Abstract
The initiation of T cell antigen receptor signaling is a key step that can result in T cell activation and the orchestration of an adaptive immune response. Early events in T cell receptor signaling can distinguish between agonist and endogenous ligands with exquisite selectivity, and show extraordinary sensitivity to minute numbers of agonists in a sea of endogenous ligands. We review our current knowledge of models and crucial molecules that aim to provide a mechanistic explanation for these observations. Building on current understanding and a discussion of unresolved issues, we propose a molecular model for initiation of T cell receptor signaling that may serve as a useful guide for future studies.
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References
Huang, J. et al. A single peptide-major histocompatibility complex ligand triggers digital cytokine secretion in CD4(+) T cells. Immunity 39, 846–857 (2013).
Purbhoo, M.A., Irvine, D.J., Huppa, J.B. & Davis, M.M. T cell killing does not require the formation of a stable mature immunological synapse. Nat. Immunol. 5, 524–530 (2004).
Sykulev, Y., Joo, M., Vturina, I., Tsomides, T.J. & Eisen, H.N. Evidence that a single peptide-MHC complex on a target cell can elicit a cytolytic T cell response. Immunity 4, 565–571 (1996).
Irvine, D.J., Purbhoo, M.A., Krogsgaard, M. & Davis, M.M. Direct observation of ligand recognition by T cells. Nature 419, 845–849 (2002).
Daniels, M.A. et al. Thymic selection threshold defined by compartmentalization of Ras/MAPK signalling. Nature 444, 724–729 (2006).
Gascoigne, N.R. & Palmer, E. Signaling in thymic selection. Curr. Opin. Immunol. 23, 207–212 (2011).
Starr, T.K., Jameson, S.C. & Hogquist, K.A. Positive and negative selection of T cells. Annu. Rev. Immunol. 21, 139–176 (2003).
Hopfield, J.J. Kinetic proofreading: a new mechanism for reducing errors in biosynthetic processes requiring high specificity. Proc. Natl. Acad. Sci. USA 71, 4135–4139 (1974).
McKeithan, T.W. Kinetic proofreading in T-cell receptor signal transduction. Proc. Natl. Acad. Sci. USA 92, 5042–5046 (1995).
Lalanne, J.B. & Francois, P. Principles of adaptive sorting revealed by in silico evolution. Phys. Rev. Lett. 110, 218102 (2013).
Iwashima, M., Irving, B.A., van Oers, N.S., Chan, A.C. & Weiss, A. Sequential interactions of the TCR with two distinct cytoplasmic tyrosine kinases. Science 263, 1136–1139 (1994).
Samelson, L.E., Davidson, W.F., Morse, H.C. III & Klausner, R.D. Abnormal tyrosine phosphorylation on T-cell receptor in lymphoproliferative disorders. Nature 324, 674–676 (1986).
Straus, D.B. & Weiss, A. Genetic evidence for the involvement of the lck tyrosine kinase in signal transduction through the T cell antigen receptor. Cell 70, 585–593 (1992).
van Oers, N.S., Killeen, N. & Weiss, A. Lck regulates the tyrosine phosphorylation of the T cell receptor subunits and ZAP-70 in murine thymocytes. J. Exp. Med. 183, 1053–1062 (1996).
Xu, C. et al. Regulation of T cell receptor activation by dynamic membrane binding of the CD3ɛ cytoplasmic tyrosine-based motif. Cell 135, 702–713 (2008).
Fernandes, R.A. et al. What controls T cell receptor phosphorylation? Cell 142, 668–669 (2010).
Shi, X. et al. Ca2+ regulates T-cell receptor activation by modulating the charge property of lipids. Nature 493, 111–115 (2013).
Li, F.Y. et al. Second messenger role for Mg2+ revealed by human T-cell immunodeficiency. Nature 475, 471–476 (2011).
van Oers, N.S., Killeen, N. & Weiss, A. ZAP-70 is constitutively associated with tyrosine-phosphorylated TCRζ in murine thymocytes and lymph node T cells. Immunity 1, 675–685 (1994).
van Oers, N.S. et al. Constitutive tyrosine phosphorylation of the T-cell receptor (TCR) ζ subunit: regulation of TCR-associated protein tyrosine kinase activity by TCRζ. Mol. Cell. Biol. 13, 5771–5780 (1993).
