Ontogeny of fetal CD8lo4lo thymocytes: Expression of CD44, CD25 and early expression of TcR α mRNA

CD8^lo 4^lo cells are the immediate precursors of immature CD8^hi4^lcTcR^lo, CD8^hi 4^hiTcR^lo and CD8^hi4^hiTcR^lo double-positive (DP) thymocytes in the adult murine thymus. These cells are the first subset in the adult thymus to express accessory CD8 and CD4 molecules, to rearrange the T cell receptor (TcR) a chain genes and to express the TcR αβ heterodimer at low levels at the surface. Here, we investigate the fetal ontogeny of CD8^lo 4^lo cells. We detect these cells on day 15 of fetal development. They dominate the thymus on day 15.5, to become progressively less prominent thereafter. An important characteristic of fetal CD8^lo 4^lo cells is the early expression of TcR α mRNA (on fetal day 15, 36–48 h earlier than reported previously). Our results also suggest, but do not prove, that the receptor may be expressed on the surface as early as day 15.5. Fetal CD8^lo 4^lo cells, like their adult counterparts, become DP in vitro. However, early fetal CD8^lo 4^lo thymocytes express both CD44 and CD25 – unlike the adult subset - and that links them to their putative precursors, fetal CD44⁺CD25⁺ double-negative cells. This finding underscores the difference between adult and fetal thymocytes in turnover of membrane molecules and/or the kinetics of progression through phenotypic stages.     

Differentiation of CD4highCD8low coreceptor-skewed thymocytes into mature CD8 single-positive cells independent of MHC class I recognition

Thymocytes with a CD4^hiCD8^lo coreceptor-skewed (CRS) phenotype have been shown to contain precursors for CD8 single-positive (SP) thymocytes, in addition to precursors for CD4 SP cells. The selection mechanisms that stimulate CD4^hiCD8^lo cells to revert to the CD8 lineage are not known. Mice transgenic (tg) for the major histocompatibility complex (MHC) class I-restricted P14 T cell receptor (TCR), on the H-2^bm13 background, generate a large number of CD4^hiCD8^lo CRS thymocytes. We analyzed the developmental potential and the differentiation requirements of the CD4^hiCD8^lo population of these mice. Using reaggregate thymic organ cultures (RTOC), we observed that these cells efficiently and almost exclusively differentiate into CD8 SP cells. Differentiation occurred independent of whether or not the MHC haplotype of the thymic stroma corresponds to the MHC restriction of the tg TCR. Loss of CD4 was independent of thymic stroma, up-regulation of CD8 to full levels was dependent on thymic stroma but independent of MHC haplotype. After trypsin treatment and overnight incubation, these CRS cells re-expressed CD8 but failed to re-express CD4, indicating that they are in the process of terminating CD4 synthesis. CD8 SP cells derived from the CRS cells proliferate in response to peptide-pulsed antigen-presenting cells. Our data suggest that CD4^hiCD8^lo CRS thymocytes bearing the P14 tg TCR have completed positive selection and differentiate autonomously into functionally competent CD8 SP cells.     

Gads‐deficient thymocytes are blocked at the transitional single positive CD4+ stage

Positive selection of T‐cell precursors is the process by which a diverse T‐cell repertoire is established. Positive selection begins at the CD4⁺CD8⁺ double positive (DP) stage of development and involves at least two steps. First, DP thymocytes down‐regulate CD8 to become transitional single positive (TSP) CD4⁺ thymocytes. Then, cells are selected to become either mature single positive CD4⁺ or mature single positive CD8⁺ thymocytes. We sought to define the function of Gads during the two steps of positive selection by analyzing a Gads‐deficient mouse line. In Gads^+/+ mice, most TSP CD4⁺ thymocytes are TCR^hiBcl‐2^hiCD69⁺, suggesting that essential steps in positive selection occurred in the DP stage. Despite that Gads^?/? mice could readily generate TSP CD4⁺ thymocytes, many Gads^?/? TSP CD4⁺ cells were TCR^loBcl‐2^loCD69^?, suggesting that Gads^?/? cells proceeded to the TSP CD4⁺ stage prior to being positively selected. These data suggest that positive selection is not a prerequisite for the differentiation of DP thymocytes into TSP CD4⁺ thymocytes. We propose a model in which positive selection and differentiation into the TSP CD4⁺ stage are separable events and Gads is only required for positive selection.     

