CXCR3-mediated T-cell chemotaxis involves ZAP-70 and is regulated by signalling through the T-cell receptor

The chemokine receptor CXCR3 is critical for the function of activated T cells. We studied the molecular mechanisms of CXCR3 signalling. The addition of CXCR3 ligands to normal human T cells expressing CXCR3 led to the tyrosine phosphorylation of multiple proteins. Addition of the same ligands to Jurkat T cells engineered to express CXCR3 induced tyrosine phosphorylation of proteins with molecular weights similar to those in normal cells. Immunoblotting with phosphotyrosine-specific antibodies identified Zeta-associated protein of 70,000 molecular weight (ZAP-70), linker for the activation of T cells (LAT), and phospholipase-C-gamma1 (PLCgamma1) to be among the proteins that become phosphorylated upon CXCR3 activation. ZAP-70 was phosphorylated on tyrosine 319, LAT on tyrosines 171 and 191, and PLCgamma1 on tyrosine 783. The ZAP-70 inhibitor piceatannol reduced CXCR3-mediated tyrosine phosphorylation of ZAP-70, LAT, PLCgamma1 and mitogen-activated protein kinase Erk and it reduced CXCL10-mediated chemotaxis of both CXCR3-transfected Jurkat T cells and normal T cells expressing CXCR3. These results are consistent with the involvement of ZAP-70 in CXCR3-mediated protein tyrosine phosphorylation and CXCR3-induced T-cell chemotaxis. Studies with the Lck-deficient Jurkat T-cell line, JCAM1.6, demonstrated that phosphorylation of ZAP-70 after CXCR3 activation is a Lck-dependent process. Finally, stimulating CXCR3-expressing Jurkat T cells and normal T cells expressing CXCR3 through the T-cell receptor attenuated CXCR3-induced tyrosine phosphorylation and CXCR3-mediated T-cell migration, indicating the occurrence of cross-talk between T-cell receptor and CXCR3-signalling pathways. These results shed light on the mechanisms of CXCR3 signalling. Such information could be useful when designing therapeutic strategies to regulate T-cell function.     

T-cell receptor signaling to integrins

Summary:  Integrin adhesion receptors are critical for antigen recognition by T cells and for regulated recirculation and trafficking into and through various tissues in the body. T-cell receptor (TCR) signaling induces rapid increases in integrin function that facilitate T-cell activation by promoting stable contact with antigen-presenting cells and extracellular proteins in the environment. In this review, we outline the molecular mechanisms by which the TCR signals to integrins and present a model that highlights four key events: (i) initiation of proximal TCR signals nucleated by the linker for activated T cells (LAT) adapter protein and involving Itk, phospholipase C-γ1, Vav1, and Src homology 2 domain-containing leukocyte-specific phosphoprotein of 76 kDa; (ii) transmission of integrin activation signals from the LAT signalosome to integrins by protein kinase (PK) C and the adapter protein, adhesion and degranulation-promoting adapter protein; (iii) assembly of integrin-associated signaling complexes that include PKD, the guanosine triphosphatase Rap1 and its effectors, and talin; and (iv) reorganization of the actin cytoskeleton by WAVE2 and other actin-remodeling proteins. These events coordinate changes in integrin conformation and clustering that result in enhanced integrin functional activity following TCR stimulation.     

Regulation of T-cell receptor signalling by membrane microdomains

There is now considerable evidence suggesting that the plasma membrane of mammalian cells is compartmentalized by functional lipid raft microdomains. These structures are assemblies of specialized lipids and proteins and have been implicated in diverse biological functions. Analysis of their protein content using proteomics and other methods revealed enrichment of signalling proteins, suggesting a role for these domains in intracellular signalling. In T lymphocytes, structure/function experiments and complementary pharmacological studies have shown that raft microdomains control the localization and function of proteins which are components of signalling pathways regulated by the T-cell antigen receptor (TCR). Based on these studies, a model for TCR phosphorylation in lipid rafts is presented. However, despite substantial progress in the field, critical questions remain. For example, it is unclear if membrane rafts represent a homogeneous population and if their structure is modified upon TCR stimulation. In the future, proteomics and the parallel development of complementary analytical methods will undoubtedly contribute in further delineating the role of lipid rafts in signal transduction mechanisms.     