Dorfman, J.R., Stefanova, I., Yasutomo, K. & Germain, R.N. CD4+ T cell survival is not directly linked to self-MHC-induced TCR signaling. Nat. Immunol. 1, 329–335 (2000).
Kim, S.T. et al. The αβ T cell receptor is an anisotropic mechanosensor. J. Biol. Chem. 284, 31028–31037 (2009).
Kim, S.T. et al. Distinctive CD3 heterodimeric ectodomain topologies maximize antigen-triggered activation of αβ T cell receptors. J. Immunol. 185, 2951–2959 (2010).
Yoon, S.T., Dianzani, U., Bottomly, K. & Janeway, C.A. Jr. Both high and low avidity antibodies to the T cell receptor can have agonist or antagonist activity. Immunity 1, 563–569 (1994).
Lanier, L.L., Ruitenberg, J.J., Allison, J.P. & Weiss, A. Distinct epitopes on the T cell antigen receptor of HPB-ALL tumor cells identified by monoclonal antibodies. J. Immunol. 137, 2286–2292 (1986).
Adams, J.J. et al. T cell receptor signaling is limited by docking geometry to peptide-major histocompatibility complex. Immunity 35, 681–693 (2011).
Kim, S.T. et al. TCR mechanobiology: torques and tunable structures linked to early T cell signaling. Front. Immunol. 3, 76 (2012).
Huppa, J.B. et al. TCR-peptide-MHC interactions in situ show accelerated kinetics and increased affinity. Nature 463, 963–967 (2010).
Huang, J. et al. The kinetics of two-dimensional TCR and pMHC interactions determine T-cell responsiveness. Nature 464, 932–936 (2010).
Liu, B., Chen, W., Evavold, B.D. & Zhu, C. Accumulation of dynamic catch bonds between TCR and agonist peptide-MHC triggers T cell signaling. Cell 157, 357–368 (2014).
O'Donoghue, G.P., Pielak, R.M., Smoligovets, A.A., Lin, J.J. & Groves, J.T. Direct single molecule measurement of TCR triggering by agonist pMHC in living primary T cells. eLife 2, e00778 (2013).
Govern, C.C., Paczosa, M.K., Chakraborty, A.K. & Huseby, E.S. Fast on-rates allow short dwell time ligands to activate T cells. Proc. Natl. Acad. Sci. USA 107, 8724–8729 (2010).
Aleksic, M. et al. Dependence of T cell antigen recognition on T cell receptor-peptide MHC confinement time. Immunity 32, 163–174 (2010).
Kjer-Nielsen, L. et al. A structural basis for the selection of dominant αβ T cell receptors in antiviral immunity. Immunity 18, 53–64 (2003).
Borroto, A. et al. Relevance of Nck-CD3 epsilon interaction for T cell activation in vivo. J. Immunol. 192, 2042–2053 (2014).
Gil, D., Schamel, W.W., Montoya, M., Sanchez-Madrid, F. & Alarcon, B. Recruitment of Nck by CD3 epsilon reveals a ligand-induced conformational change essential for T cell receptor signaling and synapse formation. Cell 109, 901–912 (2002).
Risueno, R.M., Schamel, W.W. & Alarcon, B. T cell receptor engagement triggers its CD3ɛ and CD3ζ subunits to adopt a compact, locked conformation. PLoS ONE 3, e1747 (2008).
Lettau, M., Pieper, J. & Janssen, O. Nck adapter proteins: functional versatility in T cells. Cell Commun. Signal. 7, 1 (2009).
Mingueneau, M. et al. The proline-rich sequence of CD3ɛ controls T cell antigen receptor expression on and signaling potency in preselection CD4+CD8+ thymocytes. Nat. Immunol. 9, 522–532 (2008).
Tailor, P. et al. The proline-rich sequence of CD3ɛ as an amplifier of low-avidity TCR signaling. J. Immunol. 181, 243–255 (2008).
Davis, S.J. & van der Merwe, P.A. The kinetic-segregation model: TCR triggering and beyond. Nat. Immunol. 7, 803–809 (2006).
Qi, S.Y., Groves, J.T. & Chakraborty, A.K. Synaptic pattern formation during cellular recognition. Proc. Natl. Acad. Sci. USA 98, 6548–6553 (2001).
