By
From the * Experimental Immunology Branch, National Cancer Institute, Bethesda, Maryland 20892; Fox Chase Cancer Center, Philadelphia, Pennsylvania 19111; and the § Division of Immunobiology,
Research Institute for Biological Sciences, Science University of Tokyo, Chiba 278, Japan
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Abstract |
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As a result of interaction with epithelial cells in the thymic cortex, immature CD4+8+ (double positive, DP) thymocytes express relatively few T cell receptors (TCRs) and contain diminished numbers of coreceptor-associated p56lck (lck) PTK molecules. As a result, TCR signal transduction in DP thymocytes is significantly impaired, despite its importance for repertoire selection. We report here that, in DP thymocytes, tyrosine phosphorylation of TCR signaling motifs (ITAMs) by lck, an early event in TCR signal transduction, is dependent upon ZAP-70 protein independent of ZAP-70's kinase activity. Furthermore, the dependence on ZAP-70 protein for ITAM phosphorylation diminishes as available lck increases. Importantly, ZAP-70's role in ITAM phosphorylation in DP thymocytes is not limited to protecting phosphorylated ITAMs from dephosphorylation. Rather, this study indicates that ZAP-70 protein augments ITAM phosphorylation in DP thymocytes and so compensates in part for the relative deficiency of coreceptor-associated lck.
Key words: T cell receptor; development; signaling; thymus; phosphorylation ![]() |
Introduction |
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Tcell development progresses in the thymus via an ordered series of differentiation events that are best characterized by changes in expression of CD4 and CD8 coreceptors. Early thymocytes are CD48
(double negative, DN)
and differentiate into CD4+8+ (double positive, DP) thymocytes, which in turn differentiate into CD4+8
and CD4
8+
(single positive, SP) T cells or, alternatively, are induced to
undergo cell death. Each developmental transition is induced by signals transduced by surface TCR components.
Despite the importance of TCR signals for development,
TCR expression on immature DP thymocytes is low, with
only ~10% the number of surface TCR as on mature T cells;
and coreceptor-associated p56lck (lck) is diminished in DP
thymocytes mostly, but not entirely, because their surface
CD4 molecules are chronically engaged by the high concentrations of MHC class II (MHC II) present on thymic cortical epithelium (1). Consequently, it remains unclear
how TCR signals are transduced in immature DP thymocytes.
It is known that TCR signal transduction requires activation of ZAP-70 protein tyrosine kinase (PTK) for all downstream signaling events (4). Indeed, enzymatic activation of
ZAP-70 PTK is necessary for immature murine DP thymocytes to differentiate into mature SP T cells (5, 6). However, the molecular interactions linking TCR engagements
on the cell surface with ZAP-70 activation inside the cell
are complex, involving multiple protein-protein interactions (7). TCR signal transduction is initiated primarily by
the src family PTK lck, which tyrosine phosphorylates conserved signaling motifs referred to as ITAMs (immunoreceptor tyrosine-based activation motifs) that are present in the
cytosolic tails of TCR-associated and CD3
/
/
chains.
Tyrosine phosphorylated ITAMs are bound by ZAP-70 PTK
molecules whose enzymatic activity is subsequently elicited
by lck-induced phosphorylation of ZAP-70's catalytic domain (7). Thus, tyrosine phosphorylation of ZAP-70's
catalytic domain is the target of proximal TCR signaling events.
Because of the diminished numbers of surface TCR complexes and coreceptor-associated lck molecules in immature DP thymocytes compared with mature T cells, TCR signal transduction may not proceed in DP thymocytes precisely as it does in mature T cells. Indeed, it is conceivable that TCR signal transduction in DP thymocytes may require signal amplification mechanisms that are not critical for TCR signal transduction in mature T cells. In this report, we demonstrate that ITAM phosphorylation by lck, an early event in TCR signal transduction, is significantly enhanced in DP thymocytes by ZAP-70 protein and so represents a molecular amplification mechanism that compensates in part for the relative deficiency of coreceptor-associated lck in DP thymocytes.
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Materials and Methods |
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Mice.
Normal C57BL/6 mice were obtained from The Jackson Laboratory and were designated ZAP+/+. ZAP-70 knockout mice were provided by Dennis Loh (Roche Research Institute, Nutley, NJ) and Izumi Negishi (Nippon Roche Research Center, Kanagawa, Japan; reference 5), were bred in our own animal colony, and were designated ZAPDP Thymocytes.
