CD45 enhances positive selection and is expressed at a high level in large, cycling, positively selected CD4+CD8+ thymocytes.

T-cell development is arrested at the CD4+CD8+ (DP; double-positive) stage of thymocyte development in CD45 null mice. However, the mechanism by which CD45 participates in the positive selection of T cells remains to be investigated. In this report we describe a DP thymocyte population that associates positive selection with expression of high levels of CD45, CD4 and CD8. DP thymocytes of this phenotype are large, cycling cells and represent approximately 20% of DP thymocytes in normal mice. In mice expressing a transgenic T-cell receptor (TCR) specific for the male antigen presented by H-2Db (H-Y TCR), the up-regulation of TCR, CD5 and CD69 in this large DP population occurred in a major histocompatibility complex (MHC)-restricted manner. To investigate further the role of CD45 in positive selection, we determined whether thymocytes that expressed a transgenic CD45RO molecule under the control of the proximal lck promoter can influence the positive selection of T cells in H-Y TCR transgenic mice. It was found that in female H-Y TCR transgenic mice, MHC-restricted positive selection of CD4- CD8+ H-Y TCR+ thymocytes was enhanced by increased CD45RO expression. Thus, CD45 increases the efficacy of positive selection of CD4- CD8+ thymocytes that express H-Y TCR.     

Evidence for down-regulation of highly expressed TCR by CD4 and CD45 on non-selected CD4+CD8+thymocytes

Immature CD4+CD8+ double-positive (DP) thymocytes are positivelyselected for further development if they express TCR reactingwith thymic ligands of low affinity. However, the majority ofDP thymocytes express low TCR levels. This low level of TCRmay be insufficient to recognize thymic ligands. To understandthe basis for the low expression of TCR on DP thymocytes, wedetermined the density of TCR expression at various stages oftheir development using TCR transgenic (TCR-Tg) mice. We foundthat TCR expression was high in the thymocytes that had recentlytransited into the DP stage but then gradually decreased onDP cells if they were not selected by TCR interaction with MHCmolecules. However, such TCR suppression was not observed inpositively selected DP cells and in the non-selected DP cellsobtained from CD45 deficient mice or from mice receiving anti-CD4mAb. These findings suggest that the once highly expressed TCRat the DP stage is suppressed by CD45 and/or CD4 on non-selectedthymocytes. Furthermore, TCR suppression is prevented by TCR-mediatedsignals. The maintenance of high TCR levels on positively selectedDP thymocytes may facilitate their selection.     

Interaction of merosin (laminin 2) with very late activation antigen-6 is necessary for the survival of CD4+ CD8+ immature thymocytes

The laminin alpha2-chain is a component of merosin, a member of the laminin family molecules, which is mainly expressed in the basement membranes of striated muscle. It is known that laminin alpha2 gene (lama2) null mutant mice (dy3k/dy3k) exhibit congenital muscular dystrophy (CMD). Because the laminin alpha2-chain is also expressed in the thymus, the role of merosin in the thymus was examined. In association with the onset of muscular dystrophy, CD4+ CD8+ double-positive (DP) thymocytes disappear by apoptotic cell death, while CD4+ CD8- or CD4- CD8+ thymocytes remain. In order to study the mechanisms leading to the selective death of DP cells in the absence of merosin, the role of the interaction between very late activation antigen-6 (VLA-6), a candidate merosin ligand in the thymus, and merosin was examined. The in vitro survival of thymocytes from normal mice was maintained by the addition of either anti-VLA-6 monoclonal antibodies (mAbs) or merosin. Furthermore, when the normal thymocytes were cultured on thymic epithelial cell lines, viable DP cell recoveries on wild-type epithelial cells were better than on cells from null mutant mice. The results suggest that DP cells are more sensitive to an uncharacterized apoptotic death signal, and that survival is supported by the interaction between VLA-6 and merosin.     