The power and the promise of restimulation-induced cell death in human immune diseases

Summary: Controlled expansion and contraction of lymphocytes both during and after an adaptive immune response are imperative to sustain a healthy immune system. Both extrinsic and intrinsic pathways of lymphocyte apoptosis are programmed to eliminate cells at the proper time to ensure immune homeostasis. Genetic disorders of apoptosis described in mice and humans have established Fas and Bim as critical pro-apoptotic molecules responsible for T-cell death in response to T-cell receptor restimulation and cytokine withdrawal, respectively. Emerging evidence prompts revision of this classic paradigm, especially for our understanding of restimulation-induced cell death (RICD) and its physiological purpose. Recent work indicates that RICD employs both Fas and Bim for T-cell deletion, dispelling the notion that these molecules are assigned to mutually exclusive apoptotic pathways. Furthermore, new mouse model data combined with our discovery of defective RICD in X-linked lymphoproliferative disease (XLP) patient T cells suggest that RICD is essential for precluding excess T-cell accumulation and associated immunopathology during the course of certain infections. Here, we review how these advances offer a refreshing new perspective on the phenomenon of T-cell apoptosis induced through antigen restimulation, including its relevance to immune homeostasis and potential for therapeutic interventions.     

Diversity-oriented approaches for interrogating T-cell receptor repertoire,ligand recognition,and function

Molecular diversity lies at the heart of adaptive immunity. T-cell receptors and peptide-major histocompatibility complex molecules utilize and rely upon an enormous degree of diversity at the levels of genetics, chemistry, and structure to engage one another and carry out their functions. This high level of diversity complicates the systematic study of important aspects of T-cell biology, but recent technical advances have allowed for the ability to study diversity in a comprehensive manner. In this review, we assess insights gained into T-cell receptor function and biology from our increasingly precise ability to assess the T-cell repertoire as a whole or to perturb individual receptors with engineered reagents. We conclude with a perspective on a new class of high-affinity, non-stimulatory peptide ligands we have recently discovered using diversity-oriented techniques that challenges notions for how we think about T-cell receptor signaling.     

T-cell antigen receptor peptides inhibit signal transduction within the membrane bilayer

Previous studies have shown that a synthetic peptide (core peptide, CP) corresponding to a 9-amino-acid region in the transmembrane domain of the alpha subunit of the T-cell antigen receptor (TCR) can suppress T-cell function in vitro and in vivo. The aim of these experiments was to determine the cellular site and molecular mechanism of CP inhibition in T cells. The cytochrome c-sensitive TCR-expressing hybridoma (2B4) was stimulated with pigeon cytochrome c antigen, anti-CD3 crosslinking, or PMA and ionomycin, in the presence or absence of CP, and the resulting IL-2 produced was measured in a bioassay using an IL-2-dependent cell line (CTLL-2). In the presence of CP, IL-2 production was inhibited following antigen-induced stimulation. By contrast, when stimulated with cross-linking antibodies to the CD3 complex or with PMA and ionomycin, both of which activate T cells downstream of the TCR antigen recognition site, CP had no effect on IL-2 production. These experiments suggest that CP interferes with TCR function by inhibiting T-cell activation at the transmembrane/receptor level. In addition, we show that CP inhibits early TCR signal transduction events such as TCR zeta chain phosphorylation following stimulation with either antigen or anti-CD3-crosslinking antibodies, although this is unlikely to be the mechanism leading to the reduced IL-2 production.     