Upon their removal from the thymus, thymocytes were kept strictly at 4°C in all experiments unless otherwise indicated, in order to avoid the biochemical alterations that occur in DP thymocytes upon removal from their intrathymic signaling environment (3, 8). DP thymocyte populations (>96% pure) were obtained by panning whole thymocytes on anti-CD8 plates and collecting the adherent fraction.Antibodies.
Antibodies used for immunoprecipitation and/or immunoblotting in this study were specific forSignal Generation.
DP thymocytes were coated with biotinylated anti-TCR and/or biotinylated anti-CD4 mAbs for 10 min at 4°C, after which the cells were warmed to 37°C and exposed to streptavidin for the indicated time (usually 5 min). Where indicated, cells were also treated with pervanadate (0.3 mM H2O2 and 0.1 mM Na3VO4) for 5 min at 37°C (2, 3).Immunoprecipitation and Immunoblotting.
DP thymocytes were lysed in 1% triton and the lysates immunoprecipitated with the indicated antibodies and resolved by SDS-page under reducing conditions (5 × 107 cells per sample). The gels were transferred onto immobilon PVDF membranes (Millipore), blotted with the indicated antibodies, and visualized by chemiluminescence.Immune Complex Kinase Assay.
DP thymocytes were lysed at 108 cells/ml in lysis buffer containing 1 mM vanadate (a potent inhibitor of protein tyrosine phosphatases) and 1% Triton X-100; and the lysates immunoprecipitated with the indicated antibodies. Immune complexes were incubated at ambient temperature for 3 min in kinase buffer containing 15 µCi/sample of ![]() |
Results |
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Greater than 50% of surface TCR complexes on immature DP thymocytes in the thymic cortex contain `constitutively' tyrosine phosphorylated ITAMs (3, 9), in contrast
to <5% of TCR on mature T cells in the periphery (3, 10).
Constitutive ITAM phosphorylation in DP thymocytes results from lck signals generated by interactions between DP
thymocytes and thymic cortical epithelium that are mediated primarily, but not exclusively, by CD4-MHC II
interactions. Aggregation of surface CD4 molecules on DP
thymocytes by engagement of MHC II on cortical thymic
epithelium activates CD4-associated lck to phosphorylate
ITAMs, after which the activated lck molecules are degraded (2, 3, 8). The tyrosine phosphorylated ITAMs
then recruit ZAP-70 molecules that remain enzymatically
inactive (3, 10), perhaps because the remaining pool of activated lck available to the TCR in DP thymocytes is insufficient to induce ZAP-70 activation. Importantly, the lck
that is available to the TCR complex in DP thymocytes
appears to be primarily the lck that is associated with coreceptor molecules and for which coreceptor molecules
compete for binding (2, 3). However, additional factors
may also influence the availability of lck to the TCR. For
example, transfection experiments in nonlymphoid cells
have found that ITAM phosphorylation by lck is increased by ZAP-70, an effect ascribed to ZAP-70's protection of
phospho-ITAMs from dephosphorylation (12).
To assess a possible role for ZAP-70 in ITAM phosphorylation in DP thymocytes, we examined purified DP thymocyte populations from mice expressing different quantities
of ZAP-70. Remarkably, we found that the extent of phosphorylation was proportional to the amount of ZAP-70
protein expressed (Fig. 1, columns 1-3). Importantly, all
three DP thymocyte populations (ZAP+/+, ZAP+/
, and
ZAP
/
) contained comparable levels of
protein (Fig. 1,
center row). To determine if the relationship between
ZAP-70 expression and
phosphorylation required ZAP-70
kinase activity, we examined
phosphorylation in DP thymocytes from mutant ST mice that express only kinase-dead ZAP-70 proteins. Mutant ZAP-70 proteins are less stable than their wild-type counterparts so that DP thymocytes from mutant ST mice contained reduced steady state
levels of ZAP-70 protein, comparable with the levels of
ZAP-70 protein expressed in ZAP+/
DP (Fig. 1, bottom
row). Interestingly, tyrosine phosphorylation of
ITAMs
from mutant ST and ZAP+/
mice were also essentially
equivalent (Fig. 1, compare columns 2 and 4), especially
considering that the ST lane contained somewhat less
protein. Thus, ST thymocytes contained phosphorylated
ITAMs in amounts that were roughly concordant with
their reduced level of ZAP-70 protein, indicating that
ITAM phosphorylation is quantitatively dependent upon
ZAP-70 protein but is independent of ZAP-70's enzymatic
activity.
