THEMIS is critical for conventional T‐cell development, but its precise molecular function remains elusive. Here, we show that THEMIS constitutively associates with the phosphatases SHP1 and SHP2. This complex requires the adapter GRB2, which bridges SHP to THEMIS in a Tyr‐phosphorylation‐independent fashion. Rather, SHP1 and THEMIS engage with the N‐SH3 and C‐SH3 domains of GRB2, respectively, a configuration that allows GRB2‐SH2 to recruit the complex onto LAT. Consistent with THEMIS‐mediated recruitment of SHP to the TCR signalosome, THEMIS knock‐down increased TCR‐induced CD3‐ζ phosphorylation, Erk activation and CD69 expression, but not LCK phosphorylation. This generalized TCR signalling increase led to augmented apoptosis, a phenotype mirrored by SHP1 knock‐down. Remarkably, a KI mutation of LCK Ser59, previously suggested to be key in ERK‐mediated resistance towards SHP1 negative feedback, did not affect TCR signalling nor ligand discrimination in vivo. Thus, the THEMIS:SHP complex dampens early TCR signalling by a previously unknown molecular mechanism that favours T‐cell survival. We discuss possible implications of this mechanism in modulating TCR output signals towards conventional T‐cell development and differentiation.
A THEMIS:GRB2:SHP complex dampens early TCR signalling and favours T‐cell survival by a previously unknown molecular mechanism that modulates signalling thresholds and ligand discrimination.
Mass spectrometry‐based interactomics identifies the protein tyrosine phosphatases SHP1 and SHP2 and the adapter protein GRB2 as major binding partners in the THEMIS signalling complex in human T cells
GRB2 bridges THEMIS and the SHP enzymes and recruits the complex to phosphorylated LAT
shRNA‐mediated knock‐down of THEMIS leads to increased proximal TCR signalling, up‐regulation of activation markers and activation‐induced cell death in human T cells
LCK‐S59A knock‐in mice exhibit normal T‐cell receptor signalling and ligand discrimination, setting THEMIS's mechanism of ligand discrimination apart from a previously reported ERK‐mediated feedback loop on LCK
Cell fate choices are epitomized by death‐mediated cell disposal, survival, lineage commitment, proliferation and differentiation. Regulatory feedback and feed‐forward mechanisms tailor signal kinetics and amplitude to translate signal inputs into stereotypical gene expression patterns associated with diverse cell fates (Alon, 2007). T cells represent an outstanding example of this paradigm, being capable of translating different incoming T‐cell antigen receptor (TCR) signals into many diverse biological outcomes (Gascoigne & Palmer, 2011). A distinctive feature of TCR signalling is its sensitivity to low doses of agonist ligands (peptide/MHC, pMHC) of relatively weak affinity, combined with the capability to subtly discriminate between signals induced by ligands of close affinity(Gascoigne & Palmer, 2011). Consequently, fine differences in analogue input signals can be converted, at set thresholds, into digital outputs, which can ultimately lead to opposing or divergent outcomes (Daniels et al, 2006; Naeher et al, 2007). The convoluted modular assembly of the TCR signalling machine controlled by sequential phosphorylation events and regulatory mechanisms provides the molecular framework for accurately and unfailingly executing these subtle tasks (Altan‐Bonnet & Germain, 2005; Acuto et al, 2008). However, the molecular circuits driving these choices in different developmental and functional contexts such as in thymocytes and mature T cells are far from being understood (Acuto et al, 2008).
THEMIS, a recent addition to the TCR‐proximal signalling machine (Brockmeyer et al, 2011; Paster et al, 2013; Fu et al, 2014), is rapidly tyrosine‐phosphorylated upon TCR ligation and is required for the differentiation of immature CD4/CD8 double‐positive (DP) thymocytes into mature CD4 or CD8 single‐positive (SP) thymocytes (Fu et al, 2009; Johnson et al, 2009; Kakugawa et al, 2009; Lesourne et al, 2009; Patrick et al, 2009). THEMIS is expressed only in the T‐cell lineage and is first detected in CD4/CD8 double‐negative (DN) thymocytes, reaching maximum levels at the DP stage. Following thymocyte selection, THEMIS expression is decreased in mature CD4 and CD8 SP thymocytes and peripheral T cells. Remarkably, while THEMIS is still well expressed in conventional T cells (Tconv), it is barely detected or absent in regulatory T cells (Treg) and intestinal CD8αα IELs (Johnson et al, 2009; Lesourne et al, 2009). Thus, THEMIS appears to be important for Tconv development (Fu et al, 2013) and may as well play a role in mature, peripheral Tconv. We have shown that soon after TCR stimulation, THEMIS associates to LAT, via the adapter protein GRB2, leading to THEMIS phosphorylation, and that this recruitment is required for THEMIS to function in Tconv development (Paster et al, 2013). Despite the severe phenotype of THEMIS‐deficient mice and initial hints that THEMIS was implicated in regulating TCR signalling (Fu et al, 2009; Brockmeyer et al, 2011), its precise molecular and functional role has remained obscure.
In this work, we used mass spectrometry (MS) to search for THEMIS binding partners. We found that in addition to GRB2, THEMIS was also associated with the tyrosine phosphatase SHP1 (PTPN6) and SHP2 (PTPN11). SHP1 and SHP2 constitutively interacted with THEMIS, in a GRB2‐dependent fashion. We describe a previously unreported binding of SHP1 to GRB2 N‐SH3, so that GRB2 C‐SH3 bridges to THEMIS and leaves GRB2 SH2 available for recruiting the complex onto phosphorylated LAT. In agreement with a role of SHP1 in attenuating TCR‐proximal signalling (Fawcett & Lorenz, 2005; Sankarshanan et al, 2007), we found that reducing levels of THEMIS by shRNA resulted in increased TCR‐proximal signalling as demonstrated by augmented CD3‐ζ and Erk activation. Moreover, increased apoptotic cell death was observed upon TCR stimulation in cells with reduced THEMIS expression. Consistently, shRNA‐mediated knock‐down of SHP1 also increased TCR‐induced cell death, and we found no role for SHP1 tyrosine phosphorylation in this context. We also asked whether the function of the THEMIS:SHP complex in TCR signalling was akin to a previously proposed SHP‐mediated negative feedback mechanism that relies on a direct interaction between LCK and SHP and is prevented when Ser59 of LCK is phosphorylated by Erk (Stefanova et al, 2003). However, we found no evidence for THEMIS:SHP association with LCK after TCR stimulation, nor an effect of THEMIS knock‐down on LCK phosphorylation status. Moreover, a knock‐in (KI) mutation of LCK‐Ser59 was without effect on TCR signalling or ligand discrimination in vivo. These data together with our recent in vivo evidence that THEMIS is key for setting the threshold between positive and negative selection of conventional T cells (Fu et al, 2013) support the physiological relevance of the THEMIS:GRB2:SHP1 complex as a novel mediator of a negative feedback mechanism that modulates TCR phosphorylation to favour T‐cell development and activation.
