Flanking V and J sequences of complementary determining region 3 of T cell receptor (TCR) δ1 (CDR3δ1) determine the structure and function of TCRγ4δ1

The γδ T cell receptor (TCR) differs from immunoglobulin and αβ TCR in its overall binding mode. In human, genes δ1, δ2, and δ3 are used for TCRδ chains. Previously, we have studied antigen binding determinants of TCRδ2 derived from dominant γδ T cells residing in peripheral blood. In this study we have investigated the critical determinants for antigen recognition and TCR function in TCRδ1 originated from gastric tumor-infiltrating γδ T lymphocytes using three independent experimental strategies including complementary determining region 3 (CDR3) of TCRδ1 (CDR3δ1)-peptide mediated binding, CDR3δ1-grafted TCR fusion protein-mediated binding, and TCRγ4δ1- and mutant-expressing cell-mediated binding. All three approaches consistently showed that the conserved flanking V and J sequences but not the diverse D segment in CDR3δ1 determine the antigen binding. Most importantly, we found that mutations in the V and J regions of CDR3δ1 also abolish the assembly of TCR and TCR-CD3 complexes in TCRγ4δ1-transduced J.RT3-T3.5 cells. Together with our previous studies on CDR3δ2 binding, our finding suggests that both human TCRδ1 and TCRδ2 recognize antigen predominately via flanking V and J regions. These results indicate that TCRγδ recognizes antigens using conserved parts in their CDR3, which provides an explanation for a diverse repertoire of γδTCRs only recognizing a limited number of antigens.     

Structure and diversity of T-lymphocyte antigen receptors alpha and gamma in Xenopus

Short primer PCR directed at conserved regions of amino acid sequence within the T-cell antigen receptor (TCR) and immunoglobulin (Ig) light chain variable ( V) regions was used to amplify putative TCRgamma V region amplicons from stage 45 Xenopus laevis (African clawed frog) mRNA (cDNA). An adult Xenopus spleen cDNA library was screened using the Vgamma and a putative TCRValpha amplicon. Full copy length cDNAs containing the specific PCR-derived Valpha and Vgamma amplicons were recovered at relatively low frequency. Probes complementing the TCRalpha and TCRgamma constant ( C) regions were employed to isolate equivalent numbers of additional TCR alpha and TCR gamma cDNAs in an unbiased (non- V-based) manner. Few Vgamma genes appear to be expressed relative to the highly diverse expression of V alpha genes in equivalent numbers of cDNAs that were analyzed. Two TCRgamma C regions differ at only two positions; whereas two TCRalpha C regions differ at 33 coding positions as well as in their respective 3' untranslated regions, consistent with two independent loci. However, genomic Southern blots revealed considerably higher numbers of hybridizing bands when probed with C gamma than with C alpha. A potential novel mechanism of diversification is suggested by an unusual TCR alpha cDNA in which the V region can be translated in two frames through utilization of two closely linked V genes and an alternative splicing process. This process produces a translatable cDNA that is not readily predictable from the genomic locus utilizing normal recombination and splicing mechanisms.     

Site-directed mutations in the VDJ junctional region of a T cell receptor beta chain cause changes in antigenic peptide recognition

In order to assess the importance of a conserved amino acid in the VDJ junctional region of the beta chain of T cell receptors (TCRs) specific for pigeon cytochrome c, we generated T cell transfectant clones that express either a TCR identical to that of the cytochrome c-specific clone D6 or a mutated form of the D6 TCR, in which the conserved residue was replaced by one of two other amino acids. We have found that one substitution alters antigen fine specificity, while the other substitution abolishes all detectable cytochrome c response. On the basis of these findings, we propose that this conserved amino acid is a key residue in determining the antigen specificity of the D6 TCR.     

