Coexistence of multivalent and monovalent TCRs explains high sensitivity and wide range of response

A long-standing paradox in the study of T cell antigen recognition is that of the high specificity–low affinity T cell receptor (TCR)–major histocompatibility complex peptide (MHCp) interaction. The existence of multivalent TCRs could resolve this paradox because they can simultaneously improve the avidity observed for monovalent interactions and allow for cooperative effects. We have studied the stoichiometry of the TCR by Blue Native–polyacrylamide gel electrophoresis and found that the TCR exists as a mixture of monovalent (αβγɛδɛζζ) and multivalent complexes with two or more ligand-binding TCRα/β subunits. The coexistence of monovalent and multivalent complexes was confirmed by electron microscopy after label fracture of intact T cells, thus ruling out any possible artifact caused by detergent solubilization. We found that although only the multivalent complexes become phosphorylated at low antigen doses, both multivalent and monovalent TCRs are phosphorylated at higher doses. Thus, the multivalent TCRs could be responsible for sensing low concentrations of antigen, whereas the monovalent TCRs could be responsible for dose-response effects at high concentrations, conditions in which the multivalent TCRs are saturated. Thus, besides resolving TCR stoichiometry, these data can explain how T cells respond to a wide range of MHCp concentrations while maintaining high sensitivity

Nanoclusters of the resting T cell antigen receptor (TCR) localize to non-raft domains

© 2014 Elsevier B.V. In the last decade an increasing number of plasma membrane (PM) proteins have been shown to be non-randomly distributed but instead forming submicron-sized oligomers called nanoclusters. Nanoclusters exist independently of the ligand-bound state of the receptors and their existence implies a high degree of lateral organisation of the PM and its proteins. The mechanisms that drive receptor nanoclustering are largely unknown. One well-defined example of a transmembrane receptor that forms nanoclusters is the T cell antigen receptor (TCR), a multisubunit protein complex whose nanoclustering influences its activity. Membrane lipids, namely cholesterol and sphingomyelin, have been shown to contribute to TCR nanoclustering. However, the identity of the membrane microdomain in which the TCR resides remains controversial. Using a GFP-labeled TCR we show here that the resting TCR localized in the disordered domain of giant PM vesicles (GPMVs) and PM spheres (PMSs) and that single and nanoclustered TCRs are found in the high-density fractions in sucrose gradients. Both findings are indicative of non-raft localization. We discuss possible mechanisms of TCR nanoclustering in T cells. This article is part of a Special Issue entitled: Nanoscale membrane organisation and signalling.German Research Foundation (GSC-4, the Spemann Graduate School and EXC294, the BIOSS Center for Biological Signalling Studies, by the German Research Foundation grant SCH 976/2-1, and by the European Union through grant FP7/2007-2013 SYBILLAPeer Reviewe

The short length of the extracellular domain of ζ is crucial for T cell antigen receptor function

The T cell antigen receptor (TCR-CD3) consists of the pMHC-binding TCRαβ heterodimer and the signalling dimers CD3δε, CD3γε and ζζ. The very short length of the extracellular domain (EC) of the ζ chain is preserved through evolution, however a rational explanation for this observation has not been elucidated. Here, we show that TCR-CD3 assembly is clearly defective when the murine ζ EC domain is artificially enlarged. Under these conditions, the TCR-CD3 complex is super-competent in transducing activation signals upon engagement. Furthermore, the TCR-CD3 complexes containing enlarged ζ EC domains underwent ligand-induced conformation changes with higher efficiency than TCR-CD3 complexes with an unmodified ζ EC domain. Together these data suggest that a short ζ EC domain is needed to correctly assemble the TCR-CD3 complex. When this domain is enlarged, the resulting TCR-CD3 complex is distorted leading to a hyperactive phenotype and enhanced T cell activation

Two dimensional Blue Native-/SDS-PAGE analysis of SLP family adaptor protein complexes