THEMIS constitutively interacts with SHP proteins in a GRB2‐dependent manner
To gain insight into THEMIS function, we carried out MS‐based identification of its protein‐binding partners. THEMIS tagged with One‐STrEP‐Tag (THEMIS‐Strep) was expressed in Jurkat cells and pulled down with Streptactin beads from either resting or anti‐CD3 mAb‐stimulated cells. Isolated protein complexes were eluted with biotin and analysed by nanoLC‐MS/MS. In agreement with published data, in resting cells, THEMIS co‐purified with GRB2 (Table 1 and Supplementary Table S1) (Johnson et al, 2009; Lesourne et al, 2009; Brockmeyer et al, 2011; Paster et al, 2013). However, ranking just after GRB2 for similar sequence coverage and spectral counts (SC) (see, Table 1, Supplementary Table S1 and Materials and Methods), we found the protein tyrosine phosphatases (PTPs) SHP1 (PTPN6) and SHP2 (PTPN11) to be >20‐fold enriched over background in both non‐stimulated and stimulated cells. Apart from GRB2, SHP1 and SHP2, no other protein was comparably detected or enriched over background in subsequent MS analyses. Because SHP1 and SHP2 share significant structural and functional homology (Lorenz, 2009), and both co‐purified with THEMIS, we inferred that they might be genuine THEMIS functional partners. These data were corroborated by SHP1 immunoprecipitation experiments from CD8+ Jurkat 1G4 cells (Jurkat 1G4‐CD8 hereafter, Fig 1A). Jurkat 1G4‐CD8 express an αβ TCR specific for an HLA‐A2‐restricted NY‐ESO‐1 cancer–testis peptide (Davis et al, 2012). The 1G4‐CD8 model and the NY‐ESO‐1 peptide variants (Aleksic et al, 2010) used throughout this work are introduced in >Supplementary Fig S2A. To investigate the THEMIS:SHP complex in greater detail, an shRNA‐resistant mutant of THEMIS‐Strep was co‐expressed with an shTHEMIS hairpin in Jurkat 1G4‐CD8, effectively replacing endogenous THEMIS with THEMIS‐Strep (see Materials and Methods). Both wt THEMIS and a deletion mutant of the proline‐rich region (dPRR1), which cannot associate with GRB2 (Paster et al, 2013), were expressed in this knock‐down/re‐expression system (Fig 1B). THEMIS‐Strep pull‐down showed a preformed complex including GRB2 and both SHP1 and SHP2 (Fig 1C). TCR stimulation by NY‐ESO‐1 6V peptide/HLA‐A2 tetramer did not affect complex formation. However, THEMIS‐dPRR1 failed to bind to both SHP1 and SHP2 (Fig 1C). Similarly, the potentially less disruptive THEMIS‐R555A point mutant, specifically targeting a key residue in the PxRPxK‐motif within PRR1 of THEMIS (Paster et al, 2013), no longer bound both GRB2 and SHP1 (Supplementary Fig S1A). Together, these data suggested that T cells express at steady‐state THEMIS:GRB2:SHP complexes, whose composition appears to remain unchanged upon TCR stimulation.
SHP tyrosine phosphorylation in T cells is dispensable for GRB2‐mediated THEMIS:SHP complex formation
The tyrosines in the C‐terminal regulatory region of SHP1 and SHP2 (Tyr536/Tyr564 and Tyr542/Tyr580, respectively) (Bennett et al, 1994; Minoo et al, 2004) are thought to play a role in the regulation of phosphatase activity and in providing adapter function via binding to SH2‐domain‐containing proteins (Bennett et al, 1994; Lu et al, 2001; Zhang et al, 2003). For instance, using those phosphorylated residues, the SHP enzymes can associate with the SH2 domain of GRB2 (Bennett et al, 1994; Minoo et al, 2004). Our recent work found that GRB2 associates constitutively via its C‐SH3 domain to the PxRPxK‐motif in the C‐terminus of THEMIS (Paster et al, 2013). Thus, the interaction between SHP1 and GRB2 might be driven by SHP1 C‐terminal Tyr‐phosphorylation and GRB2‐SH2. Indeed, in 1G4‐CD8 (Supplementary Fig S1B) and normal T cells (Supplementary Fig S1C), pTyr564‐SHP1 was detected at steady state. Quantitative pull‐down of THEMIS‐Strep (~90% of cellular pool) contained pTyr564‐SHP1, which remained unchanged upon TCR stimulation (Supplementary Fig S1B). However, approximately < 1% of pTyr564‐SHP1 species is bound to THEMIS (Supplementary Fig S1B), leading us to question the implication of the SHP C‐terminal tyrosines in the formation of the THEMIS:SHP complex. Because SHP1 C‐terminal Tyr‐phosphorylation is LCK dependent [(Lorenz et al, 1994) and see below], we initially inhibited LCK activity with the Src‐kinase inhibitor PP2 in 1G4‐CD8 cells expressing THEMIS‐Strep (Supplementary Fig S1D). PP2 treatment markedly decreased LCK autophosphorylation on Tyr394 and reduced 70% of pTyr564‐SHP1. However, no change in the amount of SHP1 was detected following THEMIS‐Strep pull‐down. To completely rule out that residual C‐terminal Tyr‐phosphorylation might still ensure THEMIS:GRB2:SHP1 complex formation, we turned to the LCK‐deficient Jurkat clone J.CaM1.6 (Fig 1D). JCaM1.6 showed poor basal phosphorylation of Tyr564 of SHP1, which became undetectable after PP2 treatment, and yet no change in the amounts of SHP1 associated with THEMIS was noticed. Re‐expression of LCK resulted in robust Tyr564 phosphorylation with no appreciable change in the stoichiometry of SHP1 bound to THEMIS. Finally, the THEMIS:GRB2:SHP complex was captured on beads, treated with alkaline phosphatase (AP), which reduced Tyr564 phosphorylation by 90% and washed before elution (Fig 1E). This experiment showed again no detectable change in the amounts of GRB2 and SHP1 bound to THEMIS. Together, these data provide strong evidence that in the context of SHP1 association with THEMIS, the GRB2 SH2 domain does not participate in bridging these partners.
GRB2 SH3 domains bridge THEMIS to SHP
We therefore tested which of the GRB2 SH3 domains was involved in SHP binding. HA‐immunoprecipitations were performed from HEK293 cells transiently co‐transfected with HA‐SHP1 and GRB2‐Myc wt, or mutants of the N‐SH3 (W36K) and C‐SH3 domains (W193K) (Bisson et al, 2011). Whereas wt GRB2 bound to SHP1, the W36K mutant drastically reduced SHP1 interaction (Fig 1F). However, the W193K mutation had no effect on SHP1 binding. To ascertain whether N‐SH3‐mediated GRB2 binding to SHP proteins was direct or indirect, we carried out far‐Western experiments using recombinant GRB2 SH3 GST fusion proteins on HA‐SHP1 isolated from transfected HEK293 cells (Fig 1G). Recombinant GRB2 N‐SH3‐GST recognized SHP1, whereas GRB2 C‐SH3‐GST did so only poorly and at the level of the GST‐only control. Together, these data suggested that in T cells, GRB2 bridges THEMIS and SHP1, exploiting both of its SH3 domains each bound to one partner. Consequently, GRB2‐SH2 will remain unoccupied, allowing THEMIS recruitment to phosphorylated GRB2‐binding sites on LAT after TCR stimulation, as we have previously shown (Paster et al, 2013).
