Peripheral blood T lymphocytes in systemic vasculitis: increased T cell receptor Vβ2 gene usage in microscopic polyarteritis

Antigen recognition by T lymphocytes is mediated by cell surface receptors. T cell specificity depends on the variable, diversity and junctional (VDJ) regions of the α and β polypeptide chains of the T cell receptor (TCR). The expression of the variable region genes of the β chain (Vβ) has been analysed to study the involvement of peripheral blood T cells in systemic vasculitis. RNA was extracted from peripheral blood lymphocytes of 12 patients with microscopic polyarteritis, 10 with Wegener's granulomatosis, six with unclassified vasculitis, and 28 healthy age- and sex-matched individuals. Complementary DNA was made from RNA and amplified by the anchored polymerase chain reaction (PCR) using redundant oligonucleotide primers for the TCR Vβ genes. To determine if the dominant usage of a Vβ gene family reflected the presence of particular T cell clones, cDNA was amplified with primers for the specific Vβ gene family. The product was screened for sequence homogeneity by single-stranded conformational polymorphism (SSCP) and cloned to sequence the adjoining TCR (Dβ)Jβ region. A significant increase in the mean percentage expression of the Vβ 2.1 gene was seen in vasculitis patients (11·4+1·0% (mean + s.e.m.)) compared with controls (6·6 + 0·6%; P < 0·003). The most marked increase was seen in microscopic polyarteritis (13·9 + 1·7%; P < 0·0001). There were also increases in the expression of Vβ3, 13 and 14 in peripheral blood of vasculitis patients compared with controls. SSCP analysis of Vβ 2.1 amplified products indicated the presence of oligoclonal bands in a smaller proportion of patients (8/27) than controls (12/28). There was no strong evidence for the conservation of the TCR Vβ 2.1 junctional region sequence data from a sample group of three patients with oligoclonal bands. Thus, a subset of patients with systemic vasculitis, particularly those with microscopic polyarteritis, have increased TCR Vβ 2.1 gene expression in their peripheral blood T cell repertoire. As superantigens binding Vβ 2.1 are postulated to activate T cells with diverse CDR3 sequences, it is proposed that a superantigen is involved in the immunopathogenesis of vasculitis.     

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.     

Vα domain modulates the multiple topologies of mouse T cell receptor Vβ20/staphylococcal enterotoxins A and E complexes

The superantigens staphylococcal enterotoxin A and E (SEA and SEE) both contact major histocompatibility complex (MHC) class II molecules on two sites located on the α and β chains. We have investigated the role of the T cell receptor (TCR) α chain in the modulation of the various topologies of TCR/SEA (or SEE)/class II complexes. For this purpose, we have used three mouse Vβ20 T cell lines expressing different Vα domains and two T cell hybridomas expressing mouse Vβ1 or Vβ11 segments. The response of these T cells to SEA and SEE was studied in the context of presentation by wild-type human MHC class II molecules; or by mutants on MHC, in each of the two superantigen binding sites (position α39K and β81H) to which the superantigens can still bind but with an altered conformation. Although Vβ20 T cell lines are efficiently stimulated using SEA and SEE presented by wild-type HLA-DR1 molecules, our results show that the nature of the TCR Vα domain can affect differently the recognition of the toxins bound to mutant class II molecules. This suggests that various functional topologies exist for both SEA and SEE/class II complexes and that the T cell response to each of these complexes can be modulated by the Vα domain of the TCR. Interestingly, the recognition of SEA and SEE is achieved in different fashions by a given Vβ20 T cell line.     

A Public T cell Receptor Recognized by a Monoclonal Antibody Specific for the D‐J Junction of the β‐chain

It is becoming increasingly clear that T cell responses against many antigens are dominated by public α/β T cell receptors (TCRs) with restricted heterogeneity. Because expression of public TCRs may be related to resistance, or predisposition to diseases, it is relevant to measure their frequencies. Although staining with tetrameric peptide/major histocompatibility complex (pMHC) molecules gives information about specificity, it does not give information about the TCR composition of the individual T cells that stain. Moreover, next‐generation sequencing of TCR does not yield information on pairing of α‐ and β‐chains in single T cells. In an effort to overcome these limitations, we have here investigated the possibility of raising a monoclonal antibody (moAb) that recognizes a public TCR. As a model system, we have used T cells responding to the 91–101 CDR3 peptide of an Ig L‐chain (λ2³¹⁵), presented by the MHC class II molecule I‐E^d. The CD4⁺ T cell responses against this pMHC are dominated by a receptor composed of Vα3Jα1;Vβ6DβJβ1.1. Even the V(D)J junctions are to a large extent shared between T cell clones derived from different BALB/c mice. We here describe a murine moAb (AB10) of B10.D2 origin that recognizes this public TCR, while binding to peripheral T cells is negligible. Binding of the moAb is abrogated by introduction of two Gly residues in the D‐J junction of the CDR3 of the β‐chain. A model for the public TCR determinant is presented.     