X-ray irradiation selectively kills thymocytes of different stages and impairs the maturation of donor-derived CD4~+CD8~+ thymocytes in recipient thymus

The aim of the present study was to determine whether the sensitivity of thymocytes to X-ray radiation depends on their proliferative states and whether radiation impairs the maturation of donor-derived thymocytes in recipient thymus.We assigned 8-week-old C57BL/6J mice into three treatment groups:1) untreated;2) X-ray radiation;3) X-ray radiation plus bone marrow transplantation with donor bone marrow cells from transgenic mice express-ing enhanced green fluorescent protein(GFP) on a universal promoter.After 4 weeks,the size of the thymus,the number and proliferation of thymocytes and ratios of different stage thymocytes were analyzed by immunohisto-chemistry and flow cytometry.The results showed that:1) CD4+CD8+ thymocytes were more sensitive to X-ray radiation-induced cell death than other thymocytes;2) the proliferative capacity of CD4+CD8+ thymocytes was higher than that of other thymocytes;3) the size of the thymus,the number of thymocytes and ratios of thymo-cytes of different stages in irradiated mice recovered to the normal level of untreated mice by bone marrow trans-plantation;4) the ratio of GFP-positive CD4+CD8+ thymocytes increased significantly,whereas the ratio of GFP-positive CD4+ or CD8+ thymocytes decreased significantly.These results indicate that the degree of sensitivity of thymocytes to X-ray radiation depends on their proliferative states and radiation impairs the maturation of donor-derived CD4+CD8+ thymocytes in recipient thymus.     

CD45RA-R0+ subset is the major population of dividing thymocytes in the human.

CD45, or leukocyte common antigen, is expressed in different isoforms on different subsets of thymocytes, suggesting its involvement in the process of T cell development in the thymus. We report studies on CD45 isoform expression on human thymocytes at various stages of development using three-color flow cytometric analysis and cell cycle analysis. Among CD45R0+ cells 18.4% were in S+G2/M phase and represented more than 80% of the dividing cells in the thymus. Among the CD45R0- cells 10.9% were also in cell cycle. Because the CD45R0+ population is almost exclusively CD45RA-, the CD45RA-R0+ subset constitutes the major portion of dividing cells in the thymus. Both the CD1high and the CD3- populations were actively cycling. However, the former was almost 100% and the latter only 50% CD45RA-R0+. Dividing CD45RA-R0+ cells contain, therefore, many cells that have not yet expressed the CD3/T cell receptor complex and presumably have not yet undergone selective procedures. These results are hard to reconcile with the previously presented hypothesis that CD45R0 represents a marker for cells that are destined to die in the thymus. Instead, these results suggest an alternative possibility that CD45R0+ cells may contain cells that can mature and, thus, also constitute the thymic generative lineage.     

Developmental status of CD4-CD8+ and CD4+CD8- thymocytes with medium expression of CD3

In normal mice, more than 10% of thymocytes in the CD4+CD8- and CD4-CD8+ single-positive (SP) subsets express a medium level of CD3 on the cell surface. However, the fate of CD3medium cells is unclear. The CD3medium SP subpopulations might contain (i) cells in an immature stage of the pathways leading to CD3high cells, (ii) cells in developmental pathways that do not lead to CD3high cells, or (iii) cells that have been negatively selected. We found that sorted CD3medium CD4+CD8- thymocytes from adult mice up-regulated CD3 to high levels in reaggregation thymus organ culture. Unlike their CD3high counterparts, CD3medium CD4+CD8- thymocytes were unable to undergo chemotaxis towards the chemokines CCL19 and CCL21. CD3medium thymocytes of both CD4+CD8- and CD4-CD8+ subsets were also considerably more responsive than CD3high SP cells to apoptotic signals induced in vitro by ligation of CD95 (Fas/APO-1) or by dexamethasone. In both SP subsets, a higher frequency of thymocytes expressing forbidden Vbeta+ T cell receptors reactive with endogenous mammary tumor virus superantigens was found in CD3medium subpopulations than in CD3high subpopulations. These findings argue that the CD3medium SP thymocyte subpopulations contain apoptosis-susceptible precursor cells of CD3high SP cells and are subject to negatively selecting pressures.     

A CD3- subset of CD4-8+ thymocytes: a rapidly cycling intermediate in the generation of CD4+8+ cells

T lymphocytes with the surface phenotype CD4+8- and CD4-8+ are considered to be representative of functionally mature cells. We show here that adult murine thymus contains a subpopulation of CD4-8+ cells that differ from CD4-8+ cells found in the periphery in that they do not express the T cell receptor-associated CD3 molecular complex. Such CD3-4-8+ thymocytes are cortisone sensitive and rapidly cycling in situ. Furthermore, in contrast to mature T cells, most CD3-4-8+ thymocytes express low levels of CD5 and high levels of the B2A2 antigen. CD3-4-8+ thymocytes fail to respond to a variety of mitogenic stimuli in vitro but do give rise upon short-term culture to CD4+8+ cells. It is suggested that CD3-4-8+ thymocytes represent a transitional stage of thymus differentiation between the CD4-8- and CD4+8+ compartments.     