THEMIS deficiency augments TCR‐proximal signalling
Earlier in vivo studies using transgenic mouse models have implicated SHP1 in negative regulation of TCR signalling and thymus selection processes (Carter et al, 1999; Johnson et al, 1999; Plas et al, 1999; Zhang et al, 1999). The role of SHP2 in T cells remains less defined, though it has been suggested to serve both negative and positive regulatory functions (Qu et al, 2001; Nguyen et al, 2006). SHP1 appears to be capable of dephosphorylating TCR‐proximal signalling components (Plas et al, 1996; Binstadt et al, 1998; Stefanova et al, 2003). Because THEMIS is recruited onto LAT (Paster et al, 2013) and is constitutively associated with SHP1, we hypothesized that the latter could be transported near the TCR signalling machinery upon TCR ligation and down‐modulate the incoming signal. To test this hypothesis, we made use of Jurkat 1G4‐CD8 cells stimulated with HLA‐A2 tetramers presenting the NY‐ESO‐1 peptide 9V (KD = 7.2 μM) or, ranked by decreasing affinity for 1G4 TCR, single amino acid‐substituted NY‐ESO‐1 variants 6V (KD = 18 μM), 9L (KD = 56 μM) and 4D (KD = 252 μM) (Supplementary Fig S2A). We validated this experimental system by monitoring Erk activation by flow cytometry. Supplementary Figure S2B shows FACS plots of the kinetics of TCR occupancy by each of the four tetramers and the corresponding effect on Erk activation (pT202/pY204‐Erk). As expected, stimulation reveals a digital response for Erk activation (Altan‐Bonnet & Germain, 2005; Daniels et al, 2006). The data showed that binding kinetics and maximal TCR occupancy correlated well with Erk activation and this was in accordance with increased tetramer affinity (Supplementary Fig S2C and D). This experimental system using genuine TCR ligands was therefore suitable for assessing TCR signalling phenotypes caused by genetic manipulation. To test the effect of THEMIS deficiency on TCR signalling, we employed two lentivirus‐based shRNA constructs against human THEMIS, achieving routinely 70 and 90% knock‐down (KD) efficiency in 1G4‐CD8 cells (Fig 2A). Fig 2B shows a representative kinetics experiment (60–180 s) of pErk induction following stimulation by 9V, 6V, 9L and 4D tetramers of 1G4‐CD8 THEMIS KD and control cells. Figure 2C summarizes the results of multiple experiments. Whereas the response of THEMIS KD cell lines was indistinguishable from control cells when stimulated by 9V, with 6V stimulation, both KD cell lines showed a significantly higher response over the control cell line. Moreover, with 9L tetramer, a significant increase of pErk compared to control was seen in the 90% THEMIS KD cell line. Although not reaching statistical significance, the pERK response of 90% THEMIS KD cells towards decreasing doses of 9V (from 200 to 10 nM) was consistently elevated when compared to control cells (Fig 2D and E).
These data revealed that THEMIS exerted a negative effect on the TCR signalling machinery, which might be due to the action of its binding partner SHP1 (and/or SHP2). To address the question of which of the multiple biochemical steps of the TCR signalling cascade were affected by THEMIS knock‐down, we determined whether reduction of THEMIS expression influenced basal LCK activity and TCR‐induced ζ‐ITAM phosphorylation. Monitoring LCK‐pY394 by immunoblot did not reveal convincing evidence for alterations in LCK activity in 90% THEMIS KD cells (Supplementary Fig S3A). However, detection of ζ‐ITAM phosphorylation (pY142, Fig 3A) showed a significant increase in 90% THEMIS KD cells as compared to control cells in response to 9V tetramer (Fig 3B). A similar tendency was also observed when stimulated with 6V tetramer (Fig 3B). Moreover, 9V tetramer titration experiments showed an increase of phospho‐ζ in 90% THEMIS KD over control cells (Supplementary Fig S4A and B). These data were corroborated by cell‐tracker dye experiments in which the 90% THEMIS KD and control lines were mixed, stimulated with 9V tetramer and analysed by FACS for ζ‐ITAM phosphorylation (Supplementary Fig S4C–E). A similar increase in pErk activation was observed in THEMIS KD primary human CD4 T cells (Fig 4A and B). These data suggest that the recruitment of the THEMIS:GRB2:SHP complex onto LAT evokes a negative feedback mechanism that reduces TCR signalling, thus curtailing the signalling cascade from its inception.
THEMIS deficiency results in augmented T‐cell activation markers and apoptotic cell death
Increased TCR‐proximal signalling, as a consequence of THEMIS KD, should potentially result in augmented cell surface activation markers. We carried out experiments addressing this question in human CD4 T cells. Freshly isolated donor‐derived human CD4 T cells were transduced with lentiviral THEMIS or control shRNA constructs. Cells were then expanded with anti‐CD3/CD28‐coated beads and rIL‐2 and selected with puromycin. Consistent with increased TCR‐proximal signalling and Erk activation (Fig 4B), THEMIS KD in CD4 T cells lead to increased expression of both CD69 and CD25 as compared to control cells (Fig 4C). The enhanced activation (e.g., CD69 expression) in THEMIS KD T cells was confirmed across a wide range of CD3/CD28 stimulatory strength (Fig 4D). Interestingly, we noticed that cultures of THEMIS KD CD4 T cells (and to a lesser extent also 1G4 Jurkat cells) displayed a consistently higher rate of cell death when compared to control cells. As a consequence, prolonged stimulation of human T cells with anti‐CD3/CD28 led to poor recovery of live cells in THEMIS KD cultures after several days. We therefore tested whether, in addition to increased proximal signalling, THEMIS deficiency also resulted in augmented cell death. Consistent with this hypothesis, increased apoptosis was observed in CD3/CD28‐stimulated THEMIS KD human CD4 T cells as detected by Annexin‐V staining (Figs 5A and 6D). Activation‐induced cell death (AICD) is mediated by the interaction of death factors and their receptors and plays an important role in immune system homeostasis. The Fas‐FasL system is important for AICD in peripheral T cells, and differential expression levels could modulate sensitivity to AICD (Krammer et al, 2007). No increase of Fas (CD95) or its ligand FasL (CD178) on the cell surface was observed at the time of Annexin‐V staining (Supplementary Fig S5A). Moreover, THEMIS KD 1G4‐CD8 cells stimulated with plate‐bound NY‐ESO‐1 6V MHC tetramer showed a clear increase in Annexin‐V staining when compared to control cells (Fig 5B). To corroborate these data, THEMIS KD and control 1G4‐CD8 cells were subjected to stimulation by NY‐ESO‐1 9V, 6V, 9L and 4D MHC tetramers and analysed for poly‐caspase activation by flow cytometry. Figure 5C and D shows that THEMIS KD resulted in significantly augmented TCR‐induced caspase activation. As for human T cells, THEMIS KD and control cells expressed identical surface levels of CD95 and CD178 under both resting and tetramer stimulated conditions (Supplementary Fig S5B). These data indicated that THEMIS KD leads to increased TCR‐induced cell death correlating with augmented TCR‐proximal signalling. Thus, by negatively regulating TCR‐proximal signalling, THEMIS limits activation‐induced apoptotic cell death.
Reduced SHP1 expression increases TCR‐induced apoptosis
The motheaten(me) mutant mouse strain (SHP1 null mutant) shows a severe autoimmune and immunodeficiency syndrome and exhibits a strong defect in T‐cell maturation (Lorenz, 2009). This phenotype is likely to be exacerbated by a combined defect in the innate immune compartment, which is also affected by SHP1 deficiency (Pao et al, 2007). However, transgenic over‐expression of a SHP1 loss‐of‐function mutant in otherwise normal mice enhanced both positive and negative selection (Plas et al, 1999; Zhang et al, 1999). It is unclear whether increased activation‐induced T‐cell death can be caused by SHP1 deficiency. Our findings that THEMIS constitutively associated with both SHP1 and SHP2 suggest that they could be both recruited onto LAT (Paster et al, 2013), thus initiating negative feedback that attenuates TCR signalling. To test this hypothesis, SHP1 was silenced in 1G4‐CD8 cells by a lentiviral shRNA construct. An 80% reduction of SHP1 expression in 1G4‐CD8 cells (Fig 6A) led to a significant increase in Annexin‐V‐positive cells after stimulation with plate‐bound NY‐ESO‐1 6V MHC tetramer as compared to control cells, an effect similar to that observed for THEMIS KD cells (Fig 6B). Moreover, SHP1 KD primary human T cells displayed an increase of CD69 and Annexin‐V‐positive cells following CD3/CD28 stimulation when compared to control cells, reminiscent of the THEMIS KD phenotype (Fig 6D). These data suggest that SHP1 mediates negative feedback after TCR stimulation and is able to reduce T‐cell death. The similar effect of THEMIS and SHP1 on cell death and their physical association shown here strongly supports the notion that the function of the THEMIS:GRB2:SHP1 complex is to reduce cell death during T‐cell activation.
