Assembly of the TCR/CD3 complex: CD3ϵ/δ and CD3ϵ/γ dimers associate indistinctly with both TCRα and TCRβ chains. Evidence for a double TCR heterodimer model

The TCR/CD3 complex is composed of six subunits which are expressed on the cell surface in a coordinate fashion after assembly in the endoplasmic reticulum (ER). The TCR/CD3 complex is assembled after a series of pairwise interactions involving the formation of dimers of CD3ϵ with either CD3γ or CD3δ. These dimers assemble with TCRα and TCRβ chains, and finally, the CD3ζ homodimer is added to allow export of the full complex from the ER. A model has been proposed suggesting that during assembly the CD3ϵ/CD3γ dimer interacts exclusively with TCRβ and the CD3ϵ/CD3δ dimer with TCRα to form a complex with a single TCRα/β heterodimer. We show in this study, by immunoprecipitation and two-dimensional gel electrophoresis, that in the human T cell line Jurkat as well as in total human thymocytes, this preferential interaction does not occur and instead, the CD3ϵ/CD3γ and CD3ϵ/CD3δ dimers associate with both TCR chains simultaneously and indistinctly. These data are confirmed by the analysis of the TCRα-negative T cell line MOLT-4 in which TCRβ is found separately associated with CD3ϵ/CD3γ and with CD3ϵ/CD3δ dimers. Indirectly, our results support a model of stoichiometry in which two TCRα/β heterodimers are present in a TCR/CD3 complex. Furthermore, immunoprecipitation with anti-CD3γ and anti-CD3δ antibodies from 1 % NP40 and 1 % Brij96 cell lysates showed that these subunits form independent partial complexes which are cross-linked through the CD3ζ homodimer. This suggests that CD3ζ mediates the interaction between both TCRα/β heterodimers contained in the double TCR complex. Further proof for this hypothesis is obtained after analysis of a Jurkat cell transfectant containing a point mutation in the transmembrane domain of TCRβ that impairs the association of CD3ζ. In this mutant cell line, unlike a control line with wild-type TCRβ, the CD3γ- and CD3δ-containing complexes were found completely independent. Altogether, these results support a model of TCR/CD3 assembly and stoichiometry in which two TCR-α/β heterodimers form two hemicomplexes containing either CD3ϵ/γ or CD3ϵ/δ dimers which become associated via the CD3ζ homodimer.     

The protein interactions of the immunoglobulin receptor family tyrosine-based activation motifs present in the T cell receptor ζ subunits and the CD3 γ,δ and ϵ chains

Immunoglobulin family tyrosine-based activation motifs (ITAM), which define the conserved signaling sequence EX₂YX₂L/IX₇YX₂L/I, couple the T cell antigen receptor (TCR) to cellular proteins including protein tyrosine kinases (PTK) and adapter molecules. The TCR is a multichain complex with four invariant chains CD3γ, δ and ? that each contain a single ITAM and the TCR ζ chain that contains three ITAM. The present study explores the protein interactions of the doubly phosphorylated CD3 γ, δ, ? ITAM to determine whether they have common or unique biochemical properties. The data show that the doubly phosphorylated ITAM all bind the PTK ZAP-70, but the ITAM also variably bind the PTK p59fyn and the adapters Shc, Grb-2 and the p85 regulatory subunit of phosphoinositol 3′ kinase. The CD3 and ζ ITAM display a hierarchy of ZAP-70 binding: ζ1 = γ = δ > ζ3 > ζ2 = ?. Shc, Grb-2 and p85 could bind the ζ ITAM and the CD3 γ and δ ITAM, but not the CD3 ? ITAM. There were also subtle differences in the hierarchy of reactivity of these adapters for the CD3 γ,δ and ζ ITAM that show that the ζ, CD3 γ, δ and ? ITAM have different binding properties. The present study thus shows that the different ITAM of the TCR/CD3 complex can interact with different cytosolic effectors, indicating that differential ITAM phosphorylation during T cell activation could be a mechanism to generate signaling diversity by the TCR complex.     

