CD4+CD8- thymocytes from neonatal mice induce IgM production in SCID mice.

Defective recombination of both the TCR and Ig genes results in the absence of mature lymphocytes in mice with the scid mutation. We have shown previously that the transfer of neonatal, but not adult, thymocytes results in high levels of Ig production in 100% of C.B-17-scid (SCID) mice, in contrast to the 10 to 25% of SCID mice spontaneously producing low levels of oligoclonal Ig. In this report we demonstrate that neonatal CD4+8- thymocytes were able to induce this response; the CD4+8+ and CD4-8+ subpopulations were totally inactive and CD4-8- T cells had only limited activity several weeks after transfer. The stimulation of IgM production in SCID mice was detectable by 1 wk posttransfer of CD4+8- thymocytes or splenic T cells, and could be achieved with as few as 300 cells. The ability of neonatal CD4+8- thymocytes to induce Ig diminished gradually to insignificant levels at 3 wk postbirth; this loss of function was not associated with differential survival of neonatal T cells. Neonatal CD4+8- thymocytes from C.B-17 and other H-2d strains rescued Ig production, whereas cells from H-2b, H-2a, and H-2k strains were much less effective. These results suggest that a CD4+8- subpopulation found in both neonatal thymus and peripheral lymphoid tissues is able to induce the expansion or differentiation of the small numbers of functional B lymphocytes in SCID mice, and that the inducing T cell disappears shortly after birth, perhaps during the acquisition of self-tolerance.     

Sequential appearance of host-derived T cell subsets during differentiation in nude mice grafted with rat fetal thymus

To elucidate the abnormality of T cell differentiation in nude mice grafted with rat fetal thymus that develop multiple-organ-localized autoimmune diseases, we examined sequential appearance of T cell subsets and expression of TCR genes in BALB/c nude mice after grafting with fetal F344 rat thymus. We observed progressive expression of TCR gamma/delta-alpha/beta genes in the lymph node (LN) cells from 8 to 12 wk after grafting. An appreciable number of CD4+ T cells but few CD8+ T cells were detected in the LN at 8 wk after grafting. CD8+ T cells increased slowly in number by 12 wk after grafting but remained at a low level in comparison with those in nude mice 12 wk after grafting with BALB/c thymus. In correlation with an increase in the number of T cells expressing TCR alpha/beta genes, alloreactivity as assessed by MLR was increased to a normal level. However, CTL activity against alloantigens remained at a low level in the LN cells at 12 wk. At this stage, organ-specific autoimmune diseases and a high level of anti-DNA autoantibodies were detected. In these mice host-reactive T cells such as V beta 3- or V beta 11-bearing T cells were virtually eliminated in the peripheral mature T cell pool, whereas T cells maturing in the fetal rat thymus significantly proliferated in response to donor-rat stimulator cells. These results suggest that the development of the autoimmune diseases may be ascribed to an impaired maturation of CD8+ T cells but not to failure in clonal elimination of host-reactive T cells in nude mice grafted with rat thymus.     

Effect of cyclosporin A on lymphopoiesis. I. Absence of mature T cells in thymus and periphery of bone marrow transplanted mice treated with cyclosporin A

In this report, we investigate the effect of cyclosporin A (CsA) on lymphopoiesis, and demonstrate that CsA selectively abrogates the development of CD4+CD8- and CD4-CD8+ T cells (single positive cells) in the thymus. This developmental arrest results in the complete absence of mature T cells (assessed both by phenotypic and functional analyses) in the spleen of syngeneic bone marrow transplanted mice subsequently treated with CsA. In contrast to its remarkable effect on T cells, CsA had no detectable effect on B cells differentiation. In the thymus, the generation of CD4+CD8+ thymocytes was not affected by CsA treatment, and CD4-CD8- thymocytes of CsA-treated mice expressed surface markers characteristic of normal CD4-CD8- thymocytes, and exhibited normal functional activity when stimulated with anti-CD3 antibody. Thus, CsA appears to prevent the generation of mature, single positive T cells without affecting the development of immature T cells in the thymus. In addition to its immunosuppressive effect on immunocompetent cells, these results indicate a novel feature of CsA, which involves arrest of T cell differentiation, a finding that may be important for applications in clinical bone marrow transplantation.     

T hybridoma alpha/beta gene transfected in a murine T cell hybridoma: role of CD4 molecule in vitro and in vivo--engraftment in SCID mice induces T cell maturation.