SHP1 phosphorylation at Tyr536 and Tyr564 did not appear to play a role in THEMIS‐mediated negative regulation of TCR signalling, as the replacement of SHP1 wt for a SHP1 Tyr536/564 to Phe double mutant had no effect on TCR‐induced cell death (Fig 6E). Attempts to determine whether SHP1 N‐SH2 and C‐SH2 domains played a role in the regulation of SHP1 activity in the context of THEMIS association were thwarted by considerably reduced expression levels of the corresponding mutants, likely due to the mutations affecting protein stability.
Mutation of Ser59 of LCK does not affect TCR signalling and ligand discrimination in vivo
It has been suggested that upon recognition of strong agonist ligands by the TCR, LCK undergoes Ser phosphorylation at position 59, preventing recruitment of SHP1 and subsequent TCR desensitization (Stefanova et al, 2003). Such a positive feedback loop would be inefficiently induced by weak agonist ligands and therefore thought to increase TCR ligand discrimination (Altan‐Bonnet & Germain, 2005). To address the importance of LCK‐Ser59 in vivo, we generated knock‐in mice, in which Ser59 was replaced by Ala (Supplementary Fig S6A and B). Mice homozygous for this mutation, LckS59A mice, were born at expected Mendelian frequencies, and T‐cell expression of LCKS59A was comparable to wild‐type LCK (Supplementary Fig S6C). Analysis of LckS59A mice expressing a polyclonal TCR repertoire showed that their thymi and secondary lymphoid organs were of normal size and cellular composition (Supplementary Fig S6D and E). Monitoring CD4, CD8, CD44, CD25, CD3 and CD5 expression showed no major alteration in T‐cell populations from thymus and secondary lymphoid organs (Supplementary Fig S6D and E). T‐cell proliferation and IL‐2 and IFN‐γ production in response to graded concentrations of anti‐CD3 antibody, or to a suboptimal dose of anti‐CD3 antibody in combination with increasing concentrations of anti‐CD28 antibody, were similar in LckS59A and wild‐type mice.
To analyse with a higher sensitivity the effect of the LckS59A mutation on T‐cell development and TCR ligand discrimination, LckS59A mice were backcrossed onto OT‐I mice expressing a TCR specific for an ovalbumin peptide (OVA257‐264). Tracking the monoclonal population of Vα2+ OT‐I CD8+ T cells that develops in OT‐I LckS59ARag2−/−mice showed that the presence of LCKS59A had no effect on T‐cell development (Supplementary Fig S7A and B). Moreover, normal numbers of Vα2+ OT‐I CD8+ T cells were found in secondary lymphoid organs (Fig S7C). CD69 up‐regulation has been used to measure the potency of variants of the OVA257‐264 peptide denoted as Q4, T4 and Q4R7 (Daniels et al, 2006). The presence of LCKS59A molecules did not compromise CD69 up‐regulation in responses to the OVA agonist and the Q4 and T4 weak agonists and slightly better responses were observed for all peptides as compared to those of OT‐I T cells expressing wild‐type LCK molecules (Fig 7A). Likewise, OVA and Q4 induced the down‐modulation of the OT‐I TCR and had a slightly greater potency in the presence of LCKS59A molecules (Fig 7A). Finally, when stimulated with H‐2Kb‐OVA or H‐2Kb‐Q4R7 peptide‐MHC tetramers, T cells from OT‐I Rag2−/− mice expressing LCKS59A proteins showed a higher proliferation than those from OT‐I Rag2−/− mice expressing wild‐type LCK proteins (Fig 7B). Therefore, LCKS59A did not compromise TCR signalling in response to agonist and weak agonist ligands and it even led to slightly enhanced T‐cell responses. Importantly, the potency hierarchy for all the tested OVA variant peptides was fully preserved when measured in the presence of LCKS59A molecules, suggesting that Ser59 of LCK has a modest role in the SHP‐based negative feedback pathway thought to implement TCR ligand discrimination.
In line with these data, we consistently failed to detect LCK in THEMIS:GRB2:SHP complexes, analysed by MS or immunoblotting (Supplementary Fig S1B). Additionally, inhibition of ERK activity in Jurkat 1G4‐CD8 did not ameliorate apoptosis induced by plate‐bound NY‐ESO‐1 pMHC tetramers (Supplementary Fig S8).
Altogether, these data suggest that the mechanistic model proposed by Germain and co‐workers (Stefanova et al, 2003) to explain T‐cell ligand discrimination is distinct from the one enacted by the THEMIS:GRB2:SHP1 complex (see Discussion).
We have shown that THEMIS is required to enact a TCR‐induced negative feedback mechanism that modulates signal transmission. Previous work revealed similar TCR‐induced negative feedback devices originating from the LAT:SLP‐76 complex, which were mediated by the adaptors DOK‐1/DOK‐2 or the kinase HPK1 (Dong et al, 2006; Di Bartolo et al, 2007). However, in contrast to THEMIS KO mice, HPK1 KO or DOK‐1/DOK‐2 double KO showed no detectable defect of T‐cell development (Shui et al, 2007; Yasuda et al, 2007). Thus, THEMIS is part of an as yet unique TCR‐induced regulatory mechanism critical to drive T‐cell development (Fu et al, 2013). We found that THEMIS is constitutively associated with SHP1 and SHP2 through the adaptor GRB2. THEMIS knock‐down in human T cells and Jurkat 1G4‐CD8 cells increased CD3‐ζ phosphorylation and downstream activation events. Because TCR ligation induces recruitment of THEMIS, via GRB2, onto LAT (Paster et al, 2013), we infer that THEMIS allows transport of SHP1 and/or SHP2 close to ligand‐activated TCRs, thus dampening TCR‐ITAM phosphorylation and downstream signalling cascades. LAT deficiency also leads to augmented TCR‐ITAM and ZAP‐70 phosphorylation (Salek et al, 2013), further supporting the role of LAT as a hub for signal regulation (Acuto et al, 2008; Mingueneau et al, 2009; Shen et al, 2010). However, the in vivo consequences of LAT and THEMIS deficiency are substantially different (Acuto et al, 2008; Mingueneau et al, 2009; Fu et al, 2013; Shen et al, 2010), reflecting perhaps the capacity of the TCR to utilize additional signalling conduits that cannot tightly control the TCR signal as LAT does (Roncagalli et al, 2014).
THEMIS KD in CD4 T cells and 1G4 Jurkat cells had a higher propensity than control cells to die after TCR (and CD28, for primary CD4 T cells) stimulation. Increasing ligand affinity or concentration in Jurkat 1G4‐CD8 cells directly correlated with increased apoptotic cell death. Previous work by Lenardo and co‐workers has shown that robust TCR signalling leads to T‐cell death (Combadiere et al, 1998). Therefore, it was not surprising that augmented TCR‐proximal signalling, as a result of reduced THEMIS or SHP1 expression, increased T‐cell death. This correlated with increased caspase activity but in the case of peripheral human T cells, it was not caused by IL‐2 withdrawal, as this cytokine was exogenously added at high concentration to the cell cultures. Thus, it seems that a THEMIS:GRB2:SHP complex helps antagonize an early tendency of T cells to undergo TCR‐induced apoptotic death during activation, by a cell‐intrinsic mechanism likely mediated by BH3‐only, Bcl‐2 family members‐/mitochondria stress‐mediated mechanism (Krammer et al, 2007). An interesting corollary of our findings is that reduced transition of THEMIS‐deficient DP to SP thymocytes (Fu et al, 2009) can be explained by the former cells undergoing cell death instead of survival, thus being negatively rather than positively selected. Consistent with this idea, in a recent work, we have observed that THEMIS‐deficient DP thymocytes respond to positively selecting weak agonist pMHC ligands with increased TCR‐induced signalling (e.g., LAT and PLCγ1 phosphorylation, [Ca2+]i and Erk activation) and more pronounced apoptotic cell death (Fu et al, 2013). The THEMIS−/− phenotype was almost completely rescued in the absence of the pro‐apoptotic BH3‐only, Bcl‐2 family member, Bim. Moreover, in agreement with the data presented here, we found THEMIS associated with SHP1 also in thymocytes (SHP2 was not tested) (Fu et al, 2013). Combined, these results constitute a coherent ensemble of in vitro and in vivo evidence revealing a ‘signal dampening’ function enforced by THEMIS in both DP thymocytes and mature T cells. They provide a plausible explanation for an apparent ‘THEMIS deficiency puzzle’: a relatively mild (or hard to detect) TCR signalling phenotype leading to a severe ablation of Tconv development (Fu et al, 2009, 2013; Johnson et al, 2009; Lesourne et al, 2009).
