Nck Binds to the T Cell Antigen Receptor Using Its SH3.1 and SH2 Domains in a Cooperative Manner, Promoting TCR Functioning.

Ligand binding to the TCR causes a conformational change at the CD3 subunits to expose the CD3ε cytoplasmic proline-rich sequence (PRS). It was suggested that the PRS is important for TCR signaling and T cell activation. It has been shown that the purified, recombinant SH3.1 domain of the adaptor molecule noncatalytic region of tyrosine kinase (Nck) can bind to the exposed PRS of CD3ε, but the molecular mechanism of how full-length Nck binds to the TCR in cells has not been investigated so far. Using the in situ proximity ligation assay and copurifications, we show that the binding of Nck to the TCR requires partial phosphorylation of CD3ε, as it is based on two cooperating interactions. First, the SH3.1(Nck) domain has to bind to the nonphosphorylated and exposed PRS, that is, the first ITAM tyrosine has to be in the unphosphorylated state. Second, the SH2(Nck) domain has to bind to the second ITAM tyrosine in the phosphorylated state. Likewise, mutations of the SH3.1 and SH2 domains in Nck1 resulted in the loss of Nck1 binding to the TCR. Furthermore, expression of an SH3.1-mutated Nck impaired TCR signaling and T cell activation. Our data suggest that the exact pattern of CD3ε phosphorylation is critical for TCR functioning.

A novel thymoma-associated immunodeficiency with increased naive T cells and reduced CD247 expression.

The mechanisms underlying thymoma-associated immunodeficiency are largely unknown, and the significance of increased blood γδ Τ cells often remains elusive. In this study we address these questions based on an index patient with thymoma, chronic visceral leishmaniasis, myasthenia gravis, and a marked increase of rare γδ T cell subsets in the peripheral blood. This patient showed cutaneous anergy, even though he had normal numbers of peripheral blood total lymphocytes as well as CD4(+) and CD8(+) T cells. Despite his chronic infection, analyses of immunophenotypes and spectratyping of his lymphocytes revealed an unusual accumulation of naive γδ and αß T cells, suggesting a generalized T cell activation defect. Functional studies in vitro demonstrated substantially diminished IL-2 and IFN-γ production following TCR stimulation of his "untouched" naive CD4(+) T cells. Biochemical analysis revealed that his γδ and αß T cells carried an altered TCR complex with reduced amounts of the ζ-chain (CD247). No mutations were found in the CD247 gene that encodes the homodimeric ζ protein. The diminished presence of CD247 and increased numbers of γδ T cells were also observed in thymocyte populations obtained from three other thymoma patients. Thus, our findings describe a novel type of a clinically relevant acquired T cell immunodeficiency in thymoma patients that is distinct from Good's syndrome. Its characteristics are an accumulation of CD247-deficient, hyporresponsive naive γδ and αß T cells and an increased susceptibility to infections.

The CD3 conformational change in the γδ T cell receptor is not triggered by antigens but can be enforced to enhance tumor killing.

Activation of the T cell receptor (TCR) by antigen is the key step in adaptive immunity. In the αßTCR, antigen induces a conformational change at the CD3 subunits (CD3 CC) that is absolutely required for αßTCR activation. Here, we demonstrate that the CD3 CC is not induced by antigen stimulation of the mouse G8 or the human Vγ9Vδ2 γδTCR. We find that there is a fundamental difference between the activation mechanisms of the αßTCR and γδTCR that map to the constant regions of the TCRαß/γδ heterodimers. Enforced induction of CD3 CC with a less commonly used monoclonal anti-CD3 promoted proximal γδTCR signaling but inhibited cytokine secretion. Utilizing this knowledge, we could dramatically improve in vitro tumor cell lysis by activated human γδ T cells. Thus, manipulation of the CD3 CC might be exploited to improve clinical γδ T cell-based immunotherapies.

Relevance of Nck-CD3 epsilon interaction for T cell activation in vivo.

