On the role of CD3delta chains in TCRgammadelta/CD3 complexes during assembly and membrane expression.

The present study was performed in order to analyze whether T-cell receptor (TCR)/CD3 assembly, intracellular transport and surface expression are carried in a similar way in alphabeta-and gammadelta-T cells. By means of optimal immunoprecipitation conditions with 35S-methionine/cysteine- or biotin-labelled TCR/CD3 proteins from alphabeta- or gammadelta-T-lymphoma-cell lines, as well as TCRgammadelta cDNA transfectants, it was found that CD3delta chains associate less strongly with TCRgammadelta heterodimers compared to TCRalphabeta heterodimers. This preferential reactivity of CD3delta chains appears to be structural and not owing to differences in gammadelta- versus alphabeta-T-cell intracellular environments. Our results are in accordance firstly, with data from CD3delta-deficient mice, which have gammadelta-T cells but no alphabeta-T cells, secondly with the suggested role of CD3delta chains in the positive selection of alphabeta-T cells, a process apparently not followed by gammadelta-T cells, and lastly with the differential roles of CD3delta chains versus CD3gamma chains, explaining the maintenance of two CD3delta and CD3gamma genes after the duplication from a CD3delta/gamma gene present in avians. The impaired reactivity of CD3delta chains with TCRgammadelta heterodimers seems to be owing to a less efficient association with TCRgamma chains. In contrast, CD3delta chains interact as strongly with TCRdelta chains as do CD3gamma chains with both TCRgamma and TCRdelta chains. These data may explain, at the molecular levels, why surface TCR/CD3 expression levels are impaired in gammadelta-T cells from CD3gamma-deficient mice but not from CD3delta-deficient mice.

Molecular modelling and endoplasmic reticulum retention of mutated TCR/CD3 complexes.

T cell receptor (TCR)/CD3 complex assembly takes place in the endoplasmic reticulum (ER). Normal TCR/CD3 complexes egress from the ER to the cis-Golgi, where the interaction with zeta2 homodimers occurs. This interaction leads to further uncontrolled transport of TCR/CD3/zeta molecules to the cell surface. The purpose of the present experiments was to determine firstly the basis for the impact of the Phe195/216 --> Val mutations on TCR/CD3 expression in Jurkat cells, and secondly why mutated J79-cell TCRalphabeta/CD3 hexamers are prevented from interacting with zeta2 homodimers. We found that Phe --> Val mutations cause serious perturbations in a so far undefined hydrophobic area formed by the two Phe195/216 on beta-strand F and aromatic/large hydrophobic amino acids on neighboring beta-strands B and A in Calpha and Cbeta domains, respectively. In addition, TCR/CD3 hexamers and zeta2 homodimers colocalize in normal Jurkat T cells, in revertant J79r58 cells, and in J79 cells transfected with wild-type TCRalpha cDNA but not in J79 mutant cells (confocal microscopy). Furthermore, mutated TCR/CD3 complexes seem to be actively retained in the ER in J79 cells but not in revertant J79r58 cells by a nondominant mechanism. We propose that a hitherto undefined ER-retention molecule controls both the protein structure and egress of TCR/CD3 complexes from the ER of alphabeta and gammadelta T cells.

A new monoclonal anti-CD3epsilon antibody reactive on paraffin sections.

We generated a new monoclonal antibody (MAb), F7.2.38, by immunizing mice with CD3varepsilongammadelta/CD3omega complexes purified from human T-cells by OKT3 MAb-Sepharose affinity chromatography. Immunoprecipitation experiments and Western blotting analysis showed that MAb F7.2.38 recognized the CD3varepsilon chain in CD3varepsilon cDNA-transfected FOX B-cells and in various T-cell lines. Using flow cytometry on permeabilized or intact cells, the epitope was found to be located in the cytoplasmic tail of the CD3varepsilon chain. Immunohistochemical staining on paraffin-embedded sections showed that the reactivity of MAb F7.2.38 was comparable to that of the commercially available anti-CD3varepsilon polyclonal antibody. Of the 52 well-characterized T-cell lymphomas, 41 were positive for F7. 2.38 (79%), whereas all 37 B-cell lymphomas and 69 non-lymphoid tumors were unreactive. This new anti-CD3varepsilon antibody would be particularly useful for phenotyping T-cell lymphomas on routinely processed paraffin-embedded tissue sections.

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.

On the genetic mechanism of induction of CD3gamma-negative human T cell variants.

Invariant CD3gamma molecules are important components in TCR complex formation and function. Both CD3gamma alleles seem to be expressed co-dominantly. In the present report, we present experimental data which indicate that the induction of CD3gamma(-) Jurkat variants occurs with a frequency similar to that of TCRalpha(-) or TCRbeta(-) Jurkat cells. CD3delta(-), CD3epsilon(-) or CD3zeta(-) Jurkat variants were never obtained despite extensive efforts. Our data suggest a possible explanation for this genetic puzzle: the human CD3gamma gene has a mutational hot spot in a nucleotide sequence of nine adenosines (9A) in the exon 3 encoding most of the external CD3gamma domain. Thus, both CD3gamma alleles are easily mutated to either 8A or 10A sequences. Furthermore, absence of CD3gamma molecules in Jurkat T cells causes severe defects in TCR / CD3 assembly and function.