T cell receptor diversity in alloreactive responses against HLA-B27 (B*2705) is limited by multiple-level restrictions in both α and β chains

The T cell receptors (TCR) in HLA-B27 (B*2705) alloreactivity were analyzed in cytotoxic T lymphocytes (CTL) from two individuals. Non-random usage was found in Vβ, N+Dβ, Vα, and Jα, but not in Jβ segments or Nα-regions. Vβ segments from homology subgroup 4 were predominant and not associated to a particular donor or fine specificity, suggesting involvement in recognizing the HLA-B27 molecule. In contrast, preferential Vα usage was associated with particular individuals and fine specificities, indicating distinct Vβ and Vα recruitment and contribution to allorecognition. Recurrent N+Dβ motifs and Jα segments, even from different donors, limited junctional diversity, suggesting that CDR3 usage was determined by the alloantigenic epitope independently of individuals. TCR were selected differently at various levels, as indicated by the following findings. Four clonotypes with similar fine specificity had identical β and unrelated α chains. Similar α were associated with unrelated β chains, and vice versa. CTL using Vβ subgroup 4 did not globally show concomitant predominance of other TCR elements. Vα7, one of the preferred Vα segments, was always associated with Vβ subgroups other than 4. Sometimes, a TCR showed homology in elements of one chain to a second TCR or group of TCR, and to another in the other chain. These results are best explained by differential selection of TCR elements by different epitopes, providing a key to the inner structure of allospecific TCR repertoires.     

The dynamic TCRδ: TCRδ chains in the amphibian Xenopus tropicalis utilize antibody‐like V genes

The content and organization of the Xenopus tropicalis TCRα/δ locus was determined. This locus is highly conserved among tetrapods, with the genes encoding the TCRδ chains embedded with those encoding TCRα. However, the frog TCRα/δ is unusual in that it contains V genes that appear indistinguishable from those in the IgH locus (VH). These V genes, termed VHδ, make up 70% of the V genes at the TCRδ locus and are expressed exclusively in TCRδ chains. Finding TCRδ chains that use antibody‐like V domains in frogs is similar to the situation in shark TCRδ variants and TCRμ in marsupials. These results suggest that such unconventional TCR may be more widespread across vertebrate lineages than originally thought and raise the possibility of previously unrealized subsets of T cells. We also revealed close linkage of TCRα/δ, IgH, and Igλ in Xenopus which, in combination with linkage analyses in other species, is consistent with the previous models for the emergence of these antigen receptor loci.     

Control of thymus-independent intestinal intraepithelial lymphocytes by β2-microglobulin

Murine intestinal intraepithelial lymphocytes (i-IEL) comprise thymusdependent cells such as T cell receptor (TcR) α/β CD8α/β⁺ i-IEL, as well as thymus-independent ones such as TcRα/β CD8α/α⁺ and TcRγ/δ CD8α/α⁺ i-IEL. Whilst the development of the CD8α/β expressing i-IEL is strictly contingent on major histocompatibility complex (MHC) class I surface expression, that of CD8α/α i-IEL appears largely MHC class I independent. We have used β2-microglobulin (β2m)^?/? mutant mice lacking surface-expressed MHC class I and TcRα/β CD8α/β⁺ i-IEL to analyze the potential impact of MHC class I on regional activation of thymus-independent i-IEL. To analyze the role of TcRγ/δ i-IEL in regional cell interactions, these mice were treated with the anti-TcRγ/δ mAb, GL3. Whilst numbers of TcRα/β CD8α/α i-IEL were markedly reduced in βm^+/? mice, those of TcRγ/δ i-IEL were elevated. Administration of GL3 in vivo caused TcR down-modulation and functional inactivation of TcRγ/δ i-IEL in β2m^+/? mice. In contrast, TcR expression and functional activities of TcRγ/δ i-IEL from β2m^?/? mice were not impaired by GL3 treatment. The TcRα/β CD8β i-IEL from β2m^?/? mice were expanded and functionally activated as a consequence of TcRγ/δ engagement. The TcRγ/δ i-IEL and TcRα/β CD8α/α⁺ i-IEL from athymic nu/nu mice which express MHC class I, but lack TcRα/β CD8α/β⁺ i-IEL, responded to TcRγ/δ engagement as those from the β2m^+/? controls. In addition, the TcRγ/δ i-IEL from TcRβ^?/? and TcRβ^+/? mutants were equally affected by GL3. We conclude that the absence of β2m renders TcRγ/δ i-IEL resistant to TcR-mediated inactivation and promotes activation of TcRα/β CD8β^? i-IEL. The activation of TcRγ/δ i-IEL seems to be directly controlled by β2m/MHC class I expression and independent from TcRα/β CD8β⁺ i-IEL. Regulation of self-reactive thymus-independent i-IEL through β2m/MHC class I may contribute to control of autoreactive immune responses in the intestine.     