On TCR ligation, the adaptor Nck is recruited through its src homology 3.1 domain to a proline-rich sequence (PRS) in CD3ε. We have studied the relevance of this interaction for T cell activation in vitro and in vivo by targeting the interaction sites in both partners. The first approach consisted of studying a knockin (KI) mouse line (KI-PRS) bearing a conservative mutation in the PRS that makes the TCR incompetent to recruit Nck. This deficiency prevents T cell activation by Ag in vitro and inhibited very early TCR signaling events including the tyrosine phosphorylation of CD3ζ. Most important, KI-PRS mice are partly protected against the development of neurological symptoms in an experimental autoimmune encephalitis model, and show a deficient antitumoral response after vaccination. The second approach consisted of using a high-affinity peptide that specifically binds the src homology 3.1 domain and prevents the interaction of Nck with CD3ε. This peptide inhibits T cell proliferation in vitro and in vivo. These data suggest that Nck recruitment to the TCR is fundamental to mount an efficient T cell response in vivo, and that the Nck-CD3ε interaction may represent a target for pharmacological modulation of the immune response.

Nck recruitment to the TCR required for ZAP70 activation during thymic development.

The adaptor protein Nck is inducibly recruited through its SH3.1 domain to a proline-rich sequence (PRS) in CD3ε after TCR engagement. However, experiments with a knockin mutant bearing an 8-aa replacement of the PRS have indicated that Nck binding to the TCR is constitutive, and that it promotes the degradation of the TCR in preselection double-positive (DP) CD4(+)CD8(+) thymocytes. To clarify these discrepancies, we have generated a new knockin mouse line (KI-PRS) bearing a conservative mutation in the PRS resulting from the replacement of the two central prolines. Thymocytes of KI-PRS mice are partly arrested at each step at which pre-TCR or TCR signaling is required. The mutation prevents the trigger-dependent inducible recruitment of endogenous Nck to the TCR but does not impair TCR degradation. However, KI-PRS preselection DP thymocytes show impaired tyrosine phosphorylation of CD3ζ, as well as impaired recruitment of ZAP70 to the TCR and impaired ZAP70 activation. Our results indicate that Nck is recruited to the TCR in an inducible manner in DP thymocytes, and that this recruitment is required for the activation of early TCR-dependent events. Differences in the extent of PRS mutation could explain the phenotypic differences in both knockin mice.

Stoichiometry and intracellular fate of TRIM-containing TCR complexes.

BACKGROUND: Studying the stoichiometry and intracellular trafficking of the T cell antigen receptor (TCR) is pivotal in understanding its mechanisms of activation. The alphabetaTCR includes the antigen-binding TCRalphabeta heterodimer as well as the signal transducing CD3epsilongamma, CD3epsilondelta and zeta2 subunits. Although the TCR-interacting molecule (TRIM) is also part of the alphabetaTCR complex, it has not been included in most reports so far. RESULTS: We used the native antibody-based mobility shift (NAMOS) assay in a first dimension (1D) blue native (BN)-PAGE and a 2D BN-/BN-PAGE to demonstrate that the stoichiometry of the digitonin-solublized TRIM-containing alphabetaTCR is TCRalphabetaCD3epsilon2gammadeltazeta2TRIM2. Smaller alphabetaTCR complexes possess a TCRalphabeta CD3epsilon2gammadeltazeta2 stoichiometry. Complexes of these sizes were detected in T cell lines as well as in primary human and mouse T cells. Stimulating the alphabetaTCR with anti-CD3 antibodies, we demonstrate by confocal laser scanning microscopy that CD3epsilon colocalizes with zeta and both are degraded upon prolonged stimulation, possibly within the lysosomal compartment. In contrast, a substantial fraction of TRIM does not colocalize with zeta. Furthermore, TRIM neither moves to lysosomes nor is degraded. Immunoprecipitation studies and BN-PAGE indicate that TRIM also associates with the gammadeltaTCR. CONCLUSIONS: Small alphabetaTCR complexes have a TCRalphabeta CD3epsilon2gammadeltazeta2 stoichiometry; whereas those associated with one TRIM dimer are TCRalphabeta CD3epsilon2gammadeltazeta2TRIM2. TRIM is differentially processed compared to CD3 and zeta subunits after T cell activation and is not degraded. The gammadeltaTCR also associates with TRIM.

Analysis of novel phospho-ITAM specific antibodies in a S2 reconstitution system for TCR-CD3 signalling.

