A Mechanical Switch Couples T Cell Receptor Triggering to the Cytoplasmic Juxtamembrane Regions of CD3ζζ

Lee, Mark S.; Glassman, Caleb R.; Deshpande, Neha; Badgandi, Hemant B.; Parrish, Heather L.; Uttamapinant, Chayasith; Stawski, Philipp; Ting, Alice Y.; Kuhns, Michael S.

doi:10.1016/j.immuni.2015.06.018

Cited by 110 publications

(119 citation statements)

References 48 publications

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“…The rearrangement of the previously described CD247 interface (24) to accommodate the new contacts to CD16A is striking in view of the recent report suggesting that CD247 also undergoes a significant structural alteration upon incorporation into the TCR-CD3 complex (30), and this flexibility may be particularly important for the demonstrated ability of both CD247 and FceR1γ to form stable assemblies with many different receptor TM sequences. Interestingly, despite the apparent interchangeability of human FceR1γ and CD247, murine CD247 is essentially unable to function in the assembly of either human or mouse CD16A so that, in murine NK cells, only FceR1γ participates in the assembly of this receptor complex (4).…”

Section: Discussionmentioning

confidence: 91%

Transmembrane features governing Fc receptor CD16A assembly with CD16A signaling adaptor molecules

Blázquez-Moreno

Park

et al. 2017

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

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Many activating immunoreceptors associate with signaling adaptor molecules like FceR1γ or CD247. FceR1γ and CD247 share high sequence homology and form disulphide-linked homodimers that contain a pair of acidic aspartic acid residues in their transmembrane (TM) domains that mediate assembly, via interaction with an arginine residue at a similar register to these aspartic acids, with the activating immunoreceptors. However, this model cannot hold true for receptors like CD16A, whose TM domains do not contain basic residues. We have carried out an extensive site-directed mutagenesis analysis of the CD16A receptor complex and now report that the association of receptor with the signaling adaptor depends on a network of polar and aromatic residues along the length of the TM domain. Molecular modeling indicates that CD16A TM residues F 202 , D 205, and T 206 form the core of the membrane-embedded trimeric interface by establishing highly favorable contacts to the signaling modules through rearrangement of a hydrogen bond network previously identified in the CD247 TM dimer solution NMR structure. Strikingly, the amino acid D 205 also regulates the turnover and surface expression of CD16A in the absence of FceR1γ or CD247. Modeling studies indicate that similar features underlie the association of other activating immune receptors, including CD64 and FceR1α, with signaling adaptor molecules, and we confirm experimentally that equivalent F, D, and T residues in the TM domain of FceR1α markedly influence the biology of this receptor and its association with FceR1γ. dim natural killer (NK) cells, subsets of monocytes, dendritic cells, and rare T cells. FcγRIIIB (CD16B) is encoded by a distinct gene and is preferentially expressed by neutrophils (1). CD16B is a GPI-anchored glycoprotein whereas CD16A is a type 1 membrane glycoprotein with a single transmembrane (TM) domain and a short cytoplasmic tail whose expression at the cell surface depends on association with the signaling adaptor molecules CD247 (TCRζ) and/or FceR1γ (1-4). First discovered as components of the TCR:CD3 complex and the high affinity receptor for IgE, respectively (5-7), CD247 and FceR1γ are integral membrane proteins that have subsequently been found to be obligate signaling adaptors for many immunoreceptors in different cell types. Both adaptors have very short extracellular domains and cytoplasmic tails that contain immunoreceptor tyrosinebased activating motifs (ITAMs) for signal transduction. Moreover, both CD247 and FceR1γ form dimers in the endoplasmic reticulum (ER) that are stabilized by a disulphide bond at the junction between the extracellular and TM domains so that, at the cell surface, CD247 and FceR1γ in complex with their client receptors are dimeric. In general, the receptors known to associate with CD247 and FceR1γ have short intracellular tails and thus are completely dependent on these adaptors to signal, although phosphorylation of a protein kinase C (PKC) motif in the cytoplasmic tail of CD16A can modulate the outcome of receptor ...

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Section: Discussionmentioning

confidence: 91%

Transmembrane features governing Fc receptor CD16A assembly with CD16A signaling adaptor molecules

Blázquez-Moreno

Park

et al. 2017

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

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“…This type of signaling model implies a pathway between EC and cytoplasmic domains that may involve alterations in the subunit transmembrane (TM) domains with respect to each other and/ or the lipid bilayer (13)(14)(15)(16). Consistent with this view, Kuhns and colleagues (17) recently reported a ligand-induced change in intersubunit proximity at the TM-juxtamembrane juncture in the ζζ dimer and proposed that this "mechanical switch" is coupled to signal initiation at the ζζ cytoplasmic tails. However, the nature of the upstream structural changes that trigger this switch, and whether it is required for signal initiation, remain to be determined.…”

mentioning

confidence: 92%

A conserved αβ transmembrane interface forms the core of a compact T-cell receptor–CD3 structure within the membrane

