD8+ thymocytes, is preceded by a reduction of the immature CD4- CD8+ TcR alpha beta-/low CD2high thymoblast subset.

Thymic changes in the rat induced by the thymus atrophy-inducing organotin compound di-n-butyltin dichloride (DBTC) were examined using FACS analyses. The number of CD4+CD8+ thymocytes was reduced by DBTC treatment from Day 2 onwards and reached minimum level on Days 4 and 5 after dosing. On these days the CD4-CD8- and both the CD4-CD8+ and CD4+CD8- subsets were not affected. On Day 2 we observed a reduced proportion of transferrin receptor (CD71)-positive CD4-OX44- cells, representing the cycling immature CD4-CD8+ cells, and of CD71+OX44- cells, representing the cycling CD4+CD8+ cells, but not of CD71+CD4-CD8- cells. When compared to controls, the FSChigh cell population of DBTC-treated rats contained less CD4-OX44- and OX44- cells, which were further characterized as CD2high and T-cell receptor (TcR)alpha beta- low. Moreover, fewer TcR alpha beta high cells were detected in the OX44- thymoblast subset of DBTC-treated rats. The number of CD4-CD8- thymoblasts appeared marginally decreased while the numbers of CD4+OX44+ cells, representing mature CD4+ cells, were not affected. These data indicate that DBTC causes a preferential initial depletion of immature CD4-CD8+CD2high TcR alpha beta-low thymoblasts. This initial event may result in a decreased formation of CD4+CD8+ thymoblasts and of small CD4+CD8+ thymocytes. These characteristics of the initially depleted subset indicate a specific anti-proliferative effect of DBTC and may give clues for the mechanism involved in the induction of thymus atrophy.     

Patterns of membrane TcR alpha beta and TcR gamma delta chain expression by normal blood CD4+CD8-, CD4-CD8+, CD4-CD8dim+ and CD4-CD8- lymphocytes.

Enriched CD4+CD8-/CD4-CD8-, CD4-CD8+/CD4-CD8- and CD4-CD8- cell suspensions were prepared from normal peripheral blood by selective immunomagnetic depletion of monoclonal antibody-defined lymphocyte populations. Subsequent examination of these modified cell fractions by two-colour flow cytometry provided a means of determining the expression of membrane T-cell receptor (TcR)alpha beta and TcR gamma delta chains by both major (CD4+ and CD8+) and minor (CD3+CD4-CD8dim+ and CD3+CD4-CD8-) lymphocyte subpopulations. Normal CD4+CD8- lymphocytes were almost invariably (greater than 99%) TcR alpha beta+, whereas lymphocytes expressing membrane CD8, which could be further subdivided according to differences in fluorescent staining intensity into CD3+CD4-CD8+, CD3+CD4-CD8dim+ and CD3-CD4-CD8dim+ components, were characterized by distinct differences in patterns of TcR chain expression. In contrast to CD3+CD4-CD8+ cells, which were predominantly (99%) TcR alpha beta+, CD3+CD4-CD8dim+ lymphocytes showed a significant proportion (33%) of TcR gamma delta+ cells (natural killer-associated CD3-CD4-CD8dim+ cells were uniformly TcR-). The highest proportion (62%) of TcR gamma delta+ cells was associated with the CD3+CD4-CD8- fraction, but these studies also revealed that a significant minority of this population was TcR alpha beta+. Despite some evidence for normal inter-individual variation, further analysis of membrane CD8 fluorescent intensities confirmed clear differential relationships for TcR alpha beta and TcR gamma delta chain expression.     

Membranes of activated CD4+ T cells expressing T cell receptor (TcR) alpha beta or TcR gamma delta induce IgE synthesis by human B cells in the presence of interleukin-4.

