Multiple kinases and signal transduction. Phosphorylation of the T cell antigen receptor complex

T-cell development and transmembrane signaling: changing biological responses through an unchanging receptor

The antigen receptor repertoire is conditioned by discriminating forces in the thymus. Cells that see antigen only in the context of self major histocompatibility gene products are positively selected and those that recognize self antigens are deleted. The molecular mechanisms by which this complex conditioning is achieved via a single antigen receptor is one of the most fascinating problems in immunology. Here Terri Helman Finkel and colleagues review the literature and present a unifying mechanistic model of this process.

Subcellular distribution and phosphorylation state of insulin receptors from insulin- and isoproterenol-treated rat adipose cells

Rat adipose cells treated with insulin followed by isoproterenol exhibit a change in glucose transporter intrinsic activity (lowered maximal activity) and a decrease in insulin sensitivity (rightward shift of the concentration-response curve) when assayed for 3-O-methylglucose transport. To investigate the latter phenomenon, the distribution and phosphorylation state of insulin receptors was examined. Isoproterenol augmented the effect of insulin to reduce cell surface receptors by 20-30%. These receptors were recovered in microsomal fractions. Isoproterenol also markedly reduced insulin-stimulated [32P]phosphate incorporation into the plasma membrane receptor beta-subunit. These effects may account for the effect of isoproterenol to decrease the sensitivity of the glucose transport response to insulin.

Identification of two distinct phosphoproteins as components of the human B cell antigen receptor complex

In human B cells, the molecules that, upon receptor occupancy, couple membrane immunoglobulin to intracellular signal transduction pathways have never been identified. We here describe two phosphoproteins as integral parts of the B cell antigen receptor complex. Membrane IgM is non-covalently associated with a disulfide-linked heterodimer of glycoproteins. These molecules can be demonstrated on B cell lines and freshly isolated polyclonal B cell populations and are subject to phosphorylation at serine residues. Identification of these constituents of the B cell receptor complex opens up the opportunity to study coupling of the B cell antigen receptor to the intracellular signal transduction machinery at the molecular level.

A human TCR-Ig chimeric protein used to generate a TCR alpha chain variable region-specific mAb

In a recent report, a construction containing the alpha chain-variable region (V alpha) coding sequence of a cDNA clone derived from a diphtheria toxoid-specific human T cell (P28), fused to a human immunoglobulin kappa light chain constant region (Ck), was used stably to transfect a murine myeloma cell. In the present study, these transfected cells were employed as an immunogen to raise a mAb, termed 1C5V alpha, specific both for the V alpha Ck chimeric protein secreted by the transfectant and the P28 T cell antigen receptor-V alpha region. mAb 1C5V alpha specifically immunoprecipitates the V alpha Ck protein as a family of 32-35 kDa bands present in the 35S-methionine-labeled culture supernatant from the transfected cells. It specifically binds clone P28. Surface molecules recognized by mAb 1C5V alpha are physically linked to the CD3 molecules since cell treatment with either 1C5V alpha or anti-CD3 mAbs caused the simultaneous down-regulation of the CD3/TCR molecular complex. This link is further supported by immunoprecipitation experiments. Thus, both the 1C5V alpha and the anti-CD3 mAbs precipitate the 16-28 kDa CD3 molecules and the disulfide-linked form of P28 TCR from 125I-labeled P28 T cells. Studies performed in order to define whether a stimulus directly acting on the TCR-V alpha region may trigger the intracellular events observed during human T cell activation showed that (a) mAb 1C5V alpha efficiently triggers the phospholipase C transduction pathway revealed by an accelerated phosphoinositides turn-over and an increased production of phosphorylated derivatives of inositol phosphates; (b) mAb 1C5V alpha induces an up-regulation of IL2R mRNA, accompanied by a slight increase of IL2 and IFN alpha mRNA transcripts evidently amplified in the presence of PMA; (c) soluble mAb 1C5V alpha is strongly mitogenic together with PMA. These results provide the first evidence for the structural authenticity of a secreted water-soluble chimeric form of the variable region of a human TCR alpha chain. They further demonstrate that such chimeric proteins may be valuable tool to further dissect the various functional structure of the human TCR.

Selection of T cell receptor expression mutants through the functionally linked Ly-6A

Ly-6A is a glycosyl-phosphatidylinositol (GPI)-anchored molecule that participates in murine T cell activation. Activation of T cell hybridomas with anti-Ly-6A monoclonal antibody (mAb) leads to production of interleukin-2 (IL-2), but also to a paradoxical growth inhibition, which was used to select for signaling mutants. Fifteen subclones derived from two independent mutageneses and anti-Ly-6A selection were characterized. Thirteen subclones responded poorly or not at all to soluble anti-Ly-6A mAb. Although the selective pressure was exerted through Ly-6A, only one mutant did not express the Ly-6A antigen. Interestingly, 10 of the 15 subclones expressed either nondetectable or a very low level of T cell receptor/CD3 complex (TCR/CD3). Preferential expansion of TCR/CD3 expression mutants following anti-Ly-6A selection further established functional linkage between Ly-6A and TCR/CD3 complex. The mechanism of the functional coupling was investigated by analyzing the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2), one of the early events in T cell activation. We showed that PIP2 was not hydrolyzed in response to anti-Ly-6A in TCR/CD3-negative mutants. Aluminum fluoride, which activates G protein directly, did induce PIP2 hydrolysis in these cells. These data suggest that activation signals originated from Ly-6A must be transmitted first to TCR/CD3 complex, which then couples to the G protein/phospholipase C system. A similar requirement also applies to the Thy-1 protein and lectin receptors. Thus, the TCR/CD3 complex plays a central role in the integration and transmission of activation signals that originated from several T cell surface molecules.