We found that GRB2 engages its N‐SH3 and C‐SH3 domains to bind to SHP1 and THEMIS, respectively, thus linking them together and leaving the GRB2 SH2 domain free to interact with LAT (this work and Paster et al, 2013). Because quantitative in cell or in vitro dephosphorylation of SHP1 did not alter THEMIS:GRB2:SHP1 stoichiometry, we deduce that pTyr at the C‐terminus of SHP1 does not play a major role in complex formation. Thus, while a detectable proportion of pTyr564‐SHP1 at steady state might be associated with GRB2 via GRB‐SH2, such a SHP1 pool could play a role in other signalling pathways, but not via association to THEMIS, to modulate TCR signalling. Moreover, a functional role of SHP1 C‐terminal phosphorylation in regulating SHP1 activity in the context of the TCR‐induced THEMIS‐mediated negative feedback mechanism seems unlikely. Indeed, we did not observe changes in the amounts of pTyr564‐SHP1 associated with THEMIS after TCR stimulation and SHP1 carrying mutated Tyr536 and Tyr564 behaved functionally similar to SHP1 wt. Thus, our study uncovers a previously unrecognized mechanism by which SHP1 can be recruited to the plasma membrane not directly by its SH2 domains (e.g., via ITIMs), nor via GRB2‐SH2 but in complex with a pseudo‐adaptor molecule, such as THEMIS. Inspection of the SHP protein sequences did not reveal any obvious and conserved proline‐rich sites that can be tested to try and map the GRB2‐N‐SH3 interaction site in SHP proteins. An SH3‐mediated interaction between proline‐rich motifs in the C‐SH2 and PTPase domains of SHP1 and the adaptor protein CrkL has been described recently (Evren et al, 2012). However, we tested by mutational analysis those sites but found no effect on the GRB2 association. Recent 3D structural and mutational studies have revealed an unexpected versatility of SH3 domain binding strategies. These include non‐proline‐containing sequences that are accommodated by non‐canonical binding stratagems within SH3 binding pockets (Saksela & Permi, 2012). Thus, future detailed studies will be needed to map the GRB2 N‐SH3 non‐canonical site of SHP1 (and likely SHP2). It is remarkable that the spatial arrangement created by GRB2 between SHP and THEMIS (just one of its many partners), where GRB2‐SH2 is free to interact with LAT, has not been found thus far in other receptors that use SHP for signal regulation. Such a unique topology may reflect a highly dedicated facet of SHP versatility to achieve subtle signalling regulatory effects in thymocyte selection and T‐cell activation.
SHP1 and SHP2 are relatively well expressed in DP and SP thymocytes and mature T cells (BioGPS (http://biogps.org) and Gjorloff‐Wingren et al, 2000). Earlier studies suggested that SHP1 negatively regulates TCR‐proximal signalling by dephosphorylating signalosome components and participates in the control of SP thymocyte development (Zhang et al, 1999; Lorenz, 2009). Recently, this conclusion has been challenged by the finding that CD4‐cre‐mediated SHP1 conditional deletion showed no apparent alteration of thymocyte development, although an increase of memory T cells skewed towards a Th2 phenotype was found (Johnson et al, 2013). However, the possibility that SHP2 is redundant in the DP to SP thymocyte transition remained untested. Also, SHP1 gene ablation might have been incomplete. Future investigations of conditional KO of SHP1 and SHP2 alone or combined, at the thymocyte DP developmental stage should help resolve this issue.
How is SHP phosphatase activity switched on in the context of the TCR‐dedicated THEMIS‐mediated negative feedback? ITIM motifs are not present on LAT, although the possibility exists that a single phosphorylated tyrosine of LAT could provide binding to the N‐SH2 of SHP proteins, removing its hindrance on the catalytic site in the phosphatase domain (Lorenz, 2009). Alternatively, phosphorylation of THEMIS tyrosines occurring upon recruitment to LAT (Paster et al, 2013) might provide such an unlocking mechanism. Such a hypothesis could not be tested as mutation of those tyrosines locally perturbs THEMIS conformation affecting GRB2 binding to the nearby poly‐proline site (Paster et al, 2013); hence, recruitment onto LAT and phosphorylation do not occur. However, rather than testing point mutations of SHP1 domains (e.g., SH2 domains) or in THEMIS that may have undesirable side‐effects, we aim to test the mechanism of SHP1 catalytic activation in the context of THEMIS association by a direct and simplified approach, by reconstituting the complex in vitro using recombinant proteins.
Negative feedback mechanisms in signalling networks reduce output from defined modules/nodes and thus help maintain cellular functions within a “customary” and narrow range (Amit et al, 2007). The TCR does not encounter customary ligands but rather, within a set range, a diverse, quasi‐continuum, repertoire of affinities and ligand abundance (MHC‐bound self‐ and foreign peptides). Thus, there might be need for the TCR signalosome to modulate signal output to attain stereotypical and highly reproducible gene expression responses. A continuous rectification of variable incoming signals to render them “customary”, may avoid undesired cellular events (e.g. cell death, lineage deviation). During T‐cell development, such a device must be promptly inactivated to allow thymocytes to be able to undergo negative selection at high TCR signal strength. Double‐negative feedback mechanisms do exist for this purpose (Ferrell, 2002), that alone or coupled to positive feedback offer the possibility for robust digital responses, akin to the narrow choice between life and death of DP thymocyte selection (Gascoigne and Palmer, 2011). Although valid, such a conceptual framework may be an over‐simplification, as the in situ situation of the thymic microenvironment is more complex and appears to strongly influence the way developing thymocytes perceive incoming ligands of different affinities (Melichar et al, 2013).
Earlier work by Germain and co‐workers proposed an elegant mechanism by showing that upon pMHC weak agonist engagement, LCK binds via its SH2 domain to phosphorylated SHP1, to dynamically dampen the TCR signalling directly at its inception (Stefanova et al, 2003). Moreover, they proposed that Erk activated by pMHC agonists could unlock such a mechanism by phosphorylating LCK on Ser59, which would oppose SHP binding, providing therefore the double‐negative feedback device necessary to enact ligand discrimination. The THEMIS:SHP‐mediated negative feedback mechanism that we have proposed with in vivo demonstration of its role in positive selection (Fu et al, 2013) and in the current work in a Jurkat T‐cell model and in human T cells may be conceptually similar to that model. However, we notice that our experimental evidence did not detect LCK bound to the THEMIS:GRB2:SHP complex in quantitative THEMIS pull‐downs followed by very sensitive immunoblot or MS analyses. Such an interaction should be detected reasonably well if mediated by LCK‐SH2 binding to phosphorylated SHP1 as originally proposed (Stefanova et al, 2003). We also did not detect an effect of perturbation to the THEMIS:GRB2:SHP complex on LCK activity (pY394) at steady state or after TCR stimulation, but rather an effect on CD3‐ζ phosphorylation after TCR stimulation. More importantly, a mouse KI mutation at Ser59 did not demonstrate the effect expected according to the model proposed by Germain and co‐workers, both in a developmental setting and in in vitro stimulation of T cells carrying a LCK‐Ser59Ala mutation, notably not finding the predicted aberration in TCR ligand discrimination. Finally, we did not observe the predicted effect that Erk inhibition should decrease TCR‐induced signal propagation (e.g., protect from pMHC‐induced apoptosis in the 1G4 system).