In the present study it is demonstrated that human B cells can be induced to switch to IgE production following a contact-mediated signal provided by activated T cell receptor (TcR) gamma delta+, CD4+ and TcR alpha beta+, CD4+ T cell clones and interleukin (IL)-4. The signal provided by these T cell clones was antigen nonspecific, indicating that the TcR alpha beta/CD3 or TcR gamma delta/CD3 complexes were not involved in these T-B cell interactions. Activated TcR alpha beta+, CD8+, and TcR gamma delta+, CD4-CD8-, or resting CD4+ T cell clones were ineffective. Intact TcR alpha beta+ or TcR gamma delta+, CD4+ T cell clones could be replaced by plasma membrane-enriched fractions isolated from these activated CD4+ T cell clones. In contrast, membranes isolated from resting TcR alpha beta+, CD4+, TcR gamma delta+, CD4+ T cell clones or an Epstein-Barr virus (EBV)-transformed B cell line (EBV-LCL) failed to provide the costimulatory signal that, in addition to IL-4, is required for induction of IgE synthesis. As described for intact CD4+ T cells, CD4+ T cell membranes induced purified surface IgM+ B cells to switch to IgG4- and IgE- but not to IgA-producing cells, excluding the possibility of a preferential outgrowth of IgG4- and IgE-committed B cells. The membrane activity was inhibited by protease or heat treatment. Induction of IgE synthesis by B cells co-cultured with both TcR alpha beta+, CD4+ and TcR gamma delta+, CD4+ T cell clones and membrane preparations of these cells was blocked by anti-class II major histocompatibility complex (MHC) monoclonal antibodies (mAb), whereas various anti-CD4 mAb had differential blocking effects. Murine L cells, or EBV-LCL transfected with CD4 could not replace CD4+ T cell clones. These results indicate that, although CD4 and class II MHC antigens are required for productive CD4+ T cell clone-B cell interactions, an additional signal, provided by a membrane associated (glyco)protein that is induced by activation of both TcR alpha beta and TcR gamma delta, CD4+ T cells, is needed for induction of IgE production in the presence of IL-4.     

Age-associated increase in number of CD4+CD8+ intestinal intraepithelial lymphocytes in rats.

A significant number of CD4+CD8+ T cells were detected in intestinal intraepithelial lymphocytes (IEL) of various strains of rats including Wistar, WKA, BN, LEW and F344. The site of the CD4+CD8+ population in IEL increased with age in all strains we examined. Most IEL bearing CD8 expressed no CD5 antigen in young rats, while all CD4+CD8+ IEL and some of CD8+ IEL in aged rats were of CD5+CD45RB- phenotype. In germ-free Wistar rats, age-associated increase in the number of CD4+CD8+CD5+ IEL was not evident, indicating that stimulation by the intestinal microflora was important for expansion of the CD4+CD8+CD5+CD45RB- IEL. Aged athymic F344 nude rats contained appreciable numbers of CD4+ IEL and CD8+ IEL but few CD4+CD8+ IEL, suggesting that the CD4+CD8+ IEL may be derived from thymus-dependent populations. Unlike a majority of CD4+CD8+ thymocytes bearing a low intensity of CD3/T cell receptor (TcR) alpha/beta, the CD4+CD8+ T cells in IEL expressed a high intensity of CD3/TcR alpha/beta on their surface. The CD4+CD8+ IEL appear to contribute to the spontaneous proliferation of the IEL in aged rats as assessed by tritiated thymidine incorporation after in vitro culture with medium only. These results suggest that with aging a unique CD4+CD8+ IEL may expand at a local site of the intestine under the influence of intestinal microflora and may contribute to the first line of defense against various pathogens in the epithelium.     

Repertoire of V alpha and V beta regions of T cell antigen receptors on CD4+ and CD8+ peripheral blood T cells in a novel X-linked combined immunodeficiency disease.

The repertoire of V regions of alpha/beta+ T cell receptor (TcR) on CD4+ and CD8+ T cells from the peripheral blood of six patients with a novel X-linked combined immunodeficiency was investigated by flow cytometry. The relative frequencies of V region subfamilies V alpha 2a on CD4+ T lymphocytes and V beta 5b and V beta 12a on CD8+ T lymphocytes from the peripheral blood from the affected males were decreased significantly. Also, the relative frequencies of certain other V region subfamilies on CD4+ or CD8+ T cells from the peripheral blood of some patients were either considerably below or above the ranges found in normal subjects. Although there may be other explanations including an extrathymic event, we suggest that the abnormalities in the TcR repertoire of peripheral blood T cells are consistent with a dysregulation of the intrathymic maturation/selection of T cells that leads to deficiencies in T cell populations in the peripheral blood of males with this disease.     

Presence of murine fetal liver cells capable of being induced to differentiate in vitro into T cell receptor-positive cells.