James, J.R. & Vale, R.D. Biophysical mechanism of T-cell receptor triggering in a reconstituted system. Nature 487, 64–69 (2012).
Cordoba, S. et al. The large ectodomains of CD45 and CD148 regulate their segregation from and inhibition of ligated T-cell receptor. Blood 121, 4295–4302 (2013).
Irles, C. et al. CD45 ectodomain controls interaction with GEMs and Lck activity for optimal TCR signaling. Nat. Immunol. 4, 189–197 (2003).
Pingel, J.T. & Thomas, M.L. Evidence that the leukocyte-common antigen is required for antigen-induced T lymphocyte proliferation. Cell 58, 1055–1065 (1989).
Koretzky, G.A., Picus, J., Schultz, T. & Weiss, A. Tyrosine phosphatase CD45 is required for T-cell antigen receptor and CD2-mediated activation of a protein tyrosine kinase and interleukin 2 production. Proc. Natl. Acad. Sci. USA 88, 2037–2041 (1991).
Koretzky, G.A., Picus, J., Thomas, M.L. & Weiss, A. Tyrosine phosphatase CD45 is essential for coupling T-cell antigen receptor to the phosphatidylinositol pathway. Nature 346, 66–68 (1990).
Baker, J.E., Majeti, R., Tangye, S.G. & Weiss, A. Protein tyrosine phosphatase CD148-mediated inhibition of T-cell receptor signal transduction is associated with reduced LAT and phospholipase Cγ1 phosphorylation. Mol. Cell. Biol. 21, 2393–2403 (2001).
Lin, J. & Weiss, A. The tyrosine phosphatase CD148 is excluded from the immunologic synapse and down-regulates prolonged T cell signaling. J. Cell Biol. 162, 673–682 (2003).
Chow, L.M., Fournel, M., Davidson, D. & Veillette, A. Negative regulation of T-cell receptor signalling by tyrosine protein kinase p50csk. Nature 365, 156–160 (1993).
Veillette, A., Latour, S. & Davidson, D. Negative regulation of immunoreceptor signaling. Annu. Rev. Immunol. 20, 669–707 (2002).
McNeill, L. et al. The differential regulation of Lck kinase phosphorylation sites by CD45 is critical for T cell receptor signaling responses. Immunity 27, 425–437 (2007).
Mustelin, T., Coggeshall, K.M. & Altman, A. Rapid activation of the T-cell tyrosine protein kinase pp56lck by the CD45 phosphotyrosine phosphatase. Proc. Natl. Acad. Sci. USA 86, 6302–6306 (1989).
Ostergaard, H.L. et al. Expression of CD45 alters phosphorylation of the lck-encoded tyrosine protein kinase in murine lymphoma T-cell lines. Proc. Natl. Acad. Sci. USA 86, 8959–8963 (1989).
Pingel, S., Baker, M., Turner, M., Holmes, N. & Alexander, D.R. The CD45 tyrosine phosphatase regulates CD3-induced signal transduction and T cell development in recombinase-deficient mice: restoration of pre-TCR function by active p56(lck). Eur. J. Immunol. 29, 2376–2384 (1999).
Sieh, M., Bolen, J.B. & Weiss, A. CD45 specifically modulates binding of Lck to a phosphopeptide encompassing the negative regulatory tyrosine of Lck. EMBO J. 12, 315–321 (1993).
Zikherman, J. et al. CD45-Csk phosphatase-kinase titration uncouples basal and inducible T cell receptor signaling during thymic development. Immunity 32, 342–354 (2010).
Hermiston, M.L., Zikherman, J. & Zhu, J.W. CD45, CD148, and Lyp/Pep: critical phosphatases regulating Src family kinase signaling networks in immune cells. Immunol. Rev. 228, 288–311 (2009).
Zhu, J.W., Brdicka, T., Katsumoto, T.R., Lin, J. & Weiss, A. Structurally distinct phosphatases CD45 and CD148 both regulate B cell and macrophage immunoreceptor signaling. Immunity 28, 183–196 (2008).
Alexander, D.R. The CD45 tyrosine phosphatase: a positive and negative regulator of immune cell function. Semin. Immunol. 12, 349–359 (2000).
