Sensory adaptation in naive peripheral CD4 T cells

T cell receptor interactions with peptide/major histocompatibility complex (pMHC) ligands control the selection of T cells in the thymus as well as their homeostasis in peripheral lymphoid organs. Here we show that pMHC contact modulates the expression of CD5 by naive CD4 T cells in a process that requires the continued expression of p56(lck). Reduced CD5 levels in T cells deprived of pMHC contact are predictive of elevated Ca(2)+ responses to subsequent TCR engagement by anti-CD3 or nominal antigen. Adaptation to peripheral pMHC contact may be important for regulating naive CD4 T cell responsiveness.

Insights into T-cell development from studies using transgenic and knockout mice

The generation of immunocompetent lymphocytes is a complex process that utilizes a multitude of cell surface receptors and intracellular signaling pathways. Moreover, specific cell-cell interactions and specialized microenvironments are required, so that purely in vitro experimental systems are limited in their ability to explain the complexity of T-cell development. In vivo models have been used extensively in the study of T-cell development. In the present review we summarize but a few of the seminal discoveries that have been made in this field using transgenic and knockout mouse models. In addition to demonstrating the wealth of information that can be gained, we also discuss some of the present limitations of this technology. Novel advances that allow the conditional and inducible modification of the genome and knock-in mutations promise to lead to an even more rapid advancement in our knowledge of T-cell development.

Long-term survival but impaired homeostatic proliferation of Naïve T cells in the absence of p56lck

Interactions between the T cell receptor (TCR) and major histocompatibility complex antigens are essential for the survival and homeostasis of peripheral T lymphocytes. However, little is known about the TCR signaling events that result from these interactions. The peripheral T cell pool of p56lck (lck)-deficient mice was reconstituted by the expression of an inducible lck transgene. Continued survival of peripheral naïve T cells was observed for long periods after switching off the transgene. Adoptive transfer of T cells from these mice into T lymphopoienic hosts confirmed that T cell survival was independent of lck but revealed its essential role in TCR-driven homeostatic proliferation of naïve T cells in response to the T cell-deficient host environment. These data suggest that survival and homeostatic expansion depend on different signals.

Differential survival of naive CD4 and CD8 T cells

In this paper we compare survival characteristics of transgenic and polyclonal CD4 and CD8 T cells. Transgenic CD4 T cells have an intrinsically lower capacity for survival, reflected in their gradual disappearance in thymectomized hosts, their increased sensitivity to apoptosis in vitro, and fewer divisions during homeostatic proliferation upon transfer into syngeneic lymphopenic hosts compared with CD8 T cells. Homeostatic proliferation, however, does not generally result in phenotypic conversion of activation markers unless cognate or cross-reactive Ag is present. T cells from the A18 TCR transgenic strain normally selected into the CD4 lineage are fragile as CD4 T cells, yet display the typical robust survival pattern of CD8 T cells when diverted into the CD8 lineage in a CD4-deficient host. Polyclonal CD4 and CD8 T cells also show distinctive patterns of survival, emphasizing that survival signals are relayed differently in the two lymphocyte subpopulations. However, expression levels of Bcl-2 in either transgenic or polyclonal naive CD4 and CD8 T cells are similar, excluding a role for this molecule as a key factor in differential survival of CD4 vs CD8 T cells.

Early growth response (Egr)-1 gene induction in the thymus in response to TCR ligation during early steps in positive selection is not required for CD8 lineage commitment

The early growth response gene 1 (Egr-1) is induced during positive selection in the thymus and has been implicated in the differentiation of CD4+ thymocytes. Here, we show that signals that specifically direct CD8 lineage commitment also induce Egr-1 DNA-binding activity in the nucleus. However, we find that pharmacological inhibition of mitogen-activated protein kinase/extracellular signal-related kinase kinase activity potently inhibits Egr-1 DNA-binding function at concentrations that promote differentiation of CD8+ thymocytes, suggesting Egr-1 activity is not essential for CD8 commitment. To further determine the role of Egr-1 in thymocyte development, we compare steady-state Egr-1 DNA-binding activity in thymocytes from mice with defined defects in positive selection. The data indicate that the appearance of functional Egr-1 is downstream of signals induced by TCR/MHC engagement, whereas it is less sensitive to alterations in Lck-mediated signals, and does not correlate directly with proficient positive selection. Egr-1 is one of the earliest transcription factors induced upon TCR ligation on immature thymocytes, and plays a potential role in the transcription of genes involved in thymocyte selection.

Inducible expression of a p56Lck transgene reveals a central role for Lck in the differentiation of CD4 SP thymocytes

The T lymphocyte-specific protein tyrosine kinase p56lck (Lck) is an essential component of the TCR-mediated signal transduction complex. Lck knockout mice have reduced numbers of double-positive thymocytes and very few mature single-positive cells, particularly of the CD4 lineage. Here we demonstrate the ability of a tetracycline-based tissue-specific inducible Lck transgene to restore expansion of early thymocytes and maturation of single-positive cells in Lckneg mice upon induction with doxycycline. Restoration of Lck expression is particularly important for positive selection to the CD4+ lineage but has a lesser impact on selection to the CD8+ lineage, suggesting activation of Lck is an important component of the signals involved in lineage choice during thymic differentiation.