Evidence for a selective and multi-step model of T cell differentiation: CD4+CD8low thymocytes selected by a transgenic T cell receptor on major histocompatibility complex class I molecules

We have characterized a prominent (15-20 %) thymocyte population expressing CD4 at a high and CD8 at a low level “CD4⁺8^lo” in mice transgenic for a T cell receptor “TCR” restricted by major histocompatibility complex “MHC” class I molecules. The results demonstrate that the CD4⁺8^lo population is an intermediate stage between immature CD4⁺8⁺ and end-stage CD4⁺8^- thymocytes and that the survival of these cells crucially depends on the successful interaction of the transgenic TCR with self MHC class I molecules. In addition we demonstrate that the avidity of the interaction between TCR and self MHC class I molecules determines whether CD4⁺8^lo thymocytes are found in significant numbers in this transgenic model. Our findings support a selective and multi-step model of T cell differentiation in the thymus.     

CD8/CD4 lineage commitment occurs by an instructional/default process followed by positive selection

In the present study, we investigated the developmental potential of purified populations of transitional CD4ⁱⁿ CD8^hi and CD4^hi CD8ⁱⁿ thymocytes that were further defined according to their differentiation stage by their levels of T cell receptor (TCR) expression into TCR^lo, TCRⁱⁿ and TCR^hi subpopulations. The differentiation potential of each of these subsets was tested in vitro in a single-cell suspension culture assay that showed that CD4ⁱⁿ CD8^hi TCR^hi are precursors of CD8 single-positive cells, whereas CD4^hi CD8ⁱⁿ TCR^in/hi are precursors of both CD4 and CD8 single-positive thymocytes. The analysis of transitional subsets in mutant mice for either β2-microglobulin or major histocompatibility complex (MHC) class II further revealed that lineage commitment to the CD8 lineage requires a TCR-MHC class I engagement, presumably at the immature double-positive stage of thymic development, while CD4 commitment does not require an MHC class II-mediated signal, but rather occurs by default. Using the addition of MHC class I- or class II-expressing cells or the addition of total thymocytes to purified sorted transitional precursors for the duration of the cultures in vitro, we identified an additional stage of differentiation for both CD4 and CD8 lineages that requires a positive selection signal. Examination of protein tyrosine phosphorylation of transitional precursors revealed that CD4ⁱⁿ CD8^hi transitional cells contain a high level of a 70-kDa phosphorylated protein consistent with a role for ZAP70 in the signal transduction during the positive selection of CD8⁺ cells.     

Expression of cell interaction molecules by immature rat thymocytes during passage through the CD4+8+ compartment: developmental regulation and induction by T cell receptor engagement of CD2, CD5, CD28, CD11a,CD44 and CD53

Rat thymocytes of the T cell receptor^low (TcR^low) CD4⁺8⁺ subset which is the target of repertoire selection are heterogeneous with respect to expression of the cell interaction (CI) molecules CD2, CD5, CD11a/CD18 (LFA-1), CD28 and CD44. We show that this heterogeneity is due to the developmental regulation of these CI molecules during passage through the CD4⁺8⁺ compartment, and to up-regulation by TcR engagement. Thus, cohorts of CD4⁺8⁺ cells differentiating synchronously in vitro from their direct precursors, the immature CD4^?8⁺ cells, were homogeneous with regard to CI molecule expression. Upon entry into the CD4⁺8⁺ compartment, they expressed relatively high levels of CD2 and CD44, and moderate levels of CDS, CD28 and CD11a. CD2, CD28 and CD44 were slightly down-regulated during the following 2 days, whereas CD5 slightly increased and CD11a remained constant. TcR stimulation using immobilized monoclonal antibodies resulted in rapid and dramatic up-regulation of CD2, CD5 and CD28 and, to a lesser extent, of CD11a and CD44. Finally CD53, a triggering structure absent from unstimulated CD4⁺8⁺ thymocytes was also rapidly induced by TcR stimulation. Inclusion of interleukin (IL)-2, IL-4, or IL-7 in this in vitro differentiation system did not affect the levels of CI molecules studied. Since the high levels of CI molecules induced by TcR-stimulation correspond to those found in vivo on TcR^intermediate thymocytes known to be undergoing repertoire selection, these results suggest that upregulation of CI molecules by TcR engagement provides a mechanism by which thymocytes that have entered the selection process gain preferential access to further interactions with stromal and lymphoid cells in the thymus.     