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We next wished to determine if the requirement for
ZAP-70 in coreceptor-induced ITAM phosphorylation
could be overcome by coengagement of CD4 with the
TCR. Although TCR plus CD4 co-engagement did induce ITAM phosphorylation in DP thymocytes from
ZAP+/+ mice, it failed to do so in DP thymocytes from
ZAP
/
mice (Fig. 2 A, right). The intrinsic ability of
ITAMs to be tyrosine phosphorylated was not obviously
altered in ZAP
/
thymocytes, as indicated by treatment of
DP thymocytes with pervanadate, which inhibits intracellular tyrosine phosphatases and so indiscriminately activates
intracellular PTK (13).
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To further examine TCR ITAM phosphorylation in
TCR plus CD4-signaled DP thymocytes, we assessed DP
thymocyte lysates in an immune complex kinase assay for
their ability to tyrosine phosphorylate TCR ITAMs in
vitro (Fig. 2 B). Concordant with our observation in intact
DP thymocytes, in vitro phosphorylation of TCR ITAMs ( and
) was markedly reduced >10-fold in ZAP
/
relative to ZAP+/+ anti-
immunoprecipitates from TCR plus
CD4-signaled DP thymocytes (Fig. 2 B). Because dephosphorylation of TCR ITAMs is already inhibited in in vitro
kinase assays by exogenously added vanadate, a potent tyrosine phosphatase inhibitor, the requirement for ZAP-70 protein in ITAM phosphorylation indicates that ZAP-70's
role is not limited to protecting phosphorylated ITAMs from
dephosphorylation. Rather, this experiment reveals that
ZAP-70 promotes tyrosine phosphorylation of TCR ITAMs
in DP thymocytes.
Because ITAM phosphorylation is mediated primarily by
lck, we next considered that in vivo ITAM phosphorylation might be less dependent upon ZAP-70 in DP thymocytes containing increased amounts of TCR-accessible lck.
Consequently, we examined signaling in DP thymocytes
that lacked ZAP-70 but contained increased CD4-associated lck, because their thymi did not express MHC II (Fig. 3).
In the absence of MHC II engagement in the thymus,
CD4 molecules on DP thymocytes are not aggregated and,
consequently, are not depleted of associated lck molecules
(2). Indeed, ZAP/
DP thymocytes from II
/
mice contained more CD4-associated lck than did ZAP
/
DP
thymocytes from II+/+ mice (Fig. 3). More importantly,
cocross-linking of TCR plus CD4 surface molecules on
DP thymocytes from ZAP
/
II
/
mice induced significant
ITAM phosphorylation despite the absence of ZAP-70
protein (Fig. 3 a), indicating that the requirement for ZAP-70
diminishes with increasing amounts of coreceptor-associated lck. The pool of CD4-associated lck in DP thymocytes can also be increased by removing thymocytes from
their thymic microenvironment and culturing them as
single cell suspensions in the absence of MHC II+ cells. In
such cultures, intrathymic engagements are disrupted, permitting newly synthesized CD4 and lck molecules to repopulate the depleted pool of coreceptor-associated lck (2).
It is clear that TCR plus CD4 cocross-linking increased
ITAM phosphorylation in these cultured DP thymocytes
whether or not ZAP-70 protein was present (Fig. 4, compare columns 1 and 3). Thus, ITAM phosphorylation is less
dependent upon ZAP-70 in DP thymocytes containing increased amounts of coreceptor-associated lck.
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A more stringent assessment of the role of ZAP-70 in
regulating ITAM phosphorylation is the one signaled by
engagement of the TCR alone, as opposed to ITAM phosphorylation signaled by the forcible coengagement of TCR
with CD4 (Fig. 4, compare columns 2 and 3). Signaling by
isolated TCR cross-linking requires that lck be captured
within TCR aggregates, which is an inefficient method of
bringing lck into contact with TCR ITAMs compared
with direct TCR plus CD4 cocross-linking. Nevertheless,
isolated TCR cross-linking did signal ITAM phosphorylation in cultured DP thymocytes that contained ZAP-70
protein (even enzymatically inactive ZAP-70 protein in
mutant ST thymocytes), but failed to signal ITAM phosphorylation in cultured DP thymocytes that lacked ZAP-70
protein (Fig. 4, compare columns 1 and 2). The inability of
isolated TCR cross-linking to induce ITAM phosphorylation in cultured DP thymocytes lacking ZAP-70 protein
indicates that ZAP-70 is specifically required for ITAM
phosphorylation when the amount of lck available to TCR aggregates is limiting.