In the present work, we tested in SCID and Balb/c mice the activity of T hybridoma transfected with T cell receptor (TCR) alpha/beta chain genes. A T cell hybridoma denoted D011107 was used as recipient for transfection of cytotoxic KB5C20 TCR alpha/beta heterodimer genes by protoplast fusion or electroporation. After transfection, the parental D011107 T cell line reexpressed CD5 and CD4 surface molecules. In vitro, we noted strong proliferation and unusual cytotoxic reactivities against H-2k target cells although the transfected cell line does not express the CD8 molecule. The fate of parental and transfected cells was examined in severe combined immunodeficient (SCID) and Balb/c mice at Day 16 after intravenous injection. Cells from bone marrow, thymus, and spleen tissues were analyzed by immunofluorescence. The transfected T cell hybridoma was CD3+ Desire 1+ CD4+ Thy1.2. The SCID mice grafted with the transfected T cell hybridoma presented a high percentage of CD3+ (15%), CD4+ (27%), Thy1.2+ (27.52%), and Desire 1+ (8.74%) cells in the spleen. The percentages of CD3+ (6.2%) and Thy1.2+ (5.06%) cells in the spleen from SCID mice grafted with parental T cell D011107 and from untreated SCID were similar and lower (CD3+, 3.52%; Thy1.2+, 4.34%). It seems that transfected T cells hybridoma grafted in the SCID mice induce significant expression of CD4+ Thy1.2+ Desire 1- cells (17%) in the spleen. These results indicate that transfected T cells graft may allow T cell differentiation. In Balb/c mice, the percentage of different T cell subsets in bone marrow, thymus, or spleen cells in mice injected with transfected T cells was similar to that in untreated mice. We did not observe any cytotoxic or significant allogeneic proliferation in vitro.     

Mice lacking MHC class II molecules

We have produced mice that lack major histocompatibility complex class II antigens, permitting us to evaluate the role of these molecules in diverse aspects of T and B cell differentiation. The mutant mice show near-complete elimination of CD4+ T lymphocytes from the spleen and lymph nodes; the few remaining CD4-positive cells are preferentially localized to B cell follicles. Surprisingly, substantial numbers of CD4 single-positive cells reside in the thymus; however, these are not mature thymocytes as we currently recognize them. B lymphocytes occur in normal numbers and are capable of terminal differentiation to plasma cells. Nevertheless, several aberrations in the B cell compartment are demonstrable: a lack of germinal centers, fewer IgM+IgD+ cells in certain individuals, reduced production of serum IgG1, and complete inability to respond to T-dependent antigens. In short, the class II-negative mice have confirmed some old ideas about lymphocyte differentiation, but have provided some surprises.     

Clonal analysis of the peripheral T cell compartment of the SCID-hu mouse.

Severe combined immunodeficiency (SCID) mice can be transplanted successfully with human fetal liver and thymus (SCID-hu mice). Precursor cells derived from the fetal liver differentiate in the thymus and migrate into the blood as mature T cells. In the present paper, the peripheral T cell compartment of such mice was studied. Peripheral WBC were activated by PHA and cultured in the presence of irradiated human feeder cells. The resultant cell population consisted exclusively of human CD1- CD2+ CD3+ CD7+ T lymphocytes; up to 4% of the T cells expressed the TCR gamma delta, whereas 95 to 100% were TCR alpha beta +. The CD4bright (42 to 66%) and CD8bright (30 to 54%) populations coexpressed variable but low levels of CD8 and CD4, respectively. The T cell cultures from the SCID-hu mice did not display reactivity towards the autologous human EBV-transformed B cell lines (B-LCL). On the other hand, these human T cells proliferated and were cytotoxic against allogeneic human B-LCL. T cell clones were established from cultured SCID-hu T cells. All T cell clones were TCR alpha beta + CD3+ CD2+; 61% of the clones were CD4+ CD8-, 27% were CD8+ CD4-, 11% were CD8+ CD4lo, and 2% were CD4+ CD8lo. None of these clones recognized the autologous B-LCL established from the fetal human donor. Fourteen of 100 T cell clones had specific alloreactivity, as tested on a panel of five B-LCL. Of these 14, two CD8+ CD4lo and two CD8+ CD4- clones were cytotoxic and did not proliferate in response to specific stimulator cells. Furthermore, two CD4+ CD8lo and eight CD4+ CD8- clones proliferated specifically in response to alloantigens. In conclusion, the peripheral human T cells of SCID-hu animals are functional and their TCR repertoire is polyclonal, alloreactive, and devoid of self-reactive cells. Therefore, the SCID-hu mouse can be a suitable model for the study of alloreactivity and allotolerance in vivo, as well as for the study of negative selection in the human thymus.     