Interferons alpha/beta inhibit IL-7-induced proliferation of CD4- CD8- CD3- CD44+ CD25+ thymocytes, but do not inhibit that of CD4- CD8- CD3- CD44- CD25- thymocytes.

Type 1 interferons (IFN-alpha/beta) have recently been shown to inhibit interleukin-7 (IL-7)-induced growth and survival of early B-lineage cells. The CD3- CD4- CD8- (triple negative; TN) thymocytes from normal mice strongly proliferated upon stimulation with IL-7 in suspension, culture. Such an IL-7-induced proliferation was suppressed by the addition of IFN-alpha/beta, but a fraction of the TN thymocytes still showed proliferation. The IL-7-induced growth of TN thymocytes from acid mice, which lack the CD44- CD25- subpopulation, was completely inhibited by the addition of IFN-alpha/beta. The IL-7 induced proliferation of CD4- CD8- thymocytes from T-cell receptor (TCR) transgenic mice, the majority of which are CD3+ CD44- CD25-, was resistant to IFN-alpha/beta-mediated suppression. In fetal thymus organ cultures (FTOC), the addition of IL-7 greatly increased the population of CD4- CD8- CD44+ CD25+ thymocytes and IFN-alpha/beta inhibited this IL-7-driven expansion. In contrast, the addition of IL-7 markedly decreased the percentages of CD4- CD8- CD3- CD44- CD25- cells, and IFN-alpha/beta reversed the effect and increased the subpopulations of CD44- CD25+ and CD44- CD25-. Finally, IFN-beta mRNA was found to be expressed in the thymus. The data suggest that type I interferons inhibit IL-7-driven proliferation of TN thymocytes, but do not block the normal differentiation process.     

A novel CD3-J11d+ subset of CD4+CD8- cells repopulating thymus in radiation bone marrow chimeras

Sequential appearance of T cell subpopulations occurs in the thymus of irradiated AKR (H-2k, Thy-1.1) mice at an early stage after transplantation with bone marrow cells of C3H/HeN (H-2k, Thy-1.2) mice. The donor-derived thymocytes were first detected on day 8 after bone marrow reconstitution. Although most of the thymocytes were CD4-CD8- cells, an appreciable level of CD4+CD8- cells was detected in the thymus at this stage. The early appearing CD4+CD8- cells were a novel subset of thymocytes that were J11d+CD3-. From day 10 to day 21 the proportion of CD4+CD8-CD3-J11d+ cells decreased while the proportion of CD4+CD8+ cells and CD4+CD8-CD3+J11d- cells increased. The CD4+CD8-CD3- cells seem to diversify to form CD4+CD8+ thymocytes after short-term culture in vitro. These results suggested the existence of a differential pathway from CD4-CD8- cells to CD4+CD8+ cells via CD4+CD8- cells in thymus.     

CD8+ T Cells Induce Medullary Thymic Epithelium and CD4+CD8+CD25+ TCRβ− Thymocytes in SCID Mice

During T-cell development the transition in the thymus of CD4-CD8- double negative (DN) progenitor T cells into CD4+CD8+ double positive (DP) cells is dependent on the expression of a T-cell receptor (TCR)-beta-chain protein. In this study purified peripheral CD4+ and CD8+ T lymphocytes from the C.B-17 strain of mice were adoptively transferred into syngeneic, neonatal SCID mice, where donor cells resided at constant numbers in thymus from 2 weeks until 10 weeks post cell transfer. In the recipient thymus the CD8+ donor cells outnumbered the CD4+ cells by a factor of three to five and both subsets contained a large fraction of activated cells. During the late phase of treatment, CD8+ T cells induced high numbers of DP thymocytes in the SCID mice, a process accompanied by the maturation of medullary epithelial cells. Such thymic development in the SCID mouse was inhibited by coresiding CD4+ donor T cells. These results indicate a regulatory role by mature peripheral T cells on medullary epithelial growth and thymocyte development in the treated SCID mice.     