The T cell antigen receptor (TCR-CD3) complex contains 12 different cytoplasmic tyrosines, each of which is part of an immunoreceptor tyrosine-based activation motif and thus occurs in similar sequence context. Since phosphorylation of individual tyrosines can be correlated with the quality of the T cell response, monitoring their phosphorylation is important. We thus generated novel antibodies against phospho-tyrosines of the TCR-CD3 complex and tested the specificity in a synthetic biology approach. We utilized the Drosophila S2 reconstitution system testing several kinases and stimulation conditions that lead to optimal phosphorylation of the TCR-CD3 subunit zeta. Expressing TCR-CD3 subunits and tyrosine mutants thereof we tested the specificity of the novel antibodies in Western blot and immunopurification experiments. In particular, we generated and characterized the monoclonal antibody EM-26 that specifically recognizes phosphorylation of the membrane proximal tyrosine of zeta (phospho-zetaY1) and antisera raised against the first and the second phospho-tyrosine of CD3epsilon (phospho-epsilonY1 and phospho-epsilonY2).

Detection of phosphorylated T and B cell antigen receptor species by Phos-tag SDS- and Blue Native-PAGE.

Detection of phospho-proteins and differently phosphorylated forms of the same protein are important in understanding cell behaviour. One novel method is Phos-tag SDS-PAGE. A dinuclear Mn(2+) complex that binds to phosphate groups (the Phos-tag) is covalently attached to the polyacrylamide gel matrix. Thus, phosphorylated proteins are retarded in their migration and can be distinguished from their non-phosphorylated counterparts. We applied Phos-tag SDS-PAGE to the analysis of the zeta, CD3epsilon and CD3delta subunits of the T cell antigen receptor (TCR-CD3). Pervanadate stimulation generated six different phospho-zeta and each two different CD3epsilon and CD3delta forms. This corresponds to the phosphorylatable tyrosines on their cytoplasmic tails. The phosphorylation pattern was compatible with random phosphorylation events. Further, we showed that the Phos-tag technology can be applied to Blue Native (BN)-PAGE. This extends the applicability to the analysis of native protein complexes. Upon pervanadate stimulation the TCR-CD3 complex was predominantly detected as two distinct phospho-complexes. In contrast, the B cell antigen receptor (BCR) appeared as one phospho-form. Thus, Phos-tag BN-PAGE is useful for the analysis of different phosphorylation states of multiprotein complexes.

Target-dependent T-cell activation by coligation with a PSMA x CD3 diabody induces lysis of prostate cancer cells.

Recently, we have described a bispecific PSMA x CD3 diabody with one binding site for the T-cell antigen receptor (TCR-CD3) and another for the Prostate Specific Membrane Antigen (PSMA). It effectively eliminates human prostate cancer cells by redirecting T-lymphocytes in vitro and in vivo. Here, we show that activation of the T-cells and killing of the tumor cells, only occurred when the T-cells were coincubated with PSMA-positive tumor cells and the PSMA x CD3 diabody. Both CD4+ and CD8+ human T-lymphocytes were activated. Surprisingly, they were equally potent in their cytotoxic activity, proliferation, and up-regulation of activation markers. Both, CD4+, and CD8+ T-cells mainly used the perforin-granzyme- based pathway and to a somewhat lesser extent the FasL pathway to lyse tumor cells. When Jurkat T-cells were stimulated with the diabody alone, the TCR-CD3 was not triggered. In contrast, when the diabody was clustered with a secondary antibody the TCR-CD3 was stimulated as detected by Ca(2+)-influx and Erk, IkappaB, and linker of activated T-cell phosphorylation. Clustering of the diabody could also be achieved by the dimeric PSMA antigen expressed on tumor cells. Thus, although the diabody binds to all T-cells, only those in contact with PSMA-expressing cancer cells are activated. In conclusion, the PSMA x CD3 diabody is suitable for a controlled polyclonal T-cell therapy of prostate cancer.

Segregation models.