Differential signaling through the Ig-α and Ig-β components of the B cell antigen receptor

The B cell antigen receptor is a complex containing the antigen-binding immunoglobulin molecules and the Ig-α/Ig-β heterodimer which presumably connects the B cell antigen receptor to intracellular signaling components. To analyze the functional properties of the cytoplasmic parts of the B cell antigen receptor, we used the K46 B lymphoma line (IgG2a, χ) to express chimeric molecules composed of the extracellular and transmembrane part of the CD8α molecule and the cytoplasmic sequence of either the Ig-α (CD8α/Ig-α), the Ig-β (CD8α/Ig-β) protein or the membrane-bound γ2a heavy chain (CD8α/γ2a). From these three types of chimeric molecules only CD8α/Ig-α and CD8α/Ig-β, but not CD8α/γ2a, could transduce signals, thus providing the first evidence that the cytoplasmic tail of Ig-α and Ig-β have a signaling capacity. After cross-linking with anti-CD8α antibodies, both molecules induced a similar increase in intracellular free calcium ion and in MAP kinase phosphorylation. Protein tyrosine kinases, however, were strongly activated via the CD8α/Ig-α and only marginally via the CD8α/Ig-β molecule. This suggests that the Ig-α and Ig-β proteins have distinct roles during signal transduction through the B cell antigen receptor.     

Differential interaction of the CD2 extracellular and intracellular domains with the tyrosine phosphatase CD45 and the ζ chain of the TCR/CD3/ζ complex

T cell activation via CD2 requires interaction of CD2 with several signaling molecules. To investigate the structural requirements for an association of CD2 with the tyrosine phosphatase CD45 and the ζ chain of the T cell receptor (TCR)/CD3/ζ complex, we have expressed in mouse EL4 T cells a series of human CD2 chimeric and mutant proteins. Chimeric proteins in which the CD2 transmembrane and/or cytoplasmic domains were deleted or exchanged with analogous regions of CD4, CD28 or CD58 retained association with high levels of murine CD45 phosphatase activity, suggesting that the CD2 extracellular domain largely controls interaction with CD45. To a lesser extent, the cytoplasmic domain of CD2 was also shown to interact with CD45, as demonstrated by an increase in co-immunoprecipitated phosphatase activity observed following replacement of the CD58 cytoplasmic domain with that of CD2. In contrast, the cytoplasmic domain of CD2 was found to be responsible for the majority of CD2 interaction with the ζ chain of the TCR/CD3/ζ complex. Deletion of the CD2 cytoplasmic domain, excluding the first three amino acids, removed virtually all CD2 associated ζ chain and approximately sevenfold higher levels of ζ chain were found in association with a CD58/58/2 chimera than with control human CD58 wild type. This study suggests that the CD2 extracellular and intracellular domains are differentially involved in regulating T cell activation through interaction with the tyrosine phosphatase CD45 and the ζ chain of the TCR/CD3/ζ complex.     

Importance of the T cell receptor alpha-chain transmembrane distal region for assembly with cognate subunits

Antigen recognition by alphabeta T lymphocytes is mediated via the multisubunit TCR complex consisting of invariant CD3gamma,delta,epsilon and zeta chains associated with clonotypic TCRalpha and beta molecules. Charged amino acids located centrally within the TCRalpha transmembrane region are necessary and sufficient for assembly with the CD3deltaepsilon heterodimer. Previously, we have shown that deletion of 6-12 amino acids from the carboxy terminus of the TCRalpha-chain dramatically abrogates surface TCR expression, suggesting that the distal portion of the TCRalpha transmembrane region contains information that regulates the assembly and/or intracellular transport of TCR complexes. We have examined in more detail the molecular basis for reduced TCR expression in T cells bearing truncated TCRalpha chains. We found that in contrast to wild-type (wt), variant TCRalpha proteins missing the last nine C-terminal amino acids did not associate with core CD3gamma,delta,epsilon chains and were not assembled into disulphide-linked alphabeta heterodimers. The stability of newly synthesised wt and variant TCRalpha molecules was similar, showing that the abrogated surface TCR expression was not a consequence of impaired protein survival. Nevertheless, truncated TCRalpha chains still assembled with the chaperon protein calnexin in the endoplasmic reticulum, indicating that the distal portion of the TCRalpha transmembrane region is not essential for calnexin interaction. These data document a role for the distal portion of the TCRalpha transmembrane region in the assembly of TCR complexes and provide a molecular basis for reduced TCR expression in cells bearing truncated TCRalpha chains.     