Overexpression of Bcl-2 differentially restores development of thymus-derived CD4-8+ T cells and intestinal intraepithelial T cells in IFN-regulatory factor-1-deficient mice

Mice lacking IFN-regulatory factor (IRF)-1 have reduced numbers of mature CD8+ T cells within the thymus and peripheral lymphoid organs, suggesting a critical role of IRF-1 in CD8(+) T cell differentiation. Here we show that endogenous Bcl-2 expression is substantially reduced in IRF-1(-/-)CD8+ thymocytes and that introduction of a human Bcl-2 transgene driven by Emu or lck promoter in IRF-1(-/-) mice restores the CD8(+) T cell development. Restored CD8+ T cells are functionally mature in terms of allogeneic MLR and cytokine production. In contrast to thymus-derived CD8+ T cells, other lymphocyte subsets including NK, NK T, and TCR-gammadelta(+) intestinal intraepithelial lymphocytes, which are also impaired in IRF-1(-/-) mice, are not rescued by expressing human Bcl-2. Our results indicate that IRF-1 differentially regulates the development of these lymphocyte subsets and that survival signals involving Bcl-2 are critical for the development of thymus-dependent CD8+ T cells.     

Expression of the J11d marker on peripheral T lymphocytes of MRL-lpr/lpr mice

MRL-lpr/lpr (lpr) mice spontaneously develop massive lymphadenopathy resulting from the expansion of a unique population of Thy-1+ cells which are CD4- and CD8- (double negative) and the nature of which is not clear. The antibody J11d has been shown to define a differentiation Ag found on immature thymocytes but not on mature and functional peripheral CD4+ or CD8+ T cells. To analyze the possible relationship between the lpr double-negative T cells and the thymocytes, we investigated the simultaneous expression of J11d and Thy 1 Ag on the double-negative lpr lymph node cells by using two-color immunofluorescent staining technique. We observed that lpr mice at 3 to 4 weeks of age, before the onset of lymphadenopathy, did not have significant numbers (less than 4%) of J11d+ T cells in the periphery, similar to the number found in the control MRL +/+ mice. However, with increasing age of approximately 8 to 10 weeks and coinciding with the appearance of lymphadenopathy, a significant number (approximately 35%) of J11d+ Thy-1+ cells started appearing in the periphery of lpr mice and was maintained until the mice died at 20 to 24 weeks of age. The J11d+ T cells belonged to the abnormal double-negative T cell pool, inasmuch as J11d+ CD4+ or J11d+ CD8+ cells were absent in the lymph nodes of 20-wk-old lpr mice. Furthermore, 20-wk-old lpr mice demonstrated increased numbers (approximately 41%) of double-negative T cells in the thymus, a significant proportion of which were J11d+. In contrast, the 20-wk-old +/+ mice or 4-wk-old lpr mice had only 4% double-negative T cells in the thymus. The present study suggests that a significant number of peripheral double-negative T cells of lpr mice bear the immature thymic differentiation Ag J11d. The possibility that the accumulation of double-negative T cells results from abnormal peripheralization of double-negative J11d+ thymocytes, before complete differentiation into CD4+ or CD8+ T cells, is discussed.     

Evidence for the existence of two parallel differentiation pathways in the thymus of MRL lpr/lpr mice.

MRL mice homozygous for the lpr/lpr gene develop a massive lymphadenopathy caused by the accumulation of CD4-CD8-, Thy-1-positive T cells that express B220. This phenotypically unusual T cell population coexists with normal, B220- T cells in lpr/lpr animals. To investigate the origin and differentiation pathway of B220+ T cells, the expression of a panel of developmentally regulated cell surface markers including TCR, CD4, CD8, Thy-1, and B220 was examined. Thymocytes and peripheral T lymphocytes from lpr/lpr mice were analyzed by four-color flow cytometry. The results showed that both B220+ and B220- thymocytes contained all of CD4-CD8-, CD4+CD8+, and CD4 or CD8 single positive T cell subpopulation in the lpr thymus. Expression of the V beta 11 TCR, measured by flow cytometry and reverse polymerase chain reaction, was demonstrated in lpr thymus. However, the number of T cells expressing V beta 11 was greatly reduced in both the B220+ and B220- T cell populations in lymph node, spleen, and liver. Taken together, the data provide evidence for maturation and selection of a distinct population of B220+ T cells in the thymus of MRL lpr/lpr mice.     