MEK activity regulates negative selection of immature CD4+CD8+ thymocytes

CD4+CD8+ thymocytes are either positively selected and subsequently mature to CD4 single positive (SP) or CD8 SP T cells, or they die by apoptosis due to neglect or negative selection. This clonal selection is essential for establishing a functional self-restricted T cell repertoire. Intracellular signals through the three known mitogen-activated protein (MAP) kinase pathways have been shown to selectively guide positive or negative selection. Whereas the c-Jun N-terminal kinase and p38 MAP kinase regulate negative selection of thymocytes, the extracellular signal-regulated kinase (ERK) pathway is required for positive selection and T cell lineage commitment. In this paper, we show that the MAP/ERK kinase (MEK)-ERK pathway is also involved in negative selection. Thymocytes from newborn TCR transgenic mice were cultured with TCR/CD3epsilon-specific Abs or TCR-specific agonist peptides to induce negative selection. In the presence of the MEK-specific pharmacological inhibitors PD98059 or UO126, cell recovery was enhanced and deletion of DP thymocytes was drastically reduced. Furthermore, development of CD4 SP T cells was blocked, but differentiation of mature CD8 SP T cells proceeded in the presence of agonist peptides when MEK activity was blocked. Thus, our data indicate that the outcome between positively and negatively selecting signals is critically dependent on MEK activity.

Greatly reduced efficiency of both positive and negative selection of thymocytes in CD45 tyrosine phosphatase-deficient mice

The T cell repertoire is shaped by positive and negative selection of thymocytes. TCR-mediated signals that determine these selection processes are only partly understood. The CD45 tyrosine phosphatase has been shown to be important for signal transduction through the TCR, but there has been disagreement about whether CD45 is a positive or negative regulator of TCR signaling. Using CD45-deficient mice expressing transgenic TCR, we show that in the absence of CD45 there is a large increase in the thresholds of TCR stimulation required for both positive and negative selection. Our results conclusively demonstrate that in double-positive thymocytes CD45 is a positive regulator of the TCR signals that drive thymic selection events.

Activation of the extracellular signal-related kinase/mitogen-activated protein kinase pathway discriminates CD4 versus CD8 lineage commitment in the thymus

We have investigated the role of the mitogen-activated protein kinase (MAPK) pathway in the differentiation of CD4+ and CD8+ T cells by looking specifically at the effects of inhibitors of MAPK-activating enzyme, MAPK/extracellular signal-related kinase (ERK) kinase (MEK), during the positive selection step from double-positive to single-positive (SP) thymocytes. Using a variety of transgenic/knockout mouse strain combinations that fail to differentiate individual lineages of SP thymocytes together with genetically engineered F(ab')2 reagents that induce maturation preferentially to either the CD4 or CD8 subpopulations, we show that induction of CD4 differentiation cells is highly sensitive to levels of MEK inhibition that have no effect on CD8 maturation. In addition, the presence of MEK inhibitor is able to modify signals that normally induce CD4 differentiation to instead promote CD8 differentiation. Finally, we show that continuous culture in the presence of inhibitor interferes with TCR up-regulation in SP thymocytes, suggesting that MAPK signaling may be involved in final maturation steps for both lineages. These data indicate that there is discrimination in the biochemical pathways that are necessary to specify CD4 and CD8 lineage commitment and can reconcile previously conflicting reports on the influence of MAPK activation in commitment and maturation of thymocytes.

The Rho-family GTP exchange factor Vav is a critical transducer of T cell receptor signals to the calcium, ERK, and NF-kappaB pathways

Vav is a GTP/GDP exchange factor (GEF) for members of the Rho-family of GTPases that is rapidly tyrosine-phosphorylated after engagement of the T cell receptor (TCR), suggesting that it may transduce signals from the receptor. T cells from mice made Vav-deficient by gene targeting (Vav-/-) fail to proliferate in response to TCR stimulation because they fail to secrete IL-2. We now show that this is due at least in part to the failure to initiate IL-2 gene transcription. Furthermore, we analyze TCR-proximal signaling pathways in Vav-/- T cells and show that despite normal activation of the Lck and ZAP-70 tyrosine kinases, the mutant cells have specific defects in TCR-induced intracellular calcium fluxes, in the activation of extracellular signal-regulated mitogen-activated protein kinases and in the activation of the NF-kappaB transcription factor. Finally, we show that the greatly reduced TCR-induced calcium flux of Vav-deficient T cells is an important cause of their proliferative defect, because restoration of the calcium flux with a calcium ionophore reverses the phenotype.