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Discussion |
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Current models of TCR signaling are derived primarily from experiments in mature T cells and cell lines, and do not include a role for ZAP-70 in early TCR signaling events such as ITAM phosphorylation (7). In contrast, our study found that in immature DP thymocytes ZAP-70 protein is required for ITAM phosphorylation, and that the requirement for ZAP-70 protein decreases as the amount of lck available to the TCR quantitatively increases. ZAP-70's role in ITAM phosphorylation in DP thymocytes was not limited to protecting phosphorylated ITAMs from dephosphorylation, as ZAP-70 was required for in vitro ITAM phosphorylation by DP thymocyte lysates even though tyrosine dephosphorylation was already inhibited by the pharmacologic agent vanadate. Rather, our study indicates that ZAP-70 in DP thymocytes promotes lck's phosphorylation of TCR ITAMs, a function that is especially significant in immature DP thymocytes with limiting lck.
Our understanding of ZAP-70's role in promoting ITAM phosphorylation by lck in DP thymocytes builds on the key finding that lck can bind to ZAP-70 via an SH2 domain interaction (14, 15). We suggest that ITAM phosphorylation in DP thymocytes occurs in two phases. In the first phase of ITAM phosphorylation, a chance encounter between an activated lck molecule and a TCR ITAM induces initial ITAM phosphorylation without any involvement of ZAP-70. The number of TCR ITAMs initially phosphorylated by such chance encounters depends upon the number of activated lck molecules available to the TCR. In immature DP thymocytes, the amount of lck available to the TCR is limiting, so that only a few TCR ITAMs are phosphorylated in this initial ZAP-70-independent phase, perhaps only a single ITAM in a TCR aggregate. In the second phase of ITAM phosphorylation, the initially phosphorylated ITAM is bound by a ZAP-70 molecule whose backbone tyrosine residue is phosphorylated and then bound by activated lck. The activated ZAP-70-bound lck molecule is now within the TCR complex and so can efficiently phosphorylate the remaining ITAMs in the TCR aggregate. (In fact, being bound to ZAP-70 via its SH2 domain might prolong lck's enzymatic activity because lck's SH2 domain would not be available to bind lck's regulatory phosphotyrosine, interfering with downregulation of lck's kinase activity.) The newly phosphorylated ITAMs are subsequently bound by additional ZAP-70 molecules and it is these additional ZAP-70 molecules that make up the majority of ZAP-70 molecules constitutively associated with TCR in DP thymocytes. These ZAP-70 molecules are only recruited into the TCR complex after the second phase of ITAM phosphorylation and they are not themselves tyrosine phosphorylated in DP thymocytes, presumably because the activated lck has already disappeared from the TCR complex. However, these TCR-bound ZAP-70 molecules can be efficiently activated by subsequent TCR plus coreceptor engagements of intrathymic ligands that bring newly activated lck molecules into the TCR complex. Thus, ZAP-70's promotion of ITAM phosphorylation represents a signal amplification mechanism in DP thymocytes.
In conclusion, our study demonstrates that ZAP-70 promotes ITAM phosphorylation in DP thymocytes in response to TCR and/or coreceptor engagement, and that DP thymocytes are particularly dependent upon ZAP-70 for ITAM phosphorylation because their pool of available lck is limiting.
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Footnotes |
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Address correspondence to Alfred Singer, Experimental Immunology Branch, National Cancer Institute, Bldg. 10, Rm. 4B-17, Bethesda, MD 20892. Phone: 301-496-5461; Fax: 301-496-0887; E-mail: singera{at}nih.gov
Received for publication 1 December 1998 and in revised form 10 February 1999.
We gratefully acknowledge Dennis Loh and Izumi Negishi for ZAP-70/
mice; and Larry Samelson and
Ron Wange (both from NIH, Bethesda, MD) for anti-ZAP-70 and anti-lck antibodies.
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References |
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