T cells play a central role in orchestrating immunity against pathogens, particularly viruses. Thus, impairing T cell activation is an important strategy employed by viruses to escape host immune control. The tyrosine kinase–interacting protein (Tip) of the T lymphotropic Herpesvirus saimiri (HVS) is constitutively present in lipid rafts and interacts with cellular Lck tyrosine kinase and p80 endosomal protein. Here we demonstrate that, due to the sequestration of Lck by HVS Tip, T cell receptor (TCR) stimulation fails to activate ZAP70 tyrosine kinase and to initiate downstream signaling events. TCR ζ chains in Tip-expressing T cells were initially phosphorylated to recruit ZAP70 molecule upon TCR stimulation, but the recruited ZAP70 kinase was not subsequently phosphorylated, resulting in TCR complexes that were stably associated with inactive ZAP70 kinase. Consequently, Tip expression not only markedly inhibited TCR-mediated intracellular signal transduction but also blocked TCR engagement with major histocompatibility complexes on the antigen-presenting cells and immunological synapse formation. These results demonstrate that a lymphotropic herpesvirus has evolved a novel mechanism to deregulate T cell activation to disarm host immune surveillance. This process contributes to the establishment and maintenance of viral latency.
Introduction
Activation of T cells is initiated when TCRs bind stimulatory peptides in the context of self-MHC molecules. Engagement of TCR triggers an intracellular signaling cascade that culminates in cytokine gene expression, proliferation, and the execution of T cell effector functions (1, 2). Signal transmission from TCR is mediated by sequential activation of Src family kinases, Lck, and Fyn, which phosphorylate tyrosine residues within the immunoreceptor tyrosine-based activation motifs of the CD3 and ζ subunits of TCR (3). The phosphorylation of immunoreceptor tyrosine-based activation motifs allows the tyrosine kinase ZAP70 to be recruited to the receptor complexes where it is phosphorylated and activated. Upon activation, Lck and ZAP70 presumably act in concert to propagate signals from TCR and lead to Ca2+ mobilization and the transcription of gene products for T cell activation and proliferation.
Several recent papers have described the spatial and temporal recruitment of signaling molecules to an organized contact zone known as the immunological synapse (2). The mature immunological synapse is a highly organized interaction site at the interface between a T cell and an APC. At the immunological synapse, TCRs, coreceptors, adhesion molecules, and signaling molecules are assembled. An elaborately choreographed series of movements of signaling molecules including Lck, ZAP70, LAT, and PKCθ to the immunological synapse has been shown upon TCR stimulation (4–6). Particularly, ZAP70 has been shown to be necessary to supply the synapse with LAT and PKCθ, indicating that ZAP70-dependent signaling is required for the formation of a functional immune synapse (5). Furthermore, recent studies have demonstrated that TCR signaling precedes immunological synapse formation and that the immunological synapse acts as a type of adaptive controller that not only boosts TCR signaling but also attenuates strong signals (7, 8).
Herpesvirus saimiri (HVS), an oncogenic γ2 herpesvirus, naturally infects squirrel monkeys of South America. HVS persists in T lymphocytes of the natural host without any apparent disease, but infection of other species of primate results in fulminant T cell lymphomas (9). A HVS protein, called tyrosine kinase–interacting protein (Tip) that is constitutively present in lipid rafts, is not required for viral replication but is required for T cell transformation in culture and for lymphoma induction in primates (10). Tip interacts with the SH3 domain of Lck, and this interaction interferes with early events of the TCR signal transduction pathway (11, 12). The molecular interaction between Lck and Tip has been mapped to 37 amino acid residues of Tip, termed the Lck-binding domain (LBD). The LBD consists of two motifs: a COOH-terminal Src family kinase homology motif and an SH3-binding motif (12). Tip has been also shown to interact with a novel cellular endosomal protein, p80, that contains an NH2-terminal WD (tryptophan-aspartic acid) repeat domain and a COOH-terminal coiled-coil domain (13). Interaction of Tip with p80 facilitates endosomal vesicle formation (13). Our recent study has shown that the Tip–Lck interaction recruits TCR complex to lipid rafts, and the Tip–p80 interaction subsequently induces the aggregation and internalization of lipid rafts and thereby down-regulates the TCR complex (14). Thus, the signaling and targeting functions of HVS Tip rely on two functionally and genetically separable mechanisms that independently target cellular Lck tyrosine kinase and p80 endosomal protein.