Molecular requirements for lineage commitment in the thymus--antibody-mediated receptor engagements reveal a central role for lck in lineage decisions

Recent experiments in our laboratory have focused on the receptor engagements required for the differentiation of fully mature, single positive thymocytes from their double positive precursors. We have used a novel approach which involves the ligation of surface receptors on immature thymocytes with genetically engineered F(ab1)2 reagents, which, unlike conventional antibodies, do not aggregate the CD3 complex to such an extent as to induce extensive deletion of these cells. The experimental data presented in this review indicate that differentiation of the two mature CD4 and CD8 lineages occurs in response to distinct intracellular signals induced by particular receptor engagements. The data suggest that the tyrosine kinase p56lck (lck) plays a crucial role in determining lineage choice, in that maturation of thymocytes into the CD4 lineage occurs upon recruitment of active lck to the T-cell receptor (TCR)/CD3 complex, whereas CD8 maturation can be induced by CD3 ligation in the absence of co-receptor-mediated lck recruitment. A central role for lck activity in determining the threshold for differentiation of the CD4 lineage is revealed in experiments with thymi deficient for a regulator of lck activity, CD45. A model of thymocyte differentiation is presented in which we propose that the relative balance of signals delivered by TCR engagement and lck activation determines lineage choice.

CD3 ligation on immature thymocytes generates antagonist-like signals appropriate for CD8 lineage commitment, independently of T cell receptor specificity

The signals that direct differentiation of T cells to the CD4 or CD8 lineages in the thymus remain poorly understood. Although it has been relatively easy to direct differentiation of CD4 single positive (CD4+) cells using combinations of antibodies and pharmacological agents that mimic receptor engagements, equivalent stimuli do not induce efficient maturation of CD8+ cells. Here we report that, irrespective of the MHC-restriction specificity of the TCR, differentiation of mature CD8+ thymocytes can be induced by ligation of CD3 polypeptides on immature thymocytes with a F(ab')2 reagent (CD3fos-F(ab')2). The tyrosine phosphorylation patterns stimulated by CD3fos-F(ab')2 have been shown to resemble those delivered to mature T cells by antagonist peptides, which are known to direct positive selection of CD8+ cells, and we can show that this reagent exhibits potent antagonistic-like activity for primary T cell responses. Our results suggest a distinction in the signals that specify lineage commitment in the thymus. We present a model of thymocyte differentiation that proposes that the relative balance of signals delivered by TCR engagement and by p56lck activation is responsible for directing commitment to the CD8 or CD4 lineages.

Co-capping studies reveal CD8/TCR interactions after capping CD8 beta polypeptides and intracellular associations of CD8 with p56(lck)

CD8 is a T cell surface glycoprotein that participates in recognition of peptide/MHC class I molecules by binding to their alpha 3 domains. In addition, the cytoplasmic domain of CD8 associates with the intracellular tyrosine kinase p56(lck) (lck) promoting recruitment of lck to the TCR signaling complex. Recent data have suggested also that CD8 may interact with the TCR to promote energetically favorable conformations which increase its ligand binding. We have used the techniques of co-capping and confocal microscopy to ask whether we can detect an association between CD8 and the TCR independently of their binding to MHC class I molecules. We show that capping CD8 heterodimers with antibodies to the CD8 beta polypeptide is significantly more efficient than antibodies to the CD8 alpha polypeptide at inducing co-localization of TCR molecules with CD8, suggesting that there may be preferred conformations of CD8 which stabilize interactions with the TCR. In addition, we show by microscopy that intracellular lck redistributes very efficiently to the area of a CD8 cap, suggesting that there is a stronger association between lck and CD8 than has been proposed from immunoprecipitation analyses.

CD4 and CD8: modulators of T-cell receptor recognition of antigen and of immune responses?

The response of T cells to antigen involves the participation of a number of distinct receptor-ligand engagements. The major players in the recognition of complexes of major histocompatibility complex molecules and peptide antigens are the T-cell receptors and the co-receptors CD4 and CD8. Progress in understanding the physical structures of these molecules, and how complexes between them are formed, is helping our understanding of how they participate in regulating the signals transduced to T cells.

How many thymocytes audition for selection?

T cell maturation requires the rearrangement of clonotypic T cell receptors (TCR) capable of interacting with major histocompatibility complex (MHC) ligands to initiate positive and negative selection. Only 3-5% of thymocytes mature to join the peripheral T cell pool. To investigate the basis for this low success rate, we have measured the frequency of preselection thymocytes capable of responding to MHC. As many as one in five MHC-naive thymocytes show upregulation of activation markers on exposure to MHC-expressing thymic stroma in short-term reaggregate culture. The majority of these cells display physiological changes consistent with entry into the selection process within 24 h. By exposing TCR transgenic thymocytes to a range of MHC-peptide complexes, we show that CD69 induction is indicative of thymocyte selection, positive or negative. Our data provide evidence that the fraction of thymocytes that qualify to enter the thymic selection process far exceeds the fraction that successfully complete it, and suggest that most MHC-reactive thymocytes are actively eliminated in the course of selection.