The model proposed by Stefanova et al implies that SHP1 translocation to the plasma membrane is ensured by active LCK, the only form of LCK—“open”—that can offer the SH2 to bind to phosphorylated SHP1. Recent work has demonstrated that in normal T cells and thymocytes, a sizable proportion (~40%) of LCK is present in its active form at steady state at the plasma membrane (Nika et al, 2010). In this scenario, one should expect SHP1 to bind to active LCK in resting cells. Even if such binding would occur only after TCR stimulation, SHP1 action would not be very effective as most active LCK would be spread over the entire cell surface, and not preferentially where active signalling is happening, as the THEMIS:GRB2:SHP device presumably does. Together, these data suggest that the model proposed by Germain and co‐workers is different from the one enacted by the THEMIS:GRB2:SHP1 complex, which has been proven by in vivo evidence to be required for establishing the fine threshold between positive and negative selection, hence ligand discrimination.
Materials and Methods
Plasmids and antibodies
Full‐length cDNA encoding human THEMIS was obtained from Open Biosystems (NM_001010923.2; giving rise to a 641 aa protein: UniProt Q8N1K5‐1) and used as the PCR template to generate THEMIS‐Strep, carrying a C‐terminal One‐STrEP‐Tag (IBA BioTAGnology). THEMIS‐Strep was cloned into the lentiviral expression vector pHR‐SIN‐BX‐IRES‐Emerald (kindly provided by Dr. V. Cerundolo, WIMM, Oxford) to give rise to pHR‐THEMIS‐OST. All mutants described were based on pHR‐THEMIS‐Strep and derived by site‐directed mutagenesis (QuickChange II Kit, Agilent Technologies). THEMIS knock‐down/re‐expression constructs are based on Tet‐pLKO‐Puro (Addgene 21915, Dr. Dmitri Wiederschain, Novartis Developmental and Molecular Pathways, Cambridge, MA, USA). Briefly, shRNA‐128476 (90% KD efficiency for human THEMIS) was cloned under the control of the H1/TO promoter to give rise to the doxycycline‐inducible construct Tet‐pLKO‐Puro‐128476. Exchange of the tetR gene by THEMIS‐Strep (wild‐type and mutants of the PPR1 site) carrying shTHEMIS‐128476 resistance mutations (silent mutations at wobble position of two consecutive codons within the shRNA‐target sequence) lead to construct pLKO‐Puro‐128476‐THEMIS‐Strep. C‐terminal Myc‐tagged human GRB2 wt in lentiviral pHR‐SIN‐BX‐IRES‐Emerald was described earlier (Paster et al, 2013). GRB2 N‐SH3 (W36K) and C‐SH3 (W193K) mutants were derived by site‐directed mutagenesis and cloned in pHR‐SIN‐BX‐IRES‐Emerald. Plasmid pcDNA3.1‐HA‐SHP1, coding for human SHP1 with an N‐terminal HA‐Tag, was a kind gift of Prof. Ge Baoxue (Institute of Health Sciences, Shanghai Jiao Tong University School of Medicine). All constructs were verified by sequencing. The lentiviral helper plasmids psPAX2 (Addgene 10703) and pMD2.G (Addgene 12259) were provided by Dr. Didier Trono (Ecole Polytechnique Fédérale de Lausanne, Lausanne, Switzerland) via Addgene. Lentiviral shRNA constructs were purchased from Sigma: pLKO‐shCtr (SHC002V), pLKO‐shSHP1 (TRCN0000244305) and pLKO‐shTHEMIS (TRCN0000128476 and TRCN0000130264). Mouse mAbs used included as follows: Alexa647‐conjugated anti‐phospho‐CD247 (Tyr142, clone K25‐407.69, BD Biosciences); anti‐CD247 (clone 6B10.2, Santa Cruz Biotechnologies); anti‐human CD28 (clone CD28.2, Biolegend); anti‐human CD3ε (clone UCHT1, eBioscience); APC‐conjugated anti‐CD69 (clone CH/4, Invitrogen); Alexa647‐conjugated anti‐phospho‐MAPK (ERK1/2, pThr202/pTyr204, clone E10, Cell Signaling Technology); anti‐MAPK (ERK1/2, clone 3A7, Cell Signaling Technology); anti‐phospho‐MAPK (ERK1/2, pThr202/pTyr204, clone 197G2, Cell Signaling Technology); anti‐LCK (clone 3A5, Santa Cruz); anti‐SHP1 (clone D‐11, Santa Cruz); anti‐SHP2 (clone M163, Abcam); anti‐One‐STrEP‐Tag mAb (StrepMAB Classic Cat no: 2‐1509‐001, IBA bioTAGnology; clone GT 661, MyBioscource); anti‐phosphotyrosine (clone 4G10, Millipore); anti‐Actin (clone AC‐15, Sigma); and anti‐THEMIS (clone Q13‐1103, BD Biosciences). Rabbit polyclonal Abs used were as follows: anti‐GRB2 (C‐23, Santa Cruz); anti‐phospho CD247 (Tyr142, clone EP265(2)Y, Epitomics); anti‐HA‐Tag (C29F4, Cell Signaling Technology); anti‐Myc‐Tag (Cat no: 2272, Cell Signaling Technology); anti‐SHP1 (clone C‐19, Santa Cruz); anti‐phospho SHP1 (Tyr564 clone D11G5, Cell Signaling Technologies); anti‐phospho‐Src‐family (pTyr416, Cat no: 2101, Cell Signaling Technologies); anti‐GST (Cat no: 2622, Cell Signaling Technology); and anti‐THEMIS (Cat no: HPA031425, Sigma). Anti‐HA agarose conjugate (mouse monoclonal clone HA‐7) was purchased from Sigma.
Cell lines, transfections and lentiviral transductions
Jurkat 1G4‐CD8 cells (expressing the 1G4 TCR and CD8αα) were maintained in RPMI 1640 (PAA Laboratories, Inc.) medium supplemented with 10% foetal bovine serum (FBS, Perbio). J.CaM1.6 LCK‐Tet (K. Nika, A. Schulze, T. Hoefer, M. D'abramo, A. Grottesi, L. Schermelleh, O. Acuto, manuscript in preparation), stably carrying a tetracycline‐inducible human LCK expression construct, was established using the two‐vector Lenti‐X Tet‐On Advanced inducible Expression System (Clonetech). LCK expression was induced with 1 μg/ml doxycycline for 24 h. Human embryonic kidney epithelial cells (HEK293) were maintained in DMEM, 10% FBS. HEK293 cells were transfected by standard calcium phosphate precipitation. Lentiviral particles were produced in HEK293 cells by co‐transfection of lentiviral expression vectors with the packaging plasmids psPAX2 and pMD2.G. 48 h after transfection, viral supernatants were harvested, filtered and used for the transduction of cells in the presence of 5 μg/ml Polybrene. Puromycin selection was applied 48 h post‐transduction where appropriate at 1 μg/ml. All parental cell lines are originally from ATCC, tested negative for mycoplasma within previous 3 months and are not STR profiled.
Preparation of NY‐ESO‐1 tetramers
Residues 1–278 of the A2 heavy chain with the COOH‐terminal BirA tag and β2m were expressed in E. coli as inclusion bodies and purified, and refolded to pMHC monomers in the presence of NY‐ESO‐1 peptides (Cambridge Peptides) listed in Supplementary Fig S2A. Biotinylated monomers were purified by FPLC on an S200 column and tetramerized with phycoerythrin‐conjugated streptavidin (Fluka) as described earlier (Altman & Davis, 2003).