Although the interaction of HVS Tip with Lck significantly down-regulates TCR signal transduction, the detailed mechanism is mostly unknown. To further delineate the effect of HVS Tip on TCR signal transduction, we examined the effect of Tip expression on T cells upon stimulation. In this report, we demonstrate that Tip expression inhibits the activation of T cells through the precise interruption of the phosphorylation and activation of ZAP70 kinase upon stimulation. This inhibitory activity of Tip ultimately blocks intracellular calcium mobilization, immunological synapse formation, and cytokine production, which are required for the activation and proliferation of T cells. These results detail the molecular mechanism of Tip-mediated inhibition of TCR signal transduction, a process that ultimately contributes to deactivating host immune control.
Materials And Methods
Superantigen-induced Immunological Synapse Formation.
Jurkat T cells were transfected with fusion expression plasmids encoding Tip-GFP, TipmLBD-GFP, or vector. Prior to conjugation, Raji B cells were incubated with 1 μg/ml of Staphylococcus enterotoxin E (SEE; Toxin Technology, Inc.). Jurkat T cells and Raji B cells were mixed at a 1:1 ratio, placed on poly-l-lysine–coated slides, and incubated at 37°C for 15 min. After fixation and permeabilization as described in Supplemental Materials and Methods , cells were stained and analyzed by confocal microscopy.
Flow Cytometry Analysis of T Cell–APC Conjugation.
The formation of T cell–APC conjugates after SEE treatment was determined by flow cytometry as described previously (15) with some modification. Briefly, Raji B cells were resuspended at 2 × 106 cells/ml, treated for 30 min at 37°C with 3 μg/ml of dihydroethidium (HE; Molecular Probes), washed once with medium, and further incubated with or without SEE as described previously (15). Jurkat T cells were electroporated with plasmids encoding GFP, Tip-GFP, or TipmLBD-GFP and used for the conjugate formation. Both cell lines were mixed at 1:1 ratio, incubated for 15 min at 37°C, and fixed directly in suspension by adding 4% formaldehyde solution for 20 min. The conjugates were analyzed by flow cytometry. The percentage of conjugated T cells was determined as the number of dual-labeled (HE and GFP-positive) events divided by the number of GFP-positive T cells.
Online Supplemental Materials.
Online Supplemental Materials and Methods contains cell culture and antibody, lentiviral vector (provided by Drs. P. Johnson and S. Braun, New England Primate Research Center, Harvard Medical School) construction and infection, flow cytometry and ELISA, calcium mobilization analysis, and immunofluorescence immunoprecipitation and immunoblot analyses. Fig. S1 shows the surface expression of CD3 and CD4 on Jurkat T cells expressing Tip or its mutant before stimulation. Fig. S2 shows the inhibitory effects of Tip on the immunological synapse formation and the conjugation formation between T and B cells. All
Results And Discussion
Inhibition of T Cell Receptor Signal Transduction by Tip.
Upon engagement with the MHC complexes on the APCs, TCR initiates an array of signal transduction events (1, 16). To investigate the effect of Tip on T cell receptor signal transduction, the purified CD2+ T cells from human PBMCs were transduced with lentiviral vectors carrying the GFP or Tip gene, followed by stimulation with anti–CD3 antibody–coated beads. Flow cytometry indicated ∼80–90% efficiency of lentiviral transduction in primary CD2+ T lymphocytes (not depicted). Anti-CD3 stimulation strongly induced IL-2 production in GFP-transduced T cells, whereas it did poorly in Tip-transduced T cells (Fig. 1 A). To further test Tip activity in TCR signal transduction, Jurkat T cells were electroporated with pTracer-GFP vector or pTracer-GFP/Tip vector where Tip and GFP were expressed from elongation promoter-1 and CMV early promoter, respectively. At 24 h postelectroporation, these cells were then stimulated with anti–CD3 antibody–coated beads for 24 h followed by ELISA for IL-2 production. This result also indicated that Tip expression markedly suppressed IL-2 production of Jurkat T cells induced by TCR stimulation (Fig. 1 A). Tip expression was readily detected in both lentivirus-infected primary T lymphocytes and Jurkat T cells (Fig. 1 A).