A new effect of IL-4 on human γδ T cells: promoting regulatory Vδ1 T cells via IL-10 production and inhibiting function of Vδ2 T cells

Interleukin 4 (IL-4) has a variety of immune functions, including helper T-cell (Th-cell) differentiation and innate immune-response processes. However, the impact of IL-4 on gamma delta (γδ) T cells remains unclear. In this study, we investigate the effects of IL-4 on the activation and proliferation of γδ T cells and the balance between variable delta 1 (Vδ1) and Vδ2 T cells in humans. The results show that IL-4 inhibits the activation of γδ T cells in the presence of γδ T-cell receptor (TCR) stimulation in a STAT6-dependent manner. IL-4 promoted the growth of activated γδ T cells and increased the levels of Vδ1 T cells, which in turn inhibited Vδ2 T-cell growth via significant IL-10 secretion. Vδ1 T cells secreted significantly less interferon gamma (IFNγ) and more IL-10 relative to Vδ2. Furthermore, Vδ1 T cells showed relatively low levels of Natural Killer Group 2D (NKG2D) expression in the presence of IL-4, suggesting that Vδ1 T cells weaken the γδ T cell-mediated anti-tumor immune response. For the first time, our findings demonstrate a negative regulatory role of IL-4 in γδ T cell-mediated anti-tumor immunity.     

Signal initiation in T-cell receptor microclusters

Summary: Although dynamic imaging technologies have provided important insights into the underlying processes responsible for T-cell activation, the processes that link antigen recognition to downstream signaling remain poorly defined. Converging lines of inquiry indicate that T-cell receptor (TCR) microclusters are the minimal structures capable of directing effective TCR signaling. Furthermore, imaging studies have determined that these structures trigger the assembly of oligomeric signaling scaffolds that contain the adapters and effectors required for T-cell activation. Existing models of T-cell activation accurately explain the sensitivity and selectivity of antigen recognition. However, these models do not account for important properties of microclusters, including their peripheral formation, size, and movement on the actin cytoskeleton. Here we examine how lipid rafts, galectin lattices, and protein scaffolds contribute to the assembly, function, and fate of TCR microclusters within immune synapses. Finally, we propose a 'mechanical segregation' model of signal initiation in which cytoskeletal forces contribute to the lateral segregation of molecules and cytoskeletal scaffolds provide a template for microcluster assembly.     

Organization of the resting TCR in nanoscale oligomers

Nucleotide oligomerization and binding domain (NOD)-like receptors (NLRs) are a major constituent of the cytosolic innate immune-sensing machinery and participate in a wide array of pathways including nuclear factor κB (NF-κB), mitogen-activated protein kinase (MAPK), inflammasome, and type I interferon (IFN) signaling. NLRs have known roles in autoimmune, autoinflammatory, and infectious diseases. With respect to virus infection, NLRP3 is the most extensively studied NLR, including mechanisms of activation and inhibition. Furthermore, the importance of NLRP3 in both innate and adaptive immunity has been demonstrated. In comparison to NLRP3, the roles of other NLRs during virus infection are only just emerging. NLRC2 is an important activator of innate antiviral signaling and was recently found to mitigate inflammation during virus infection through autophagy. Finally, functions for NLRX1 in immune modulation and reactive oxygen species production require further examination and the importance of NLRC5 as a transactivator of major histocompatibility complex (MHC) class I and antigen presentation is currently developing. In this review, we discuss current knowledge pertaining to viruses and NLRs as well as areas of potential research, which will help advance the study of NLR biology during virus infection.     

The immunological synapse controls local and global calcium signals in T lymphocytes

Summary:  Cell polarization is a key feature of T-cell function. The immunological synapse (IS) between T cells and antigen-presenting cells is a beautiful example of how polarization of cells is used to guide cell function. Receptors, signal transducers, the cytoskeleton, and organelles are enriched at or depleted from the IS after its formation, and in many cases these re-localizations have already been linked with certain T-cell functions. One key step for T-cell activation is a rise in the cytoplasmic calcium concentration. Whereas it is undisputed that the IS initiates and controls calcium signals in T cells, very little is known about the role of T-cell polarization for calcium signals and calcium-dependent signal transduction. We briefly summarize the basic commonly agreed principles of IS-dependent calcium signal generation but then focus on the less well understood influence of polarization on calcium signals. The discussion of the role of polarization for calcium signals leads to a model how the IS controls local and global calcium signals and calcium-dependent T-cell functions. We develop a theoretical formalism based on existing spatiotemporal calcium dynamic simulations to better understand the model in the future and allow further predictions which can be tested by fast, high resolution live-cell microscopy.     