Double-negative thymocyte subsets in CD3′ chain-deficient mice: Absence of HSA+CD44−CD25− cells

Double-negative (DN) thymocyte subsets were examined in mice deficient in the CD3′ chain (ζ −/−). The HSA ⁺CD44⁻CD25⁻ subset was found to be missing, and DN thymocytes seemed to differentiate directly from HSA⁺CD25⁺CD44⁻cells to double-positive (DP) cells. When fetal thymic ontogeny was examined, we found a marked difference between ζ −/− embryos and heterozygous littermates from embryonic day 17.5, in terms of CD25, CD4 and CD8 expression, and thymus size. The ζ −/− thymocytes failed to down-regulate CD25 and to expand exponentially. The cell cycle status of adult thymocyte subsets indicated that although the HSA ⁺CD25⁻CD44⁻ subset was missing, the CD25⁺ DN population contained normal numbers of cycling cells, and the CD25⁺ DP cells (which were not detectable in normal mice) contained 5–10% cells in G2/M + S. Taken together these data suggest that the CD3′ chain might have a specific role in the control of proliferation of DN thymocytes during T cell development. Our data clearly show that one can dissociate the signal for a CD25⁺ DN cell to differentiate (which occurs in the absence of CD3′), from a signal to proliferate and from loss of cell surface CD25.     

The CD45 tyrosine phosphatase regulates CD3-induced signal transduction and T cell development in recombinase-deficient mice: restoration of pre-TCR function by active p56(lck).

The pre-TCR complex regulates the transition from CD4(-)CD8(-) double-negative (DN) to CD4(+)CD8(+) double-positive (DP) thymocytes during T cell development. In CD45(-/-) mice there is an accumulation of DN cells, suggesting a possible role for CD45 in pre-TCR signaling. We therefore crossed CD45(-/-) with Rag-1(-/-) mice to investigate the signaling functions of the CD3 complex in DN thymocytes. Remarkably, treatment of Rag-1(-/-)/CD45(-/-) mice with a CD3 mAb caused maturation to the DP stage at only 3% of the level measured in Rag-1(-/-) mice. Furthermore, ligation of the CD3 complex on Rag-1(-/-) /CD45(-/-) thymocytes in vitro induced less tyrosine phosphorylation in specific proteins when compared to Rag-1(-/-) thymocytes. CD45(-/-) mice were also crossed with pLGFA mice expressing a constitutively active form of the lck tyrosine kinase which restored the DN to DP transition to near normal levels. Our results are consistent with a model in which CD45-activated p56(lck) is critical for pre-TCR signal transduction.     

Characterization of constitutive and strain-dependent subsets of CD45RA+ cells in the thymus.

We have previously shown that the occurrence of CD45RA+ adult mouse thymocytes is strain-dependent, e.g. constituting approximately 0.6% in C57BL/Icrf and approximately 2.5% in BALB/c (Huby, R. and Goff, L., 1992. Eur. J. Immunol. 22:1659). Here we show that irrespective of strain, the thymus contains approximately 0.6% CD45RA+ cells which are composed of slg+ B cells (approximately 0.4%), slg- CD4-CD8- cells (< 0.2%), and CD4+ CD8+ cells (< 0.2%). In some strains an additional CD45RA+ population, representing up to approximately 2% of all thymocytes, is present and has a CD4-CD8+ phenotype. It is this CD4-CD8+CD45RA+ subset which is responsible for the observed strain difference. In BALB/c mice, this additional population comprises approximately 90% of the CD45RA+ thymic cells. They are larger than the majority of thymocytes, with a size typical of mature, single positive cells (CD4+CD8- or CD4-CD8+). Further phenotyping for co-expression of other maturation markers showed them to be distinctive; they are CD3int-hi, i.e. as bright as other CD8 single positives, which are dimmer than CD4 single positives. In addition they are CD44hi, MEL-14dim and hi, Thy-1lo, HSAlo/-, and PNAlo, suggesting them to be amongst the most mature cells in the thymus. This was corroborated by their phenotypic similarity to CD45RA+ lymph node T cells. Furthermore, in BALB/c adult thymus sections, CD45RA+ cells are localized mainly in the medulla, consistent with a mature phenotype. Comparable with most mature thymocytes, cell cycle analysis revealed this subset to be composed of resting (G0/G1) cells. The CD4-CD8+CD45RA+ cells are amongst the most mature thymocytes and yet are indistinguishable from peripheral T cell counterparts; the possibilities that they are mature thymocytes due to exit the thymus, or that they may represent recirculating peripheral T cells, are discussed.     