Active form of Notch imposes T cell fate in human progenitor cells

The crucial role of Notch signaling in cell fate decisions in hematopoietic lineage and T lymphocyte development has been well established in mice. Overexpression of the intracellular domain of Notch mediates signal transduction of the protein. By retroviral transduction of this constitutively active truncated intracellular domain in human CD34+ umbilical cord blood progenitor cells, we were able to show that, in coculture with the stromal MS-5 cell line, depending on the cytokines added, the differentiation toward CD19+ B lymphocytes was blocked, the differentiation toward CD14+ monocytes was inhibited, and the differentiation toward CD56+ NK cells was favored. The number of CD7+cyCD3+ cells, a phenotype similar to T/NK progenitor cells, was also markedly increased. In fetal thymus organ culture, transduced CD34+ progenitor cells from umbilical cord blood cells or from thymus consistently generated more TCR-gammadelta T cells, whereas the other T cell subpopulations were largely unaffected. Interestingly, when injected in vivo in SCID-nonobese diabetic mice, the transduced cells generated ectopically human CD4+CD8+ TCR-alphabeta cells in the bone marrow, cells that are normally only present in the thymus, and lacked B cell differentiation potential. Our results show unequivocally that, in human, Notch signaling inhibits the monocyte and B cell fate, promotes the T cell fate, and alters the normal T cell differentiation pathway compatible with a pretumoral state.     

Differentiation and functional maturation of bone marrow-derived intestinal epithelial T cells expressing membrane T cell receptor in athymic radiation chimeras

The thymus dependency of murine intestinal intraepithelial lymphocytes (IEL) was studied in an athymic F1----parent radiation chimera model. IEL, although not splenic or lymph node lymphocytes, from athymic chimeras displayed normal levels of cells bearing the class-specific T cell Ag, CD4 and CD8; the TCR-associated molecule, CD3; and the Thy-1 Ag. Moreover, two-color flow cytometric analyses of IEL from athymic mice demonstrated regulated expression of T cell Ag characteristic of IEL subset populations from thymus-bearing mice. In immunoprecipitation experiments, surface TCR-alpha beta or TCR-gamma delta were expressed on IEL, although not on splenic lymphocytes, from athymic chimeras. That IEL from athymic chimeras constituted a population of functionally mature effector cells activated in situ, similar to IEL from thymus-bearing mice, was demonstrated by the presence of CD3-mediated lytic activity of athymic lethally irradiated bone marrow reconstituted IEL. These data provide compelling evidence that intestinal T cells do not require thymic influence for maturation and development, and demonstrate that the microenvironment of the intestinal epithelium is uniquely adapted to regulate IEL differentiation.     

Lineage divergence at the first TCR-dependent checkpoint: preferential γδ and impaired αβ T cell development in nonobese diabetic mice

The first TCR-dependent checkpoint in the thymus determines αβ versus γδ T lineage fate and sets the stage for later T cell differentiation decisions. We had previously shown that early T cells in NOD mice that are unable to rearrange a TCR exhibit a defect in checkpoint enforcement at this stage. To determine if T cell progenitors from wild-type NOD mice also exhibit cell-autonomous defects in development, we investigated their differentiation in the Notch-ligand-presenting OP9-DL1 coculture system, as well as by analysis of T cell development in vivo. Cultured CD4 and CD8 double-negative cells from NOD mice exhibited major defects in the generation of CD4 and CD8 double-positive αβ T cells, whereas γδ T cell development from bipotent precursors was enhanced. Limiting dilution and single-cell experiments show that the divergent effects on αβ and γδ T cell development did not spring from biased lineage choice but from increased proliferation of γδ T cells and impaired accumulation of αβ T lineage double-positive cells. In vivo, NOD early T cell subsets in the thymus also show characteristics indicative of defective β-selection, and peripheral αβ T cells are poorly established in mixed bone marrow chimeras, contrasting with strong γδ T as well as B cell repopulation. Thus, NOD T cell precursors reveal divergent, lineage-specific differentiation abnormalities in vitro and in vivo from the first TCR-dependent developmental choice point, which may have consequences for subsequent lineage decisions and effector functions.     