Mouse fetal liver cells were analyzed for the surface expression of T cell markers. Fetal liver cells prepared from mouse embryos at 14.5 days of gestation contained a small number of CD4+ cells (1.4%), but virtually no cells positive for any other T cell markers such as CD8, CD3 and T cell receptor (TcR). When a fetal liver cell suspension prepared from BALB/c(male) x AKR(female) F1 embryos at 14.5 days of gestation was cultured in medium supplemented with culture supernatants of both WEHI-3 and concanavalin A-stimulated rat spleen cells, TcR alpha beta+ and CD4+ cells were generated, whereas CD8+ and TcR gamma delta+ cells were hardly detectable. Most of TcR alpha beta+ and CD4+ cells were H-2d+, thus clearly showing their fetal origin. Treatment with anti-CD4, anti-CD3 or anti-TcR alpha beta antibodies plus complement or electronic sorting to remove cells expressing these markers failed to inhibit the generation of T cell marker-positive cells following culture in vitro. On the other hand, depletion of Thy-1.2+ cells reduced their generation. These findings indicate the presence of some progenitor T cells in fetal liver with the Thy-1+, CD3-, CD4-, CD8-, TcR- phenotype, which can be induced to differentiate into TcR alpha beta+ cells in the presence of specific humoral supplements without the influence of the thymus.     

Differential expression and regulation of the human CD8α and CD8β chains

The CD8 glycoprotein is expressed by thymocytes, mature T cells and natural killer (NK) cells and has been implicated in the recognition of monomorphic determinants on major histocompatibility complex (MHC) Class I antigens, and in signal transduction during the course of T-cell activation. Both human and rodent CD8 antigens are comprised of two distinct polypeptide chains, alpha and beta. The majority of monoclonal antibodies (mAb) reactive with the human CD8 antigen bind the CD8 alpha chain, while a single mAb, T8/2T8-5H7, has been identified which binds to the CD8 alpha/beta heterodimer. While the two chains of CD8 have been presumed to be coordinately expressed in normal T cells, this is not always the case. Northern blot analysis of a panel of T-cell leukemias and normal cells demonstrate that CD8 alpha and CD8 beta are not invariably co-transcribed and phenotypic analysis of fresh and interleukin 2 (IL-2) expanded peripheral blood mononuclear cells (PBMC) confirm that the CD8 alpha and CD8 beta chains are differentially expressed at the cell surface. Four distinct subpopulations of CD8+ cells have been identified based on the expression of CD8 alpha/alpha or CD8 alpha/beta complexes: (1) T-cell receptor (TcR) alpha beta+ T cells which are CD8 alpha+/beta+; (2) TcR alpha beta+ T cells which are CD8 alpha+/beta-; (3) TcR gamma delta+ T cells which are CD8 alpha+/beta- and (4) natural killer (NK) cells which are CD8 alpha+/beta-. We also demonstrate the down-regulation of the CD8 alpha/beta heterodimers from the surface of a CD8+ T-cell clone following treatment with phorbol myristate acetate (PMA) while CD8 alpha/alpha homodimers remain on the cell surface. This observation demonstrates that a) a CD8+ T-cell clone can express both CD8 alpha/alpha homodimers and CD8 alpha/beta heterodimers and b) these two complexes do not have identical biological properties. Together, these data suggest that CD8 alpha/alpha and CD8 alpha/beta dimers may not subserve identical functions. The differential contribution of these two CD8 complexes should be considered in models of T-cell-mediated cytotoxicity and T-cell activation.     

Preferential positive selection of V alpha 2+ CD8+ T cells in mouse strains expressing both H-2k and T cell receptor V alpha a haplotypes: determination with a V alpha 2-specific monoclonal antibody.

A monoclonal antibody, B20.1, was generated by fusing spleen cells from a Lou rat immunized with a soluble alpha/beta T cell receptor (TcR; V alpha 2/V beta 2) to mouse myeloma cells. Analysis of a panel of V alpha 2 mRNA-expressing T cell lines, hybridomas and transfectants revealed that the B20.1 antibody was specific for murine TcR V alpha 2 chains. The V alpha 2+ T cell population was examined in various inbred strains by two-color immunofluorescence using B20.1 and CD4- and CD8-specific antibodies with the following results: (a) the B20.1 antibody detected most members of the TcR V alpha 2 subfamily in the four TcR V alpha haplotypes tested; (b) in most strains examined, TcR V alpha 2 expression was biased to the CD4 subset (7.4%-17.4% V alpha 2+ T cells) as compared to the CD8 compartment (3.8%-13.3%); (c) TcR V alpha 2 expression was not influenced by Mls gene products and (d) increased positive selection of V alpha 2+ CD8+ T cells by H-2k major histocompatibility complex molecules occurred in all murine strains tested of the TcR V alpha a, but not in those bearing the TcR V alpha b haplotype.     

