Perinatal thymic-derived CD8αß-expressing γδ T cells are innate IFN-γ producers that expand in IL-7R-STAT5B-driven neoplasms.

The contribution of γδ T cells to immune responses is associated with rapid secretion of interferon-γ (IFN-γ). Here, we show a perinatal thymic wave of innate IFN-γ-producing γδ T cells that express CD8αß heterodimers and expand in preclinical models of infection and cancer. Optimal CD8αß+ γδ T cell development is directed by low T cell receptor signaling and through provision of interleukin (IL)-4 and IL-7. This population is pathologically relevant as overactive, or constitutive, IL-7R-STAT5B signaling promotes a supraphysiological accumulation of CD8αß+ γδ T cells in the thymus and peripheral lymphoid organs in two mouse models of T cell neoplasia. Likewise, CD8αß+ γδ T cells define a distinct subset of human T cell acute lymphoblastic leukemia pediatric patients. This work characterizes the normal and malignant development of CD8αß+ γδ T cells that are enriched in early life and contribute to innate IFN-γ responses to infection and cancer.

Distinct metabolic programs established in the thymus control effector functions of γδ T cell subsets in tumor microenvironments.

Metabolic programming controls immune cell lineages and functions, but little is known about γδ T cell metabolism. Here, we found that γδ T cell subsets making either interferon-γ (IFN-γ) or interleukin (IL)-17 have intrinsically distinct metabolic requirements. Whereas IFN-γ+ γδ T cells were almost exclusively dependent on glycolysis, IL-17+ γδ T cells strongly engaged oxidative metabolism, with increased mitochondrial mass and activity. These distinct metabolic signatures were surprisingly imprinted early during thymic development and were stably maintained in the periphery and within tumors. Moreover, pro-tumoral IL-17+ γδ T cells selectively showed high lipid uptake and intracellular lipid storage and were expanded in obesity and in tumors of obese mice. Conversely, glucose supplementation enhanced the antitumor functions of IFN-γ+ γδ T cells and reduced tumor growth upon adoptive transfer. These findings have important implications for the differentiation of effector γδ T cells and their manipulation in cancer immunotherapy.

Noncanonical binding of Lck to CD3ε promotes TCR signaling and CAR function.

Initiation of T cell antigen receptor (TCR) signaling involves phosphorylation of CD3 cytoplasmic tails by the tyrosine kinase Lck. How Lck is recruited to the TCR to initiate signaling is not well known. We report a previously unknown binding motif in the CD3ε cytoplasmic tail that interacts in a noncanonical mode with the Lck SH3 domain: the receptor kinase (RK) motif. The RK motif is accessible only upon TCR ligation, demonstrating how ligand binding leads to Lck recruitment. Binding of the Lck SH3 domain to the exposed RK motif resulted in local augmentation of Lck activity, CD3 phosphorylation, T cell activation and thymocyte development. Introducing the RK motif into a well-characterized 41BB-based chimeric antigen receptor enhanced its antitumor function in vitro and in vivo. Our findings underscore how a better understanding of the functioning of the TCR might promote rational improvement of chimeric antigen receptor design for the treatment of cancer.

The BTG2-PRMT1 module limits pre-B cell expansion by regulating the CDK4-Cyclin-D3 complex.

Developing pre-B cells in the bone marrow alternate between proliferation and differentiation phases. We found that protein arginine methyl transferase 1 (PRMT1) and B cell translocation gene 2 (BTG2) are critical components of the pre-B cell differentiation program. The BTG2-PRMT1 module induced a cell-cycle arrest of pre-B cells that was accompanied by re-expression of Rag1 and Rag2 and the onset of immunoglobulin light chain gene rearrangements. We found that PRMT1 methylated cyclin-dependent kinase 4 (CDK4), thereby preventing the formation of a CDK4-Cyclin-D3 complex and cell cycle progression. Moreover, BTG2 in concert with PRMT1 efficiently blocked the proliferation of BCR-ABL1-transformed pre-B cells in vitro and in vivo. Our results identify a key molecular mechanism by which the BTG2-PRMT1 module regulates pre-B cell differentiation and inhibits pre-B cell leukemogenesis.

Caveolin-1-dependent nanoscale organization of the BCR regulates B cell tolerance.