Family of disulphide-linked dimers containing the zeta and eta chains of the T-cell receptor and the gamma chain of Fc receptors

Stimulation of T cells by antigen activates many signalling pathways. The capacity for this range of biochemical responses may reside in the complex structure of the seven-chain T-cell antigen receptor (TCR). In addition to the complexity shared by all TCRs, coexpression of zeta (zeta) and the distinct but related eta (eta) chains creates structural diversity among the TCR complexes expressed on a given cell. In most murine T cells that we have studied, about 90% of the heptameric receptor complexes contain a zeta zeta disulphide homodimer, whereas 10% contain a zeta eta disulphide heterodimer. Recent studies suggest that zeta has a critical role in allowing antigen to activate the cell, whereas eta expression has been correlated with the capacity for antigen-induced phosphoinositide turnover. A third zeta-related protein, the gamma (gamma) chain of the Fc epsilon and some Fc gamma receptors, exists as a disulphide homodimer in those complexes. The structural relatedness of zeta and gamma is emphasized by the recent demonstration of zeta zeta in association with CD16 in TCR-negative natural killer cells. Here we identify T cells lacking Fc receptors but coexpressing zeta, gamma, and eta, document the formation of novel heterodimers between zeta and gamma and between eta and gamma and show their association with the TCR. A greater range of homologous coupling structures than previously thought may be one way of achieving the variety of TCR-mediated (and possibly Fc receptor-mediated) biochemical responses and effector functions.

The G protein coupling T cell antigen receptor/CD3-complex and phospholipase C in the human T cell lymphoma Jurkat is not a target for cholera toxin

Intact Jurkat cells could be stimulated by monoclonal antibodies against the Tcell antigen receptor complex (OKT3 directed against the CD3 complex, BMA031 directed against constant framework epitopes in the alpha/beta heterodimer). The accumulation of inositol phosphates was inhibited by prior incubation of the cells with cholera holotoxin. The inhibitory effect of cholera toxin (CT) was not cAMP mediated because forskolin (a direct activator of adenylate cyclase) did not mimic the inhibitory effect. When measuring phospholipase C (PLC) in a cell-free assay system by using [3H]inositol-labeled membranes, the enzyme could be stimulated by the poorly hydrolyzable GTP analogue guanosine 5'-O-(thiotriphosphate (GTP gamma S). Both anti-receptor antibodies augmented the GTP gamma S stimulatory effect, while the antibodies alone had no stimulatory capacity. In membranes from CT-pretreated cells, whereas the antibodies lost their stimulatory effect on PLC as in untreated cells, whereas the antibodies lost their stimulatory capacity in the presence of GTP gamma S. These data imply that CT exerts its inhibitory effect on signaling by acting at the receptor level while the PLC regulating G protein is not a target for CT-mediated alterations. This assumption is supported by the finding that in intact Jurkat cells CT, which ADP ribosylated only the alpha-subunit of the stimulatory G protein of the adenylate cyclase, led to a loss of the T cell antigen receptor complex from the cell surface as demonstrated by a decrease of receptor density using flow cytometry analysis. Receptor loss could not be achieved by forskolin treatment or incubation of the cells with the binding subunit of the toxin alone.

Regulation of expression of interleukin 2 receptors upon triggering of the TCR-CD3 complex on human T lymphocytes

Monoclonal antibodies reactive with CD3 molecular complex can induce antigen-associated early biochemical changes in purified, monocyte-depleted resting T cell populations and synergize with interleukin 2 (IL2) in the induction of T-cell proliferation. Interleukin 2 mediates its effects via two receptor molecules of apparent 70-75 kD (p70/p75) and 50-55 kD (p50/55) molecular weights respectively. Using radioactive IL2 and bi-functional cross-linking chemistry, we are able to determine that incubation of purified, monocyte-depleted, resting T cells with anti-CD3 (OKT3) antibody induces a significant and selective increase in the expression of p70/75 IL2 receptors from their low constitutively expressed levels. This event occurs in the complete absence of cellular proliferation. Although IL2 also causes the upregulation of p70/75 molecules, it is the synergistic action of both antibody and lymphokine which is needed for the induction of significant amounts of the p50/55 IL2 receptors and the concomitant cellular proliferation. The effect of anti-CD3 on p70/75 receptor expression is specific, as determined by the inability of a non-related (anti-CD2) monoclonal antibody of the same subclass (IgG2a) to induce a similar effect. The Ca++ ionophore ionomycin, under conditions that cause significant intracellular Ca++ influx cannot by itself mediate upregulation of IL2 receptor expression in T cells. Since anti-CD3 itself can induce intracellular Ca++ increase in purified T cells, the finding with the ionophore suggests that the intracellular Ca++ accumulation alone cannot account for the IL2 receptor molecular events described here. Addition of PMA induces both p70/75 and p50/55 IL2 receptor upregulation, as well as IL2-dependent proliferation. Although resting T cells constitutively express p70/75 receptors, under our experimental conditions and with the concentration of IL2 used, these molecules cannot transduce the lymphokine signal efficiently. Thus, in a physiologic context, a simple interpretation of our data could be that upon interaction of the TCR/CD3 with antigen a selective upregulation of p70/75 IL2 receptors renders them competent of not only binding the lymphokine, but also transducing its signal. The latter event leads to the expression of p50/55 receptors and subsequent proliferation. Whether an increase in the numbers of these receptors is all that is needed or additional events are necessary merits further investigation.