The CD1d natural killer T-cell antigen presentation pathway is highly conserved between humans and rhesus macaques

Natural killer T (NKT) cells play an important role in controlling cancers, infectious diseases and autoimmune diseases. Although the rhesus macaque is a useful primate model for many human diseases such as infectious and autoimmune diseases, little is known about their NKT cells. We analyzed V alpha 24TCR+ T cells from rhesus macaque peripheral blood mononuclear cells stimulated with alpha-galactosylceramide (alpha-GalCer) and interleukin-2. We found that rhesus macaques possess V alpha 24TCR+ T cells, suggesting that recognition of alpha-GalCer is highly conserved between rhesus macaques and humans. The amino acid sequences of the V-J junction for the V alpha 24TCR of rhesus macaque and human NKT cells are highly conserved (93% similarity), and the CD1d alpha1-alpha2 domains of both species are highly homologous (95.6%). These findings indicate that the rhesus macaque is a useful primate model for understanding the contribution of NKT cells to the control of human diseases.     

Amino acid residues in the T cell receptor CDR3 determine the antigenic reactivity patterns of insulin-reactive hybridomas

We examined TCR gene usage in a panel of beef insulin/I-Ad-restricted T cell hybrids obtained from BALB/c mice. These hybrids demonstrated several distinct patterns of reactivity defined by their ability to respond to species variants of insulin. Correlation of TCR-alpha and -beta-gene usage with these patterns of reactivity demonstrated that TCR gene usage was restricted within Ag reactivity groups. In particular, V-J junctional regions (CDR3 equivalent) were restricted with conserved junctional amino acid motifs present in both TCR-alpha- and -beta-chains. Comparison of TCR gene usage in hybrids expressing identical V alpha and V beta gene segments but demonstrating different patterns of reactivity revealed that changes in either J alpha and/or J beta gene segment usage could alter antigenic reactivity. Indeed, single or limited amino acid differences within the CDR3 region were sufficient to markedly alter fine specificity. These data demonstrate the critical role for CDR3 in determining antigenic reactivity in beef insulin-reactive hybrids and are compatible with the current model of TCR/peptide/MHC interaction.     

The isolation and characterization of the murine T cell antigen receptor zeta chain gene

The T cell antigen receptor (TCR) is a multisubunit complex which has a dual function of antigen recognition and signal transduction. One of its invariant subunits, the zeta chain, has been shown to have a significant role in the expression and function of the TCR on the cell surface. The mouse and human zeta cDNAs share significant homologies to each other but are distinct from all of the previously characterized TCR components. We now report the isolation and structural analysis of the complete murine zeta gene. This gene spans at least 31 kilobases and divides into eight exons. The first exon, which is located at least 20 kilobases upstream from the second exon, codes for the 5'-untranslated region and most of the signal peptide. The second exon codes for the remainder of the signal peptide, the extracellular domain, the transmembrane domain, and the first three amino acids of the intracytoplasmic domain. Exons 3-7 encode the majority of the intracytoplasmic domain. The eight exon encodes the carboxyl-terminal 21 amino acids and the 3'-untranslated region. Four groups of mRNA initiation sites have been identified at approximately 140 base pairs upstream to the AUG codon. No TATA-like box has been detected. The gene is localized to the distal part of chromosome 1 in a linkage group highly conserved between man and mouse.     

A T helper cell hybridoma produces an antigen-specific regulatory activity. Relationship to the T cell receptor by serology and antigenic fine specificity.

We have previously shown that a T cell hybridoma, A1.1, constitutively produces an Ag-specific regulatory factor with specificity for poly-18, a synthetic polypeptide. This cell also responds to poly-18 plus I-Ad by producing lymphokines. The antigenic specificity of the factor and the T cell appeared to be the same. This suggested the possibility that some part of the TCR, responsible for antigenic specificity of the cell, also imparts specificity to the A1.1-derived factor. This was supported by the observation that the factor was bound and eluted from a monospecific anti-TCR antiserum. Further, we demonstrated that antisense oligodeoxynucleotides corresponding to the TCR V alpha of A1.1 (but not TCR V beta) block production of the Ag-specific factor. Herein, we report recent findings that strengthen the proposed relationship between the TCR and the A1.1-derived factor. The factor was bound and eluted from a monoclonal anti-TCR C alpha antibody, but not from anti-TCR beta, anti-V beta 6, nor anti-CD3 epsilon. The anti-TCR C alpha antibody bound a Mr 46-kDa protein from A1.1 supernatants, which is the same apparent size at which activity could be eluted from an SDS-PAGE gel separation of concentrated factor. Antigenic fine-specificity analysis revealed that two amino acids in poly-18 are critical for the recognition of the antigen by the Ag-specific factor. These two amino acids appear to be those recognized by the TCR. The factor that was bound and eluted from the monoclonal anti-TCR C alpha showed this fine-specificity as well. This, combined with our earlier studies, supports the view that the A1.1-derived factor is encoded, at least in part, by TCR-alpha.     