Intrathymic T cell receptor (TcR) targeting in mice lacking CD4 or major histocompatibility complex (MHC) class II: Rescue of CD4 T cell lineage without co-engagement of TcR/CD4 by MHC class II

A critical step during intrathymic T cell development, termed positive selection, is associated with rescue of short-lived, immature thymocytes from programmed cell death, T cell lineage commitment, and induction of lineage-specific differentiation programs. T cell receptor (TcR)-major histocompatibility complex (MHC) interactions during positive selection can be closely mimicked by targeting TcR on immature thymocytes to cortical epithelial cells in situ via hybrid antibodies. Here, we show that antibody-mediated TcR signaling in mice deficient for CD4 or MHC class II expression induces polyclonal differentiation of the CD4 T cell lineage. Following a single TcR signal pulse in situ, a temporal sequence of phenotype changes can be discerned: CD69 up-regulation (< 1 day), CD8 down-regulation, TcR up-regulation (1–1.5 days) and down-regulation of the heat-stable antigen (1.5–2 days). Differentiation of phenotypically and functionally mature CD4 T cells in situ is attained within 3 days. Rescue of CD4 lineage T cells in the absence of TcR/CD4 co-engagement by MHC class II in this experimental system supports the stochastic/selective model of T cell lineage commitment.     

Class II major histocompatibility complex-restricted T cell function in CD4-deficient mice

Previously, we and others have demonstrated that CD4-deficient mice have a normal number of T cells and B cells with a significant population of CD4^-8^-TcRαβ⁺ T cells. Surprisingly, however, these mice lacking CD4 show in vivo immunoglobulin isotype class switching from IgM to IgG in response to sheep erythrocytes and vesicular stomatitis virus. In this study we have depleted various subpopulations of T cells in vivo and shown that the population of CD4^-8^-TcRαβ⁺ T cells is responsible for providing “help” in the antibody response of CD4-deficient mice to vesicular stomatitis virus infection. We have used antigen-specific proliferation assays and blocking studies with class I and II major histocompatibility complex (MHC)-specific purified antibodies to show that these cells are class II MHC-restricted in responses against the T cell-dependent antigen keyhole limpet hemocyanin (KLH). Finally, phenotypic analysis of the CD4^- CD8^-thymocytes in CD4-deficient mice shows that these cells have a more mature phenotype than the CD4^-8^- thymocytes in wild type mice. These results indicate that CD4 is not absolutely necessary for positive selection or effector function of class II MHC-restricted helper T cells.     

CD3 components at the surface of pro-T cells can mediate pre-T cell development in vivo

Developmentally arrested pro-T cells (CD4^?8^?, IL-2R⁺, HSA⁺⁺) of RAG-1-deficient mice appear to express low levels of CD3 molecules in the absence of T cell receptor (TcR) chains at their surface, while developmentally arrested pre-T cells of TcRα-deficient mice express low levels of a disulfide-linked TcRβ chain in association with CD3 molecules. Cross-linking of the CD3 modules on pro-T cells of RAG-1^?/- mice in vivo, with either of two different CD3′-specific monoclonal antibodies, induces differentiation of these pro-T cells into pre-T cells (CD4⁺8⁺, IL-2R^?, HSA⁺), concomitant with a rapid expansion of the thymic T cell compartment, up to 175-fold within 12 days. The same effects can be produced by introduction of a mutant TcRβ transgene lacking most of the variable domain (ΔV-TcRβ) into the RAG-1^?/- background. These experiments suggest that cross-linking of the CD3 modules on pro-T cells mimics the signaling function expected of the pre-TcR complex, which is found at the surface of pre-T cells prior to functional TcRa gene rearrangement. The variable domain of the TcRβ chain is apparently not essential for inducing these aspects of T cell development.     

T lymphocyte development in p56lck deficient mice: allelic exclusion of the TcR β locus is incomplete but thymocyte development is not restored by TcR β or TcR αβ transgenes

The protein tyrosine kinase, p56^lck, is involved in signal transduction in mature T cells and in the molecular events controlling early thymocyte differentiation. Thymuses of mice deficient for p56^lck expression (p56^lck-/-) consist of immature CD4-CD8- double-negative (DN) and CD4⁺CD8⁺ double-positive (DP) thymocytes and are severely reduced in total cell number. In this report we have studied DN thymocytes from p56^lck-/- mice and found an increase in the proportion of the CD44^?CD25⁺ subset, suggesting that transit through this stage, which is known to require T cell receptor (TcR) β expression, may be delayed in the absence of p56^lck expression. In addition, the expression of a transgenic TcR β chain or TcR αβ pair did not restore thymic development in p56^lck-/- mice. However, in contrast to mice expressing a dominant negative isoform of p56^lck in which DP thymocytes do not develop, DP thymocytes still develop in nontransgenic and TcR transgenic p56^lck-/- mice. These results demonstrate that expansion of the DP subset is impaired in p56^lck-/- mice. In contrast, allelic exclusion is not severely compromised. Although there was an increase in the number of peripheral T cells expressing more than one Vβ chain in TcR transgenic p56^lck-/- mice, we found that inhibition of endogenous TcR β gene rearrangement was almost complete in thymocytes of Vβ transgenic p56^lck-/- mice and we could not detect any peripheral T cells that expressed more than one Vβ chain in non-transgenic p56^lck-/- mice.     