Transmembrane helical interactions and the assembly of the T cell receptor complex

Studies of the subunit interactions of the multicomponent T cell antigen receptor (TCR) revealed that specific pairs of chains have the ability to assemble after transfection into fibroblasts. For one such pair, TCR-alpha and CD3-delta, their ability to assemble was encoded by their transmembrane domains. The specificity of this interaction suggests that well-defined helical interactions in the membrane can explain the assembly of some multichain membrane complexes.

Multiple tyrosine protein kinases structurally related to p56 lck are down-regulated following mitogenic stimulation of human T lymphocytes

p56 lck is a well-characterized tyrosine protein kinase (TPK) which is thought to play a role in mitogenic signal transduction in T lymphocytes. Immunoblot analysis of human lymphocyte proteins using an antiserum cross-reactive with phosphotyrosine resulted in the detection of a 55-60 kDa protein band (presumably p56 lck) as well as several additional phosphotyrosyl proteins in lymphocyte extracts. All of these phosphotyrosyl proteins were down-regulated following mitotic stimulation. Autophosphorylation of lymphocyte microsomal fractions in the presence of [gamma-32P] ATP resulted in the labelling of p56 lck as well as other proteins of different molecular weights. Analysis of these labelled proteins by tryptic digestion resulted in strikingly similar peptide maps. The data suggest that lymphocytes may contain a family of TPKs structurally related to p56 lck. The down-regulation of the putative TPKs following mitogenic stimulation of lymphocytes with phytohaemagglutinin suggests that this family of TPKs may participate in mitotic signalling events, followed by their down-regulation.

Tyrosine phosphatase CD45 is essential for coupling T-cell antigen receptor to the phosphatidyl inositol pathway

Stimulation of T lymphocytes through their antigen receptor (T-cell receptor; TCR) results in the activation of a tyrosine kinase and the generation of phosphatidyl inositol (PtdIns)-derived second messengers. Several reports have indicated that CD45, a haematopoietic cell-specific surface glycoprotein with tyrosine phosphatase activity in its cytoplasmic domain, is important in lymphocyte activation. To examine the possibility that CD45 might influence proximal signal transduction events through the TCR, we have isolated a variant of the human T-cell leukaemic line, HPB-ALL, which fails to express this phosphatase. Unlike cells expressing CD45, stimulation of the TCR in the CD45-negative cell does not result in PtdIns-derived second messengers. Reconstitution of CD45 expression restored early signalling events through the TCR. To localize the site of CD45 action, the human muscarinic type 1 receptor, which also activates the PtdIns second messenger pathway, was transfected into the CD45-negative cell. Although stimulation of the TCR failed to generate PtdIns-derived second messengers, there was normal activity of the PtdIns pathway when human muscarinic receptor type 1 was stimulated, despite the absence of CD45. These data indicate that CD45 influences a cellular component that is essential for effective coupling of the TCR to the PtdIns second messenger pathway.

Stimulation of protein tyrosine phosphorylation by the B-lymphocyte antigen receptor

Signalling by membrane immunoglobulin, the B-lymphocyte antigen receptor, regulates B-cell maturation and activation. Crosslinking of membrane immunoglobulin by antigen or by anti-immunoglobulin antibodies inactivates immature B cells, eliminating many of the B cells capable of producing auto-antibodies. By contrast, crosslinking of membrane immunoglobulin promotes activation of mature B cells for clonal expansion and antibody production against foreign antigens. Crosslinking membrane IgM on the immature B-cell line WEHI-231 induces growth arrest. This response may be analogous to the deletion or inactivation of immature B cells that is induced by antigen or anti-IgM antibodies. Membrane immunoglobulin crosslinking stimulates phosphoinositide hydrolysis, which leads to increases in intracellular calcium and activation of protein kinase C. The induced phosphoinositide breakdown is important for inhibiting WEHI-231 growth (ref. 7 and D. Page, M.R.G., K. Fahey, L. Matsuuchi and A.L.D., manuscript submitted for publication), but may not be sufficient, as agents that elevate calcium and activate protein kinase C cause only partial growth arrest. We now show that in both mature splenic B cells and the immature B-cell line WEHI-231 crosslinking membrane immunoglobulin also stimulates phosphorylation of protein tyrosine, a reaction that has been implicated as a key regulator of cell growth. Most of these phosphorylations were not a consequence of the phosphoinositide pathway. Thus, tyrosine phosphorylation is a second mode of transmembrane signalling by membrane immunoglobulin.

Protein kinase C and T cell activation

Understanding the intracellular mechanisms by which binding of ligands, such as hormones and growth factors, to their specific receptors elicits the appropriate cellular response has long been a topic of great interest. Considerable excitement was generated when it was recognised that several receptor-ligand interactions operate via the hydrolysis of inositol phospholipids. This yields, at least, two 'second messengers', namely, inositol 1,4,5-trisphosphate [Ins(1,4,5)P3], which causes the release of Ca2+ from intracellular stores, and 1,2-diacylglycerol (ac2Gro), which activates the serine/threonine-specific enzyme, protein kinase C(PKC), reviewed in [1] and [2]. The pertinent question that follows is, how do PKC activation and elevation of the intracellular Ca2+ concentration evoke cell responses? In this review, attention has been focused on PKC, and the consequences of its activation in resting human T cells. Evidence that PKC activity is, at least partially, responsible for activation of resting human T cells will be examined, and some of the more recent research investigating how PKC activation elicits this cell response will be described.