Mammalian T-lymphocyte antigen receptor genes: genetic and nongenetic potential to generate variability

Summary T lymphocytes of higher vertebrates are able to specifically recognize a seemingly unlimited number of foreign antigens via their receptors, the T cell antigen receptors (TCRs). T lymphocytes mature by passing through the thymus and acquire antigen specificity by expressing the TCR molecules on their cell surface. Genetic and somatic diversification mechanisms give rise to the enormous degree of TCR variability observed in mature T cells: germline and combinatorial diversity as well as junctional and the so-called N-region diversity. In contrast to the situation in immunoglobulin genes somatic hypermutation does not seem to play a significant role in TCR diversification. It is argued here that the enzyme terminal nucleotidyl-transferase is potentially a major factor in generating the immense diversity. We propose furthermore that this enzyme ensures the flexibility of T cell responses to novel antigens by random insertion of so-called N-region nucleotides. Apart from the physiological functions of TCR genes any involvement in the etiology of T cell neoplasia remains to be proven.     

Rational design of T cell receptors with enhanced sensitivity for antigen

Enhancing the affinity of therapeutic T cell receptors (TCR) without altering their specificity is a significant challenge for adoptive immunotherapy. Current efforts have primarily relied on empirical approaches. Here, we used structural analyses to identify a glycine-serine variation in the TCR that modulates antigen sensitivity. A G at position 107 within the CDR3β stalk is encoded within a single mouse and human TCR, TRBV13-2 and TRBV12-5 respectively. Most TCR bear a S107. The S hydroxymethyl side chain intercalates into the core of the CDR3β loop, stabilizing it. G107 TRBV possess a gap in their CDR3β where this S hydroxymethyl moiety would fit. We predicted based on modeling and molecular dynamics simulations that a G107S substitution would increase CDR3β stability and thereby augment receptor sensitivity. Experimentally, a G107S replacement led to an ～10-1000 fold enhanced antigen sensitivity in 3 of 4 TRBV13-2(+) TCR tested. Analysis of fine specificity indicated a preserved binding orientation. These results support the feasibility of developing high affinity antigen specific TCR for therapeutic purposes through the identification and manipulation of critical framework residues. They further indicate that amino acid variations within TRBV not directly involved in ligand contact can program TCR sensitivity, and suggest a role for CDR3 stability in this programming.     

The T cell receptor V beta 6 domain imparts reactivity to the Mls-1a antigen

A monoclonal antibody secreting hybridoma was established by fusing spleen cells from a rat immunized with a murine T cell clone, OI11, which has I-Ab restricted specificity for the male H-Y antigen and unrestricted specificity for the minor lymphocyte stimulating antigen, Mls-1a, to the mouse myeloma P3X63AG8.653 and screening for the capacity of the hybridoma supernatants to stimulate the OI11 T cell clone. An antibody (RR4-7) was found to be specific not only for the immunizing T cell clone but virtually for all T cells using the V beta 6 TCR gene product as part of their surface antigen receptor. When the expression of the V beta 6 gene in various strains of mice was analyzed, it was found that strains expressing the Mls-1a antigen contained few T cells expressing V beta 6-encoded TCRs. The majority of T cell hybridomas which expressed V beta 6-encoded TCRs were found to be reactive to the Mls-1a antigen. These data confirm the finding of H. R. MacDonald et al. (Nature (London) 332, 40, 1988) that most TCRs encoded by the V beta 6 gene have a biased specificity for the Mls-1a antigen.     