Many antigen receptors of the immune system belong to the family of multichain immune recognition receptors (MIRRs). Binding of ligand (antigen) to MIRR results in receptor phosphorylation, triggering downstream signaling pathways and cellular activation. How ligand binding induces this phosphorylation is not yet understood. In this Chapter, we discuss two models exploring the possibility that kinases and phosphatases are intermingled on the cell surface. Thus, in resting state, MIRR phosphorylation is counteracted by dephosphorylation. Upon ligand binding, phosphatases are removed from the vicinity of the MIRR and kinases, such that phosphorylated MIRRs can accumulate (segregation models). In the first model, clustering of MIRRs by multivalent ligand leads to their concentration in lipid rafts where kinases, but not phosphatases, are localized. The second model takes into account that the MIRR-ligandpair needs dose apposition of the two cell membranes, in cases where ligand is presented by an antigen-presenting cell. The intermembrane distance is too small to accommodate transmembrane phosphatases, which possess large ectodomains. Thus, phosphatases become spatially separated from the MIRRs and kinases (kinetic-segregation model).

Enhanced B-cell activation mediated by TLR4 and BCR crosstalk.

Despite the important role of B lymphocytes as a bridge between the innate and the adaptive immune system, little is known regarding lipopolysaccharide (LPS) recognition, activation of signalling networks or conceivable cooperation between LPS and the B-cell antigen receptor (BCR). Here, we show that primary B cells can efficiently discriminate between different LPS chemotypes, responding with at least 100-fold higher sensitivity to rough-form LPS compared with smooth-form LPS. Using genetically modified mice, we demonstrate that B lymphocytes recognize all LPS chemotypes via Toll-like receptor 4 (TLR4). In addition, we dissect the signalling pathways that lead to CD69 upregulation upon TLR4 and BCR activation in primary B cells. Our data suggest that TLR4 and BCR induce CD69 transcription via two distinct sets of signalling molecules, exerting quantitative and qualitative differences in B-cell activation. Finally, we show that simultaneous stimulation of TLR4 and BCR additively elevates B-cell activation. In contrast, co-engagement of TLR4 and BCR by antigen-coupled LPS synergistically enhances activation of B cells, pointing out attractive targets for signalling crosstalk in B lymphocytes.

The extracellular part of zeta is buried in the T cell antigen receptor complex.

The zeta chain is a key component of the T cell antigen receptor (TCR-CD3) complex, required for the expression of the receptor on the cell surface. It contains an extremely small extracellular (EC) part of nine amino acids. Interestingly, the length, but not the sequence, of the zeta EC has been highly conserved through evolution. Here, we examined the effect of increasing the length of human zeta EC on TCR-CD3 assembly and surface expression. Appending a 30 kDa polypeptide to the N-terminus of zeta completely abolished assembly and transport of the TCR-CD3 to the cell surface. Addition of only 17 amino acids, including the HA-tag (HAzeta), strongly reduced the efficiency of TCR-CD3 assembly and led to reduced expression on the surface, suggesting that the short zeta EC region is located within the receptor complex. In Blue Native gels (BN-PAGE) these receptors had a normal size, indicating that they have a stoichiometry of alphabetagammaepsilondeltaepsilonzetazeta. In resting TCR-CD3s the HA-tag, and thus the zeta EC region, was not accessible for anti-HA antibody binding, demonstrating that it was indeed buried in a cavity within the receptor complex. However, prolonged stimulation with antigen permitted the access of the anti-HA antibody, thus suggesting that stimulation led to architectural changes in the TCR-CD3.

High-sensitivity detection and quantitative analysis of native protein-protein interactions and multiprotein complexes by flow cytometry.

Most mechanisms of cell development, physiology, and signal transduction are controlled by protein-protein interactions. Immunoprecipitation of multiprotein complexes detected by flow cytometry (IP-FCM) is a means to quantitatively measure these interactions. The high sensitivity of this method makes it useful even when very little biomaterial is available for analysis, as in the case of rare primary cell subsets or patient samples. Detection of the T cell antigen receptor associated with the CD3 multiprotein complex from as few as 300 primary murine T cells is presented as an example. The method is compatible with quantitative flow cytometry techniques, making it possible to estimate the number of coimmunoprecipitated molecules. Both constitutive and inducible protein-protein interactions can be analyzed, as illustrated in related methodology using glutathione S-transferase-fusion protein pull-down experiments. IP-FCM represents a robust, quantitative, biochemical technique to assess native protein-protein interactions, without requiring genetic engineering or large sample sizes.