T cell antigen receptor-mediated activation of phospholipase C requires tyrosine phosphorylation

Triggering of the antigen-specific T cell receptor-CD3 complex (TCR-CD3) stimulates a rapid phospholipase C-mediated hydrolysis of inositol phospholipids, resulting in the production of second messengers and in T cell activation and proliferation. The role of tyrosine phosphorylation in these events was investigated with a tyrosine protein kinase (TPK) inhibitor, genistein. At doses that inhibited TPK activity and tyrosine phosphorylation of the TCR zeta subunit, but not phospholipase C activity, genistein prevented TCR-CD3-mediated phospholipase C activation, interleukin-2 receptor expression, and T cell proliferation. These findings indicate that tyrosine phosphorylation is an early and critical event that most likely precedes, and is a prerequisite for, inositol phospholipid breakdown during receptor-mediated T cell activation.

CD45 ligation in T cells regulates signal transduction through both the interleukin-2 receptor and the CD3/Ti T-cell receptor complex

The cytoplasmic domain of the CD45 leukocyte cell surface antigen has recently been shown to possess protein tyrosine phosphatase (PTPase) activity. The existence of a cell membrane-bound PTPase may represent a mechanism by which an activation signal, initiated by ligand binding to a surface receptor, is down-regulated following delivery of the signal. Both the interleukin-2 (IL2) growth factor receptor and the CD3/Ti T-cell antigen receptor contain a subunit which is phosphorylated on tyrosine by an activated protein kinase (PTK) during T-cell activation. We compared the effect of CD45 ligation on signal transduction mediated by the binding of IL2 or anti-CD3 to these two receptors. Immunoblotting with anti-phosphotyrosine antiserum was used to investigate the effect of CD45 ligation on anti-CD3- or IL2-induced protein tyrosine phosphorylation. When CD3 and CD45 were triggered together, changes in the pattern of tyrosine phosphorylation of specific substrates was observed in comparison to the stimulus triggered through CD3 alone. In contrast, CD45 ligation did not alter the pattern of tyrosine-phosphorylated proteins in "resting" T-cell blasts responding to IL2, except for a mobility shift of a 55 kDa protein and increased phosphorylation of a 112 kDa substrate. The proliferative response of T cells to both anti-CD3 or IL2 was inhibited by ligating CD45. The CD45 molecule down-regulated CD3-induced T-cell activation when the CD45 and CD3 molecules were ligated simultaneously with immobilized antibodies. In contrast, immobilized CD45 mAb alone inhibited IL2-induced proliferation, and the inhibition was not potentiated by simultaneously using a CD25 mAb which was non-competitive for IL2-binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural nature of the interaction between T lymphocyte surface molecule CD4 and the intracellular protein tyrosine kinase lck

The strong non-covalent interactions between T lymphocyte surface CD4 or CD8 molecules and the intracellular membrane-associated protein tyrosine kinase lck are likely to mediate the role of CD4 and CD8 molecules in the immune response. The delineation of the structural nature of the CD4/lck and CD8/lck complexes is important for the understanding of the biochemical and functional significance of the interactions. Complementary charged regions in the C-terminal intracytoplasmic portions of CD4 or CD8, and in the N-terminal region of protein tyrosine kinase lck were noted. Peptides spanning these regions, residues 417 to 429 of CD4 and 10 to 22 of lck, were found to specifically dissociate these two molecules in CD4/lck complexes. A structural model of the interaction that accounts for its high stability is proposed.

Potent selective inhibitors of protein kinase C

A series of potent, selective inhibitors of protein kinase C has been derived from the structural lead provided by the microbial broth products, staurosporine and K252a. Our inhibitors block PCK in intact cells (platelets and T cells), and prevent the proliferation of mononuclear cells in response to interleukin 2 (IL2).

The lymphocyte-specific protein tyrosine kinase p56lck is hyperphosphorylated on serine and tyrosine residues within minutes after activation via T cell receptor or CD2

Human T cells can be activated and induced to proliferate through either the antigen-specific receptor complex (TcR-CD3) or the CD2 surface molecule. Following stimulation, both serine and tyrosine phosphorylation of cellular protein have been demonstrated to occur. p56lck, a protein tyrosine kinase associated to the inner face of the plasma membrane, is almost exclusively expressed in lymphoid cells, especially T cells. Within minutes after activation of a human T cell-derived line (Jurkat) via stimulation of either the TcR-CD3 complex or the CD2 glycoprotein, we observed a hyperphorphosylation of p56lck. A concomitant shift to a higher molecular weight in sodium dodecyl sulfate-polyacrylamide gel was also observed. Similar changes were obtained with phorbol 12-myristate 13-acetate. Tryptic phosphopeptide analysis of the hyperphosphorylated form of p56lck yielded new phosphorylated sites in serine residues and an increased tyrosine phosphorylation. These results suggest that p56lck may be intimately connected to the signaling pathway in T cell activation.