The evolution of vertebrate antigen receptors: a phylogenetic approach

Classical T cells, those with alpha beta T-cell receptors (TCRs), are an important component of the dominant paradigm for self-nonself immune recognition in vertebrates. alpha beta T cells recognize foreign peptide antigens when they are bound to MHC molecules on the surfaces of antigen-presenting cells. gamma delta T cells bear a similar receptor, and it is often assumed that these T cells also require specialized antigen-presenting molecules for immune recognition, which we term "indirect antigen recognition." B-cell receptors, or immunoglobulins, bind directly to antigens without the help of a specialized antigen-presenting molecule. Phylogenetically, it has been assumed that T-cell receptors and the genes that encode them are a monophyletic group, and that "indirect" antigen recognition evolved before the split into two types of TCR. Recently, however, it has been proposed that gamma delta-TCRs bind directly to antigens, as do immunoglobulins (Ig's). This calls into question the null hypothesis that indirect antigen recognition is a common characteristic of TCRs and, by extension, the hypothesis that all TCR gene sequences form a monophyletic group. To determine whether alternative explanations for antigen recognition and other historical relationships among TCR genes might be possible, we performed phylogenetic analyses on amino acid sequences of the constant and variable regions which encode the basic subunits of TCR and Ig molecules. We used both maximum-parsimony and genetic distance-based methods and could find no strong support for the hypothesis of TCR monophyly. Analyses of the constant region suggest that TCR gamma or delta sequences are the most ancient, implying that the ancestral immune cell was like a modern gamma delta T cell. From this gamma delta-like ancestor arose alpha beta T cells and B cells, implying that indirect antigen recognition is indeed a derived property of alpha beta-TCRs. Analyses of the variable regions are complicated by strong selection on antigen-binding sequences, but imply that direct antigen binding is the ancestral condition.     

Endowing T cells with antibody specificity using chimeric T cell receptors.

T cells recognize antigen in the form of a peptide associated with a cell surface molecule encoded by the major histocompatibility gene complex (MHC). The elaborate requirements for the T cell receptor (TCR)-antigen interaction stand in contrast to the simple and defined nature of the antigenic determinants recognized by antibodies. The similarity in the molecular structure and gene organization between antibodies and the TCR has prompted attempts to interchange the antigen-binding, variable regions of these molecules. To this end, chimeric TCR (cTCR) genes, composed of the variable domains of antibodies linked to TCR constant regions, have been used to confer antibody-type specificity on T cells. cTCR-expressing T cells respond to stimulator cells as well as to immobilized antigen in an MHC unrestricted and independent manner. The antibody-like specificity of the resulting T cells has been exploited, using defined ligands, to elucidate the physicochemical parameters that govern TCR-mediated signaling, and to provide a useful experimental system to study the role of MHC and cell-adhesion/accessory molecules in T cell activation. The successful expression of such cTCR in transgenic mice opens new avenues to explore the role of the MHC in T cell development and maturation. Eventually, chimeric receptors specific to tumor or viral antigens might be used for in vivo targeting of T cells in the framework of immuno- and gene therapy.     

Transmembrane helical interactions: zeta chain dimerization and functional association with the T cell antigen receptor.

Members of the zeta family of receptor subunits (zeta, eta and gamma) are structurally related proteins found as components of the T cell antigen receptor (TCR) and certain Fc receptors. These proteins share the ability to form disulfide-linked dimers with themselves and with other members of the family. Comparison of the amino acid sequences of zeta and gamma reveals a significant degree of homology, which is highest within their membrane-spanning domains. Analysis of their transmembrane sequences on a helical wheel projection suggests that all of the identical amino acids are clustered on one face of a potential alpha-helix. This face contains the only cysteine residue within zeta, suggesting that this conserved region may function to mediate dimerization. Indeed, replacing the transmembrane domain of the Tac antigen (alpha chain of the interleukin-2 receptor) by that of the zeta chain resulted in the formation of disulfide-linked dimers of Tac. The conserved aspartic acid residue found in the zeta and gamma transmembrane sequences was found to play a role in disulfide linkage. Replacing the aspartic acid with a lysine but not with an alanine or valine residue allowed formation of disulfide-linked dimers. The ability of the aspartic acid residue to support dimerization was dependent upon its position within the helix. Thus, these observations indicate that residues within the zeta transmembrane domain play a critical role in the formation of disulfide-linked dimers. Expression of zeta mutants in zeta-deficient T cells revealed that the zeta transmembrane domain is also responsible for reconstituting transport of functional TCR complexes to the cell surface and differentiated the requirements for disulfide-linked dimerization per se from assembly of the TCR complex.     