Diacylglycerol kinase alpha activity promotes survival of CD4+ 8+ double positive cells during thymocyte development

The diacylglycerol kinases (DGK) form a family of isoenzymes that catalyse the conversion of diacylglycerol (DAG) to phosphatidic acid (PA), both powerful second messengers in the cell. DGKalpha is expressed in brain, peripheral T cells and thymocytes and has been shown to translocate to the nuclear matrix upon T-cell receptor (TCR) engagement. Here, we show that high level expression of DGKalpha is induced following a signal transmitted through the pre-TCR and the protein tyrosine kinase, lck. Activity of DGKalpha contributes to survival in CD4+ 8+ (DP) thymocytes as pharmacological inhibition of DGK activity results in death of this cell population both in cell suspension and thymic explants. DGKalpha promotes survival in these thymocytes through a Bcl-regulated pathway. A consequence of inhibition of DGKalpha is the specific down-regulation of Bcl-xl, whereas in transgenic mice that over-express Bcl-2, death induced by the inhibitor is partially blocked. Thus we report a novel activity of DGKalpha in survival of thymocytes immediately after entry into the DP stage in development.     

Dual functions of Runx proteins for reactivating CD8 and silencing CD4 at the commitment process into CD8 thymocytes

To understand how CD8 expression is regulated during the transition process from CD4+8+ (CD4 and CD8 double positive, DP) to CD4-8+ (CD8 single positive, CD8SP) cells in the thymus, the involvement of Runx proteins in the alteration of chromatin configuration was investigated. Using the chromatin immunoprecipitation assay, we first demonstrated that Runx proteins bind to the stage-specific CD8 enhancer, as well as the CD4 silencer, in CD8SP thymocytes. Among Runx family members, Runx3 expression was initiated in DP thymocytes receiving a positive selection signal and increased in concert with differentiation to the CD8SP stage. Furthermore, reactivation of the CD8 gene, as well as CD4 silencing, was suppressed in positively selected thymocytes of Runx dominant-negative transgenic mice. These results suggest that Runx proteins, especially Runx3, are involved in lineage specification of CD8 T cells and provide important information for understanding the mechanism for the mutually exclusive expression of coreceptors in mature thymocytes.     

Peripheral blood CD4+CD8+ lymphocytes in cynomolgus monkeys are of resting memory T lineage

In this study, we analyzed peripheral blood CD4+CD8+ double-positive (DP) lymphocytes in adult cynomolgus monkeys (Macaca fascicularis). Forty of 55 monkeys had > 5% of the peripheral blood DP subpopulation (9.3 +/- 5.9%; mean +/- SD) in peripheral blood lymphocytes (PBL) in contrast to a low percentage of peripheral blood DP cells in humans and mice. In a cross-sectional study, the peripheral blood DP cells were found to increase in proportion with age. To clarify whether peripheral blood DP lymphocytes were immature precursors released from thymus without prior differentiation, the expressions of CD8 chains and CD1b on peripheral blood DP lymphocytes were compared with those on thymocytes. The peripheral blood DP lymphocytes were CD8 alpha + beta- and CD1b-, while thymic DP lymphocytes were CD8 alpha + beta + and CD1b +, suggesting that the peripheral blood DP cells are extrathymic T lymphocytes. Furthermore, the peripheral blood DP lymphocytes exhibited a resting memory T cell phenotype with CD2hiCD3+CD28-CD29hiCD49dhiCD69- CD80lo. Taken together, adult cynomolgus monkeys possess a unique peripheral blood DP T cell subpopulation which expresses a resting memory T cell phenotype. In addition, similar phenotypic properties of DP lymphocytes were distributed in the spleen and lymph nodes, although the proportion was less in the spleen and much less in lymph nodes than in PBL.      

