T-cell triggering thresholds are modulated by the number of antigen within individual T-cell receptor clusters

Manz, Boryana N.; Jackson, Bryan L.; Petit, Rebecca S.; Dustin, Michael L.; Groves, Jay T.

doi:10.1073/pnas.1018771108

Cited by 170 publications

(223 citation statements)

References 43 publications

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“…Activation violates the attenuation steadystate, and the cell is shifted to a preferred activated state. In addition, we and other investigators showed that Ag density, and not quantity, is the decisive factor in activation of a T cell and that the minimal number of pMHC-I complexes/TCR cluster required for the activation is approximately four (24,57). Our results suggest that, in addition to this minimal activation requirement, maximal cluster activation might exist, as well.…”

Section: Discussionsupporting

confidence: 69%

Antigen-Dependent Integration of Opposing Proximal TCR-Signaling Cascades Determines the Functional Fate of T Lymphocytes

Wolchinsky

Hod-Marco

Oved

et al. 2014

The Journal of Immunology

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T cell anergy is a key tolerance mechanism to mitigate unwanted T cell activation against self by rendering lymphocytes functionally inactive following Ag encounter. Ag plays an important role in anergy induction where high supraoptimal doses lead to the unresponsive phenotype. How T cells “measure” Ag dose and how this determines functional output to a given antigenic dose remain unclear. Using multiparametric phospho-flow and mass cytometry, we measured the intracellular phosphorylation-dependent signaling events at a single-cell resolution and studied the phosphorylation levels of key proximal human TCR activation- and inhibition-signaling molecules. We show that the intracellular balance and signal integration between these opposing signaling cascades serve as the molecular switch gauging Ag dose. An Ag density of 100 peptide–MHC complexes/cell was found to be the transition point between dominant activation and inhibition cascades, whereas higher Ag doses induced an anergic functional state. Finally, the neutralization of key inhibitory molecules reversed T cell unresponsiveness and enabled maximal T cell functions, even in the presence of very high Ag doses. This mechanism permits T cells to make integrated “measurements” of Ag dose that determine subsequent functional outcomes.

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Section: Discussionsupporting

confidence: 69%

Antigen-Dependent Integration of Opposing Proximal TCR-Signaling Cascades Determines the Functional Fate of T Lymphocytes

Wolchinsky

Hod-Marco

Oved

et al. 2014

The Journal of Immunology

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“…The triggering chemical thresholds are very high for SLB experiments, 0.2 pMHC per 1 µm 2 , which corresponds to ∼16 pMHC beneath the cell (28). At least four pMHCs within a single TCR cluster spanning 400 × 400 nm 2 and containing 18-100 TCRs are sufficient to induce the Ca 2+ flux (71). TCR-pMHC clusters form and begin to organize actin machinery, eliciting transport and IS formation with distal, peripheral, and central supramolecular activation clusters.…”