A requirement for the Rho-family GTP exchange factor Vav in positive and negative selection of thymocytes

The T cell repertoire is shaped by positive and negative selection of thymocytes that express low levels of T cell receptor (TCR) and both CD4 and CD8. TCR-mediated signals that determine these selection processes are only partly understood. Vav, a GDP-GTP exchange factor for Rho-family proteins, is tyrosine phosphorylated following TCR stimulation, suggesting that it may transduce TCR signals. We now demonstrate that mice lacking Vav are viable and display a profound defect in the positive selection of both class I- and class II-restricted T cells. In contrast, Vav is not essential for negative selection, though in its absence negative selection is much less effective. Vav may influence the efficiency of TCR-induced selection events by regulating the intracellular calcium flux of thymocytes.

A CD8 genomic fragment that directs subset-specific expression of CD8 in transgenic mice

Helper and cytotoxic T cell subsets require the expression of different coreceptors (CD4 and CD8, respectively) for their development and function. We have cloned the CD8 gene locus from genomic cosmid and P1 libraries and analyzed the region around the CD8alpha and CD8beta genes for gene expression regulatory elements. DNase I (DNase I) hypersensitivity analysis of 80 kb in the CD8 locus identified four clusters of putative regulatory regions, three of which are thymocyte specific. Transgenic mice carrying the cloned CD8alphabeta genomic locus and containing the identified DNase I-hypersensitive site clusters express the transgenic CD8 in a developmentally regulated, tissue-specific, and CD8 T cell subset-specific manner.

Signals through CD8 or CD4 can induce commitment to the CD4 lineage in the thymus

Differentiation of thymocytes into mature single-positive T cells is an ordered process involving sequential interactions between T cell receptor (TCR), co-receptors (CD4 or CD8) and their appropriate major histocompatibility complex-encoded ligands. Precisely how these receptor/co-receptor engagements determine lineage commitment is still controversial, but recently it has been suggested that quantitative differences in the signal transmitted by co-ligation of CD4 versus CD8 with TCR might provide the discriminating signal. We examine this hypothesis, using bispecific F(ab')2 antibodies to mimic TCR/ co-receptor engagement during thymocyte differentiation. These bispecific antibodies lack Fc and can engage surface molecules without extensive cross-linking or targeting to Fc receptor-bearing cells. We show that TCR/CD3 co-ligation with CD4 induces efficient differentiation of mature CD4 lineage cells, irrespective of their TCR specificity. Interestingly, TCR/CD3 co-ligation with CD8 also induces maturation of CD4 T cells, although less efficiently, but not of CD8 T cells. Thus, although the signals delivered by co-ligation of TCR and CD8 appear weaker than from co-ligation of TCR and CD4, the outcome from either engagement is the same. These data suggest that differences in signal intensity alone do not determine lineage commitment in the thymus, but that distinct signals are required for CD4 and CD8 single-positive cell differentiation.

A CD8 genomic fragment that directs subset-specific expression of CD8 in transgenic mice

Helper and cytotoxic T cell subsets require the expression of different coreceptors (CD4 and CD8, respectively) for their development and function. We have cloned the CD8 gene locus from genomic cosmid and P1 libraries and analyzed the region around the CD8alpha and CD8beta genes for gene expression regulatory elements. DNase I (DNase I) hypersensitivity analysis of 80 kb in the CD8 locus identified four clusters of putative regulatory regions, three of which are thymocyte specific. Transgenic mice carrying the cloned CD8alphabeta genomic locus and containing the identified DNase I-hypersensitive site clusters express the transgenic CD8 in a developmentally regulated, tissue-specific, and CD8 T cell subset-specific manner.

Transgene-encoded human CD2 acts in a dominant negative fashion to modify thymocyte selection signals in mice

CD2 is a cell surface glycoprotein present on all T cells which has been shown to function as an adhesion and signaling molecule. Expressed early in T cell development, human CD2 (HCD2) has been suggested to play a role during thymopoiesis. However, the relevance of CD2 in T cell development has been called into question recently, as neither disruption of the CD2 gene nor anti-CD2 antibody treatment of fetal thymic organ cultures in mouse were shown to have any discernible consequences. We have expressed HCD2 at high levels in transgenic mice and found a profound effect of the transgene on thymocyte differentiation. Transgenic thymuses are considerably reduced in cell number as a consequence of increased apoptosis of double-positive (DP) thymocytes in the cortex. The remaining DP cells have up-regulated levels of T cell receptor (TCR) and are resistant to apoptosis mediated by administration of antigen. These effects are dependent on the cytoplasmic domain of HCD2, as mice expressing comparable levels of a tailless HCD2 transgene have a normal phenotype. The HCD2 cytoplasmic domain contains several regions of identity with mouse CD2 and can interact effciently with mouse intracellular signaling machinery. These results suggest there is considerable cross-talk between CD2 and TCR on developing thymocytes with consequences for the stimulation threshold of mature T cells.

