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.

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.

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.

Defective interactions between TCR chains and CD3 heterodimers prevent membrane expression of TCR-alpha beta in human T cells.

The human TCR complex is composed of two clonotypic polypeptide chains, TCR-alpha and TCR-beta (or TCR-gamma and TCR-delta) associated with CD3 gamma-, delta-, and epsilon-chains and zeta 2 homodimers. All six polypeptide chains are indispensable for TCR membrane expression and signaling function. In the present paper is described the analysis of a new TCR membrane-negative Jurkat T cell variant: E6.R3. The defect in this variant bears on the interaction between TCR and CD3 chains. E6.R3 cells have deleted three nucleotides in the TCR-alpha transmembrane (TM) region, which consequently lacks a leucine. This defect causes 1) lack of association between TCR alpha-chains and CD delta epsilon heterodimers; 2) lack of formation of disulphide-linked, fully glycosylated TCR-alpha beta heterodimers; and 3) lack of interaction between TCR-alpha beta/CD3 complexes and zeta-chains. Despite these defective interactions, TCR alpha-chains appear to become fully glycosylated, i.e., they are not retained in the endoplasmic reticulum but are further processed in the Golgi apparatus without such interactions. The defect may be due to the observation that in the E6.R3 TCR alpha- chains TM region, the two charged amino acids are situated on the same side of the alpha-helix; these two amino acids are exposed on opposite faces of the TM alpha-helix in normal TCR alpha-chains, possibly allowing TCR alpha-chains to interact with both CD3 delta- and CD3 epsilon-chains. Further possible consequences of the leucine deletion in the E6.R3 TCR-alpha TM region are discussed.

Functionally important amino acids in the TCR revealed by immunoselection of membrane TCR-negative T cells.

A spontaneous TCR cell surface variant (3P11) of the Jurkat T cell line is described and characterized. 3P11 was selected by incubation of Jurkat cells with anti-TCR mAb followed by passage through Ig anti-Ig columns and cloning. 3P11 contained mRNA for both Ti alpha and Ti beta and CD3 gamma, delta, epsilon and zeta. Biochemical analyses demonstrated that all of the TCR components were produced in 3P11 cells. The Ti alpha beta/CD3 gamma delta epsilon zeta complex was assembled in the endoplasmic reticulum but the zeta did not associate with this complex. Epitopes recognized by the Ti beta chain specific mAb beta F1 and JOVI as well as anti-V beta 8 were affected in the 3P11 Ti beta chain indicating that the 3P11 Ti beta chain was mutated. Transfection of a wild-type Ti beta cDNA into 3P11 cells reconstituted TCR expression. Sequence analyses of the 3P11 Ti beta chain demonstrated a guanine to adenine change in the second nucleotide of the triplet coding for cysteine191 resulting in a cysteine to tyrosine exchange. Cysteine191 is the C-terminal cysteine involved in the intrachain disulfide bond in the C domain of the Ti beta chain; thus, the 3P11 Ti beta chain did not contain this disulfide bond. Transfection of a site-directed Ti beta chain containing the 3P11 mutation into a Ti beta negative variant of the Jurkat cell line resulted in a TCR phenotype identical with 3P11 demonstrating that the mutation identified in the 3P11 Ti beta chain was the sole cause for the 3P11 defect.

The IE allogeneic response of T cells from C57Bl/6 mice is associated with genes in the TCRa locus.

It has been demonstrated that induction of immune responses, infectious diseases and autoimmune manifestations can be associated with at least four gene loci: the major histocompatibility complex (MHC) locus; the immunoglobulin (Ig) heavy chain (Hc) locus; and the T-cell receptor (TCR) TCR-alpha or TCR-beta chain loci. In the present study, we have analysed whether T-cell responses of IE-negative C57Bl/6 (B6) mice to IE alloantigen (IE alpha transgenic B6 mice = B6.E alpha 16) or to trinitrophenylated (TNP) syngeneic spleen cells were influenced by changes in the Ig-Hc locus or the TCRa locus. Whereas the fine specificity of T-cell responses to IE alloantigen was the same in B6 mice and in Ig-Hc congenic B6.26a or TCRa congenic B6.10TCa mice, the latter strain of mice demonstrated much higher IE-specific T-cell responses against B6.E alpha 16 spleen cells than B6 or B6.26a mice. This high responsiveness was a dominant feature and associated with the TCRa locus. In addition, the TCRV alpha or V beta repertoire of the congenic strains of mice was polyclonal and very similar. The TNP-specific T-cell responses of B6 and B6.10TCa mice showed the same restricted TCRV alpha and V beta repertoire. It is concluded that in both an oligoclonal T-cell response (anti-TNP) and a polyclonal T-cell response (anti-IE), exchange of Ig-Hc or TCRa loci does not significantly influence the TCRV alpha or V beta repertoire in IE-negative C57Bl/6 mice.