Restricted V-(D)-J junctional regions in the T cell response to lambda-repressor. Identification of residues critical for antigen recognition.

The T cell response to lambda-repressor is directed to a 15 amino acid peptide (P12-26) of the protein in A/J mice. Previous studies have demonstrated a preferential use of V alpha 2 and V beta 1 amongst the T cell hybridomas specific for P12-26 in the context of I-Ek. By using the polymerase chain reaction, the sequences of a panel of the T cells using V alpha 2 and V beta 1 were determined. A highly conserved alpha-chain V-J junctional sequence was found in six of the eight T cell hybrids. This consensus alpha-chain VJ sequence may be combined with different members of V alpha 2, indicating a more restricted selection on the junctional region than on the V element in these T cells. In contrast, greater diversities were found on the V-D-J region of beta-chains despite the same V beta 1 and J beta 2.1 were used. However, a highly conserved glutamic acid residue was found at the same position of beta-chains where a similar conservation was identified in cytochrome c-specific T cells. The correlation of the TCR sequence with the fine specificities of these T cells suggests that a single amino acid deletion in the V alpha-J alpha region may reduce the P12-26 response and abolish the recognition of an altered peptide [Phe22] P12-26. In addition, three amino acid difference in the V-D-J region of the beta-chain also determine the P12-26 reactivity. Thus the V(D)J junctional regions of both alpha- and beta-chains may be critical for the recognition of the peptide Ag presented by the specific MHC molecule.     

The membrane proximal proline-rich region and correct order of C-terminal tyrosines on the adaptor protein LAT are required for TCR-mediated signaling and downstream functions

The primary activating receptor for T cells is the T cell receptor (TCR), which is stimulated upon binding to an antigen/MHC complex. TCR activation results in the induction of regulated signaling pathways vital for T cell differentiation, cellular adhesion and cytokine release. A critical TCR-induced signaling protein is the adaptor protein LAT. Upon TCR stimulation, LAT is phosphorylated on conserved tyrosines, which facilitates the formation of multiprotein complexes needed for propagation of signaling pathways. Although the role of the conserved tyrosines in LAT-mediated signaling has been investigated, few studies have examined the role of larger regions of LAT in TCR-induced pathways. In this study, a sequence alignment of 97 mammalian LAT proteins was used to identify several “functional” domains on LAT. Using LAT mutants expressed in Jurkat E6.1 cells, we observed that the membrane proximal, proline-rich region of LAT and the correct order of domains containing conserved tyrosines are necessary for optimal TCR-mediated early signaling, cytokine production, and cellular adhesion. Together, these data show that LAT contains distinct regions whose presence and correct order are required for the propagation of TCR-mediated signaling pathways.     

The versatility of the αβ T‐cell antigen receptor

The T‐cell antigen receptor is a heterodimeric αβ protein (TCR) expressed on the surface of T‐lymphocytes, with each chain of the TCR comprising three complementarity‐determining regions (CDRs) that collectively form the antigen‐binding site. Unlike antibodies, which are closely related proteins that recognize intact protein antigens, TCRs classically bind, via their CDR loops, to peptides (p) that are presented by molecules of the major histocompatibility complex (MHC). This TCR‐pMHC interaction is crucially important in cell‐mediated immunity, with the specificity in the cellular immune response being attributable to MHC polymorphism, an extensive TCR repertoire and a variable peptide cargo. The ensuing structural and biophysical studies within the TCR‐pMHC axis have been highly informative in understanding the fundamental events that underpin protective immunity and dysfunctional T‐cell responses that occur during autoimmunity. In addition, TCRs can recognize the CD1 family, a family of MHC‐related molecules that instead of presenting peptides are ideally suited to bind lipid‐based antigens. Structural studies within the CD1‐lipid antigen system are beginning to inform us how lipid antigens are specifically presented by CD1, and how such CD1‐lipid antigen complexes are recognized by the TCR. Moreover, it has recently been shown that certain TCRs can bind to vitamin B based metabolites that are bound to an MHC‐like molecule termed MR1. Thus, TCRs can recognize peptides, lipids, and small molecule metabolites, and here we review the basic principles underpinning this versatile and fascinating receptor recognition system that is vital to a host's survival.     