A TCR α chain transgene induces maturation of CD4− CD8− α β+ T cells from γ δ T cell precursors

The proportion of CD4⁻ CD8⁻ double-negative (DN) α β T cells is increased both in the thymus and in peripheral lymphoid organs of TCR α chain-transgenic mice. In this report we have characterized this T cell population to elucidate its relationship to α β and γ δ T cells. We show that the transgenic DN cells are phenotypically similar to γ δ T cells but distinct from DN NK T cells. The precursors of DN cells have neither rearranged endogenous TCRα genes nor been negatively selected by the Mls^a antigen, suggesting that they originate from a differentiation stage before the onset of TCR α chain rearrangements and CD4/CD8 gene expression. Neither in-frame VδDδJδ nor VγJγ rearrangements are over-represented in this population. However, since peripheral γ δ T cells with functional TCRβ gene rearrangements have been depleted in the transgenics, we propose that the transgenic DN population, at least partially, originates from the precursors of those cells. The present data lend support to the view that maturation signals to γ δ lineage-committed precursors can be delivered via TCR α β heterodimers.     

Structure of the T cell receptor in a TiαVβ2,αVβ8-positive T cell line

The T cell receptor (TcR) is composed of at least six different polypeptide chains consisting of the clonotypic Ti heterodimer (Tiαβ or Tiγδ) and the noncovalently associated CD3 chains (CD3γδ?ζ). The exact number of subunits constituting the TcR is still not known; however, it has been suggested that each TcR contains two Ti dimers. To gain insight into the structure of the TcR we constructed a TiαVβ2,αVβ8-positive T cell line which expressed the endogenous human TiVβ8 and the transfected mouse TiVβ2 both in association with the endogenous Tiα and CD3 chains at the cell surface. Preclearing experiments with radioiodinated cell lysate prepared with digitonin lysis buffer demonstrated that depleting the lysate of TiαVβ8 by immunoprecipitation with anti-Vβ8 monoclonal antibody (mAb) did not reduce the amount of TiαVβ2 in the lysate, and likewise, depleting the lysate of TiαVβ2 with anti-Vβ2 mAb did not reduce the amount of TiαVβ8. Comodulation experiments showed that Vβ8 and Vβ2 did not comodulate with each other. Furthermore, functional tests demonstrated that TcR containing Vβ8 and TcR containing Vβ2 mediated transmembrane activation signals independently of each other. These data demonstrate that mouse Vβ2 and human Vβ8 were not expressed in the same TcR in agreement with a TcR model where each TcR contains only one Ti dimer.     

Characterization of T cell receptor assembly and expression in a Ti γδ-positive cell line

Tcell antigen receptor (TcR) heterodimers of both the Ti-αβ and Ti-γδ types are expressed at the surface of T cells noncovalently associated with the CD3 complex composed of the monomorphic chains γ, δ, ε and ξ. The structural relationship and assembly of the various components of this multimeric protein complex is still not fully understood. In this report, the human leukemic Tcell line Lyon which expresses a Ti-γδ/CD3 complex, was characterized and compared to another human leukemic Tcell line Jurkat (Ti-αβ/CD3). Membrane TCR^?/CD3^? variants of the Tcell Lyon were induced and found to produce all of the Ti/CD3 components, with the exception of Ti-δ. Biochemical analysis indicated that: (1) Ti-γ/CD3γ, δ, ε complexes were formed in the endoplasmic reticulum in the absence of Ti-δ; (2) the CD3-ξ chain did not associate with the Ti-γ/CD3γδε complex and (3) the Ti-δ chain was required for cell surface expression of the Ti-γδ/CD3 complex. Introduction of Jurkat wild-type Ti-α cDNA into Lyon T cells resulted in Ti-αβ/CD3 expression and abrogated Ti-γδ/CD3 expression. In contrast, the expression of the Ti-γδ/CD3 complex was not affected by transfection of a mutated Ti-α cDN A into Lyon cells. The mutated Ti-α chain formed complexes with Ti-β and CD3γδε, but the CD3-ξ; chain did not associate with these complexes. Taken together analysis of Lyon cells transfected with either wild-type or mutated Ti-α suggested that the CD3-ξ, chain may have higher affinity for Ti-αβ/CD3 complexes than for Ti-γδ/CD3 complexes.     