Differential T‐cell receptor signals for T helper cell programming

Upon encounter with their cognate antigen, naive CD4 T cells become activated and are induced to differentiate into several possible T helper (Th) cell subsets. This differentiation depends on a number of factors including antigen‐presenting cells, cytokines and co‐stimulatory molecules. The strength of the T‐cell receptor (TCR) signal, related to the affinity of TCR for antigen and antigen dose, has emerged as a dominant factor in determining Th cell fate. Recent studies have revealed that TCR signals of high or low strength do not simply induce quantitatively different signals in the T cells, but rather qualitatively distinct pathways can be induced based on TCR signal strength. This review examines the recent literature in this area and highlights important new developments in our understanding of Th cell differentiation and TCR signal strength.     

Signaling function of reconstituted CD16: zeta: gamma receptor complex isoforms.

Natural killer cells express an Fc receptor for IgG (CD16) in association with disulfide-linked dimers composed of two homologous subunits: the zeta chain of the T cell antigen receptor complex and the gamma chain of the mast cell/basophil Fc receptor for IgE. The ability of zeta and gamma to transduce CD16-mediated activation signals was compared by reconstituting distinct CD16 receptor isoforms composed of various combinations of zeta- and gamma-containing dimers. Stably transformed non-hematopoietic and hematopoietic cell lines were established that expressed chimeric molecules comprising the extracellular domain of CD16 joined to the transmembrane and intracellular domains of zeta or gamma. Reconstituted CD16 receptor complexes triggered Ca2+ influx, tyrosine phosphorylation, and IL-2 production in stable transformants of the Jurkat T cell line. However, cross-linking of the CD16/gamma chimera induced a specific pattern of tyrosine phosphorylation and was more efficient at signal transduction than a CD16, zeta-zeta complex, suggesting that zeta and gamma cytoplasmic domains may be coupled to distinct tyrosine kinase pathways that differentially regulate CD16-mediated activation signals. By contrast, both CD16/zeta and CD16/gamma chimeric molecules were not functional in stable transformants of the fibroblast Chinese Hamster Ovary cell line, indicating a requirement for downstream signaling components present in hematopoietic cells. Finally, the zeta transmembrane domain appears to preferentially associate with CD16 rather than the CD3:TCR complex, suggesting that a hierarchy of molecular interactions governs NK and T cell differentiation.     

Regulation of T-cell survival and mitochondrial homeostasis by TSC1

The mammalian target of rapamycin (mTOR) is a key regulator of cell growth and metabolism. It associates with multiple proteins and forms two distinct signaling complexes, mTORC1 and mTORC2. Accumulating evidence has revealed critical roles for intact mTOR signaling during T-cell activation and responses to microbial infection. However, the importance of mTOR regulation in T cells has yet to be explored. The TSC1/TSC2 complex has been shown to inhibit mTORC1 signaling in cell line models. We show here that deletion of TSC1 in the murine T-cell lineage results in a dramatic reduction of the peripheral T-cell pool, correlating with increased cell death. While mTORC1 is constitutively activated, mTORC2 signaling, reflected by Akt phosphorylation and activity, is decreased in TSC1-deficient T cells. Furthermore, TSC1-deficient T cells contain elevated reactive oxygen species (ROS) and exhibit decreased mitochondrial content and membrane potential, which is correlated with the activation of the intrinsic death pathway. Overall, our results demonstrate that TSC1 differentially regulates mTORC1 and mTORC2 activity, promotes T-cell survival, and is critical for normal mitochondrial homeostasis in T cells.     