A new polymorphism of thyroxin-binding globulin in three African groups (Mali) with endemic nodular goitre.

The thyroxin-binding globulin (TBG) polymorphism was investigated in three African groups: two belonged to the Bwa villages of Mali, and the third was a Dogon group living in the same area. The Bwa groups were characterized by the occurrence of nodular goitres, whereas the Dogon population did not show similar pathological symptoms. Females were more affected by goitre than males in the affected villages. The TBG polymorphism enabled us to demonstrate the presence of an undescribed allele (TBG C1) in these populations. The frequency of the TBG S allele was also higher than previously published in other African groups. We observed a disequilibrium in the distribution of the C and S alleles in the population, with an excess of homozygous TBG S individuals. No clear relationship between the TBG polymorphism and the number of nodules can be drawn.

Polymorphism of the vitamin D binding protein (DBP) among primates: an evolutionary analysis.

The distribution of the DBP (vitamin D binding protein) polymorphism is now well characterized among human populations but for primates only limited results are known. The aim of this paper is to describe the electrophoretic polymorphism of this protein among various species. Using three different electrophoretic methods, we are able to detect an unknown polymorphism and to classify the different alleles observed. These results may be used to set an international nomenclature for further comparisons. The different electrophoretic mobilities between Old and New World Monkeys show that: 1) the Cercopithecoïdea are presenting the largest genetic heterogeneity; 2) the DBP among the Galago corresponds to the lowest isoelectric points observed among Primates; 3) during the evolution from nonhuman Primates to Man, the DBP is able to keep its affinity for vitamin D derivatives despite the occurrence of significant molecular modifications; 4) among Anthropoïdea, the electrophoretic patterns of DBP are very close to the human Gc1 proteins. These results show that evolution at the DBP level can be considered as a continuous mechanism of structural modifications. A significant transition occurs during the differentiation between Cercopithecoïdea and Anthropoïdea. It is not too speculative to consider that some electrophoretic forms detected among Gorilla, Pongo, or Pan may be identical to rare variants observed among humans.

Serum protein polymorphism in Bali (Indonesia).

Serum samples from Bali, obtained in three different ethnic groups and in one isolated village were tested by isoelectric focusing electrophoresis for Gc, Pi, Tf and Hp subtyping. In addition to the three common alleles Gc1F, Gc1S and Gc2, two variants Gc1A1 and Gc1A8 were observed. In the Pi system, five alleles were present: PiM1, PiM2, PiM3, PiM4 and PiX. The Tf variability was exceptional with the presence of eight alleles: TfB1, TfC1, TfC2, TfC3, TfC4, TfC8, TfD1 and TfDchi. For Hp, there were two common alleles Hp1S and Hp1FS and two rare ones: Hp1F and Hp2SS. As expected, the genetic polymorphism is reduced in the isolated community. The anthropological significance of these genetic data is discussed.

Haptoglobin polymorphism among Saharian and West African groups. Haptoglobin phenotype determination by radioimmunoelectrophoresis on Hp O samples.

The haptoglobin (Hp) polymorphism is investigated in 11 African groups living in an area from the Algerian Sahara to Central Africa. More than 4,000 samples were examined. In the Saharian samples, the Hp1 gene frequency is higher than in any other African group. From north to south, a decrease in the Hp1 gene frequency is observed; in the Pygmy sample only, this frequency is lower than the frequency of the Hp2 gene. By means of a sensitive radioimmunoelectrophoresis, the presence of a residual Hp in Hp O sera in which the Hp polymorphism can also be determined can be revealed. Absence of Hp 1-1 and significant excess of Hp 2-2 individuals were observed. More Hp 2-1M phenotypes were detected in the Hp O population than in the non-Hp O population examined. In the Hp O samples, the influence of the phenotype distribution on the Hp gene frequencies is discussed. The heavy polymers of the Hp related to the presence of the alpha 2 chain (Hp2 gene product) are involved only in the biological mechanisms responsible for the presence of Hp O and Hp 2-1 M phenotypes among African groups.

Pi M4: an additional Pi M subtype.

The authors studied Pi polymorphism using the Separator isofocusing method with slight modification. A new Pi allele was observed. Family pedigrees confirmed co-dominant inheritance with other Pi alleles. According to the electrophoretic mobility of its isoprotein bands, and to its frequency (0.04) this new allele is considered as a fourth Pi M subtype: Pi M4.

GcT (Toulouse): a fast variant of the groupspecific system in an Pyrenean family.

In the course of a genetic investigation carried out in a Pyrenean population, a family with a new allele of the Gc system was found. Electrophoretic analysis revealed a faster migrating variant with a double band pattern. Presumably, this variant represents a mutant of the Gc1 allele. The variant is transmitted as an autosomal codominant trait. This additional allele at the Gc locus is named GcT (TcToulouse).