To further examine the effect of Tip on TCR signal transduction, Jurkat T cells were electroporated with pTracer-GFP or pTracer-GFP/Tip and then measured for their level of intracellular free calcium mobilization. Jurkat-GFP cells exhibited a rapid increase in intracellular calcium concentration immediately after anti-CD3 stimulation, whereas Jurkat-Tip cells were not capable of increasing intracellular calcium concentration under the same conditions (Fig. 1 B). To further investigate the negative effect of Tip on TCR-induced intracellular calcium mobilization, we included numerous Tip mutants in the same assay. These mutants were: TipmLBD, which does not interact with Lck; Tip LBD, which contains only 37 amino acids of the Lck-binding domain and is able to bind to Lck; Tip Δ2, which does not interact with p80 (13); Tip Y114F, which does not interact with STAT3 (17); Tip Y127F, which lacks tyrosine phosphorylation at Y127; and TipΔTM, which has a deletion of the COOH-terminal transmembrane region. Flow cytometry showed that TipΔ2, TipΔTM, Tip Y114F, and Tip Y127F were capable of inhibiting the elevation of intracellular calcium concentration upon anti-CD3 stimulation as efficiently as WT Tip. Thus, the interaction with p80 and STAT, the tyrosine phosphorylation at Y114 or Y127 residues, and the COOH-terminal transmembrane region are not necessary for Tip to down-regulate TCR signal transduction (Fig. 1 B). By contrast, both TipmLBD and Tip LBD were incapable of inhibiting the increase of intracellular calcium concentration, indicating that Lck interaction is necessary but not sufficient for Tip to down-regulate TCR signal transduction (Fig. 1 B).
Furthermore, the surface expression of CD69 early lymphocyte activation marker, which is the consequence of TCR signal transduction, was measured on CD2+ primary T cells infected with lentivirus containing GFP, Tip, or TipmLBD and on Jurkat T cells electroporated with pTracer, pTracer/Tip, pTracer/TipmLBD, or pTracer/TipΔ2 expression vector upon TCR stimulation. PMA stimulation was included as a control. As seen with IL-2 production and intracellular calcium mobilization, T cells expressing GFP or the TipmLBD mutant up-regulated the surface expression of CD69 upon TCR stimulation, whereas T cells expressing WT Tip or TipΔ2 mutant showed little or no increase of CD69 surface expression (Fig. 1 C). CD3 and/or CD4 surface expression was detected on CD2+ primary T cells and Jurkat T cells at equivalent levels before anti-CD3 stimulation (Fig. S1). These results indicated that Tip expression effectively inhibits TCR signal transduction, evidenced by the suppression of IL-2 production, intracellular calcium mobilization, and CD69 surface expression, and that Lck interaction is required but not sufficient for Tip to exhibit such activity.
Selective Inhibition of ZAP70 Activation by Tip Expression.
The phosphorylation of CD3ζ by Lck and the subsequent recruitment and activation of ZAP70 kinase are proximal signaling events of TCR signal transduction. Particularly, the phosphorylation of the Y319 residue of ZAP70 has been shown to be a critical event for T cell activation (18). To delineate the molecular mechanism of Tip-mediated inhibition of TCR signal transduction, Jurkat T cells were infected with lentivirus carrying GFP or WT Tip, stimulated with anti–CD3 antibody–coated beads for the indicated times, and then examined for the tyrosine phosphorylation of CD3ζ and ZAP70. Phospho-specific CD3ζ (pCD3ζ and ZAP70 Y319 [pZAP70 Y319]) antibodies were used for immunoblot assay. The result showed that upon anti-CD3 stimulation GFP-expressing Jurkat cells showed robust tyrosine phosphorylation of the CD3ζ chain and ZAP70 Y319 residue (Fig. 2 A). Despite the strong tyrosine phosphorylation of CD3ζ, however, Jurkat T cells expressing Tip displayed little or no phosphorylation of ZAP70 at Y319 (Fig. 2 A). By striking contrast, Jurkat T cells expressing TipmLBD showed robust phosphorylation of both CD3ζ and ZAP70 Y319 upon TCR stimulation, as seen in GFP-expressing Jurkat T cells (Fig. 2 B). Both CD3ζ and ZAP70 expression levels were equivalent in Jurkat-GFP, Jurkat-Tip, and Jurkat-TipmLBD cells (Fig. 2, A and B).