Shared amino acid sequences in the NDβN and Nα regions of the T cell receptors of tumor-infiltrating lymphocytes within malignant glioma

The purpose of this study was to assess the V-(D)-J junctional region of the T cell receptor (TCR), the CDR3 region, which is responsible for glioma-specific antigen contact in αβ TCR-mediated recognition. We sequenced the TCR α and β chians of Vα7, and Vβ13.1 cDNA derived from tumor-infiltrating lymphocytes (TIL) of 12 glioma patients and also the corresponding clones from the patients' peripheral blood lymphocytes (PBL). A shared Vβ13.1 DJ sequence of the CDR3 region, NDβN, was demonstrated in 49 of 66 Vβ13.1⁺ clones (74.2 %) from the glioma TIL, whereas only 4 of 33 clones (12.1 %) were observed in the Vβ13.1⁺ clones from the PBL (p < 0.001). A common VDJ sequence, FCASS (Vβ13.1)-YRLPWGTSDS (NDβN)-GELFF(Jβ2.2), was observed not only in the gliomas from each patient, but also among all the patients with a preference for Vβ13.1. In contrast, the amino acid sequences of the Vβ13.1⁺ PBL clones were diverse and random. Next, we sequenced subclones from other Vβ subfamilies randomly selected to compare their VDJ region rearrangements (Vβ3 and Vβ5.1). In contrast to Vβ13.1, the amino acid sequences of these junctional regions were completely different in these subclones. The V-J junctional region of the α chain is dominated by a few clones in some patients, and no shared amino acid sequences were detected in the TCR Vα junctional region. However, in the Nα region of the Vα7-bearing TIL clones, arginine was used in 27 of 44 clones (61.4%) compared to only 3 of 12 clones from the PBL (p < 0.05). These results are consistent with the hypothesis that a clonal expansion/accumulation of glioma lineage-specific T cells occurred in vivo at the tumor site and that these T cells may be recognizing glioma-specific antigens.     

T cell receptor-γδ-expressing fetal mouse thymocytes are generated without T cell receptor Vβ selection

We investigated whether fetal mouse T cell receptor (TCR) γδ cells have been subjected to so-called TCRβ selection at the CD25 stage of thymus development. To this end, we carried out a comparative three-color flow microfluorimetric analysis of TCRβδ cells developing in the fetal, neonatal and adult thymus using monoclonal antibodies to CD2, CD8, CD24, CD25 and CD44. Day-15 fetal TCRγδ cells were CD2⁺, suggesting an origin at a post-CD25 stage. Molecular analysis of TCRβ rearrangements were also carried out. Thus, by semi-quantitative polymerase chain reaction (PCR) amplification of Vβ6 and Vβ8 to Jβ2 rearrangements day-15 fetal TCRγδ showed extensive TCRβ rearrangements, a finding confirmed by PCR amplification from single micromanipulated cells. Finally, sequencing analysis of 104 PCR-amplified TCR VDJβ2 fragments showed that the majority (58%) were rearranged out of frame. Taken together, these phenotypic and molecular analyses suggest that fetal TCRγδ cells have not been subject to TCRβ selection.     

Analysis of TCR β chains in Lewis rats with experimental allergic encephalomyelitis. II. Vβ8.2+ T cells with limited CDR3 N region additions derive from the adult thymus