Krshnan

Park

et al. 2016

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

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The T-cell antigen receptor (TCR) is an assembly of eight type I single-pass membrane proteins that occupies a central position in adaptive immunity. Many TCR-triggering models invoke an alteration in receptor complex structure as the initiating event, but both the precise subunit organization and the pathway by which ligandinduced alterations are transferred to the cytoplasmic signaling domains are unknown. Here, we show that the receptor complex transmembrane (TM) domains form an intimately associated eighthelix bundle organized by a specific interhelical TCR TM interface. The salient features of this core structure are absolutely conserved between αβ and γδ TCR sequences and throughout vertebrate evolution, and mutations at key interface residues caused defects in the formation of stable TCRαβ:CD3δe:CD3γe:ζζ complexes. These findings demonstrate that the eight TCR-CD3 subunits form a compact and precisely organized structure within the membrane and provide a structural basis for further investigation of conformationally regulated models of transbilayer TCR signaling.T-cell receptor | transmembrane structure | NMR | MD simulation | cysteine cross-linking T he antigen-specific T-cell response depends critically upon the ability of the T-cell receptor (TCR) to signal the recognition of activating ligands. The variable TCR proteins (α, β, δ, and γ) that bind to these ligands have no intrinsic intracellular signaling capability and transmit information through the noncovalently associated CD3δe, CD3γe, and ζζ modules containing cytoplasmic immunoreceptor tyrosine-based activation motifs (ITAMs) that are phosphorylated by the Src-family kinase Lck. The mechanism by which antigen sensing is translated from ligand binding at the distal end of the TCR to phosphorylation events at the cytoplasmic tails of the associated signaling modules remains an important open question in T-cell biology. A mounting pool of evidence implicates ligand-induced alterations in receptor structure (1) and/or TCR-CD3 configuration (2-6) as the triggering event. Changes in the structured extracellular (EC) domains are proposed to translate, through an unknown mechanism, into alterations in the CD3 and ζζ cytoplasmic tails, converting them to a conformation that is receptive to phosphorylation by Lck and binding of other proximal signaling components (7-12). This type of signaling model implies a pathway between EC and cytoplasmic domains that may involve alterations in the subunit transmembrane (TM) domains with respect to each other and/ or the lipid bilayer (13-16). Consistent with this view, Kuhns and colleagues (17) recently reported a ligand-induced change in intersubunit proximity at the TM-juxtamembrane juncture in the ζζ dimer and proposed that this "mechanical switch" is coupled to signal initiation at the ζζ cytoplasmic tails. However, the nature of the upstream structural changes that trigger this switch, and whether it is required for signal initiation, remain to be determined. Tracing possible transbilayer conformational pathway...

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“…Soluble monomeric pMHC are poor activators of TCR triggering, while surface-bound pMHC efficiently activate TCRs, suggesting that TCR triggering requires additional steps beyond pMHC binding [25, 32]. Structural studies indicate that electrostatic interactions between the TCR-α and CD3 transmembrane regions create a pivot which can mechanically couple antigen binding and force application to conformational changes within the CD3ζζ cytosolic regions [33] (Fig. 1a, inset).…”

Section: Mechanosensing At the Molecular Scalementioning

confidence: 99%

“…While forces tangential to the cell membrane can engage the TCR-CD3 pivot driving the conformational changes leading to triggering [33], forces normal to the cell membrane along the TCR axis are required to engage the catch-bond and induce signaling [28]. Overall, these observations raise the following questions: what is the magnitude and direction of forces in situ ?…”

Section: Mechanosensing At the Molecular Scalementioning

confidence: 99%

Mechanosensing in the immune response

Upadhyaya

2017

Seminars in Cell & Developmental Biology

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Cells have a remarkable ability to sense and respond to the mechanical properties of their environment. Mechanosensing is essential for many phenomena from cell movements and tissue rearrangements to cell differentiation and the immune response. Cells of the immune system get activated when membrane receptors bind to cognate antigen on the surface of antigen presenting cells. Both T and B lymphocyte signaling has been shown to be responsive to physical forces and mechanical cues. Cytoskeletal forces exerted by cells likely mediate this mechanical modulation. Here we discuss recent advances in the field of immune cell mechanobiology at the molecular and cellular scale.

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A Mechanical Switch Couples T Cell Receptor Triggering to the Cytoplasmic Juxtamembrane Regions of CD3ζζ

Cited by 110 publications

References 48 publications

Transmembrane features governing Fc receptor CD16A assembly with CD16A signaling adaptor molecules

Transmembrane features governing Fc receptor CD16A assembly with CD16A signaling adaptor molecules

A conserved αβ transmembrane interface forms the core of a compact T-cell receptor–CD3 structure within the membrane

Mechanosensing in the immune response

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