Down-regulation of T cell receptors on self-reactive T cells as a novel mechanism for extrathymic tolerance induction.

By generating two types of transgenic mice we have investigated how extrathymic events can contribute to self tolerance. The major histocompatibility complex class I gene Kb was expressed under the control of the glial fibrillary acidic protein promoter in cells of neuroectodermal origin outside the thymus. These mice were tolerant to Kb. When crossed to transgenic mice expressing a Kb-specific T cell receptor (TCR), clonotype+, CD8+CD4- mature T cells could be detected in normal numbers in the thymus of the double-transgenic mice but were strongly reduced in spleen and lymph nodes in comparison with TCR single-transgenic mice. After isolation of clonotype negative splenic T cells and activation in vitro, reappearance of the clonotype+, CD8+CD4- cells was observed. These results indicate that down-regulation of TCR and CD8 molecules on the antigen-specific T cells is a novel mechanism, by which peripheral tolerance to this antigen can occur.     

Differential control of autoantibodies and lymphoproliferation by Fas ligand expression on CD4+ and CD8+ T cells in vivo.

We have previously shown that the gld autoimmune syndrome is suppressed in lethally irradiated gld mice reconstituted with a mixture of normal and gld bone marrow (BM). Furthermore, in vivo depletion of normal Thy-1+ cells restores lymphoproliferation and autoantibody production in such chimeras, suggesting that T cells bearing Fas ligand are responsible for correcting the gld defect. In this study, mixed-BM chimeras lacking either normal CD4+ (B6CD4KO-B6gld) or normal CD8+ T cells (B6CD8KO-B6gld) were generated to determine the contribution of the normal T cell subsets to disease suppression. Lymphoproliferation was completely suppressed in B6CD4KO-B6gld chimeras but only modestly in B6CD8KO-B6gld chimeras. On the other hand, both types of mixed-BM chimeras had incomplete effects on the suppression of serum autoantibodies when compared with B6gld reconstituted with isologous BM. These results suggest that both T cell subsets provide Fas ligand to suppress immune cells responsible for autoantibody production; however, CD8+ T cells are mainly responsible for preventing lymphoproliferation.     

Natural killer cells in the thymus. Studies in mice with severe combined immune deficiency

The relationship between NK cell and T cell progenitors was investigated by using mice with severe combined immune deficiency (scid). Scid mice are devoid of mature T and B cells because they cannot rearrange their Ig and TCR genes. However, they have normal splenic NK cells. Thymus of scid mice, although markedly hypocellular, contains cells that lyse YAC-1, an NK-sensitive tumor cell. By flow cytometry, two populations of cells were identified in the scid thymus. Eighty percent of the cells were Thy-1+, IL-2R(7D4)+, J11d+, CD3-, CD4-, CD8- whereas the remaining were IL-2R-, J11d-, CD3-, CD4-, and CD8-. By cell sorting, all NK activity was found in the latter population, which is phenotypically similar to splenic NK cells. To determine if the thymus contains a bipotential NK/T progenitor cell, J11d+, IL-2R+ cells were cultured and analyzed for the generation of NK cells in vitro. These cells were used because they resemble 15-day fetal and adult CD4- CD8- thymocytes that are capable of giving rise to mature T cells. Cultured J11d+ thymocytes acquired non-MHC-restricted cytotoxicity, but in contrast to mature NK cells, the resulting cells contained mRNA for the gamma, delta, and epsilon-chains of CD3. This suggests that J11d+ cells are early T cells that can acquire the ability to kill in a non-MHC-restricted manner, but which do not give rise to NK cells in vitro. The differentiative potential of scid thymocytes was also tested in vivo. Unlike bone marrow cells, scid thymocytes containing 80% J11d+ cells failed to give rise to NK cells when transferred into irradiated recipients. Together these results suggest that mature NK cells reside in the thymus of scid mice but are not derived from a common NK/T progenitor.     