Restricted usage of T cell receptor V alpha/J alpha gene segments with different nucleotide but identical amino acid sequences in HLA-DR3+ sarcoidosis patients.

BACKGROUND: Sarcoidosis is a granulomatous disease characterized by the accumulation of activated T cells in the lungs. We previously showed that sarcoidosis patients expressing the HLA haplotype DR3(17),DQ2 had increased numbers of lung CD4+ T cells using the T cell receptor (TCR) variable region (V) alpha 2.3 gene segment product. In the present study, the composition of both the TCR alpha- and beta-chains of the expanded CD4+ lung T cells from four DR3(17),DQ2+ sarcoidosis patients was examined. MATERIALS AND METHODS: TCR alpha-chains were analyzed by cDNA cloning and nucleotide sequencing. TCR beta-chains were analyzed for V beta usage by flow cytometry using TCR V-specific monoclonal antibodies or by the polymerase chain reaction (PCR) using V beta- and C beta-specific primers. J beta usage was analyzed by Southern blotting of PCR products and subsequent hybridization with radiolabeled J beta-specific probes. RESULTS: Evidence of biased J alpha gene segment usage by the alpha-chains of V alpha 2.3+ CD4+ lung T cells was found in four out of four patients. Both different alpha-chain nucleotide sequences coding for identical amino acid sequences and a number of identically repeated alpha-chain sequences were identified. In contrast, the TCR beta-chains of FACS-sorted V alpha 2.3+ CD4+ lung T cells were found, with one exception, to have a nonrestricted TCR V beta usage. CONCLUSIONS: The finding of V alpha 2.3+ CD4+ lung T cells with identical TCR alpha-chain amino acid sequences but with different nucleotide sequences strongly suggests that different T cell clones have been selected to interact with a specific sarcoidosis associated antigen(s). The identification of T cells with restricted TCR usage, which may play an important role in the development of sarcoidosis, and the possibility of selectively manipulating these cells should have important implications for the treatment of the disease.     

Antigen Specificity of �æ� T Cells Depends Primarily on the Flanking Sequences of CDR3��

The structural basis that determines the specificity of γδ T cell receptor (TCR) recognition remains undefined. Our previous data show that the complementary determining region of human TCRδ (CDR3δ) is critical to ligand binding. Here we used linear and configurational approaches to examine the roles of V, N-D-N, or J regions in CDR3δ-mediated antigen recognition. Surprisingly, we found that the binding activities of CDR3δ from different γδ TCRs to their target tissues and ligands depend on the conserved flanking sequences (V and J) but not as much on the D region of CDR3δ fragment. We further defined the key residues in the V and J regions of CDR3δ fragments, including the cysteine residue in the V fragment and the leucine residue in the J fragment that determine their ligand binding specificity. Our results demonstrate that TCRδ primarily uses conserved flanking regions to bind ligands. This finding may provide an explanation for the limited number of γδ TCR ligands that have as yet been identified.Extensive studies suggest that γδ T cells play important roles in host defense against microbial infections, monitoring of tumorigenesis, immunoregulation, and development of autoimmunity (1–3). However, little is known about the structural basis of antigenic recognition by γδ T cell receptor (TCR)³ because of the limited identified specific ligands for γδ TCR and the lack of structural information revealing how γδ TCR might interact with such ligands.The crystallographic structure of a murine γδ TCR in complex with major histocompatibility complex class (MHC) Ib T22 (4, 5) showed that the CDR loops οf γδ TCR, predominantly germline-encoded residues of the complementary determining region of human TCRδ (CDR3δ), are in direct contact with T22, suggesting that the primary sequence of CDR3 in γδ TCR, especially CDR3δ, serves as a key determinant for the specificity of antigen recognition. Our recent finding that CDR3δ peptide mimics human γδ TCR binding to tumor cells and tissues is consistent with the role of CDR3δ in γδ TCR recognition (6).Based on this finding, we used synthesized CDR3δ peptide as a probe to screen putative protein ligands in tumor protein extracts by affinity chromatography analysis. With this novel strategy, we have successfully identified seven tumor-related epitopes, two hepatitis B virus (HBV) infection-related antigenic epitopes, and two self proteins including heat shock protein (HSP) 60 and human mutS homolog 2 (hMSH2) that are recognized by human γδ TCR (7). These results further support that the primary sequence of CDR3δ in γδ TCR determine the specificity of antigen binding.CDR3δ is composed of fragments derived from V, N-D-N, and J gene segments. The flanking sequences composed of V and J fragment is conserved while N-D-N region is diverse. The diversity of γδ TCRs is supposedly higher than that of TCRαβ due to the link of D gene fragment and the insertion of nucleotide acids (8). However, the number of identified antigenic ligands recognized by γδ TCR remains very limited. It has been demonstrated that γδ TCR recognizes some protein antigens and small phosphate or amine-containing compounds, including nonclassical MHC class I molecule T22 and T10 in mice (9), UL-16-binding protein (ULBP) (10) and mitochondrial F1-ATPase in humans (11). Nevertheless, important questions regarding γδ TCR recognition remain to be addressed. For example, given the seemingly high diversity of γδ TCR, why have only limited antigenic ligands been identified? What are the contributions of individual fragments of CDR3δ to antigen recognition? In αβ TCR, a single mutation in D gene fragment (12) abolishes its antigenic recognition, whereas the contribution of the different fragments in γδ TCR recognition remain unknown. Answers to these questions will shed important insights to antigen recognition of γδ T cells.In this study, we investigated the contribution of individual fragments of CDR3δ in antigen recognition. We mutated V, N-D-N, or J fragments of a Vδ2 TCR CDR3 sequence (OT3) in peptide and engineered γδ TCR. We found that the conserved flanking regions of CDR3δ play a critical role in antigenic binding to OEC cells/tissues or hMSH2 protein, a new ligand for γδTCR we found recently (7). Furthermore, we have identified the cysteine residue in V fragment and the leucine residue in J fragment as critical residues in the binding activity of γδ TCR. These results demonstrate that TCRδ chain uses the conserved flanking regions to recognize their antigens, suggesting that ligands for γδ ΤCR may also be conserved and limited in number.     