T cell receptor targeting to thymic cortical epithelial cells in vivo induces survival,activation and differentiation of immature thymocytes

We report that targeting of T cell receptors (TcR) to non-major histocompatibility complex (MHC) molecules on thymic cortical epithelial cells by hybrid antibodies in vivo and in fetal thymic organ cultures results in phenotypic and functional differentiation of thymocytes. A single pulse with hybrid antibodies rescues immature, CD4/8 double-positive thymocytes from their programmed death in vivo, induces expression of the early activation antigen CD69 followed by TcR up-regulation, concomitant down-regulation of CD8 or CD4 and their conversion to functional mature T cells by day 3. This temporal sequence of maturation only affects small thymocytes without co-induction of blastogenesis. TcR targeting to MHC class II-positive epithelial cells predominantly induces CD4-positive T cells. This generation of CD4 single-positive T cells occurs also in MHC class II-deficient mice and thus is independent of CD4-MHC class II interactions. Moreover, in the presence of a specific deleting antigen (Mls 1^a),TcR targeting results in transient activation of immature thymocytes, however, not in subsequent TcR (Vβ6) up-regulation and development of single-positive T cells. Our findings imply that TcR cross-linking to cortical epithelial cells is sufficient to confer a differentiation signal to immature thymocytes. Futhermore, this approach distinguishes two independent TcR-mediated intrathymic events: activation and subsequent deletion of the same thymocyte subset.     

NK1.1+ CD4+ CD8- thymocytes with specific lymphokine secretion

CD4+8^? or CD4^?8⁺ thymocytes have been regarded as direct progenitors of peripheral T cells. However, recently, we have found a novel NK1.1⁺ subpopulation with skewed T cell antigen receptor (TcR) Vβ family among heat-stable antigen negative (HSA^?) CD4⁺8^? thymocytes. In the present study, we show that these NK1.1⁺ CD4+8^? thymocytes, which represent a different lineage from the major NK1.1^? CD4⁺8^? thymocytes or CD4⁺ lymph node T cells, vigorously secrete interleukin (IL)-4 and interfron (IFN)-γ upon stimulation with immobilized anti-TcR-αβ antibody. On the other hand, neither NK1.1^? CD4+8^?thymocytes nor CD4⁺ lymph node T cells produced substantial amounts of these lymphokines. A similar pattern of lymphokine secretion was observed with the NK1.1⁺ CD4⁺ T cells obtained from bone marrow. The present findings elucidate the recent observations that HSA^? CD4⁺8^? thymocytes secrete a variety of lymphokines including IFN-γ, IL-4, IL-5 and IL-10 before the CD4⁺8^? thymocytes are exported from thymus. Our evidence indicates that NK1.1⁺ CD4⁺8^? thymocytes are totally responsible for the specific lymphokine secretions observed in the HSA- CD4⁺8^? thymocytes.     

T cell development in a major histocompatibility complex class II-deficient patient

In this report we show that the major histocompatibility complex (MHC) class II-negative thymus of a bare lymphocyte syndrome (BLS) patient contains a reduced CD4⁺ CD8^? T cell population when compared to thymocytes derived from a MHC class II-expressing thymus. Of these CD4⁺ CD8^? BLS thymocytes, approximately only one third co-expressed the CD3 antigen, moreover at a lower expression level when compared to control thymocytes. This suggests a partial maturation of the CD4⁺ CD8^? T cells in the absence of MHC class II expression. Among the BLS thymocytes, CD4⁺ CD8⁺ thymocytes could easily be detected. Noteworthy, the number of CD4^? CD8⁺ thymocytes was significantly increased. CD4⁺ CD8^? T cells could also be found among the BLS peripheral blood mononuclear cells, albeit at reduced numbers. Despite the absence of peripheral MHC class II expression, the majority of these CD4⁺ CD8^? T cells co-expressed the CD45RO marker. In the BLS patient, thymocytes as well as peripheral CD4⁺ CD8^? T cells were not restricted in the use of the available T cell receptor (TcR) V gene family pool. However, the lack of detectable levels of thymic and peripheral MHC class II antigen expression in the BLS patient had altered the CD4^?skewing patterns of TcR V gene families which were present in normal individuals. In conclusion, the lack of MHC class II expression in the BLS patient does not completely inhibit the CD4+ CD8^? T cell development.     