Caveolin-1 (Cav1) regulates the nanoscale organization and compartmentalization of the plasma membrane. Here we found that Cav1 controlled the distribution of nanoclusters of isotype-specific B cell antigen receptors (BCRs) on the surface of B cells. In mature B cells stimulated with antigen, the immunoglobulin M BCR (IgM-BCR) gained access to lipid domains enriched for GM1 glycolipids, by a process that was dependent on the phosphorylation of Cav1 by the Src family of kinases. Antigen-induced reorganization of nanoclusters of IgM-BCRs and IgD-BCRs regulated BCR signaling in vivo. In immature Cav1-deficient B cells, altered nanoscale organization of IgM-BCRs resulted in a failure of receptor editing and a skewed repertoire of B cells expressing immunoglobulin-µ heavy chains with hallmarks of poly- and auto-reactivity, which ultimately led to autoimmunity in mice. Thus, Cav1 emerges as a cell-intrinsic regulator that prevents B cell-induced autoimmunity by means of its role in plasma-membrane organization.

Pro- and antitumorigenic functions of γδ T cells.

γδ T cells are a subset of T cells that are characterized by the expression of a TCR-γδ instead of a TCR-αß. Despite being outnumbered by their αß T cell counterpart in many tissues, studies from the last 20 years underline their important and non-redundant roles in tumor and metastasis development. However, whether a γδ T cell exerts pro- or antitumorigenic effects seems to depend on a variety of factors, many of them still incompletely understood today. In this review, we summarize mechanisms by which γδ T cells exert these seemingly contradictory effector functions in mice and humans. Furthermore, we discuss the current view on inducing and inhibiting factors of γδ T cells during cancer development.

From thymus to periphery: Molecular basis of effector γδ-T cell differentiation.

The contributions of γδ T cells to immune (patho)physiology in many pre-clinical mouse models have been associated with their rapid and abundant provision of two critical cytokines, interferon-γ (IFN-γ) and interleukin-17A (IL-17). These are typically produced by distinct effector γδ T cell subsets that can be segregated on the basis of surface expression levels of receptors such as CD27, CD44 or CD45RB, among others. Unlike conventional T cells that egress the thymus as naïve lymphocytes awaiting further differentiation upon activation, a large fraction of murine γδ T cells commits to either IFN-γ or IL-17 expression during thymic development. However, extrathymic signals can both regulate pre-programmed γδ T cells; and induce peripheral differentiation of naïve γδ T cells into effectors. Here we review the key cellular events of "developmental pre-programming" in the mouse thymus; and the molecular basis for effector function maintenance vs plasticity in the periphery. We highlight some of our contributions towards elucidating the role of T cell receptor, co-receptors (like CD27 and CD28) and cytokine signals (such as IL-1ß and IL-23) in these processes, and the various levels of gene regulation involved, from the chromatin landscape to microRNA-based post-transcriptional control of γδ T cell functional plasticity.

Proximal Lck Promoter-Driven Cre Function Is Limited in Neonatal and Ineffective in Adult γδ T Cell Development.

During T cell development, Lck gene expression is temporally controlled by its proximal and distal promoters. The pLckCre transgenic mouse available from The Jackson Laboratory, in which the proximal promoter of Lck drives Cre expression, is a commonly used Cre driver line to recombine genes flanked by loxP sites in T cells. pLckCre drives recombination early in thymocyte development and is frequently used to delete genes in αß and γδ T cells. We found that pLckCre failed to efficiently delete floxed genes in γδ T cells in contrast to a complete deletion in conventional as well as unconventional αß T cells. Mechanistically, γδ T cells inefficiently transcribed the endogenous proximal Lck promoter compared with αß T cells during adult thymic development. A small population of γδ T cells that had activated pLckCre was detected, many of which were located in nonlymphoid organs as well as precommitted IL-17- or IFN-γ-producing γδ T effector cells. In newborn thymi, both pLckCre and endogenous Lck proximal promoter expression were substantially enhanced, giving rise to an elevated fraction of γδ T cells with recombined floxed genes that were increased in unique γδ T subsets, such as the IL-17-producing γδ T cells. Our data point out striking differences in Lck transcription between perinatal and adult γδ T cell development. Taken together, the data presented in this study shed new light on γδ T cell development and stimulate a reanalysis of data generated using the pLckCre transgenic mice.

Activation loop phosphorylation regulates B-Raf in vivo and transformation by B-Raf mutants.

Despite being mutated in cancer and RASopathies, the role of the activation segment (AS) has not been addressed for B-Raf signaling in vivo. Here, we generated a conditional knock-in mouse allowing the expression of the B-Raf(AVKA) mutant in which the AS phosphoacceptor sites T599 and S602 are replaced by alanine residues. Surprisingly, despite producing a kinase-impaired protein, the Braf(AVKA) allele does not phenocopy the lethality of Braf-knockout or paradoxically acting knock-in alleles. However, Braf(AVKA) mice display abnormalities in the hematopoietic system, a distinct facial morphology, reduced ERK pathway activity in the brain, and an abnormal gait. This phenotype suggests that maximum B-Raf activity is required for the proper development, function, and maintenance of certain cell populations. By establishing conditional murine embryonic fibroblast cultures, we further show that MEK/ERK phosphorylation and the immediate early gene response toward growth factors are impaired in the presence of B-Raf(AVKA). Importantly, alanine substitution of T599/S602 impairs the transformation potential of oncogenic non-V600E B-Raf mutants and a fusion protein, suggesting that blocking their phosphorylation could represent an alternative strategy to ATP-competitive inhibitors.