T-cell receptor cross-linking transiently stimulates adhesiveness through LFA-1

Effective interaction between T cells and their targets requires that recognition of specific antigen be coordinated with increased cell-cell adhesion. We show that antigen-receptor cross-linking increases the strength of the adhesion mechanism between lymphocyte function-associated molecule-1 (LFA-1) and intercellular adhesion molecules (ICAMs), with intracellular signals transmitted from the T-cell antigen receptor to the LFA-1 adhesion molecule. The increase in avidity is rapid and transient, providing a dynamic mechanism for antigen-specific regulation of lymphocyte adhesion and de-adhesion.

Calcium and T lymphocyte activation

A prolonged (at least 2-4 hr) elevation of [Ca2+]i accompanies early T cell activation by TCR/CD3-specific ligands. Ca2+ is generally thought to be an essential second messenger for early activation, but the precise molecular events contingent upon the Ca2+ signal remain to be determined. The Ca2+ signal can be separated into an early transient peak due to InsP3-released Ca2+ from intracellular stores, and a sustained plateau due to altered transmembrane Ca2+ flux. Patch clamp studies have identified an InsP3-activated, Ca2+ permeable channel in the plasma membrane of T lymphocytes that may be responsible for the sustained elevation of [Ca2+]i during continuous TCR/CD3 occupancy. The Ca2+ signal can be further resolved at the level of the single cell into a series of repetitive oscillations between peak and trough levels with a period of 16-20 s. The oscillations may be part of a frequency-encoded signaling system. Several nonlinear internal feedback controls may contribute to the periodic nature of the Ca2+ signal: PKC-mediated phosphorylation of the CD3 gamma subunit, which is a feedback inhibitor of TCR/CD3 function; amplification of Ca2+ release from endoplasmic reticulum by a highly cooperative step in the opening of Ca2+ channels by InsP3, and Ca2+-dependent feedback enhancement of PLC function; autoregulatory negative feedback on Ca2+ influx by Ca2+, both by a direct effect on the plasma membrane Ca2+ channel and by induction of membrane hyperpolarization secondary to Ca2+-activated K+ efflux. In addition, several other internal feedback controls on TCR/CD3 function, by CD4-induced tyrosine-specific phosphorylation of the CD3 zeta subunit, or on the Ca2+ signal, by extracellular Cl- or by GM1 gangliosides, are also postulated. The question of whether a G protein couples TCR/CD3 to PI hydrolysis and to Ca2+ mobilization is unresolved, although some indirect evidence for the involvement of GTP binding proteins in T cell activation has recently been obtained with cholera toxin. There is also preliminary evidence that TCR/CD3 may structurally conform to G protein coupled receptors, i.e., having a core structure of seven alpha helical transmembrane spanning segments, a ligand recognition site, loci for regulatory phosphorylation, and a putative nucleotide binding site.

DNA fragmentation and cell death mediated by T cell antigen receptor/CD3 complex on a leukemia T cell line

An anti-T cell receptor (TcR) monoclonal antibody (mAb), LC4, directed against a human leukemic T cell line, SUP-T13, caused DNA fragmentation ("apoptosis") and cell death upon binding to this cell line. Cross-linking of receptor molecules was necessary for this effect since F(ab')2, but not Fab', fragments of LC4 could induce cell death. Five anti-CD3 mAb tested also caused apoptosis, but only when they were presented on a solid phase. Interestingly, soluble anti-CD3 mAb induced calcium flux and had an additive effect on the calcium flux and interleukin 2 receptor expression induced by LC4, but these anti-CD3 mAb reversed the growth inhibition and apoptosis caused by LC4. The calcium ionophore A23187, but not the protein kinase C activator phorbol 12-myristate 13-acetate (PMA), also induced apoptosis, suggesting that protein kinase C activation alone does not cause apoptosis, although PMA is growth inhibitory. These results suggest that two distinct biological phenomena can accompany stimulation of the TcR/CD3 complex. In both cases, calcium flux and interleukin 2 receptor expression is induced, but only in one case is apoptosis and cell death seen. The signal initiating apoptosis can be selectively prevented by binding CD3 portion of the receptor in this cell line. This difference in signals mediated by the TcR/CD3 complex may be important in explaining the process of thymic selection, as well as in choosing anti-TcR mAb for therapeutic use.

A function for the lck proto-oncogene

Proto-oncogenes encode products that comprise a select group of cellular regulatory proteins whose mutation or aberrant expression can result in oncogenic transformation. With the exception of certain growth factors and their receptors, the definition of normal functions for most proto-oncogene products has been elusive. The discovery that a member of the src-family of tyrosine protein kinases (p56lck) is associated with both the CD4 and CD8 T-lymphocyte surface glycoproteins provides the first clue to understanding the potential physiological functions of this family of proto-oncogenes.