Section: Discussionmentioning

confidence: 99%

Mechanosensing drives acuity of αβ T-cell recognition

Feng

Brazin

Kobayashi

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

162

197

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T lymphocytes use surface αβ T-cell receptors (TCRs) to recognize peptides bound to MHC molecules (pMHCs) on antigen-presenting cells (APCs). How the exquisite specificity of high-avidity T cells is achieved is unknown but essential, given the paucity of foreign pMHC ligands relative to the ubiquitous self-pMHC array on an APC. Using optical traps, we determine physicochemical triggering thresholds based on load and force direction. Strikingly, chemical thresholds in the absence of external load require orders of magnitude higher pMHC numbers than observed physiologically. In contrast, force applied in the shear direction (∼10 pN per TCR molecule) triggers T-cell Ca 2+ flux with as few as two pMHC molecules at the interacting surface interface with rapid positional relaxation associated with similarly directed motor-dependent transport via ∼8-nm steps, behaviors inconsistent with serial engagement during initial TCR triggering. These synergistic directional forces generated during cell motility are essential for adaptive T-cell immunity against infectious pathogens and cancers.mechanosensor | T-cell receptor | T-cell activation | optical tweezers | cellular force relaxation T he T-cell receptor (TCR) expressed on T lymphocytes of the adaptive immune system is a stout and squat (12-nm wide × 8-nm tall) multisubunit surface complex with a ligand binding moiety that is an αβ disulfide-linked heterodimer buttressed by the associated invariant CD3 subunits (1-3). The αβ chains are each encoded by V and J gene segments and in the case of the β, a D segment as well (4). The clone-specific TCR unique to each T lymphocyte endows mammals with the capacity to detect perturbations in host cellular function resulting from myriad infectious pathogens, physical damage (thermal, irradiation, etc.), or premalignant or malignant cellular transformations while averting strong self-reactivities that could induce autoimmunity (5).Signaling is initiated through ligation of the clonotype by its cognate antigenic peptide bound to an MHC molecule (pMHC) and displayed on the surface of antigen-presenting cells (APCs) (6, 7). Ligation impacts disposition and function of the associated CD3 dimers (CD3 γ, CD3 δ, and CD3ζζ) as well as the transmembrane domains of the TCR heterodimer and CD3 subunits that interdigitate in the membrane to signal into the cytoplasm (8, 9). A cascade of intracellular events involving phosphorylation of immunoreceptor tyrosine-based activation motifs (ITAMs) on the CD3 cytoplasmic domains with subsequent ZAP70 activation and downstream signaling follows (10, 11). Membrane-associated CD8 and CD4 coreceptors, marking cytotoxic T lymphocytes (CTLs) and helper T cells, respectively, function to bring the membrane-anchored Src family tyrosine kinase Lck to the TCR-pMHC complex for the initiation of ITAM phosphorylation. Signaling, in turn, leads to a transient rise of cytosolic Ca 2+ and other biochemical events resulting in transcriptional activation, ultimately resulting in developmental decisions or effector functi...

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“…The recent application of advanced optical techniques (10-13) in combination with substrate patterning and functionalization (14,15) is providing detailed information on how the lateral organization of a variety of molecules located on both sides of the immunological synapse contributes to controlling T-cell activation. Specifically, single-molecule dynamic approaches and superresolution optical nanoscopy experiments have provided indisputable proof that many receptors on the cell membrane organize in small nanoclusters before ligand activation (16).…”

mentioning

confidence: 99%

The actin cytoskeleton modulates the activation of iNKT cells by segregating CD1d nanoclusters on antigen-presenting cells

Torreño-Pina

Manzo

Salio

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Invariant natural killer T (iNKT) cells recognize endogenous and exogenous lipid antigens presented in the context of CD1d molecules. The ability of iNKT cells to recognize endogenous antigens represents a distinct immune recognition strategy, which underscores the constitutive memory phenotype of iNKT cells and their activation during inflammatory conditions. However, the mechanisms regulating such "tonic" activation of iNKT cells remain unclear. Here, we show that the spatiotemporal distribution of CD1d molecules on the surface of antigen-presenting cells (APCs) modulates activation of iNKT cells. By using superresolution microscopy, we show that CD1d molecules form nanoclusters at the cell surface of APCs, and their size and density are constrained by the actin cytoskeleton. Dual-color single-particle tracking revealed that diffusing CD1d nanoclusters are actively arrested by the actin cytoskeleton, preventing their further coalescence. Formation of larger nanoclusters occurs in the absence of interactions between CD1d cytosolic tail and the actin cytoskeleton and correlates with enhanced iNKT cell activation. Importantly and consistently with iNKT cell activation during inflammatory conditions, exposure of APCs to the Toll-like receptor 7/8 agonist R848 increases nanocluster density and iNKT cell activation. Overall, these results define a previously unidentified mechanism that modulates iNKT cell autoreactivity based on the tight control by the APC cytoskeleton of the sizes and densities of endogenous antigen-loaded CD1d nanoclusters.cell membrane compartmentalization | iNKT cell autoreactivity | protein nanoclustering | single-particle tracking | stimulated emission depletion nanoscopy

show abstract

T-cell triggering thresholds are modulated by the number of antigen within individual T-cell receptor clusters

Cited by 170 publications

References 43 publications

Antigen-Dependent Integration of Opposing Proximal TCR-Signaling Cascades Determines the Functional Fate of T Lymphocytes

Antigen-Dependent Integration of Opposing Proximal TCR-Signaling Cascades Determines the Functional Fate of T Lymphocytes

Mechanosensing drives acuity of αβ T-cell recognition

The actin cytoskeleton modulates the activation of iNKT cells by segregating CD1d nanoclusters on antigen-presenting cells

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