To further detail the Tip-mediated inhibition of ZAP70 activation, we investigated whether Tip expression affected the recruitment of ZAP70 into the tyrosine phosphorylated CD3ζ chain upon TCR stimulation. Jurkat T cells infected with GFP or Tip lentivirus were treated with or without anti–CD3 antibody–coated beads, and their lysates were used for immunoprecipitation with anti-CD3ζ or anti-ZAP70 antibody, followed by immunoblotting with anti-CD3ζ anti-ZAP70, anti-phospho CD3ζ, or anti-ZAP70 Y319 antibodies. ZAP70 was efficiently recruited into the tyrosine-phosphorylated CD3ζ chain in both Jurkat-GFP and Jurkat-Tip cells upon TCR stimulation, indicating that Tip expression had no effect on the recruitment of ZAP70 into the TCR complex (Fig. 2 C). To further delineate the Tip effect on ZAP70 kinase activity, we examined the tyrosine phosphorylation of linker for activation of T cells (LAT) and PLC-γ1, which both are substrates of ZAP70 in living cells. LAT and PLC-γ1 underwent a robust tyrosine phosphorylation in Jurkat-GFP cells after TCR stimulation, whereas they did not showed a detectable level of tyrosine phosphorylation in Jurkat-Tip cells under the same conditions (Fig. 2 C). These results demonstrate that Tip expression inhibits the activation of T cells through the precise interruption of the phosphorylation and activation of ZAP70 kinase upon stimulation and that this inhibitory activity of Tip ultimately resulted in blocking TCR signal transduction.
Inhibition of Immunological Synapse Formation by Tip.
One of the first phenomena described during TCR activation by APCs is the clustering of the TCR–CD3 complex in the zone of contact, resulting in the formation of an immunological synapse (2). Several recent papers have shown that this clustering of receptors, adhesion molecules, and signaling molecules is dependent on signaling events mediated by Lck and ZAP70 (5, 19). Since Tip and Lck interaction effectively inhibited ZAP70 activation induced by TCR stimulation, we investigated whether Tip affected the formation of the immunological synapse. To do this, Jurkat T cells electroporated with vector or GFP–Tip fusion vector were engaged with Raji B cells primed with SEE, and the localization of CD3ζ, LFA-1, Lck, and cellular tyrosine phosphorylation was then detected by the corresponding antibodies and examined by confocal microscopy. Jurkat T cells in the control set showed well-organized recruitment of CD3ζ, LFA-1, and Lck to the zone of contact between T cells and B cells in the presence of SEE (Fig. 3 A). In addition, the intracellular localized appearance of tyrosine-phosphorylated proteins was strongly detected at the T cell–APC contact area in control Jurkat T cells (Fig. 3). By striking contrast, the recruitment of CD3ζ, LFA-1, Lck, and tyrosine phosphorylated proteins to the T cell–APC contact area was remarkably impaired in Jurkat T cells expressing Tip–GFP under the same conditions (Fig. 3). Specifically, instead of being recruited to the immunological synapse area, these proteins accumulated in the intracellular enlarged endosomal compartments of the cells; this localization has been shown to be induced by Tip and p80 interaction (13) (Fig. 3). However, Jurkat T cells expressing TipmLBD showed concentrations of CD3ζ, LFA-1, Lck, and tyrosine phosphorylated proteins at the contact areas between T cells and APCs as strongly as control Jurkat cells (Fig. 3). This indicates that Tip expression efficiently inhibits immunological synapse formation and that this activity of Tip requires Lck interaction.