Unprimed T cells are inefficiently stimulated by glycosylphosphatidylinositol-linked H-2Kb because of its lipid anchor rather than defects in CD8 binding

Many non-classical, or class Ib, MHC molecules, including those linked to the cell membrane via glycosylphosphatidylinositol (GPI) membrane anchors, are poor stimulators of primary cytotoxic T cell responses. Some studies have suggested that certain amino acid substitutions in the alpha 3 domains of class Ib molecules may adversely affect their ability to interact with CD8, thereby affecting their ability to stimulate CD8+ T cells. In this report we show that poor stimulation by GPI-linked class I MHC molecules is not simply due to a failure to interact with CD8, but to a fundamental difference in the way T cells respond to GPI-anchored class I molecules. We have demonstrated this in two ways. Firstly, we have shown that GPI-linked H-2Kb molecules in which the amino acid sequence of the alpha 3 domain is identical to that of transmembrane H-2Kb remain less effective stimulators of a primary T cell response than membrane-spanning H-2Kb molecules. Secondly, using CD8- responder T cell hybridomas and responder T cells from transgenic mice expressing a CD8-independent TCR, we can show that the poor stimulatory ability of GPI-linked H-2Kb molecules is unrelated to their ability to interact with either CD8 or the TCR. These results suggest that the transmembrane linkage of class I MHC molecules plays an important role in the initial priming of T cells.

T cell activation results in physical modification of the mouse CD8 beta chain

The T lymphocyte glycoprotein, CD8, is an essential component of the response of class I MHC-restricted T cells to Ag. CD8 is expressed on the surface of class I-restricted T cells as disulfide-bonded heterodimers and higher multimers of two distantly related polypeptides, alpha and beta. The CD8 alpha polypeptide, expressed in transfection studies as homodimers, is able to reproduce both the adhesive and stimulatory properties of CD8, leaving the function of the CD8 beta polypeptide unresolved. Herein we demonstrate that the CD8 beta polypeptide changes physically during T cell maturation and activation by reversibly altering its sialic acid content. These changes occur specifically on CD8 beta not -alpha, indicating that the primary role of the CD8 beta chain may be regulatory, influencing the physical structure of the CD8 complex, and suggesting a novel mechanism of controlling receptor/ligand interactions.

T cell activation results in physical modification of the mouse CD8 beta chain

The T lymphocyte glycoprotein, CD8, is an essential component of the response of class I MHC-restricted T cells to Ag. CD8 is expressed on the surface of class I-restricted T cells as disulfide-bonded heterodimers and higher multimers of two distantly related polypeptides, alpha and beta. The CD8 alpha polypeptide, expressed in transfection studies as homodimers, is able to reproduce both the adhesive and stimulatory properties of CD8, leaving the function of the CD8 beta polypeptide unresolved. Herein we demonstrate that the CD8 beta polypeptide changes physically during T cell maturation and activation by reversibly altering its sialic acid content. These changes occur specifically on CD8 beta not -alpha, indicating that the primary role of the CD8 beta chain may be regulatory, influencing the physical structure of the CD8 complex, and suggesting a novel mechanism of controlling receptor/ligand interactions.

Is CD8 dependence a true reflection of TCR affinity for antigen?

Cytotoxic T lymphocytes (CTL) are generally specific for class I MHC proteins plus antigen and express CD8 co-receptor molecules. The effector function of some CTL can be blocked by antibodies to CD8 (CD8 dependent CTL), whereas that of others is resistant to blocking (CD8 independent CTL). This difference in sensitivity to antibody-mediated inhibition is assumed to reflect variations in affinity of particular TCR for antigen. However, we have found that a major difference between CD8 independent and CD8 dependent T cells lies in their sensitivity to stimulation, the former responding to lower concentrations of anti-CD3 antibody than the latter. Thus the contribution to cell signalling provided by the co-association of p56lck and CD8 is particularly relevant for CD8 dependent cells. These data challenge the notion that the affinity of an individual TCR for antigen is related to the sensitivity of a cell to inhibition by anti-CD8 antibodies. Furthermore we show that antibodies to co-receptor molecules have multiple distinct effects on T cell activation, only some of which may be related to T cell affinity.

Identification of thymocyte precursors in murine fetal liver

We have isolated thymic stem cells from murine fetal liver using a combination of approaches including discontinuous albumin density gradient separation and anti-heat-stable antigen (HSA) antibody plus complement-mediated lysis. A population of early precursors has been identified which comprises approximately 1% of fetal liver, and which has the capacity to reconstitute alymphoid lobes and give rise to the four thymic subpopulations defined by expression of the T cell differentiation antigens CD4 and CD8. These early precursors express CD44 (Pgp-1), however, they are negative for expression of Thy-1, CD4, CD8, CD3, membrane immunoglobulin and HSA cell surface molecules.

