Some hints concerning the shape of T-cell receptor structures.

Several models are proposed for T-cell antigen receptor (TCR) assembly and structure. However, there is little experimental data favouring directly either one or the other(s). The minimal complex appears to be composed of a TCRalphabeta/CD3deltaepsilon,gammaepsilon/zeta2 structure but at the cell membrane, multimers of this minimal structure may be formed. Quantitative cytofluometry has suggested three CD3epsilon chains for two TCRbeta (or TCRdelta) chains/complex. Such data should be repeated with monoclonal antibodies (MoAb) against extracellular (EC) parts of CD3delta or CD3gamma chains. In the present review, we have compared the TCR/CD3 assembly of pre-TCR, TCRgammadelta and TCRalphabeta containing complexes, and analysed the reactivity of antibodies (Abs) against the EC part of CD3delta chains. Our data suggest an alternative assembly pathway and structure of TCR/CD3 complexes.

Evolution of T cell receptor (TCR) alpha beta heterodimer assembly with the CD3 complex.

T cell antigen receptors (TCR) are composed of an antigen-recognizing unit, the TCRalpha beta heterodimer, and a signal transduction ensemble, the CD3 complex. Whereas mammals possess three CD3 dimers (delta epsilon, gamma epsilon, and zeta2), birds and amphibians have only two (delta/gamma-epsilon and zeta2). To understand evolutionary changes in TCR/CD3 assembly,a phylogenetic approach was employed to dissect the interaction of TCRalpha beta heterodimers with the CD3 components. While sheep and mouse TCRalpha and TCRbeta chains could replace the corresponding human chains in mutant human T cells to restore surface TCR/CD3 expression and function, chicken TCRalpha, TCRbeta and CD3delta/gamma chains were unable to replace the corresponding human chains in forming a chimeric TCR/CD3 complex. The inability of chicken TCR/CD3 components to replace the human molecules in T cells was found to result from the lack of interaction between chicken TCRalpha beta heterodimers and the human CD3 complex. In contrast, if no CD3 molecules are present (non-T cells), TCRalpha -TCRbeta chain pairing can take place in an apparently non-controlled way. Thus, the TCR-CD3 interactions have changed with the evolutionary divergence of two mammalian CD3gamma and CD3delta genes from a single prototypic chicken delta/gamma gene. Our data suggest that the structures in mammalian TCR.C regions, which distinguish between CD3delta and CD3gamma chains, have evolved with the appearance of two separate CD3delta and CD3gamma functions.

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.