Molecular mechanisms in the TCR (TCR alpha beta-CD3 delta epsilon, gamma epsilon) interaction with zeta 2 homodimers: clues from a 'phenotypic revertant' clone.

The association between the TCRalphabeta-CD3gammaepsilondeltaepsilon hexamers and zeta2 homodimers in the endoplasmic reticulum (ER) constitutes a key step in TCR assembly and export to the T cell surface. Incompletely assembled TCR-CD3 complexes are degraded in the ER or the lysosomes. A previously described Jurkat variant (J79) has a mutation at position 195 on the TCR Calpha domain causing a phenylalanine to valine exchange. This results in a lack of association between TCRalphabeta-CD3gammaepsilondeltaepsilon hexamers and zeta2 homodimers. Two main hypotheses could explain this phenomenon in J79 cells: TCR-CD3 hexamers may be incapable of interacting with zeta2 due to a structural change in the TCR Calpha region; alternatively, TCR-CD3 hexamers may be incapable of interacting with zeta2 due to factors unrelated to either molecular complex. In order to assess these two possibilities, the TCR-CD3 membrane-negative J79 cells were treated with ethylmethylsulfonate and clones positive for TCR membrane expression were isolated. The characterization of the J79r58 phenotypic revertant cell line is the subject of this study. The main question was to assess the reason for the TCR re-expression. The TCR on J79r58 cells appears qualitatively and functionally equivalent to wild-type TCR complexes. Nucleotide sequence analysis confirmed the presence of the original mutation in the TCR Calpha region but failed to detect compensatory mutations in alpha, beta, gamma, delta, epsilon or zeta chains. Thus, mutated J79-TCR-CD3 complexes can interact with zeta2 homodimers. Possible mechanisms for the unsuccessful TCR-CD3 interaction with zeta2 homodimers are presented and discussed.

Expression and signal transduction of T-cell antigen receptor (TCR)/CD3 complexes on fresh or in vitro expanded T lymphocytes from patients with Hodgkin's and non-Hodgkin's lymphomas.

T-cell responses against soluble antigens, alloantigens and mitogens are frequently diminished in patients with certain types of cancer. In the present study, the authors investigated possible mechanisms for the partial T-cell immunodeficiency in patients with Hodgkin's or non-Hodgkin's lymphomas. It was found that T-cells from lymphoma patients had significantly reduced proliferative responses to EBV-transformed B-cell lines and to anti-TCR/CD3 MoAb; a 30-50% reduction of cells expressing membrane T-cell receptor (TCR) complexes; and a significantly reduced signal transduction function. Long-term in vitro culture conditions were developed to expand T cells in TCR/CD3-dependent or TCR/CD3-independent manners. With such methods, it was found that the decreased T-cell responses in patients with Hodgkin's and non-Hodgkin's lymphomas appeared to be an intrinsic T-cell defect (not at the antigen presenting cell level), and the T-cell responses could be recovered after only a few days in culture. Thus, it is suggested that the T-cell response-defect in Hodgkin or non-Hodgkin lymphoma patients is a reversible phenomenon, dependent on the patient's tumour-bearing environment.

Mutation in splicing consensus sequences causes lack of TCR membrane expression due to exon excision.

T-cell antigen receptor (TCR) membrane-negative T-cell mutants can be divided into two groups: 1) those which lack one of the six TCR polypeptides and 2) those which contain a mutated TCR chain. The present experiments reveal a new mechanism for the development of TCR membrane-negative T-cell variants: mutations in splicing consensus motifs causing excision or misreading of an entire exon (exon 3 of the TCRAC or TCRBC genes). C27.15 cells transcribe a TCR alpha chain consisting of TCRAVJCexon1Cexon2-encoded amino acids plus six new amino acids. The assembly defect seems to be that the truncated alpha chain does not interact with CD3 delta molecules; consequently, no TCR alphabeta/CD3 deltaepsilongammaepsilon complexes are formed. E6.E12 cells transcribe a TCR beta chain composed of TCRBVDJCexon1Cexon2-encoded amino acids plus twenty-seven new amino acids, which seem not to form a transmembrane region. The truncated beta chain does associate with CD3 gammaepsilon heterodimers, yet no TCR alphabeta/CD3 deltaepsilongammaepsilon complexes are made. This may be due either to low assembly of TCR beta/CD3 gammaepsilon trimers or to lack of access of the mutated TCR beta/CD3 gammaepsilon trimers to the TCR alpha/CD3 deltaepsilon compartment in the endoplasmic reticulum.

Serum cholinesterase polymorphism in France: an epidemiological survey of the deficient alleles detected by an automated micro-method.

The polymorphism of the serum cholinesterase CHE 1 was determined using an automated micro-method. The procedure developed represents an improvement of the manual method and enabled us to study more than 2400 samples obtained in 15 different geographical areas in France. Four alleles were detected: CHE1* U, A, S and F. An exceptionally high frequency of an atypical variant (CHE1*A) was observed in the central part of France (Cevennes, Limousin and Dauphiné). The populations belonging to these areas are at particular risk in case of anaesthesia.