N-terminal negatively charged residues in CD3 chains as a phylogenetically conserved trait potentially yielding isoforms with different isoelectric points: Analysis of human CD3 chains

CD3 chains are essential to the structure, expression and signaling of T cell receptors. Here, we extend to human CD3 our previous data in mouse CD3 showing that, in T cells, proteolytic processing of the acidic N-terminal sequence of CD3 chains generate distinct polypeptide species that can be identified by two-dimension (IEF-SDS PAGE) electrophoresis and immunoblot. This was shown first by showing the processing of a fusion protein of GFP and the extracellular domain of mouse CD3 (mCD3GFP) expressed in Jurkat cells. Secondly, pI heterogeneity was also found in human CD3 chains immunoprecipitated from the surface of Jurkat cells or PHA blasts of human blood T lymphocytes.Comparison of CD3 chains from 27 different species shows that their N-terminal sequences share a strong acidic nature, despite the large differences in terms of length and composition, even among closely related species. Our results suggest that generation of CD3 chain isoforms with different N-terminal sequence and pI is a general phenomenon. Thus, as previously observed in the mouse, the relative abundance of CD3 chain species might regulate TCR/CD3 structure and function, including the strength of the interactions between CD3 dimers and the TCR clonotypic receptors, as well as TCR/CD3 activation thresholds.Interestingly, CD3 chains from 7 out of 27 species studied have putative N-glycosylation (NxS or NxT) motifs in their Ig extracellular domain. Their location, plus the conservation of residues involved in domain organization, the interactions with other CD3 chains, or the TCR, and signal triggering add new data useful to establish a permissive topology for the interaction between CD3 dimers and the TCR chains.     

Dissection of the role of CD3gamma chains in profound but reversible T-cell receptor down-regulation

T-lymphocyte activity in the immune system is regulated by the quantity of surface membrane T-cell antigen receptors (TCR). The amount of surface-bound TCR is dependent on the rate of [1] biosynthesis, assembly and intracellular transport of the individual chains composing the TCR/CD3 complex and [2] the internalization and recycling of the receptors. The TCR-ligand interaction augments receptor internalization. In the present paper, we have studied short- and long-term down-regulation of TCR/CD3 complexes with monoclonal anti-TCR/CD3 antibodies, and attempted to determine which component(s) of the TCR/CD3 complex are responsible for these two phenomena. Our data indicate that short- and long-term down-regulation is mediated by different mechanisms, and that the extracellular and/or transmembrane regions of CD3gamma molecules appear to play an important role in chronic TCR/CD3 down-regulation and subsequent deficient re-expression. These results may have important implications for the understanding of induction of T-cell tolerance or anergy.     

CD2-mediated signaling in T cells lacking the ζ-chain-specific immune receptor tyrosine-based activation (ITAM) motif

T lymphocytes can be activated via the T cell receptor (TCR) or by triggering through a number of other surface structures, including the CD2 co-receptor molecule. Signaling through the CD2 molecule was shown previously to be dependent on the TCR-associated ζ-chain. Here, we show that CD2-induced activation also functions in T cells which express ζ-chains lacking a functional immune-receptor tyrosine-based activation motif (ITAM). TCR-positive T cells that express only the transmembrane part of the ζ-chain protein and thus lack a functional ζ-derived ITAM readily produce interleukin (IL)-2 when cross-linked with CD2-specific monoclonal antibodies (mAb). TCR-negative T cell hybridomas expressing minimal receptors consisting of an extracellular CD25 and an intracellular ζ-chain-derived segment were effectively stimulated via CD2-specific mAb. For CD2-mediated co-stimulation of TCR-negative cells, two ζ-chain-derived ITAM were sufficient to induce IL-2 when the CD2 molecules were co-cross-linked with the chimeric CD25-ζ molecules. Taken together, our results show that CD2-induced signaling does not necessarily employ the ζ-chain in TCR-positive cells and that CD2-dependent co-stimulation in TCR-negative cells can be mediated via two functional ζ-chain-derived ITAM.     

The T cell receptor αβ V-J shuffling shows lack of autonomy between the combining site and the constant domain of the receptor chains

In order to assess the structural independence of the T cell receptor (TCR) combining site from the rest of the molecule we have generated two recombinant chains consisting of aTCR V-J α region linked to the Cβ and aTCR V-J β linked to the Cα. If the V and C domains of the TCR form independent domains, as has been shown for the Ig molecules, we would expect to obtain a functional chimeric TCR. Interestingly, it was found that the shuffled molecules are produced intracellularly in T cell hybridomas, but are not expressed on the cell surface. To explain this failure of the shuffled molecules we propose that the TCR has a more compact structure, compared to the Ig, and that it is indispensable to keep a longitudinal inter-domain contact between the V-J and C portion to have a functional molecule.