Mass spectrometry data acquisition and analysis
Data were converted to .mzXML format using MSconvert (Proteowizard) and uploaded into the Central Proteomics Facility Pipeline (CPFP) (Trudgian et al, 2010) for analysis. Enzyme was set to trypsin allowing for up to 2 missed cleavages. Carbamidomethyl cysteine was set as a fixed modification and oxidation (methionine), deamidation (NQ), acetylation (Protein‐N) and phosphotyrosine as variable modifications. Mass tolerances for MS and MS/MS peak identifications were 20 ppm and 0.1 Da, respectively. InterProphet probability (IP Prob) is derived by the combination of results from multiple search engines within CPFP and improves coverage and confidence over use of a single search engine. Label‐free quantitation was performed using the SINQ (Spectral index quantitation) tool within CPFP (Trudgian et al, 2011). Only proteins which were >20‐fold abundant over the biotin‐blocked control sample were considered for further analysis using the CRAPOME contaminant repository (Mellacheruvu et al, 2013). Finally, proteins found in less than 5% of all Strep‐Tag background pull‐down experiments listed within CRAPOME were considered as true interactors.
MS data deposition
The mass spectrometry data from this publication have been submitted to the ProteomeXchange Consortium (Vizcaino et al, 2014) via the PRIDE partner repository (http://www.ebi.ac.uk/pride) with the data set identifier PXD001410.
shRNA‐mediated gene knock‐down in human CD4+ T cells
For each shRNA construct, lentiviral supernatants from three 100‐mm dishes of HEK293 cells (10 ml each) were pooled at 48 h post‐transfection, filtered through a 0.45‐μm syringe filter and subjected to ultracentrifugation at 23,000 × g (SW28 rotor) for 90 min at 4°C. Viral pellets were gently resuspended in 300 μl serum‐free DMEM medium and either used immediately for transductions or snap‐frozen in liquid nitrogen and stored at −80°C for future use. Briefly, human peripheral CD4+ T cells were isolated from blood by negative selection using the Dynabeads Untouched Human CD4 T‐cell isolation kit (Life Technologies Corp.). 2.5 × 107 CD4+ T cells were stimulated per well of a 6‐well plate by plate‐bound CD3 mAb (UCHT‐1, 10 μg/ml), soluble CD28 mAb (CD28.2, 1 μg/ml) and recombinant human IL‐2 (50 U/ml; AbDSerotec) for 5 h prior to transduction. Cells were then harvested, suspended in 800 μl RPMI, 10% FBS plus 200 μl concentrated lentiviral supernatant, 5 μg/ml Polybrene, 1 μg/ml CD28 mAb and 50 U/ml IL‐2 and reapplied to a CD3 mAb coated 6‐well for overnight incubation. Cells were harvested next day and incubated with Human T‐activator CD3/CD28 beads (Life Technologies) at a bead:cell ratio of 1:5 in the presence of 50 U/ml IL‐2.
For SHP1 immunoprecipitation assays, Jurkat 1G4‐CD8 cells were lysed in ice‐cold lysis buffer (25 mM Tris pH 7.4, 150 mM NaCl, 1 mM EDTA pH 8.0, 1% Triton, 1.75% Octyl β‐D‐glucopyranoside (Affymetrix), 1 mM Na3VO4, protease inhibitor cocktail (Roche)). Lysates were cleared by centrifugation at 14,000 × g for 10 min. Lysates were pre‐cleared with Protein A/G agarose beads (Santa Cruz) for 45 min, and antibody immunoprecipitation was carried out for 2 h using 2 μg of SHP1 (rabbit polyclonal; Santa Cruz C‐19) or rabbit IgG antibody, respectively. Protein complexes were pulled down with Protein A/G agarose beads for 2 h, followed by three washes in ice‐cold lysis buffer and elution by boiling in SDS sample buffer. For HA IPs, anti‐HA agarose (clone 4A6, Millipore) conjugate was used.
Streptactin pull‐down assays and protein interaction analysis by mass spectrometry
Streptactin pull‐downs were performed as described recently (Paster et al, 2013). Where indicated, protein complexes on Streptactin‐Sepharose beads were incubated for 30 min at 37°C with 3 units of alkaline phosphatase (calf intestinal phosphatase, New England Biolabs) in phosphatase buffer [10 mM NaCl, 5 mM Tris pH 7.9, 1 mM MgCl2, 0.1 mM DTT and protease inhibitor cocktail (Roche)] or phosphatase buffer only. Following washes, proteins were eluted as described before. For MS analysis, resting or anti‐CD3‐activated Jurkat cells (1 × 108) expressing THEMIS‐Strep were lysed and pulled down as described (Paster et al, 2013). Biotin‐blocked Streptactin‐Sepharose beads were used to assess background. Biotin‐eluted proteins were boiled in reducing SDS NuPAGE sample buffer (Invitrogen), followed by alkylation with 55 mM iodoactamide (Sigma). In‐gel digest and MS data acquisition were performed as described (Brockmeyer et al, 2011).
Phospho‐flow and apoptosis flow cytometry
For Phospho‐flow, 5 × 105 1G4‐CD8 cells were stimulated with 200 nM tetramers in RPMI at 37°C. Samples were fixed immediately in fixation buffer (BD Bioscience) at 37°C for 10 min, washed with PBS, 1% BSA, 0.01% azide before permeabilization with 10% saponin on ice for 30 min (Perm/wash buffer 1, BD Bioscience). Antibody staining was for 1 h at RT in 10% saponin buffer. Flow cytometry was performed on a FACSCalibur (Becton Dickinson), and the experiment was analysed using FlowJo (Tree Star, Inc.). Statistical analysis was performed in GraphPad Prism. To detect apoptosis, 2 × 105 1G4‐CD8 cells were stimulated with 20 nm pMHC tetramers or 2 μg/ml camptothecin for 24 h at 37°C in RPMI with 10% FCS. After incubation, cells were stained with FAM‐ or far‐red‐FLICA (Immunochemistry Technologies). For plate‐bound stimulations, biotinylated 6V monomers were immobilized at the indicated concentrations on Streptavidin‐coated 96‐well plates (Thermo Scientific) at 4°C overnight in PBS. Plates were washed twice with PBS, and 105 1G4‐CD8 cells/well were incubated ON at 37°C in RPMI with 10% FCS. Cells were harvested, washed in PBS and stained with Annexin‐V‐Alexa647 (Life Technologies) in 100 mM HEPES, 140 mM NaCl, 25 mM CaCl2, pH 7.4. Flow data were analysed as described above.
Wild‐type, LckS59A (this paper), transgenic OT‐I (Hogquist et al, 1994) and Rag2−/− (Shinkai et al, 1992) mice were maintained in specific pathogen‐free conditions. OT‐I mice expressing wild‐type LCK or LCKS59A proteins were maintained on a Rag2−/− background. All experiments involving mice were done in accordance with French and European guidelines for animal care.
Construction of LckS59A knock‐in mice
A genomic fragment containing all the exons of the Lck gene was isolated from a BAC clone of C57BL/6 origin (n° RP23‐209C6, Deutsches Ressourcenzentrum für Genomforschung). The TCC codon found in exon 2 of the Lck gene and coding for the serine residue present at position 59 of LCK was converted into a GCC codon coding for an alanine. A loxP‐tACE‐CRE‐PGK‐gb2‐neor‐loxP cassette (NEO; Mingueneau et al, 2008) was introduced in the intron separating exons 8 and 9 of the Lck gene, and a thymidine kinase expression cassette (TK) was abutted to the 5′ end of the targeting vector (Supplementary Fig S6A).
Isolation of recombinant ES clones.