Molecular interactions, T-cell subsets and a role of the CD4/CD8:p56lck complex in human T-cell activation

Several T-cell structures are capable of generating intracellular signals linked to T-cell proliferation. Crosslinking of CD2, CD4 and CD45 with Ti/CD3 to several of these antigens can augment the minimal signal induced by antigen binding to the Ti/CD3 complex. Importantly, some of these regulatory structures (CD4, CD8 and CD45) are also expressed on subsets of T cells with distinct activation requirements and functional programs (helper, suppressor, suppressor-inducer and cytotoxic function). The CD4+ CD45RA+ (2H4+) subset responds well to self-Ia, poorly to soluble antigen and possesses suppressor-inducer function. A reciprocal subset CD4+ CD45RA- (4B4+) is preferentially activated by soluble recall antigens and possesses helper function. Each of these subsets can be distinguished by virtue of the differential expression of CD45 antigens. Importantly, the anti-2H4 antibody which reacts with a specific region near the N-terminus of two CD45 isoforms can effectively block its function. Crosslinking of CD4 with the Ti/CD3 complex preferentially activated the CD4+ CD45+ RA- subset, while soluble antibodies to CD2 preferentially affected the CD45 CD45RA+ subset. Thus, CD3 and CD4 more effectively synergize in the activation process on the CD4+ CD45RA- subset, a result consistent with the ability of this subpopulation to respond to recall antigens. The regulatory role of the CD4, CD8 and CD45 antigens may be mediated by an interactive network of protein-tyrosine phosphorylation and dephosphorylation. We have shown the CD4 and CD8 antigens to be associated with the T cell-specific protein-tyrosine kinase (p56lck). p56lck is a member of a family of protein-tyrosine kinases with an established ability to activate and transform mammalian cells. The CD4/CD8:p56lck complex is catalytically active as shown by its ability to phosphorylate various members of the Ti/CD3 complex. By contrast, the CD45 antigens possess protein-tyrosine phosphatase activity within their intracellular domains and are postulated to function by virtue of a regulatory interaction with CD4/CD8:p56lck and its potential substrates. Thus, the differences in the response of the CD4+ CD45RA+/- subsets to various stimuli and the expansion of T-cell subsets with distinct immunoregulatory programs may be governed by a pathway of tyrosine-mediated events.

Cyclic AMP can enhance mouse B cell activation by regulating progression into the late G1/S phase

This study demonstrates that several substances which raise intracellular adenosine 3',5'-cyclic monophosphate (cAMP) levels in different ways were able to enhance both RNA and DNA synthesis in mouse purified B cells co-stimulated by the protein kinase C activator phorbol 12-myristate 13-acetate and the Ca2+ ionophore ionomycin, while earlier activation events were not modified. These included early changes in cell size and chromatin decondensing demonstrated by light scatter properties at narrow and 90 degrees angles, increase in Ia expression and loss of surface IgD. We concluded that cAMP can up-regulate mouse B cell activation by controlling progression into the late G1 (G1B)/S phase, but not transition from G0 to early G1 (G1A). Furthermore, because cAMP could synergize with ionomycin but not with phorbol 12-myristate 13-acetate to induce RNA and DNA synthesis, we proposed that the cAMP effects in this model may be related to the protein kinase C pathway.

Do CD4 and CD8 control T-cell activation via a specific tyrosine protein kinase?

The CD4 and CD8 glycoproteins play an important role in T-cell activation by binding to major histocompatibility complex (MHC) class II or class I molecules, respectively, and stabilizing their interactions with the T-cell receptor-CD3 complex during antigen presentation. Recent evidence suggesting that the cytoplasmic domains of CD4 and CD8 are physically, and perhaps functionally, linked to the T-cell specific tyrosine protein kinase, p56lck, adds a new dimension to our current understanding of their physiological function. Based on these and other recent findings, Tomas Mustelin and Amnon Altman present a working hypothesis that defines a novel role for CD4 or CD8 in regulating T-cell activation, and perhaps other processes, such as thymic repertoire selection and human immunodeficiency virus (HIV)-induced immunosuppression.

Increased cyclic AMP levels block interleukin 2-induced protein kinase C substrate phosphorylation but not the mitogenic response

Protein kinase C (PKC) has been implicated in the signaling of a number of cellular responses including activation of T cells. In the present report we have evaluated the effect of increased cAMP levels on PKC activation after stimulation of two distinct receptor systems on normal human T cells. PKC substrate phosphorylation can be induced via either the CD3 complex or, to a limited extent, the high affinity interleukin 2 (IL 2) receptor. Substrate phosphorylation via both pathways is shown to be blocked by increased intracellular levels of cAMP. In accordance with previous reports, the CD3-dependent autocrine proliferative response could also be blocked by a cAMP-dependent mechanism. Since direct activation of PKC with a phorbol ester reversed this inhibition, a causal relationship between cAMP-dependent PKC blockage and inhibition of the CD3 response is suggested. In contrast, however, initiation of IL 2-induced proliferation was essentially unaltered by cAMP and could progress in the apparent absence of PKC activity. Thus, this study indicates that IL 2-induced proliferation can under such conditions be completely uncoupled from IL 2-induced PKC activation in normal T cells.