Immunization of Lewis (LEW) rats with guinea pig myelin basic protein (MBP) induces a population of encephalitogenic CD4 T cells having specificity for the dominant immunogenic peptide of MBP, 68 – 86. The TCR β chains of these disease-causing T cells show three distinct features: they are almost exclusively Vβ8.2, they use AspSer as the first two amino acid residues of the third complementarity-determining region (CDR3) and these junctional region sequences show few if any non-germline N-region nucleotide additions. This last feature raises the possibility that these autoimmune T cell precursors derive from TCR gene rearrangements occurring during early, perinatal ontogeny, a period when the enzyme terminal deoxynucleotidyl transferase (TdT), responsible for N region additions, is not expressed. An alternative possibility is that these features of the TCR of MBP 68 – 86-reactive T cells are dictated by considerations of antigen selection throughout ontogeny both in the thymus and in the periphery – i.e., that such β chains are conformationally the most appropriate for triggering by an epitope of 68 – 86 complexed to class II RT1.B^l MHC molecules. We show here that active experimental allergic encephalomyelitis, while delayed in onset, occurs in heavily irradiated animals, but not in the absence of a thymus, a finding indicating that this autoimmune disease is caused by a T cell subpopulation derived from the post-irradiation adult thymus. These disease-causing T cells are heavily Vβ8.2⁺ , CDR3 AspSer⁺ and use few N region additions. We conclude that T cells with these TCR β chain features can be generated in the adult thymus and most likely reflect requirements imposed by antigen selection.     

TCR β PCR from crude preparations for restriction digest or sequencing

T cell specificity is determined by the combinatorial association of specific variable (V), diversity (D), and junctional (J) regions. Clones of T cells (clonality) can occur, in the blood or in tissue, after proliferation of activated T cells. Determining clonality in mutation assays is necessary to distinguish between mutants and mutational events. We have developed a novel approach to determine clonality among T cell isolates, using restriction digests of PCR-amplified cDNA of the T cell receptor β gene. The T cell receptor β gene was PCR-amplified by use of a consensus primer, beginning from a cell pellet of 2,000–5,000 cells or from extracted RNA. This TCR (T cell receptor) β chain PCR product can also be directly sequenced, allowing simple and easy identification of Vβ and CDR3 sequence from a small number of cells. The utility of this method is demonstrated by PCR, restriction digest, and sequencing of the TCR β cDNA from eight T cell clones isolated from 2 individuals. A clone of three identical isolates (one 3-mer) and a clone of two identical isolates (one 2-mer) were determined from restriction digests using two different enzymes. This new method is an easier and more rapid way of determining clonality than traditional methods, e.g., Southern blotting. © 1996 Wiley-Liss, Inc.     

Role of the T cell receptor α-chain in superantigen recognition

Superantigens bind to antigen-presenting cells on the outside of the major histocompatibility complex (MHC) class II molecule and to T cells via the external face of the T cell receptor (TCR) Vβ element. As a consequence, superantigens stimulate populations of T cells in a Vβ-specific, non-MHC-restricted manner. However, accumulating evidence has shown an additional contribution of the TCR α-chain and polymorphic residues of the MHC molecule to superantigen recognition by some T cells. These data suggest that the TCR and MHC come into contact during superantigen engagement and indirectly modulate the superantigen reactivity. Thus, additional interactions between non-Vβ elements of the TCR and MHC play a role in the overall stability of the superantigen/MHC/TCR complex, explaining the influence of the TCR α-chain. It is likely that this additional interaction is of greater consequence for weakly reactive T cells. This modulation of superantigen reactivity in individual T cells may have physiological consequences, for example, in the induction of autoimmunity.     

Analysis of T cell receptor Vβ diversity in peripheral CD4+ and CD8+ T lymphocytes in patients with autoimmune thyroid diseases

Autoimmune thyroid diseases are characterized by intrathyroidal infiltration of CD4⁺ and CD8⁺ T lymphocytes reactive to self‐thyroid antigens. Early studies analysing T cell receptor (TCR) Vα gene usage have shown oligoclonal expansion of intrathyroidal T lymphocytes but not peripheral blood T cells. However, TCR Vβ diversity of the isolated CD4⁺ and CD8⁺ T cell compartments in the peripheral blood has not been characterized fully in these patients. We performed complementarity‐determining region 3 (CDR3) spectratyping as well as flow cytometric analysis for the TCR Vβ repertoire in peripheral CD4⁺ and CD8⁺ T cells from 13 patients with Graves' disease and 17 patients with Hashimoto's thyroiditis. Polyclonal TCR Vβ repertoire was demonstrated by flow cytometry in both diseases. In contrast, CDR3 spectratyping showed significantly higher skewing of TCR Vβ in peripheral CD8⁺ T cells but not CD4⁺ T cells among patients with Hashimoto's thyroiditis compared with healthy adults. We found trends towards a more skewed CDR3 size distribution in those patients having disease longer than 5 years and requiring thyroid hormone replacement. Patients with Graves' disease exhibited no skewing both in CD4⁺ and CD8⁺ T cells. These findings indicate that clonal expansion of CD8⁺ T cells in Hashimoto's thyroiditis can be detected in peripheral blood and may support the role of CD8⁺ T cells in cell‐mediated autoimmune attacks on the thyroid gland in Hashimoto's thyroiditis.     