Human CD2 is functional in CD2 transgenic mice

We aimed to study the biochemical consequences of T-cell activation via the CD2 antigen in mouse T cells. The lack of stimulatory monoclonal antibodies against the mouse CD2 antigen led us to analyse this problem in transgenic mice carrying and expressing the human CD2 gene. Monoclonal antibodies to the human CD2 antigen that were mitogenic for human T cells induced proliferation of mouse T cells from the CD2 transgenic mice. Stimulation was accompanied by rapid phosphorylation of the murine CD3 gamma chain and T-cell receptor zeta chain. These results demonstrate that the human CD2 antigen is functional in the CD2 transgenic mice and indicate a considerable conservation of the signal transducing processes and also the activation mechanisms between mouse and man.

Phosphorylation of murine CD8 alpha is not essential for responses of T cell hybridomas to antigen

CD8 T cell differentiation antigens, expressed on class I-restricted T cells, have a key role in the control of recognition and response of these cells to antigen. It has been suggested that these molecules function as co-receptors together with antigen-specific T cell receptors to regulate T cell responses. We have addressed the question of whether cytoplasmic serine phosphorylation, which occurs on CD8 molecules after activation by antigen or phorbol esters, is relevant to its co-receptor function. By mutagenesis, we show that phorbol ester-induced phosphorylation occurs exclusively on CD8 alpha serine residue 216. However, inhibition of CD8 polypeptide phosphorylation does not appear to have a detrimental effect on several responses of CD8-dependent transfectants to antigen. This is in contrast to results reported with CD4 (N.Glaichenhaus, N.Shastri, D.R. Littmann and J.M.Turner. 1991. Cell, 64:511), suggesting that CD4 and CD8 molecules may play somewhat different roles in the control of T cell activation.

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.

Anti-CD3-induced cell death in T cell hybridomas: mitochondrial failure and DNA fragmentation are distinct events

Triggering of the T cell receptor of T cell hybridomas leads to interleukin (IL) 2 secretion, inhibition of spontaneous growth, degradation of genomic DNA and cell death. We have investigated the relationship between the ability of mitochondria to convert 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT), DNA fragmentation and growth arrest in hybridomas stimulated with anti-CD3/T cell receptor antibodies. We describe a variant T hybridoma whose mitochondrial function remains unaffected upon stimulation with anti-CD3 antibody, although it does undergo DNA fragmentation. By contrast, treatment of another anti-CD3-stimulated T hybridoma with endonuclease inhibitor completely inhibits the DNA fragmentation response but not mitochondrial failure induced by anti-CD3 antibody. Thus, we have been able to dissociate anti-CD3-induced mitochondrial failure and DNA fragmentation, suggesting that they are separate events. Although both undoubtedly contribute to cell death induced by activation the primary cause of death may be mitochondrial failure rather than DNA fragmentation.

Inability of CD8 alpha' polypeptides to associate with p56lck correlates with impaired function in vitro and lack of expression in vivo

T-cell accessory molecules, particularly CD4 and CD8, seem to be involved in the control of T-cell activation by antigen. Precisely how such molecules operate is not fully understood, but evidence to date suggests a dual role, as receptors binding ligands on stimulator cells and by direct or indirect involvement in intracellular signalling events. In mouse, truncated 'tailless' CD8 molecules occur naturally (CD8 alpha' polypeptides) and although they are expressed on the surface of thymocytes, they are not expressed on the surface of mature T cells. In this study, we show that truncated CD8 molecules are impaired in their ability to interact with the protein tyrosine kinase, p56lck, and have decreased ability to restore immune responsiveness in vitro. Our data support a dual function for CD8 molecules correlated with expression of external domains and cytoplasmic domains, respectively. Both functions appear to be critical for a competent immune system in vivo.

Problems in the physiology of class I and class II MHC molecules, and of CD45

1. Co-processing of alloantigens suggests that epitope-loaded MHC class I molecules may pass from tissue cells to dendritic cells. 2. Antigen-presenting cells in the thymus need some special trick in order to load their MHC class II molecules with epitopes from "intermediate concentration" self-proteins in order to induce self-tolerance in developing cells. 3. Cell-cell interactions may transmit signals simply by rearranging surface glycoproteins and thus locally perturbing a phosphorylation equilibrium. 4. The CD45 and STB1 phenotype of most cells in the thymus may be characteristic of a doomed cell.

Peripheral tolerance mechanisms prevent the development of autoreactive T cells in chimeras grafted with two minor incompatible thymuses

The thymus has been shown to play an important role in the generation of T cell tolerance to self antigens. Developing T cells are readily tolerized to antigens which are expressed in the thymus, and it is generally thought that such thymic tolerance occurs by a mechanism of clonal deletion. We sought to examine whether T cells which initially encountered a "self antigen" post-thymically would be rendered tolerant of that antigen, and if so whether the mechanism of tolerance induction would differ from that found for thymic antigens. We constructed bone marrow radiation chimeras which were grafted with two thymus lobes differing in minor histocompatibility antigens. T cells which matured in one thymus would be tolerized to the minor histocompatibility antigens expressed in that thymus but would not encounter, and would therefore have no early opportunity of being tolerized to the minor histocompatibility antigens expressed by the other thymus. The initial encounter with the minor antigens on the second thymus would occur post-thymically. Would these T cells be tolerant or responsive to those minor histocompatibility antigens? We found that tolerance was dominant in these chimeras. The data further suggest that the mechanism responsible for tolerance induction in the periphery may differ from that which operates in the thymus.