Dephosphorylation of the human T lymphocyte CD3 antigen

Previous studies demonstrated that activation of T lymphocytes by phorbol ester or mitogenic lectin leads to phosphorylation of Ser 126 of the CD3 antigen gamma chain, whereas treatment with ionomycin results in phosphorylation of both Ser 123 and 126 [Davies, A. A. et al. (1987) J. Biol. Chem. 262, 10918-10921]. In the present study, the dephosphorylation of Ser 123 and Ser 126 of the gamma chain was investigated. Phorbol-ester-induced phosphorylation of the gamma-chain Ser 126 in vivo was reversed following removal of phorbol ester. Dephosphorylation of both Ser 123 and 126 was also observed in vitro using the microsome fraction of T lymphocytes. In order to identify the phosphatases acting at these two sites, the immunoprecipitated gamma chain was used as substrate either following treatment with protein kinase C in vitro, in which case phosphorylation occurs mainly at Ser 123, or following in vivo phosphorylation of Ser 126. Purified oligomeric forms of the polycation-stimulated phosphatases were more effective in dephosphorylating both phosphorylated forms of the gamma chain compared with equivalent amounts of ATP,Mg2+-dependent phosphatases or calcineurin. By using phosphopeptide analogues of the CD3 gamma chain containing Ser 123 or Ser 126 as substrates (A3 and A6), it was shown that polycation-stimulated phosphatases selectively dephosphorylated Ser 123 compared to Ser 126. In order to determine which phosphatases dephosphorylate the gamma chain in microsomes, A3 and A6 were used as substrates for characterising phosphatases in microsomes from human T leukaemia Jurkat 6 cells. Three phosphopeptide phosphatases (250-400 kDa) co-eluted through five purification steps with three forms of polycation-stimulated phosphorylase phosphatase. The partially purified A3/A6 phosphopeptide phosphatases were insensitive to Ca2+, calmodulin and inhibitor-1, and dephosphorylated A3 preferentially compared with A6. A latent form of microsomal ATP,Mg2+-dependent phosphorylase phosphatase was stimulated 10-fold by trypsinisation, but did not dephosphorylate phosphopeptides A3 and A6. The results show that high-Mr forms of polycation-stimulated phosphatases are the only enzymes in human T leukaemia cell microsomes which dephosphorylate gamma chain phosphopeptides. The data point to an important role for polycation-stimulated phosphatases in regulating the phosphorylation state, and so function(s), of the CD3 antigen.

Signal transduction through the CD4 receptor involves the activation of the internal membrane tyrosine-protein kinase p56lck

The CD4 T-cell surface antigen is an integral membrane glycoprotein of relative molecular mass 55,000 which binds class II major histocompatibility complex (MHC) molecules expressed on antigen presenting cells (APCs). It is thought to stabilize physical interactions between T cells and APCs (for a review, see ref. 1). Evidence is accumulating that suggests that CD4 can transduce an independent signal during T-cell activation. It has recently been shown that CD4 expressed on human and murine T cells is physically associated with the Src-related tyrosine protein kinase p56lck (refs 7, 8). These results indicate that CD4 can function as a signal transducer and suggest that tyrosine phosphorylation events may be important in CD4-mediated signalling. Here, we present evidence that cross-linking of the CD4 receptor induces a rapid increase in the tyrosine-specific protein kinase activity of p56lck and is associated with the rapid phosphorylation of one of the subunits (zeta) of the T-cell receptor complex on tyrosine residues. These data provide direct evidence for a specific CD4 signal transduction pathway that is mediated through p56lck and suggest that some of the tyrosine phosphorylation events detected during antigen-mediated T-cell activation may result from signalling through this surface molecule.

Serine and tyrosine phosphorylation of 28- and 35-kDa proteins of human T lymphocytes stimulated by streptococcal M protein

Purified polypeptide fragments of certain surface M proteins of group A streptococci stimulate blastogenesis and the differentiation of cytotoxic T lymphocytes of normal human lymphocytes. The biochemical basis of lymphocyte stimulation by a type M5 protein polypeptide fragment (pep M5) was investigated. Optimal blastogenic doses of pep M5 or phytohemagglutinin stimulated the phosphorylation of several cellular proteins. However, pep M5 but not phytohemagglutinin induced the phosphorylation of 28- and 35-kDa proteins. The 28-kDa protein was shown to be phosphorylated only at serine residues, whereas the 35-kDa protein was phosphorylated only at tyrosine residues. Stimulation of peripheral blood lymphocytes with pep M5 caused a two-fold increase in the CD8+ and CD4+ 4B4+ subpopulations of T lymphocytes. The phosphorylation of the 28-kDa protein appeared to be confined to the CD4+ T cell subpopulation.

Activation of human T cells is associated with tyrosine phosphorylation of several cellular proteins

Human T lymphocytes are activated to proliferate after triggering the T Cell Antigen Receptor Complex. CD3-Ti, with either antigen, mitogenic lectins or monoclonal antibodies against its different subunits. Stimulation of Jurkat leukemic human T cells with anti-CD3 or anti-Ti monoclonal antibodies was found to induce, within 1 min, an increase in the phosphorylation of a set of cellular proteins that can be precipitated with anti-phosphotyrosine antibodies. Seven phosphotyrosine-containing proteins were separated with respective mol. wt of 21, 25, 38, 55, 70, 80 and 110 kDa, among which the 38 kDa species is predominant. Moreover, incubation of Jurkat T cells with sodium orthovanadate, a potent inhibitor of phosphotyrosine protein-phosphatases, was found to potentiate the effects of anti-CD3 mAb on tyrosine phosphorylation. In addition vanadate also induced IL-2 secretion in Jurkat cells when associated with the phorbol ester TPA, further demonstrating the importance of these phosphorylation reactions in the process of T cell activation. Our results therefore allow us to identify several protein substrates of a tyrosine kinase activity, whose stimulation appears to be an early event in human T cell activation through the antigen receptor pathway.