T cell receptor β chain dimers on immature thymocytes from normal mice

During T cell development the T cell receptor (TCR) β chain is expressed before the TCRα chain. Experiments in TCRβ transgenic severe combined immune deficiency (SCID) mice have shown that the TCRβ protein can be expressed on the cell surface of immature thymocytes in the absence of the TCRα chain and that the TCRβ protein controls T cell development with regard to cell number, CD4/CD8 expression and allelic exclusion of the TCRβ chain. Subsequent experiments have shown that on the surface of thymocytes fromTCRβ transgenic SCID mice the TCRβ protein can be expressed in a monomelic and dimeric form whereas only the dimeric form was found on the surface of a TCRβ-transfected, immature T cell line. The results presented here show that normal thymocytes from 16-day-old fetuses likewise express only the dimeric form and that the monomelic form on the surface of thymocytes from transgenic mice results from glycosyl phosphatidylinositol linkage. Our results show for the first time that under physiological conditions a TCRβ dimer can be expressed on the cell surface without the TCRα chain.     

Systematic study of human αβ T cell receptor V segments shows allelic variations resulting in a large number of distinct T cell receptor haplotypes

The variation of the αβ T cell receptor (TCR) results mainly from rearrangements of germ-line V, D and J elements combined with the processes of N- and P-region addition. In addition to this extensive diversity, diallelic polymorphism is also recognized in V regions of β loci. Four such polymorphisms have previously been defined, but the full extent of such variation has not yet been established. To investigate allelic polymorphism, we used a strategy based on V locus-specific polymerase chain reaction and single-strand conformation polymorphisms. Studying the two Vβ 2 loci and the Vα8.1 locus, we found that all exhibited a coding polymorphism. One of the Vβ 2 loci proved to be the first multiallele segment to be recognized, with three common variants. The second Vβ 2 locus, for which none of the two alleles has been identified in cDNA, appeared in fact to be a Vβ orphon, in abnormal location on the chromosome 9. A yeast artificial chromosome containing part of the TCRB locus allowed us to place the first Vβ 2 segment on the known map to define haplotypes with two other polymorphic segments: Vβ 1 and Vβ 6.7. Multiple distinct haplotypes result from combinations between these polymorphic loci, showing that Vβ regions are highly variable between individuals. Two alleles exist at the Vα8.1 segment and both are expressed. This represents the first example of a frequent coding polymorphism for TCRA gene. The distribution of allele frequencies for these segments suggest the action of balancing selection. These data add a further dimension to TCR polymorphism and suggest new candidates to explore TCR-encoded susceptibility to autoimmune diseases.     

The hypervariable region 4 (HV4) and position 93 of the α chain modulate CD1d‐glycolipid binding of iNKT TCRs

TCRs of invariant NKT (iNKT) cells bind α‐galactosylceramide (αGC) loaded CD1d in a highly conserved fashion and show a characteristic TCR gene usage: An “invariant” α chain with a canonical AV14/AJ18 rearrangement in mice (AV24/AJ18 in humans) is paired with β chains containing characteristic Vβ segments. In the rat, a multimember AV14 gene family increases the variability within this system. This study characterizes CD1d binding of rat AV14 gene segments in TCR transductants as well as CD1d binding and iNKT TCR expression of expanded polyclonal F344 rat iNKT populations. It defines an important role of position 93 at the V‐J transition for TCR avidity and species cross‐reactivity of the rat iNKT TCR. Furthermore, for the first time we identified variability within the fourth hypervariable loop (HV4) of the α chain as a modulator of CD1d:αGC binding in rat and mouse. Additionally, we confirmed the importance of the CDR2β for CD1d:αGC binding, but also show that the CDR3β may even have opposite effects on binding depending on the pairing α chain. Altogether, we characterized naturally occurring sources of variability for the iNKT TCR and speculate that they rather level than increase the largely germline encoded differences of iNKT TCR ligand avidity.     