Rat "first-wave" mature thymocytes: cycling lymphoblasts that are sensitive to activation-induced cell death but rescued by interleukin 2

The sequential appearance of thymocyte subsets in rat ontogeny was studied using the surface markers CD4, CD8, and the alpha/beta T cell receptor (here referred to as TcR). It was noted that the first TcRhigh thymocytes, appearing around birth, are not resting lymphocytes but cycling blast cells. These "first wave" TcRhigh cells are medullary in location and predominantly of the CD4/CD8 "single-positive" phenotype. Only about 5% express the light chain of the interleukin (IL)2 receptor, indicating that binding of IL 2 to high-affinity receptors is not driving proliferation of these blasts. Newborn TcR high blast cells were purified and analyzed in vitro. When cultured without further additions, they rapidly stopped cycling. Stimulation with cross-linked anti-TcR monoclonal antibody plus IL 2 resulted in vigorous and rapid proliferation that exhibited accelerated kinetics as compared to peripheral resting T cells. In contrast, TcR cross-linking without exogenous IL 2 induced cell death. This TcR-induced cell death involved fragmentation of DNA characteristic of apoptosis that was readily detectable within 18 h of culture. Addition of IL 2 to these short-term cultures prevented TcR-induced DNA fragmentation. Together, these results suggest that in newly formed TcRhigh thymocytes, TcR engagement results in clonal deletion if the IL 2 receptor remains unoccupied but allows clonal expansion if IL 2 is provided. This mechanism may be operative in the establishment of self-tolerance during T cell development.     

Effects of cyclosporin A on T-cell development in organ-cultured foetal thymus.

The effects of cyclosporin A (CsA) on T-cell development were assessed in an organ culture of murine foetal thymus. Applying three-colour flow cytometric analysis, we showed that the agent inhibits the development of mature CD3/T-cell receptor alpha beta (TcR alpha beta)+ cells both in CD4+8- and CD4-8+ populations. CD4-8- cells appeared to be accumulated by CsA. We examined the heterogeneity of CD4-8- cells generated in the organ culture, and defined five subpopulations by the expression of the cell-surface molecules CD3/TcR, J11d and CD25. It has been demonstrated that only the CD3/TcR alpha beta+ J11d- CD25- subpopulation is susceptible to the suppressive effects of CsA among CD4-8- cells, whereas all the other four subpopulations, including CD3/TcR gamma delta+ cells, are resistant. Thus, all of the TcR alpha beta-bearing cells, including CD4-8- cells but none of the TcR alpha beta- cells, are CsA sensitive. Because it is known that CsA inhibits the TcR-mediated signalling events in mature T cells and that signallings mediated via the interaction of TcR with major histocompatibility complex (MHC) molecules on thymic stroma cells are crucial for thymic selection of T cells, these results indicate that TcR alpha beta-bearing CD4-8- cells but not TcR gamma delta-bearing CD4-8- cells undergo thymic positive selection.     

Autoreactive T cells in normal mice: unrestricted recognition of self peptides on dendritic cell I-A molecules by CD4-CD8- T cell receptor alpha/beta+ T cell clones expressing V beta 8.1 gene segments

CD4-CD8- double-negative (DN) and CD4+CD8- T cell clones were derived from splenic precursors resistant to killing by anti-Thy-1, -CD5, -CD4 and -CD8 monoclonal antibodies and complement. Both DN and CD4+ clones express functional T cell receptor (TcR) alpha/beta and exhibit strong autoreactivity in vitro. DN cells can be induced to proliferate by dendritic cells (DC) of all haplotypes tested, although this activation is inhibited by antibodies specific for I-A determinants expressed on the stimulatory DC. In contrast, CD4+ clones only respond to syngeneic or I-Ad-compatible DC. Both DN and CD4+ autoreactive clones do not proliferate when cultured with class II+ H-2d normal or tumor macrophages and B cell lines or with class II-transfected L cells, suggesting that these cells recognize self peptides only present on the surface of DC. Despite their phenotype resembling that of immature thymocytes and their inability to interact directly with B lymphocytes, DN cloned T cells, like CD4+ T cells, exhibit nonspecific helper functions and can induce polyclonal B cell proliferation and differentiation. DN TcR alpha/beta+ peripheral T cells represent, like TcR gamma/delta+ lymphocytes, a new T cell subset physiological role whose remains to be defined.     