The human T cell antigen receptor is encoded by variable, diversity, and joining gene segments that rearrange to generate a complete V gene

A cDNA clone YT35 , synthesized from poly(A)+ RNA of the human T cell tumor Molt 3, exhibits homology to the variable (V), joining (J), and constant (C) regions of immunoglobulin genes. We have isolated and sequenced the germ-line V and J gene segment counterparts to YT35 from a human cosmid library, and these failed to encode 14 nucleotides of the cDNA clone between the V and J regions. We postulate that these 14 nucleotides are encoded by a third gene segment analogous to the diversity (D) gene segments of immunoglobulin heavy chain genes. This T cell antigen receptor V gene appears to be assembled from three gene segments, V, D, and J, and accordingly most closely resembles immunoglobulin heavy chain V genes.     

Molecular analysis of TCR and peptide/MHC interaction using P18-I10-derived peptides with a single D-amino acid substitution

For the structural analysis of T-cell receptor (TCR) and peptide/MHC interaction, a series of peptides with a single amino acid substitution by a corresponding D-amino acid, having the same weight, size, and charge, within P18-I10 (aa318-327: RGPGRAFVTI), an immunodominant epitope of HIV-1 IIIB envelope glycoprotein, restricted by the H-2Dd class I MHC molecule, has been synthesized. Using those peptides, we have observed that the replacement at positions 324F, 325V, 326T, and 327I with each corresponding D-amino acid induced marked reduction of the potency to sensitize targets for P18-I10-specific murine CD8+ cytotoxic T lymphocytes (CTLs), LINE-IIIB, recognition. To analyze further the role of amino acid at position 325, the most critical site for determining epitope specificity, we have developed a CTL line [LINE-IIIB(325D)] and its offspring clones specific for the epitope I-10(325v) having a D-valine (v) at position 325. Taking advantage of two distinct sets of CD8+ CTLs restricted by the same Dd, three-dimensional structural analysis on TCR and peptide/MHC complexes by molecular modeling was performed, which indicates that the critical amino acids within the TCRs for interacting with 325V or 325v appear to belong to the complementarity-determining region 1 but not to the complementarity-determining region 3 of Vbeta chain.