A CD8 polypeptide that is lost after passing the Golgi but before reaching the cell surface: a novel sorting mechanism

The murine CD8 T cell differentiation antigen is a glycoprotein expressed on the cell surface as a heterodimer comprising the products of two closely linked genes, Ly-2 and Ly-3. The Ly-2 gene encodes, through a mechanism of alternate splicing, two polypeptide chains, alpha and alpha', that differ from one another in the lengths of their cytoplasmic tails. All T cells transcribe and translate both the alpha and alpha' polypeptides of Ly-2 and form heterodimers of each of these polypeptides disulphide-bonded with the Ly-3 polypeptide. However, there is very specific, developmentally controlled regulation of the expression of these heterodimers on the cell surface. Namely, immature T cells show no discrimination of CD8 molecules and express on their cell surface heterodimers containing the Ly-3 polypeptide linked to either the alpha or alpha' chain of Ly-2. In contrast, mature T cells express on their cell surface predominantly the heterodimer containing the Ly-2 alpha chain, the species which has a cytoplasmic tail. Moreover, in mature T cells the complexes which contain the alpha' chain are retained within the cell late in processing. These data emphasize the importance of the CD8 accessory molecule in the development of the functional T cell repertoire and uncover a novel protein sorting mechanism in mature T cells.

Molecular linkage of the Ly-3 and Ly-2 genes. Requirement of Ly-2 for Ly-3 surface expression

We have isolated the Ly-3 gene by chromosomal walking from the previously cloned Ly-2 gene. These genes are shown to be 36 kb apart and in the same transcriptional orientation. Transfection of the Ly-3 gene into mouse L cells results in cell surface expression of Ly-3 protein only in the presence of Ly-2 (or its human homolog, CD8), although Ly-2 surface expression is not similarly dependent on Ly-3. cDNA clones encoding Ly-3 have been isolated and sequenced and show little sequence similarity to Ly-2, whereas both Ly-2 and Ly-3 are homologous to Ig variable regions. One cDNA clone encodes a form of Ly-3 lacking a transmembrane region. Although two alleles of Ly-3 have been previously defined serologically, Northern blot analyses of Ly-3 mRNA from a series of inbred mouse strains show unusual polymorphisms in the lengths of Ly-3 mRNA species defining at least three allelic variants of this gene.

Molecular linkage of the Ly-3 and Ly-2 genes. Requirement of Ly-2 for Ly-3 surface expression

We have isolated the Ly-3 gene by chromosomal walking from the previously cloned Ly-2 gene. These genes are shown to be 36 kb apart and in the same transcriptional orientation. Transfection of the Ly-3 gene into mouse L cells results in cell surface expression of Ly-3 protein only in the presence of Ly-2 (or its human homolog, CD8), although Ly-2 surface expression is not similarly dependent on Ly-3. cDNA clones encoding Ly-3 have been isolated and sequenced and show little sequence similarity to Ly-2, whereas both Ly-2 and Ly-3 are homologous to Ig variable regions. One cDNA clone encodes a form of Ly-3 lacking a transmembrane region. Although two alleles of Ly-3 have been previously defined serologically, Northern blot analyses of Ly-3 mRNA from a series of inbred mouse strains show unusual polymorphisms in the lengths of Ly-3 mRNA species defining at least three allelic variants of this gene.

Reconstitution of MHC class I specificity by transfer of the T cell receptor and Lyt-2 genes

The T cell receptor alpha and beta chain genes donated by an H-2 class I-specific, CD8-dependent cytotoxic T cell clone were transferred, alone or in combination with the Lyt-2 gene, into a class II-restricted, CD4+ T cell hybridoma. Two important points emerged. First, the alpha and beta T cell receptor genes endowed the recipient with the H-2 class I specificity of the donor only if the same cell had also been transfected with the Lyt-2 gene. Second, the functional Lyt-2 molecule was expressed on the transfected cells in the absence of the Lyt-3 polypeptide. These results demonstrate that, besides the T cell receptor, the Lyt-2 polypeptide is the only subset-specific molecule required to retarget a class II-reactive, CD4+ T cell line toward H-2 class I molecules.

Transfection of the CD8 gene enhances T-cell recognition

Antibodies against CD8 or CD4 antigens can prevent T-cell functions induced by T-cell targets. As CD8 or CD4 antibodies can also initiate negative signals in T cells in the absence of appropriate targets it is not clear whether CD8 and CD4 molecules are directly involved in the interaction of T cells with their targets. In previous experiments we have introduced the T-cell receptor alpha- and beta-chain genes from a CD8-positive cytolytic T cell specific for the antigen fluorescein (FL) and the H-2D molecule of the major histocompatibility complex (MHC) into a CD8-negative recipient cell. The CD8-positive donor cell lysed both FL-conjugated fibroblasts and lymphoblasts, which express relatively high and low amounts of H-2D molecules, respectively. In contrast the CD8-negative transfectant lysed FL-conjugated fibroblasts only. Here we show that recognition of FL-conjugated lymphoblasts by the transfectant is enhanced by supertransfecting it with the CD8 gene.