A sequence conserved between CD5 and CD6 binds an FERM domain and exerts a restraint on T-cell activation

CD5 and CD6 are related surface receptors that limit and promote T-cell responses. Co-stimulatory effects of CD6 depend on binding a cell surface ligand, CD166, and recruitment of the intracellular adaptor proteins GADS and SLP-76 by C-terminal phosphotyrosines. We have continued to identify interactions of CD5 and CD6 to understand their roles in T-cell activation. In a screen to identify binding partners for peptides containing a cytoplasmic sequence, SDSDY conserved between CD5 and CD6, we identified ezrin radixin moesin (ERM) proteins, which link plasma membrane proteins to actin. Purified radixin FERM domain bound directly to CD5 and CD6 SDSDY peptides in a phosphorylation-dependent manner (K_D = 0·5-2 μm ) at 37°. In human T-cell blasts, mutation of the CD6 SDSDY sequence enhanced CD69 expression in response to CD3 monoclonal antibody. In this proximal readout, interactions of the SDSDY sequence were dominant compared with the C-terminal tyrosines of CD6. In contrast, in a more downstream readout, interleukin-2 expression, in response to immobilized CD3 and CD6 monoclonal antibodies, the C-terminal tyrosines were dominant. The data suggest that varying functional effects of CD6 and potentially CD5 depend on interactions of different cytoplasmic regions with the cytoskeleton and alter depending on the stimuli.     

Qualitatively differential regulation of T cell activation and apoptosis by T cell receptor zeta chain ITAMs and their tyrosine residues

The issue of whether three ITAMs in the TCR zeta chain can transmit qualitatively distinct signals or redundantly amplify TCR-mediated activation signals was extensively investigated using stable hCD8-zeta Jurkat transfectants which contain stepwise deletions of each ITAM or mutations of tyrosine residues in each ITAM of TCR zeta chain. The influence of mutations of each tyrosine residue on reduction of the amount and species of tyrosine phosphorylated proteins recruited to zeta chain was quite distinctive, but they were roughly proportional to the number of functionally intact ITAMs. However, the first N-terminal ITAM had a signaling potential to trigger most intracellular signaling events for T cell activation and apoptosis similar to wild-type CD8-zeta, but this level was substantially reduced in the presence of the first and second N-terminal ITAM together. Mutations of tyrosine residues in first and second N-terminal ITAM significantly impaired most signaling events leading to T cell activation and activation-induced cell death, but phosphorylation of mitogen-activated protein kinases (MAPKs) was differentially impaired in each mutant. The mutation of the first tyrosine residue in C-terminal ITAM did not show any impairment in induction of surface antigens and cell death, but rather increased IL-2 secretion and MAPK phosphorylation. Therefore, in this study we demonstrated that the ITAMs and their tyrosine residues of TCR zeta chain can transmit qualitatively differential intracellular signals upon TCR stimulation through distinctive regulation of recruitment of tyrosine phosphorylated proteins to zeta chain and activation of various MAPKs.     

No-shows in T-cell responses are frequent for clones of low T-cell receptor affinity

The magnitude of CD8 T-cell responses against intracellular pathogens is thought to primarily depend on the expansion capacity of naïve T cells, given that their recruitment is considered optimal. In the current issue of the European Journal of Immunology [Eur. J. Immunol. 2023. 53: 000-000], Leube et al. challenge these concepts and show that the recruitment of naïve T-cell clones into primary responses can be far from complete. The failure to efficiently recruit T-cell clones occurs more frequently in case of low-affinity interactions of the T-cell receptor with cognate antigen of the pathogen. Using single-cell fate-mapping in the Lm-OVA model, the authors demonstrate that naïve T-cell clones of low affinity in contrast to those of high affinity often do not expand after pathogen encounter. These low-affinity clones are maintained as naïve CD8 T cells that can robustly respond upon secondary encounter with the same pathogen, in particular when the reencountered pathogen contains modifications resulting in improved recognition. Thus, this study indicates that the regulation of the response size of CD8 T cells is yet more elaborate than anticipated and involves control at the level of recruitment and expansion of naïve CD8 T cells.     