After electroporation of Bruce 4 C57BL/6 ES cells (Kontgen et al, 1993) and selection in G418 and ganciclovir, colonies were screened for homologous recombination by Southern blot. The 5′ single‐copy probe corresponded to a 486‐bp genomic fragment containing exons 5 and 6 (Supplementary Fig S1A). When tested on AseI‐digested DNA, it hybridized to a 14.7‐kb wild‐type fragment or to a 13.7‐kb recombinant fragment. The occurrence of an appropriate homologous recombination event at the 3′ side was screened using a 3′ single‐copy probe corresponding to a 480‐bp fragment of the Neomycin resistance cassette (amplified using primers 5′‐GGGAAGGGACTGGCTGCTATTG‐3′ and 5′‐GCGATACCGTAAAGCACGAGG‐3′). When tested on BglI‐digested DNA, it hybridized to a 10‐kb recombinant fragment.
Production of mutant mice.
Mutant ES cells were injected into FVB blastocysts. Germline transmission led to the self‐excision of the NEO selection cassette in male germinal cells. Presence of the intended mutation was checked in homozygous LckS59Amice by sequencing a 434‐bp genomic fragment encompassing the targeted chromosomal region and using primers 5′‐GAATTCAGAGACAAGGTTCAACCA‐3′ and 5′‐AAGTCTCCATCATGGGAGGGCTCA‐3′. Screening of mice for the presence of the LckS59A mutation was performed by PCR using the following oligonucleotides: 5′‐CCTCCCCAGGGATTAAAGCTGTGCATC‐3′ and 5′‐GCCTGTGTCTTCTTCCCAGAGACCTGA‐3′. This pair of primers amplifies a 400‐bp band in the case of the wild‐type allele and a 479‐bp band in the case of the LckS59A allele. Mice harbouring the LckS59A mutation (international strain designation C57BL/6‐Lcktm3Mal) are available upon request from EMMA (https://www.infrafrontier.eu) under ID number 04456.
Flow cytometry and intracellular staining.
The following antibodies were used: anti‐CD5 (53–7.3), anti‐CD4 (RM4‐5), anti‐CD8α (53–6.7), anti‐TCRβ (H57‐597), anti‐CD44 (IM7), anti‐CD3 (145‐2C11), anti‐CD24 (M1/69), anti‐Vα2 (B20‐1) all from BD Biosciences and anti‐CD25 (PC61.5) from BioLegend. Cell viability was evaluated using SYTOX Blue (Life Technologies). For intracellular staining of LCK, cells were permeabilized using the BD Cytofix/Cytoperm™ Fixation/Permeabilization Kit according to manufacturer protocol. Anti‐LCK antibody (clone 3A5; Santa Cruz) and an isotype control antibody (mouse IgG2b from BD Biosciences) were used at 10 μg/ml. A FITC‐conjugated goat anti‐mouse IgG2b secondary antibody (Southern Biotechnology) was used to reveal the primary antibody. Stained cells were analysed using an LSRII system (BD Biosciences). Data were analysed with Diva software (BD Biosciences), and overlayed plots were constructed with FlowJo software.
OVA peptides and tetramers.
OVA peptide variants and a null peptide VSV were synthesized and purified as described (Daniels et al, 2006). Biotinylated, soluble peptide‐MHC monomer involving the H‐2Kb molecule and OVA peptide variants were tetramerized with streptavidin as described (Daniels et al, 2006).
Mouse T‐cell isolation and stimulation
T cells were purified from pooled lymph nodes and spleens of wild‐type and LckS59A mice with Dynabeads Untouched Mouse T cell kits (Life Technologies) with a cell purity of over 90%. Purified cells were stimulated for 72 h with plate‐bound anti‐CD3 (145‐2C11; American Type Culture Collection) with or without soluble anti‐CD28 (37–51; American Type Culture Collection). Intracellular IL‐2 and IFN‐γ were measured as described (Mingueneau et al, 2008). Proliferation was measured using CFSE labelling. After 3 days, the absolute numbers of T cells having diluted CFSE were counted after adding Flow‐Count™ Fluorospheres (Beckman Coulter).
OT‐I cell stimulation
Splenocytes from Cd3eΔ5/Δ5 mice (Malissen et al, 1995) were used as antigen‐presenting cells (APC) and loaded with VSV or the OVA peptide variants described above. Briefly, Cd3eΔ5/Δ5 splenocytes were irradiated (3,000 rad) and pulsed for 2 h at 37°C with serial dilution of OVA peptide variants. Peptide‐loaded APCs were incubated with lymph node T cells from Tg OT‐I Rag2−/− or LckS59A Tg OT‐I Rag2−/− mice and tested for CD69 up‐regulation and TCR down‐modulation. TCR down‐modulation was followed by FACS by measuring the decrease of Vα2 expression and was calculated according the formula: % TCR down‐regulation = 100 × (X/Y × 100) where X is the mean fluorescence of the TCR expressed when stimulated with APCs pulsed with the OVA or Q4 peptide and Y is the mean fluorescence of the TCR expressed when stimulated with APCs pulsed with a peptide that is not recognized by the OT‐I TCR. In the case of stimulation with peptide‐MHC tetramers, serial dilution of H‐2Kb‐OVA or H‐2Kb‐Q4R7 tetramers were incubated with CFSE‐loaded lymph node T cells from OT‐I Rag2−/− or LckS59A OT‐I Rag2−/− mice. After 3 days, the absolute numbers of CFSE+ T cells were counted after adding Flow‐Count™ Fluorospheres (Beckman Coulter).
OA and WP initiated the project and conceived the experiments of the THEMIS and SHP1 study. WP, AMB and KK performed the experiments of the THEMIS and SHP1 study. S‐PC generated stable CD8 co‐receptor expressing Jurkat 1G4 cells. KCM prepared reagents and provided technical assistance. GF and NRJG provided key reagents and help with data analysis. SMF and PCS provided recombinant GRB2 SH3‐GST and advised on far‐Western experiments; KN provided the LCK Tet‐inducible J.CaM1.6 cell line and AC did Erk inhibition experiments for activation and apoptosis; OD helped in analysing the phospho‐flow data; CG and BM conceived and developed the LckS59A mice; CG analysed the LckS59A mice with the help of RR, OA and WP wrote the manuscript with contributions from all authors.
Conflict of interest
The authors declare that they have no conflict of interest.
Supplementary Figure S1
Supplementary Figure S2
Supplementary Figure S3
Supplementary Figure S4
Supplementary Figure S5
Supplementary Figure S6
Supplementary Figure S7
Supplementary Figure S8
Supplementary Table S1
Supplementary Figure Legends
We thank Dr. Ge Baoxue for providing plasmid pcDNA3.1‐HA‐SHP1 and Drs. Ji‐Li Chen and Vincenzo Cerundolo for initial help with the Jurkat 1G4 system. We thank Ben Thomas, Svenja Hester and Philip Charles for help with mass spectrometry data analysis and all members of the T Cell Signalling Laboratory for helpful discussions. We are grateful for the support of the PRIDE team in depositing our proteomics data set. We thank Ed Palmer for providing peptide‐MHC monomers in the frame of the ‘Sybilla’ project and the Centre d'Immunophénomique for blastocyst injection. This work was supported by: Wellcome Trust grant WT094296MA (to O.A) and EU‐FP7 ‘Sybilla’ grant 201106 to O.A. and B.M., NIH grants AI073870 and GM065230 to N.R.J.G.; grants from Centre National de la Recherche Scientifique, from the Institut National de la Santé et de la Recherche Médicale; from Agence Nationale de Recherche (projects ‘ADAPT’ and ‘BASILIC’, to B.M.), and from the European Research Council (project ‘Integrate’ to B.M.); grants EU‐FP7 ‘Targetbinder’ and from Breast Cancer Campaign (to S.M.F.); P.C.S. is further supported by the Rosetrees Trust. O.D. was supported by a Sir Henry Dale Fellowship jointly funded by the Wellcome Trust and the Royal Society (098363). A.M.B. was supported by a Case‐MRC fellowship.
This is an open access article under the terms of the Creative Commons Attribution 4.0 License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
- © 2014 The Authors. Published under the terms of the CC BY 4.0 license