Baker, M. et al. Development of T-leukaemias in CD45 tyrosine phosphatase-deficient mutant lck mice. EMBO J. 19, 4644–4654 (2000).
Veillette, A., Rhee, I., Souza, C.M. & Davidson, D. PEST family phosphatases in immunity, autoimmunity, and autoinflammatory disorders. Immunol. Rev. 228, 312–324 (2009).
Zikherman, J., Doan, K., Parameswaran, R., Raschke, W. & Weiss, A. Quantitative differences in CD45 expression unmask functions for CD45 in B-cell development, tolerance, and survival. Proc. Natl. Acad. Sci. USA 109, E3–E12 (2012).
Zikherman, J., Parameswaran, R. & Weiss, A. Endogenous antigen tunes the responsiveness of naive B cells but not T cells. Nature 489, 160–164 (2012).
Cloutier, J.F. & Veillette, A. Cooperative inhibition of T-cell antigen receptor signaling by a complex between a kinase and a phosphatase. J. Exp. Med. 189, 111–121 (1999).
Schoenborn, J.R., Tan, Y.X., Zhang, C., Shokat, K.M. & Weiss, A. Feedback circuits monitor and adjust basal Lck-dependent events in T cell receptor signaling. Sci. Signal. 4, ra59 (2011).
Tan, Y.X. et al. Inhibition of the kinase Csk in thymocytes reveals a requirement for actin remodeling in the initiation of full TCR signaling. Nat. Immunol. 15, 186–194 (2014).
Davis, M.M. et al. T cells as a self-referential, sensory organ. Annu. Rev. Immunol. 25, 681–695 (2007).
Hoerter, J.A. et al. Coreceptor affinity for MHC defines peptide specificity requirements for TCR interaction with coagonist peptide-MHC. J. Exp. Med. 210, 1807–1821 (2013).
Krogsgaard, M. et al. Agonist/endogenous peptide-MHC heterodimers drive T cell activation and sensitivity. Nature 434, 238–243 (2005).
Li, Q.J. et al. CD4 enhances T cell sensitivity to antigen by coordinating Lck accumulation at the immunological synapse. Nat. Immunol. 5, 791–799 (2004).
Valitutti, S., Muller, S., Cella, M. & Lanzavecchia, A. Serial triggering of many T-cell receptors by a few peptide-MHC complexes. Nature 375, 148–151 (1995).
Coombs, D., Kalergis, A.M., Nathenson, S.G., Wofsy, C. & Goldstein, B. Activated TCRs remain marked for internalization after dissociation from pMHC. Nat. Immunol. 3, 926–931 (2002).
Holler, P.D. & Kranz, D.M. Quantitative analysis of the contribution of TCR/pepMHC affinity and CD8 to T cell activation. Immunity 18, 255–264 (2003).
Altan-Bonnet, G. & Germain, R.N. Modeling T cell antigen discrimination based on feedback control of digital ERK responses. PLoS Biol. 3, e356 (2005).
Das, J. et al. Digital signaling and hysteresis characterize ras activation in lymphoid cells. Cell 136, 337–351 (2009).
Xie, J. et al. Photocrosslinkable pMHC monomers stain T cells specifically and cause ligand-bound TCRs to be 'preferentially' transported to the cSMAC. Nat. Immunol. 13, 674–680 (2012).
Lo, W.L. et al. An endogenous peptide positively selects and augments the activation and survival of peripheral CD4+ T cells. Nat. Immunol. 10, 1155–1161 (2009).
Nakayama, T., Singer, A., Hsi, E.D. & Samelson, L.E. Intrathymic signalling in immature CD4+CD8+ thymocytes results in tyrosine phosphorylation of the T-cell receptor ζ-chain. Nature 341, 651–654 (1989).
Persaud, S.P., Parker, C.R., Lo, W.L., Weber, K.S. & Allen, P.M. Intrinsic CD4+ T cell sensitivity and response to a pathogen are set and sustained by avidity for thymic and peripheral complexes of self peptide and MHC. Nat. Immunol. 15, 266–274 (2014).
Honda, T. et al. Tuning of antigen sensitivity by T cell receptor-dependent negative feedback controls T cell effector function in inflamed tissues. Immunity 40, 235–247 (2014).