The half-life of the T-cell receptor/peptide-major histocompatibility complex interaction can modulate T-cell activation in response to bacterial challenge

T-cell activation results from engagement of the T-cell receptor (TCR) by cognate peptide-major histocompatibility complex (pMHC) complexes on the surface of antigen-presenting cells (APC). Previous studies have provided evidence supporting the notion that the half-life of the TCR/pMHC interaction and the density of pMHC on the APC are two parameters that can influence T-cell activation. However, whether the half-life of the TCR/pMHC interaction can modulate T-cell activation in response to a pathogen challenge remains unknown. To approach this question, we generated strains of bacteria expressing variants of the ovalbumin (OVA) antigen, carrying point mutations in the SIINFEKL sequence. When bound to H-2K(b), this peptide is the cognate ligand for the OT-I TCR. Variants of the H-2K(b)/SIINFEKL bind to the OT-I TCR with distinct half-lives. Here we show that dendritic cells (DCs) infected with bacteria expressing OVA variants were incapable of activating OT-I T cells when the half-life of the TCR/H-2K(b)/OVA interaction was excessively short. Consistent with these data, T-cell activation was only observed in mice infected with bacteria expressing OVA variants that bound to OT-I with a half-life above a certain threshold. Considered together, our data suggest that the half-life of TCR/pMHC interaction can significantly modulate T-cell activation in vivo, as well as influence recognition of antigens expressed by bacteria. These observations underscore the importance of the TCR/pMHC half-life on the clearance of pathogens.     

The Tec kinases Itk and Rlk regulate conventional versus innate T-cell development

Summary:  Tec family kinases are important components of antigen receptor signaling pathways in B cells, T cells, and mast cells. In T cells, three members of this family, inducible T-cell kinase (Itk), resting lymphocyte kinase (Rlk), and Tec, are expressed. In the absence of Itk and Rlk, T-cell receptor signaling is impaired, with defects in mitogen-activated protein kinase activation, Ca²⁺ mobilization, and actin polymerization. During T-cell development in the thymus, no role has been found for these kinases in the CD4⁺ versus CD8⁺ T-cell lineage decision; however, several studies indicate that Itk and Rlk contribute to the signaling leading to positive and negative selection. In addition, we and others have recently described an important role for Itk and Rlk in the development of conventional as opposed to innate CD4⁺ and CD8⁺ T cells. Natural killer T and γδ T-cell populations are also altered in Itk- and Rlk/Itk-deficient mice. These findings strongly suggest that the strength of T-cell receptor signaling during development determines whether T cells mature into conventional versus innate lymphocyte lineages. This lineage decision is also influenced by signaling via signaling lymphocytic activation molecule (SLAM) family receptors. Here we discuss these two signaling pathways that each contribute to conventional versus innate T-cell lineage commitment.     

Expression and agonist responsiveness of CXCR3 variants in human T lymphocytes

The chemokine receptor CXCR3 and its ligands CXCL9, CXCL10 and CXCL11 are involved in variety of inflammatory disorders including multiple sclerosis, rheumatoid arthritis, psoriasis and sarcoidosis. Two alternatively spliced variants of the human CXCR3-A receptor have been described, termed CXCR3-B and CXCR3-alt. Human CXCR3-B binds CXCL9, CXCL10, CXCL11 as well as an additional ligand CXCL4. In contrast, CXCR3-alt only binds CXCL11. We report that CXCL4 induces intracellular calcium mobilization as well as Akt and p44/p42 extracellular signal-regulated kinase phosphorylation, in activated human T lymphocytes. These responses have similar concentration dependence and time-courses to those induced by established CXCR3 agonists. Moreover, phosphorylation of Akt and p44/p42 is inhibited by pertussis toxin, suggesting coupling to Gα(i) protein. Surprisingly, and in contrast with the other CXCR3 agonists, stimulation of T lymphocytes with CXCL4 failed to elicit migratory responses and did not lead to loss of surface CXCR3 expression. Taken together, our findings show that, although CXCL4 is coupled to downstream biochemical machinery, its role in T cells is probably distinct from that of CXCR3-A agonists.