Evidence for the persistence of monoclonal expansions of CD8+ T cells following primary simian immunodeficiency virus infection

A longitudinal study of the CD8⁺ TCR variable (Vβ) chain repertoire was performed in rhesus macaques experimentally infected with simian immunodeficiency virus (SIV) using both TCR Vβ chain-specific monoclonal antibodies and TCR β chain CDR3 length analysis. Expansions of subpopulations of CD8⁺ T cells were detected during the acute phase of SIV infection. In all monkeys studied, monoclonal expansions persisted for at least 18 months and increasingly dominated the repertoire of CD8⁺ T cells expressing the relevant Vβ chain. This study shows that persistent CD8⁺ T cell expansions develop in response to a virus infection. This is important not only for our understanding of the T cell response to viruses but also for understanding the factors that determine the normal CD8⁺ TCR repertoire.     

Amplification of TCRβ gene rearrangements from micromanipulated single cells: T cells rosetting around Hodgkin and Reed-Sternberg cells in Hodgkin's disease are polyclonal

Despite accounting for only a minor fraction of all cells in Hodgkin's lymphoma tissue, the Hodgkin and Reed-Sternberg (HRS) cells represent the malignant tumor cell clone in Hodgkin's disease (HD). By far the most abundant cell type in the tumor tissue are CD4⁺ T cells. Some of them intimately associate with HRS cells forming rosettes around them. This study addresses the question whether the rosetting phenomenon reflects a specific interaction between T and HRS cells by asking whether the rosettes are composed of T cells expressing a restricted TCR repertoire. Single rosetting T cells were micromanipulated from frozen sections of tumor tissue in two cases of nodular sclerosing HD and one case of lymphocyte predominant HD. TCR Vβ gene rearrangements were amplified from these single cells by PCR. Of 83 potentially functional Vβ gene rearrangements obtained altogether from the three cases, 81 were found to be clonally unrelated. Furthermore, they did not show signs of selection of the receptor chains for recognition of common epitopes: The usage of Vβ and Jβ gene segments as well as the distribution of complementarity-determining region (CDR) 3 lengths was similar to what was seen in a collection of 60 Vβ gene rearrangements from blood of healthy donors and no recurrent CDR3 amino acid motifs were found. These data suggest that the HRS cells attract CD4⁺ T cells nonspecifically.     

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.     

T cell development and repertoire of mice expressing a single T cell receptor α chain

We examined T cell development and T cell repertoire in transgenic mice expressing a single T cell receptor (TCR) α chain derived from the H-2D^b -lymphocytic choriomeningitis virus (LCMV)-specific cytolytic T lymphocyte (CTL) clone P14. To generate these α P14 mice, mice transgenic for the P14 TCR α chain were backcrossed to TCR α-deficient mice. Thymi from α P14 mice exhibited a marked decrease of mature CD4⁺8^? and CD8⁺4^? single-positive thymocytes comparable to thymi from TCR α-deficient mice. Correspondingly, the number of peripheral T cells was reduced in the CD4 (tenfold) and in the CD8 (twofold) subsets when compared to normal mice. T cells from α P14 mice generated a primary anti-LCMV CTL response when stimulated in vitro with LCMV in contrast to normal mice which require priming in vivo; elimination of LCMV in vivo was, however, not improved. Flow cytometric analysis of T cells with Vβ-specific antibodies showed a diverse endogenous TCR Vβ repertoire. Functional analysis of the T cell repertoire, however, revealed a strongly reduced (30-fold) allogeneic and the absence of a vesicular stomatitis virus-specific CTL response and an impaired ability to provide T cell help for antibody isotype switching. Thus, T cell selection in the thymus was impaired and the T cell repertoire was limited in mice expressing only one type of TCR α chain.     

Superantigen recognition by gammadelta T cells: SEA recognition site for human Vgamma2 T cell receptors

Human gammadelta T cells expressing the Vgamma2Vdelta2 antigen receptors recognize nonpeptide prenyl pyrophosphate and alkylamine antigens. We find that they also recognize staphylococcal enterotoxin A superantigens in a manner distinct from the recognition of nonpeptide antigens. Using chimeric and mutant toxins, SEA amino acid residues 20-27 were shown to be required for gammadelta TCR recognition of SEA. Residues at 200-207 that are critical for specific alphabeta TCR recognition of SEA do not affect gammadelta TCR recognition. SEA residues 20-27 are located in an area contiguous with the binding site of V beta chains. This study defines a superantigen recognition site for a gammadelta T cell receptor and demonstrates the differences between Vgamma2Vdelta2+ T cell recognition of superantigens and nonpeptide antigens.