Krogsgaard, M., Juang, J. & Davis, M.M. A role for “self” in T-cell activation. Semin. Immunol. 19, 236–244 (2007).
Janeway, C.A. Jr., Travers, P., Walport, M. & Shlomchik, M. Immunobiology: The Immune System in Health and Disease 5th edn. (Garland Science, 2001).
Luescher, I.F. et al. CD8 modulation of T-cell antigen receptor-ligand interactions on living cytotoxic T lymphocytes. Nature 373, 353–356 (1995).
Wooldridge, L. et al. Interaction between the CD8 coreceptor and major histocompatibility complex class I stabilizes T cell receptor-antigen complexes at the cell surface. J. Biol. Chem. 280, 27491–27501 (2005).
Gao, G.F., Rao, Z. & Bell, J.I. Molecular coordination of αβ T-cell receptors and coreceptors CD8 and CD4 in their recognition of peptide-MHC ligands. Trends Immunol. 23, 408–413 (2002).
Artyomov, M.N., Lis, M., Devadas, S., Davis, M.M. & Chakraborty, A.K. CD4 and CD8 binding to MHC molecules primarily acts to enhance Lck delivery. Proc. Natl. Acad. Sci. USA 107, 16916–16921 (2010).
Varma, R., Campi, G., Yokosuka, T., Saito, T. & Dustin, M.L. T cell receptor-proximal signals are sustained in peripheral microclusters and terminated in the central supramolecular activation cluster. Immunity 25, 117–127 (2006).
Yokosuka, T. et al. Newly generated T cell receptor microclusters initiate and sustain T cell activation by recruitment of Zap70 and SLP-76. Nat. Immunol. 6, 1253–1262 (2005).
Veillette, A., Bookman, M.A., Horak, E.M., Samelson, L.E. & Bolen, J.B. Signal transduction through the CD4 receptor involves the activation of the internal membrane tyrosine-protein kinase p56lck. Nature 338, 257–259 (1989).
Nika, K. et al. Constitutively active Lck kinase in T cells drives antigen receptor signal transduction. Immunity 32, 766–777 (2010).
Stirnweiss, A. et al. T cell activation results in conformational changes in the Src family kinase Lck to induce its activation. Sci. Signal. 6, ra13 (2013).
Rossy, J., Owen, D.M., Williamson, D.J., Yang, Z. & Gaus, K. Conformational states of the kinase Lck regulate clustering in early T cell signaling. Nat. Immunol. 14, 82–89 (2013).
Mandl, J.N., Monteiro, J.P., Vrisekoop, N. & Germain, R.N. T cell-positive selection uses self-ligand binding strength to optimize repertoire recognition of foreign antigens. Immunity 38, 263–274 (2013).
Yan, Q. et al. Structural basis for activation of ZAP-70 by phosphorylation of the SH2-kinase linker. Mol. Cell. Biol. 33, 2188–2201 (2013).
Brdicka, T., Kadlecek, T.A., Roose, J.P., Pastuszak, A.W. & Weiss, A. Intramolecular regulatory switch in ZAP-70: analogy with receptor tyrosine kinases. Mol. Cell. Biol. 25, 4924–4933 (2005).
Pelosi, M. et al. Tyrosine 319 in the interdomain B of ZAP-70 is a binding site for the Src homology 2 domain of Lck. J. Biol. Chem. 274, 14229–14237 (1999).
Hsu, L.Y., Tan, Y.X., Xiao, Z., Malissen, M. & Weiss, A. A hypomorphic allele of ZAP-70 reveals a distinct thymic threshold for autoimmune disease versus autoimmune reactivity. J. Exp. Med. 206, 2527–2541 (2009).
Xu, H. & Littman, D.R. A kinase-independent function of Lck in potentiating antigen-specific T cell activation. Cell 74, 633–643 (1993).
Acknowledgements
We thank M. Fruschicheva for help with the references. We also thank K. Vicari of the Nature Publishing Group for her artistic work on the figures in this article. This work was supported, in part, by a grant from the US National Institutes of Health (PO1 AI091580 to A.K.C. and A.W.).
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Chakraborty, A., Weiss, A. Insights into the initiation of TCR signaling. Nat Immunol 15, 798–807 (2014). https://doi.org/10.1038/ni.2940
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