Distinct requirement for an intact dimer interface in wild-type, V600E and kinase-dead B-Raf signalling.

The dimerisation of Raf kinases involves a central cluster within the kinase domain, the dimer interface (DIF). Yet, the importance of the DIF for the signalling potential of wild-type B-Raf (B-Raf(wt)) and its oncogenic counterparts remains unknown. Here, we show that the DIF plays a pivotal role for the activity of B-Raf(wt) and several of its gain-of-function (g-o-f) mutants. In contrast, the B-Raf(V600E), B-Raf(insT) and B-Raf(G469A) oncoproteins are remarkably resistant to mutations in the DIF. However, compared with B-Raf(wt), B-Raf(V600E) displays extended protomer contacts, increased homodimerisation and incorporation into larger protein complexes. In contrast, B-Raf(wt) and Raf-1(wt) mediated signalling triggered by oncogenic Ras as well as the paradoxical activation of Raf-1 by kinase-inactivated B-Raf require an intact DIF. Surprisingly, the B-Raf DIF is not required for dimerisation between Raf-1 and B-Raf, which was inactivated by the D594A mutation, sorafenib or PLX4720. This suggests that paradoxical MEK/ERK activation represents a two-step mechanism consisting of dimerisation and DIF-dependent transactivation. Our data further implicate the Raf DIF as a potential target against Ras-driven Raf-mediated (paradoxical) ERK activation.

Kidins220/ARMS associates with B-Raf and the TCR, promoting sustained Erk signaling in T cells.

The activation kinetics of MAPK Erk are critical for T cell development and activation. In particular, sustained Erk signaling is required for T cell activation and effector functions, such as IL-2 production. Although Raf-1 triggers transient Erk activation, B-Raf is implicated in sustained Erk signaling after TCR stimulation. In this study, we show that B-Raf is dephosphorylated on its inhibitory serine 365 upon TCR triggering. However, it is unknown how B-Raf activation is coupled to the TCR. Using mass spectrometry, we identified protein kinase D-interacting substrate of 220 kDa (Kidins220)/ankyrin repeat-rich membrane spanning protein, mammalian target of rapamycin, Rictor, Dock2, and GM130 as novel B-Raf interaction partners. We focused on Kidins220, a protein that has been studied in neuronal cells and found that it associated with the pre-TCR, αßTCR, and γδTCR. Upon prolonged TCR stimulation, the Kidins220-TCR interaction was reduced, as demonstrated by immunoprecipitation and proximity ligation assays. We show that Kidins220 is required for TCR-induced sustained, but not transient, Erk activation. Consequently, induction of the immediate early gene products and transcription factors c-Fos and Erg-1 was blocked, and upregulation of the activation markers CD69, IL-2, and IFN-γ was reduced. Further, Kidins220 was required for optimal calcium signaling. In conclusion, we describe Kidins220 as a novel TCR-interacting protein that couples B-Raf to the TCR. Kidins220 is mandatory for sustained Erk signaling; thus, it is crucial for TCR-mediated T cell activation.

Kidins220 and Aiolos promote thymic iNKT cell development by reducing TCR signals.

Development of T cells is controlled by the signal strength of the TCR. The scaffold protein kinase D-interacting substrate of 220 kilodalton (Kidins220) binds to the TCR; however, its role in T cell development was unknown. Here, we show that T cell-specific Kidins220 knockout (T-KO) mice have strongly reduced invariant natural killer T (iNKT) cell numbers and modest decreases in conventional T cells. Enhanced apoptosis due to increased TCR signaling in T-KO iNKT thymocytes of developmental stages 2 and 3 shows that Kidins220 down-regulates TCR signaling at these stages. scRNA-seq indicated that the transcription factor Aiolos is down-regulated in Kidins220-deficient iNKT cells. Analysis of an Aiolos KO demonstrated that Aiolos is a downstream effector of Kidins220 during iNKT cell development. In the periphery, T-KO iNKT cells show reduced TCR signaling upon stimulation with α-galactosylceramide, suggesting that Kidins220 promotes TCR signaling in peripheral iNKT cells. Thus, Kidins220 reduces or promotes signaling dependent on the iNKT cell developmental stage.