Using confocal microscopy, we also estimated the percentages of T cell–APC conjugates that showed the enhanced recruitment of CD3ζ and Lck to the contacting synaptic area (Fig. S2 A). Approximately 65% of conjugates between Jurkat T cells and Raji B cells showed the cluster of CD3ζ and Lck at the synaptic area in the presence of SEE (Fig. S2 A). By contrast, only 15% of conjugates between Jurkat-Tip-GFP T cells and Raji B cells showed the cluster of CD3ζ and Lck at the synaptic area in the presence of SEE (Fig. S2 A). This result was almost comparable to that observed when Jurkat T cells were incubated with unprimed APCs. In addition, ∼70% of conjugates between Jurkat-TipmLBD-GFP T cells and SEE-primed Raji B cells also showed the cluster of CD3ζ and Lck in the synaptic area (Fig. S1 A).
Finally, we investigated whether, besides blocking immunological synapse formation, Tip also inhibited the conjugation between T cell and APC. To do this, we used a flow cytometry-based assay as described previously (15). Raji B cells were stained with HE, incubated with or without SEE, and mixed with Jurkat T cells expressing GFP, Tip-GFP, or TipmLBD-GFP at a 1:1 ratio. Although a low level of conjugation between Jurkat-GFP or Jurkat-TipmLBD T cells and Raji B cells was detected in the absence of SEE, the percentage of conjugation between these cells increased by approximately three- to fivefold in the presence of SEE (Fig. S2 B). However, Jurkat T cells expressing WT Tip-GFP fusion showed little or no increase of conjugation between T and B cells induced by SEE treatment (Fig. S2 B). These results collectively indicate that Tip inhibits the movement of TCR and Lck to the site of contact with SEE-primed APC, suppresses the formation of the immunological synapse, and ultimately abrogates the activation of TCR stimulation.
Because of its biological significance in orchestrating immunity against pathogenic challenges, particularly viral infections, TCR signal transduction is a common target of viruses as a strategy to persist in the host (20, 21). The earliest signaling event after TCR engagement is the sequential activation of the nonreceptor protein tyrosine kinases (PTKs) of the Src, Tec, Syk families (16). Lck and Fyn are the Src family PTK, Itk is the Tec family PTK, and ZAP70 is the Syk family PTK. Upon TCR stimulation, together with Lck and Fyn, the ZAP70 and Itk kinases promote the phosphorylation of many intracellular signaling molecules, which ultimately induces various cellular events such as cytoskeletal alteration, intracellular Ca2+ influx, transcription factor activation, and cytokine/chemokine production (16). Mounting evidence suggests that Lck and ZAP70 tyrosine kinases play central roles in this TCR signal transduction. The complex interactions of the SH2 and/or SH3 domains of Lck and ZAP70 with substrates or downstream effectors ultimately transduce signals for T cell activation and proliferation, resulting in the generation of a host immune response to invading pathogens. We demonstrated that, due to the sequestration of Lck by HVS Tip, TCR stimulation fails to activate ZAP70 tyrosine kinase and to initiate downstream signaling events. CD3ζ chains in Tip expressing T cells were initially phosphorylated to recruit ZAP70 kinase upon TCR stimulation, but the recruited ZAP70 molecule was not subsequently phosphorylated, resulting in TCR complexes that were stably associated with inactive ZAP70 kinase. This phenomenon is strikingly similar to that in CD4+ and CD8+ thymocytes whose TCR signaling has been shown to be blocked due to the occupation of TCR ζ chains with inactive ZAP70 kinase (22). Furthermore, TCR signaling in CD4+CD8+ thymocytes is impaired because the number of available Lck molecules is diminished by intrathymic CD4–MHC II interactions that initially activate Lck molecules, which are subsequently degraded (22). We have also shown that Tip recruits Lck to the lysosomal compartments where it likely undergoes degradation (13). This suggests that, as seen in thymocytes (22), HVS utilizes Tip–Lck interaction to block TCR signal transduction, which renders virus-infected cells inert and unresponsive to stimulus. Thus, impairment of the TCR signal transduction pathway, in particular Lck and ZAP70 function, may be a vital strategy employed by T lymphotropic HVS to escape host immune control and maintain latency.
Acknowledgments
We especially thank J. Macke for manuscript editing.
This work was partly supported by U.S. Public Health Service grants CA39363 and RR00168. J. Jung is a Leukemia and Lymphoma Society Scholar.
The authors have no conflicting financial interests.
References
The online version of this article contains supplemental material.