T cell receptor-negative thymocytes from SCID mice can be induced to enter the CD4/CD8 differentiation pathway

In order to investigate the role of T cell receptor (TcR) expression in thymocyte maturation, we have analyzed thymocytes from C.B-17/SCID mice, which are unable to productively rearrange their antigen receptor genes and fail to express TcR. Despite this defect, SCID thymocytes are functional as they produce lymphokines and proliferate in response to a variety of stimuli. Phenotypic analysis revealed that thymocyte populations from young adult SCID mice resemble thymocyte populations from normal embryonic mice in that they are large, Thy-1.2+, CD4-, CD8-, TcR- and enriched in CD5lo, IL2R+ and Pgp1+ cells. However, other TcR- populations normally present in adult mice (i.e., CD4-CD8+ cells and CD4+CD8+ cells) are absent from the thymus of TcR- adult SCID mice. To understand the basis of the developmental arrest of TcR- SCID thymocytes at the CD4-CD8- stage of differentiation, we analyzed thymi from the occasional "leaky" SCID mouse which possesses small numbers of TcR+ thymocytes. We found that the presence of TcR+ cells within a SCID thymus was invariably associated with the presence of CD4+ and/or CD8+ SCID thymocytes. Interestingly, however, the CD4+/CD8+ SCID thymocytes were not themselves necessarily TcR+. That is, emergence of SCID thymocytes expressing CD4/CD8 was tightly linked to the presence of TcR+ cells within that SCID thymus, but the SCID thymocytes that expressed CD4/CD8 were not necessarily the same cells that expressed TcR. Finally, we found that the introduction into TcR- SCID mice of normal bone marrow cells that give rise to TcR+ cells within the SCID thymus promoted the differentiation of SCID thymocytes into CD4-CD8+ and CD4+CD8+ TcR- cells. These data indicate that TcR+ cells within the thymic milieu provide critical signals which promote entry of CD4-CD8-TcR- precursor T cells into the CD4/CD8 differentiation pathway. When applied to differentiation of normal thymocytes, these findings may imply a critical role for early appearing CD4-CD8- TcR (gamma/delta)+ cells in initiating normal thymic ontogeny.     

A bone marrow-derived stroma cell line, ST2, can support the differentiation of fetal thymocytes from the CD4−CD8−double negative to the CD4+CD8+ double positive differentiation stage in vitro

T-cell precursors differentiate into mature T cells predominantly in the thymus. However, it has also been reported that T-cell precursors mature in extrathymic organs such as the liver, bone marrow, or intestines. In order to investigate the nature of the extrathymic microenvironment that supports T-cell maturation, we examined the effect of a bone marrow-derived stroma cell line, ST2, on T-cell precursors by using a reaggregate thymic organ culture (RTOC) system. We found that ST2 cells supported the differentiation of fetal thymocytes at day 14.5 of gestation from a CD4- CD8- double negative (DN) to a CD4+ CD8+ double positive (DP) differentiation stage in a manner similar to that observed in thymus. Anti-interleukin-7 receptor (IL-7R) and anti-c-kit antibodies blocked the growth of thymocytes in RTOC with ST2 cells, but did not inhibit the generation of DP thymocytes. These data indicate that a bone marrow-derived stroma cell, ST2, which supports B-cell differentiation, is also able to support T-cell development and may constitute one of the microenvironmental components for extrathymic T-cell development.     

Scheduled kinetics of cell proliferation and phenotypic changes during immature thymocyte generation

Precursor CD4-CD8- (DN) thymocytes rearrange their TCR-beta genes, and only those which succeed in beta-selection subsequently expand and differentiate into immature CD4+CD8+ (DP) thymocytes. The cell subsets corresponding to the successive steps of this transition can be defined in terms of CD44 and CD25 expression. We partially synchronized the differentiation process by eliminating cycling cells with the anti-mitotic agent demecolcine. Using in vivo pulse labeling with bromodeoxyuridine, we determined the order of entry into DNA synthesis of the different DN and transitory (CD4-/lo CD8+) cell subsets. Two independent proliferation phases were identified. The first cells to enter the cell cycle were CD44-CD25lo, and CD4/CD8/TCR-/BrdU four-color staining showed that they all expressed a low density of the TCR-beta chain, an element of the pre-TCR (the TCR-alpha locus is still in germ-line configuration at this stage). Cycling of CD44+CD25+ cells was detected later, and no starting point was observed at the CD44-CD25hi stage. CD8 expression was immediately detectable in cycling cells, but they took 24 h to reach the DP stage. The study of TCR-Calpha-deficient mice showed that beta gene rearrangement occurred once proliferation had ceased at the DP stage, and that it had no influence on the DN-DP transition. These data show that precursor thymocytes undergo two independent waves of expansion, and that the second wave is restricted to cells capable of pre-TCR expression.