T cell CD3-zeta eta heterodimer expression and coupling to phosphoinositide hydrolysis

The T cell antigen receptor consists of an antigen-binding heterodimer that is noncovalently associated with at least five CD3 subunits (gamma, delta, epsilon, zeta, and eta). The CD3-zeta chains are either disulfide-linked homodimers (CD3-zeta 2) or disulfide-linked heterodimers with eta (CD3-zeta eta). Variants of a murine antigen-specific T cell hybridoma that express normal amounts of CD3-zeta 2 but decreased amounts of CD3-zeta eta were isolated. When activated, the parental cell line increased both phosphatidylinositol hydrolysis and serine-specific protein kinase activity to a much greater extent than the variants. In contrast, the activation of a tyrosine-specific kinase after stimulation with a cross-linking antibody to CD3 was similar among these cells. There was a positive linear relation between the expression of CD3-zeta eta and phosphoinositide hydrolysis stimulated by the TCR, suggesting a differential coupling of the T cell alpha beta heterodimer to signal transduction mechanisms due to alpha beta association with either CD3-zeta 2 or CD3-zeta eta.

Protein kinase C is required for responses to T cell receptor ligands but not to interleukin-2 in T cells

We have tested the role of protein kinase C in mRNA expression and T cell proliferation mediated through the T cell receptor and through the interleukin-2 (IL-2) receptor. Chronic treatment of a mouse T cell clone with phorbol esters caused a complete loss of protein kinase C activity and a concomitant loss of proliferation to T cell receptor ligands (antigen, lectins, antireceptor antibodies). In contrast, kinase C-depleted T cells retained the ability to proliferate to IL-2. Loss of the T cell receptor response was not due to decreased cell surface expression of receptor or impairment of early receptor function (phosphatidylinositol turnover, calcium mobilization). Kinase C-depleted T cells showed no induction of mRNAs for activation-associated genes on exposure to the T cell receptor ligand Concanavalin A; expression of a subset of the same mRNAs in response to IL-2 was unaffected. We conclude that kinase C is required for mRNA expression and subsequent proliferation mediated through the T cell receptor pathway but is not involved in mRNA expression and proliferation in response to IL-2.

Cyclic AMP-mediated alteration of the CD2 activation process in human T lymphocytes. Preferential inhibition of the phosphoinositide cycle-related transduction pathway

Activation of human T lymphocytes via the CD2 molecule produces an enhanced turnover of phosphatidylinositol (PI) cycle-related phospholipids accompanied by the increased production of diacylglycerol (DG) and phosphorylated derivatives of inositol (IP). In this report we demonstrate that increased levels of intracellular cyclic AMP induced in human T lymphocytes by prostaglandin E2 or dibutyryl cAMP antagonize these early biochemical events of the CD2 activation process. Thus, a substantial inhibition of the CD2-induced increase in 32P-phosphatidic acid and 32P-PI values is observed. In parallel, both the DG production and the IP release triggered by the CD2 signal are strongly reduced contrasting with an almost conserved Ca2+ response. We also report here that cAMP does inhibit the CD2-induced proliferation in a dose-dependent manner while the proliferation generated independently of DG and IP production by a combination of Ca2+ ionophore A23187 and 12-O-tetradecanoylphorbol 13-acetate is not affected. These results therefore suggest that (a) intracellular cAMP levels may participate in the regulation of the PI cycle-related transduction pathway involved in the activation process of human T lymphocytes via the CD2 molecule; (b) the observed cAMP-mediated functional inhibitory effects are mainly related to an alteration of this cellular transduction signal; and (c) considering the putative critical second messenger role in the T cell proliferative response of DG and IP, respectively thought to activate the protein kinase C and to raise the intracellular free Ca2+, the lowering of DG production may be the key event responsible for this cAMP-mediated effect.

Mitogenesis of 3T3 fibroblasts induced by endogenous ganglioside is not mediated by cAMP, protein kinase C, or phosphoinositides turnover

The B subunit of cholera toxin, which binds specifically to ganglioside GM1, stimulates DNA synthesis in quiescent Swiss 3T3 fibroblasts grown in chemically defined medium. The mitogenic response to the B subunit was potentiated by insulin and other growth factors. To elucidate the mechanism by which the B subunit stimulates cell growth , its effects on several transmembrane signaling systems which have been suggested to play a vital role in cell growth regulation were examined. The B subunit did not increase cAMP levels nor activate adenylate cyclase. The B subunit induced a rapid and profound increase in intracellular free Ca2+ as measured with the fluorescent Ca2+-sensitive dye quin 2/AM. Removal of external Ca2+ completely inhibited the signal, thus suggesting that the B subunit elevates intracellular Ca2+ through a net influx of extracellular Ca2+ rather than by causing the release of Ca2+ from intracellular stores. These findings are consistent with the observations that the B subunit induced reinitiation of DNA synthesis without activation of phospholipase C. There was no increase in the formation of inositol trisphosphate, the second messenger that mediates release of Ca2+ from intracellular stores. In addition, the B subunit still stimulated DNA synthesis in Swiss 3T3 cells pretreated with phorbol ester to down-regulate protein kinase C. These results suggest that the mitogenic effects of the B subunit are mediated mainly by facilitation of Ca2+ influx and that activations of adenylate cyclase, phospholipase C, or protein kinase C are not obligatory steps in the initiation of cell growth by the B subunit. Furthermore, the observation that Ca2+ ionophores, such as ionomycin and A23187, are not mitogenic implies that additional undefined growth signaling pathways may exist in this system.