Selective expansion of a specific anti-tumor CD8+ cytotoxic T lymphocyte clone in the bulk culture of tumor-infiltrating lymphocytes from a melanoma patient: cytotoxic activity and T cell receptor gene rearrangements

In vitro culture of metastatic melanoma fragments with 150 units of recombinant interleukin 2 resulted in the successive expansion of CD4+ and then CD8+ tumor-infiltrating lymphocytes (TIL) throughout a 2-month period. TIL cultured for 43 days and consisting of 95% CD8+ and 10% CD4+ T lymphocytes were cloned by limiting dilution (LD). Thirteen CD8+ and thirty-one CD4+ clones were obtained, indicating that the frequency of clonogenic CD8+ proliferative T lymphocytes was much lower than that of their CD4+ homologues. When LD was performed in the presence of autologous melanoma cells the frequency of CD8+ clones was increased by factor 4. The DNA from TIL of day 43 bulk culture and of six CD8+ clones was hybridized with T cell receptor (TcR) beta and gamma probes. Identical configuration of the nonfunctional gamma and functional beta TcR genes was found in "bulk culture" and cloned TIL. The CD8+ clones therefore derived from a clonal population of CD8+ cells which had expanded in vitro before the LD. All the CD8+ clones tested were strongly cytotoxic for autologous melanoma cells but did not kill autologous fibroblasts or concanavalin A blasts, or any of the 10 allogeneic tumor targets tested, including 5 melanomas, 2 breast cell lines, 1 neuroblastoma, K-562 and the Epstein-Barr virus-transformed cell line used as a feeder. Furthermore, specific killing was inhibited by monoclonal antibodies against CD3, CD8, TcR alpha/beta and against class I major histocompatibility complex antigens indicating that these cytotoxic T lymphocyte clones recognized autologous tumor cells through the TcR, in an HLA class I-restricted manner. These data show that it is feasible to obtain tumor-specific cytotoxic T lymphocytes from melanoma TIL with a simple culture technique and that a single clone could be expanded to more than 10(10) cells which should allow testing of immunotherapeutic potential of these cells by adoptive transfer into melanoma patients.     

Phenotypic heterogeneity of intraepithelial T lymphocytes from mouse small intestine.

We have used two-colour flow cytometry to examine the heterogeneity of intraepithelial lymphocytes (IEL) from mouse small intestine. We have confirmed the predominance of CD3+ Thy 1- CD8+ IEL and show that a substantial but variable proportion of CD8+ IEL does not express the alpha beta T-cell receptor (TcR) for antigen. Simultaneous analysis of the co-expression of the alpha and beta chains of the CD8 heterodimer and of the alpha beta TcR revealed three populations of CD8+IEL. The first of these expressed both CD8 alpha and beta chains and had normal expression of V beta families and so represented conventional CD8+ alpha beta TcR+ T cells. The second population comprised alpha beta TcR- T cells (presumed gamma delta TcR+) which expressed only the alpha chain of the CD8 molecule. Finally, we identified a second, unique population of alpha beta TcR+ CD8+ IEL which were also CD8 beta-. Gamma delta + IEL predominated in mice aged less than 8 weeks, but there was a rapid increase in both populations of alpha beta TcR+ CD8+ IEL in older mice. CD8+ IEL were similar to peripheral CD8+ T cells in having high expression of the CD45RB molecule, but CD4+ IEL had generally lower expression of CD45RB than their peripheral counterparts, despite having normal expression of TcR. These findings emphasize the heterogeneity of IEL and underline the need to study phenotypically defined populations.     

T cell receptor expression on immature thymocytes with in vivo and in vitro precursor potential

Immature CD8-CD4- double-negative (DN) thymocytes differentiate intrathymically into CD8+CD4- and CD8-CD4+ thymocytes and migrate to the periphery. This differentiation proceeds through several intermediate phenotypic changes in the expression of CD8 and CD4. We have recently established the existence of a CD8loCD4lo cell population in murine thymus that can repopulate the irradiated thymus in vivo and differentiate rapidly in vitro to CD8+CD4+ double-positive (DP) cells. The CD8loCD4lo cells score as DN upon direct cytofluorometric analysis, yet are distinct from true DN cells by various criteria. Experimental evidence strongly suggests that they are descendants of true DN in the maturation pathway. In the experiments presented here, we further characterize this CD8loCD4lo thymocyte population. Northern blot and RNA protection analysis reveal that these cells transcribe full length mRNA for the T cell receptor (TcR)alpha chain, unlike the less mature interleukin 2 receptor-positive DN thymocytes. Surface expression of the TcR-associated CD3 molecule occurs on approximately 15% of these cells at low levels characteristic of immature cells. In the course of in vitro differentiation a vast majority (approximately 80%) of these cells convert to CD8+CD4+ and significant numbers of the brightly staining DP convertants (11%-34% on day 1 and 48%-68% on day 2) express immature levels of CD3. Our results indicate that CD8lo, CD4lo cells might be the first thymic subset to rearrange TcR alpha chain genes and express TcR alpha/beta heterodimer on the surface at levels characteristic of immature cells. Furthermore, the surface expression of TcR persists on the in vitro progeny of these thymocytes.