Structure, sequence, and polymorphism of the Lyt-2 T cell differentiation antigen gene

We have determined the nucleotide sequence and genomic organization of the mouse Lyt-2 T lymphocyte differentiation antigen gene. This gene consists of five exons and four introns, and the organization roughly parallels the protein domains. Alternative splicing to include or exclude exon IV (encoding part of the cytoplasmic tail) results in two forms of mRNA and accounts for the difference in size between the alpha- and alpha'-chains of Lyt-2. The gene structure provides further evidence for the evolutionary relationship between Lyt-2 and immunoglobulin genes. Comparison of the nucleotide sequence of the Lyt-2.1 and Lyt-2.2 alleles shows a high degree of conservation, but indicates that a single nucleotide change and consequent amino acid substitution in the variable region-like domain accounts for the serologic difference between these two alleles.

Structure, sequence, and polymorphism of the Lyt-2 T cell differentiation antigen gene

We have determined the nucleotide sequence and genomic organization of the mouse Lyt-2 T lymphocyte differentiation antigen gene. This gene consists of five exons and four introns, and the organization roughly parallels the protein domains. Alternative splicing to include or exclude exon IV (encoding part of the cytoplasmic tail) results in two forms of mRNA and accounts for the difference in size between the alpha- and alpha'-chains of Lyt-2. The gene structure provides further evidence for the evolutionary relationship between Lyt-2 and immunoglobulin genes. Comparison of the nucleotide sequence of the Lyt-2.1 and Lyt-2.2 alleles shows a high degree of conservation, but indicates that a single nucleotide change and consequent amino acid substitution in the variable region-like domain accounts for the serologic difference between these two alleles.

Two Lyt-2 polypeptides arise from a single gene by alternative splicing patterns of mRNA

The Lyt-2/3 molecule is a glycoprotein expressed on T lymphocytes and has classically been considered a marker for the cytotoxic/suppressor T cell subset. It has been postulated to be a receptor for class I major histocompatibility complex proteins. We have used a cDNA clone encoding the analogous human protein, Leu-2/T8, to isolate mouse cDNA clones, which were used as probes to isolate mouse genomic clones. By transfection we have shown that the mouse homologue of Leu-2/T8 is Lyt-2 and not Lyt-3. We have further demonstrated that two Lyt-2 polypeptide chains are encoded by a single gene and result from alternative modes of mRNA splicing. The nucleotide sequence of cDNA clones encoding each of these polypeptide chains has been determined and shows the difference between the two Lyt-2 polypeptide chains to be in the lengths of their cytoplasmic tails.

Allosuppression: evidence for the involvement of both "noncytotoxic" and cytotoxic T cells

Allogeneic suppressor cells were generated by priming to a minor histocompatibility antigen. C57BL/10 female mice were primed to the male-specific minor transplantation antigen, H-Y. After boosting, anti-male-primed cells could potently suppress the secondary antibody response of male spleen cells in vitro. Anti-male suppressor cells were H-2-restricted, radiation-resistant T cells which could act on either T or B cells in the responding population. Mapping the restriction elements for anti-male suppressor cells revealed two distinct subpopulations of effector cells. The majority subpopulation was restricted to H-Y in the context of the H-2Db molecule. These cells were probably cytotoxic T cells as they were inhibited by culture of the suppressor cells in pyrilamide (a histamine receptor antagonist, which prevents the maturation of cytotoxic T cells from their precursors). The second subpopulation of suppressor cells was restricted to H-Y in the context of H-2K or I region-coded molecules. as neither H-2Kb nor H-2Ib molecules can act as restriction elements for anti-male-specific cytotoxic T cells, this subpopulations was almost certainly not composed of conventional cytotoxic cells. Furthermore, these cells were not affected by culture in pyrilamide. Together these two populations act to completely inhibit the anti-trinitrophenyl (TNP) plaque-forming cell response of male spleen cells in vitro.

Self tolerance is H-2-restricted

H-2 restriction is an established characteristic of T-cell behaviour and, in effect, it means that mouse T cells are activated against foreign antigens only if those antigens are presented in a membrane association with molecules of the mouse major histocompatibility complex, H-2. Whether T-cell inactivation or tolerance is also H-2-restricted is a question which has been tested directly and indirectly several times in the past. In each case the answer was 'No' but in each case the answer was inconclusive. Doubts arose because of the observation that activation of T cells, in vivo, is an H-2-restricted event which appears unrestricted because of antigen processing by the host. If antigen processing is involved in the induction of tolerance, then tolerance might also be an H-2-restricted process disguised to appear unrestricted. We report here a study designed to minimize antigen processing in which we find that T-cell tolerance induction to 'self' minor histocompatibility (H) antigens is indeed H-2-restricted.