Maternal γδ T cells shape offspring pulmonary type 2 immunity in a microbiota-dependent manner.

Immune development is profoundly influenced by vertically transferred cues. However, little is known about how maternal innate-like lymphocytes regulate offspring immunity. Here, we show that mice born from γδ T cell-deficient (TCRδ-/-) dams display an increase in first-breath-induced inflammation, with a pulmonary milieu selectively enriched in type 2 cytokines and type 2-polarized immune cells, when compared with the progeny of γδ T cell-sufficient dams. Upon helminth infection, mice born from TCRδ-/- dams sustain an increased type 2 inflammatory response. This is independent of the genotype of the pups. Instead, the offspring of TCRδ-/- dams harbors a distinct intestinal microbiota, acquired during birth and fostering, and decreased levels of intestinal short-chain fatty acids (SCFAs), such as pentanoate and hexanoate. Importantly, exogenous SCFA supplementation inhibits type 2 innate lymphoid cell function and suppresses first-breath- and infection-induced inflammation. Taken together, our findings unravel a maternal γδ T cell-microbiota-SCFA axis regulating neonatal lung immunity.

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.

Caveolin-1: The Unnoticed Player in TCR and BCR Signaling.

T and B lymphocytes are key players of the adaptive immune system. They recognize pathogenic cues via the T cell antigen receptor (TCR) and the B cell antigen receptor (BCR) to get activated and execute their protective function. TCR and BCR signaling are initiated at the plasma membrane and subsequently propagated into the cell, ultimately leading to cell activation and a protective immune response. However, inappropriate activation of T and B cells can be detrimental to the host resulting in autoimmune disorders, immunodeficiencies, and cancer. The TCR and BCR are located at the plasma membrane, which composition is highly heterogenic. Membrane compartmentalization based on specific lipid-lipid and protein-lipid interactions has raised the interest of the scientific community, converting the plasma membrane into an active player in the initiation of signaling and adding an additional layer of regulation to our current understanding of the functioning of antigen receptors. Caveolin-1 is an integral membrane protein and a crucial component of caveolae. It has been long thought that lymphocytes lack Caveolin-1 expression, due to the absence of detectable caveolae in lymphocytes and the failure to detect Caveolin-1 in T and B cell lines. However, Caveolin-1 is expressed at low levels in primary lymphocytes, and recent studies have shown the importance of Caveolin-1 for the basal membrane organization of the BCR and the TCR as well as their reorganization upon activation. Here, we review our current understanding of the initial signaling events of TCR and BCR activation with respect to receptor compartmentalization on the plasma membrane and with special emphasis on the previously unnoticed role of Caveolin-1.

Kidins220/ARMS binds to the B cell antigen receptor and regulates B cell development and activation.

B cell antigen receptor (BCR) signaling is critical for B cell development and activation. Using mass spectrometry, we identified a protein kinase D-interacting substrate of 220 kD (Kidins220)/ankyrin repeat-rich membrane-spanning protein (ARMS) as a novel interaction partner of resting and stimulated BCR. Upon BCR stimulation, the interaction increases in a Src kinase-independent manner. By knocking down Kidins220 in a B cell line and generating a conditional B cell-specific Kidins220 knockout (B-KO) mouse strain, we show that Kidins220 couples the BCR to PLCγ2, Ca(2+), and extracellular signal-regulated kinase (Erk) signaling. Consequently, BCR-mediated B cell activation was reduced in vitro and in vivo upon Kidins220 deletion. Furthermore, B cell development was impaired at stages where pre-BCR or BCR signaling is required. Most strikingly, λ light chain-positive B cells were reduced sixfold in the B-KO mice, genetically placing Kidins220 in the PLCγ2 pathway. Thus, our data indicate that Kidins220 positively regulates pre-BCR and BCR functioning.

Activation of the TCR complex by peptide-MHC and superantigens.

Drug hypersensitivity reactions are immune mediated, with T lymphocytes being stimulated by the drugs via their T-cell antigen receptor (TCR). In the nonpathogenic state, the TCR is activated by foreign peptides presented by major histocompatibility complex molecules (pMHC). Foreign pMHC binds with sufficient affinity to TCRαß and thereby elicits phosphorylation of the cytoplasmic tails of the TCRαß-associated CD3 subunits. The process is called TCR triggering. In this review, we discuss the current models of TCR triggering and which drug properties are crucial for TCR stimulation. The underlying molecular mechanisms mostly include pMHC-induced exposure of the CD3 cytoplasmic tails or alterations of the kinase-phosphatase equilibrium in the vicinity of CD3. In this review, we also discuss triggering of the TCR by small chemical compounds in context of these general mechanisms.