Permissive recognition during positive selection

In the periphery αβ T lymphocytes recognize antigens in conjunction with major histocompatibility complex (MHC) molecules. In the thymus immature T cells are positively selected on MHC molecules in the apparent absence of cognate peptides. Thus, at different developmental stages a T cell responds to different epitopes, yet uses the identical αβ T cell antigen receptor (TcR). To explain this paradox it has been hypothesized that during positive selection immature T cells see peptides/ligands unique to the thymus, are selected by specific antagonists related to their cognate peptides, or are driven by lowered affinity thresholds of their TcR. Though different in detail, these theories rely on defined peptides uniquely matched to select certain TcR. However, we find that in a TcR-transgenic (TcR_trans⁺) mouse severely limiting the diversity of peptides does not impair positive selection. We show that many unrelated peptides, including some naturally occurring on the cell surface, induce maturation of CD4^?CD8⁺TcR^high thymocytes. The same peptides when presented in conjunction with the selecting MHC molecule, are not recognized by peripheral T cells expressing the same TcR_trans. Therefore, these findings point to a promiscuous rather than discriminate recognition mode used by immature T cells.     

CD8 is needed for positive selection but differentially required for negative selection of T cells during thymic ontogeny

During thymic development, immature thymocytes expressing major histocompatibility complex (MHC) class I-restricted T cell receptors (TcR) differentiate into CD8⁺ T cells with cytolytic functions. To evaluate the role of CD8 in positive and negative selection during thymic ontogeny, mice rendered CD8-null by gene targeting were bred with three lines of transgenic mice expressing unique MHC class I-restricted TcR. In all three instances CD8 was required for positive selection of MHC class I-restricted transgenic T cells. The efficiency of positive selection decreased in accordance with a reduced level of CD8 expression on thymocytes. Surprisingly, there was a differential requirement for CD8 expression in negative selection of MHC class I-restricted thymocytes, depending on the antigen specificity of TcR. These observations show that CD8 is essential for positive selection but is differentially required for negative selection of MHC class I-restricted T cells. Thus thymic selection, at least for negative selection, can occur in the absence of the CD8 accessory molecule.     

CD5− dendritic epidermal T cells are derived from CD5+ precursor cells

Murine Thy-1⁺, TcR Vγ3/Vδ⁺ dendritic epidermal T cells (DETC) differ from most other T cell subsets by the absence of CD4 and CD8 antigens as well as the lack of CD5 expression. To see whether negativity for those antigens is an intrinsic feature of a given T cell population or if such triple-negative T cells go through a maturational stage where they express these antigens, we determined the phenotype of TcR Vγ3⁺ fetal thymocytes which are the precursor cells of DETC. We found that TcR Vγ3⁺ fetal thymocytes phenotypically differ from mature DETC in that they are CD5⁺, mostly CD8⁺ and partly CD4⁺. The injection of fetal thymic suspensions containing TcR Vγ3⁺/CD5⁺ (but not TcR Vγ3⁺/CD5^?) thymocytes into Thy-1-disparate athymic nude mice resulted in the appearance of donor-type TcR Vγ3⁺/CD5^? dendritic cells in the recipients' epidermis, indicating that TcR Vγ3⁺ thymocytes are indeed the precursors of CD5^? DETC. Tracing CD5 expression on DETC precursors during their intrathymic maturation and their migration to the fetal skin, we found that (i) the earliest DETC precursor cells as defined by TcR Vγ3 expression express high levels of CD5 antigen (day 15 of gestation), (ii) after day 16 of gestation 70% of TcR Vγ3⁺ thymocytes express high and 30% express intermediate levels of CD5, (iii) TcR Vγ3⁺ cells in the fetal blood express low levels of CD5, (iv) the first TcR Vγ3⁺ cells entering the epidermis express very low levels of this antigen and (v) TcR Vγ3⁺ epidermal cells later than day 19 of gestation are CD5^?. A similar down-regulation of CD5 expression on DETC precursors was also noted when TcR Vγ3⁺ cells were cultured in vitro. Even the addition of PMA and ionomycin, which up-regulates CD5 expression on TcR α/β-bearing thymocytes and lymph node T cells, could not prevent down-regulation on DETC precursors. The described cell system may serve as a useful tool in further experiments aimed to clarify the function of the CD5 glycoprotein as well as the mechanism(s) regulating its expression.