Cutting edge: B cells promote CD8+ T cell activation in MRL-Fas(lpr) mice independently of MHC class I antigen presentation

Spontaneous CD8+ T cell activation in MRL-Faslpr mice is B cell dependent. It is unclear whether this B-dependent activation is mediated by direct Ag presentation via MHC class I proteins (i.e., cross-presentation) or whether activation occurs by an indirect mechanism, e.g., via effects on CD4+ cells. To determine how CD8+ T cell activation is promoted by B cells, we created mixed bone marrow chimeras where direct MHC class I Ag presentation by B cells was abrogated while other leukocyte compartments could express MHC class I. Surprisingly, despite the absence of B cell class I-restricted Ag presentation, CD8+ T cell activation was intact in the chimeric mice. Therefore, the spontaneous B cell-dependent CD8+ T cell activation that occurs in systemic autoimmunity is not due to direct presentation by B cells to CD8+ T cells.     

Regulation of thymic NKT cell development by the B7-CD28 costimulatory pathway

Invariant NKT (iNKT) cells are a population of TCRalphabeta-expressing cells that are unique in several respects. In contrast to conventional T cells, iNKT cells are selected in the thymus for recognition of CD1, rather than conventional MHC class I or II, and are selected by CD1-expressing double-positive thymocytes, rather than by the thymic stromal cells responsible for positive selection of conventional T cells. We have probed further the requirements for thymic iNKT cell development and find that these cells are highly sensitive to B7-CD28 costimulatory interactions, as evidenced by the substantially decreased numbers of thymic iNKT cells in CD28 and in B7 knockout mice. In contrast to the requirement for CD1, B7-CD28 signaling does not affect early iNKT cell lineage commitment, but exerts its influence on the subsequent intrathymic expansion and differentiation of iNKT cells. CD28 wild-type/CD28-deficient mixed bone marrow chimeras provided evidence of both cell-autonomous and non-cell-autonomous roles for CD28 during iNKT cell development. Paradoxically, transgenic mice in which thymic expression of B7 is elevated have essentially no measurable thymic iNKT cells. Taken together, these results demonstrate that the unique pathway involved in iNKT cell development is marked by a critical role of B7-CD28 interactions and that disruption or augmentation of this costimulatory interaction has substantial effects on iNKT cell development in the thymus.     

CD83 expression influences CD4+ T cell development in the thymus

T lymphocyte selection and lineage commitment in the thymus requires multiple signals. Herein, CD4+ T cell generation required engagement of CD83, a surface molecule expressed by thymic epithelial and dendritic cells. CD83-deficient (CD83-/-) mice had a specific block in CD4+ single-positive thymocyte development without increased CD4+CD8+ double- or CD8+ single-positive thymocytes. This resulted in a selective 75%-90% reduction in peripheral CD4+ T cells, predominantly within the naive subset. Wild-type thymocytes and bone marrow stem cells failed to differentiate into mature CD4+ T cells when transferred into CD83-/- mice, while CD83-/- thymocytes and stem cells developed normally in wild-type mice. Thereby, CD83 expression represents an additional regulatory component for CD4+ T cell development in the thymus.     

Elimination of CD8+ thymocytes in transgenic mice expressing an anti-Lyt2.2 immunoglobulin heavy chain gene.

Individual T cell populations are characterized by specific surface proteins, namely by the T cell receptor complex (TCR) and by two accessory molecules, CD8 (Lyt2) and CD4 (L3T4). CD8 and CD4 are required for T cell interactions with class I or class II major histocompatibility complex molecules. In the thymus, immature CD8(-4)-TCR- cells differentiate, possibly via a short stage of CD8+4- thymocytes, into CD8+4+ TCR+ T cells and mature further into the main T cell populations, the CD8+4- TCR+ cytotoxic T lymphocytes and the CD4+8- TCR+ T helper cells. In order to analyse the differentiation steps involving CD8, we generated transgenic mice expressing mu heavy chain genes from an anti-Lyt2.2 hybridoma. Transgenic lines expressing either the complete (mu sm) or only the secreted mu protein (mu s) suffer from a severe depletion of their CD8+4+ thymocytes affecting also the mature CD8+4- and CD4+8- populations. The depletion is correlated to the expression of transgenic mu-chain proteins within thymocytes. This intrathymocyte expression of the mu chain prevents CD8-4- thymocytes from further differentiation, most probably via intracellular interactions between mu heavy chain and CD8 proteins. These results show that CD8 plays an important role during thymocyte maturation.