SH2 domain containing leukocyte protein (SLP) adaptor proteins serve a central role in the antigen-mediated activation of lymphocytes by organizing multiprotein signaling complexes. Here, we use two dimensional native-/SDS-gel electrophoresis to study the number, size and relative abundance of protein complexes containing SLP family proteins. In non-stimulated T cells all SLP-76 proteins are in a approximately ~400 kDa complex with the small adaptor protein Grb2-like adaptor protein downstream of Shc (Gads), whereas half of Gads is monomeric. This constitutive SLP-76/Gads complex could be reconstituted in Drosophila S2 cells expressing both components, suggesting that it might not contain additional subunits. In contrast, in B cells SLP-65 exists in a 180 kDa complex as well as in monomeric form. Since the complex was not found in S2 cells expressing only SLP-65, it was not di/trimeric SLP-65. Upon antigen-stimulation only the complexed SLP-65 was phosphorylated. Surprisingly, stimulation-induced alteration of SLP complexes could not be detected, suggesting that active signaling complexes form only transiently, and are of low abundance

A native antibody-based mobility-shift technique (NAMOS-assay) to determine the stoichiometry of multiprotein complexes

Characterization of multiprotein complexes (MPCs) is an important step toward an integrative view of protein interaction networks and prerequisite for a molecular understanding of how a certain MPC functions. Here, we present a technique utilizing monoclonal subunit-specific antibodies for an electrophoretic immunoshift assay in Blue Native-gels (NAMOS-assay), which allows the determination of the stoichiometry of MPCs. First, we use the B cell antigen receptor as a model MPC whose stoichiometry is known, confirming the HC₂LC₂Igα/β₁ stoichiometry. Second, we demonstrate that the digitonin-extracted T cell antigen receptor (TCR) extracted from T cells has a stoichiometry of αβε₂γδζ₂. We then show that the NAMOS-assay does not require purified MPCs, since it can determine the stoichiometry of an MPC in cell lysates. The NAMOS-assay is also compatible with use of epitope tags appended to the protein of interest, as e.g. the widely used HA-tag, and anti-epitope antibodies for the assay. Given its general applicability, this method has a wide potential for MPC research

Blue native polyacrylamide gel electrophoresis (BN-PAGE) for the identification and analysis of multiprotein complexes.

Multiprotein complexes (MPCs) play crucial roles in cell signaling. Two kinds of MPCs can be distinguished: (i) Constitutive, abundant MPCs--for example, multisubunit receptors or transcription factors; and (ii) signal-induced, transient, low copy number MPCs--for example, complexes that form upon binding of Src-homology 2 (SH2) domain-containing proteins to tyrosine-phosphorylated proteins. Blue native polyacrylamide gel electrophoresis (BN-PAGE) is a separation method with a higher resolution than gel filtration or sucrose density ultracentrifugation that can be used to analyze abundant, stable MPCs from 10 kD to 10 MD. In contrast to immunoprecipitation and two-hybrid approaches, it allows the determination of the size, the relative abundance, and the subunit composition of an MPC. In addition, it shows how many different complexes exist that share a common subunit, whether free monomeric forms of individual subunits exist, and whether these parameters change upon cell stimulation. Here, we give a detailed protocol for the separation of MPCs from total cellular lysates or of prepurified MPCs by one-dimensional BN-PAGE or by two-dimensional BN-PAGE and SDS-PAGE

Detection of protein complex interactions via a blue native-page retardation assay

We describe the Blue Native (BN)-PAGE retardation assay for the detection of interactions of biomolecules with protein complexes. Potential interactors of proteins are included in the BN gel matrix, resulting in retardation of proteins that interact with the added molecule. After validation using the T-cell antigen receptor, we applied the assay for a general identification of dextran interactors in combination with mass spectroscopy. The proteomic screen revealed triosephosphate isomerase oligomer as a dextranbinding, high M_R complex