Regulation of surface antigen expression in Paramecium primaurelia. II. Role of the surface antigen itself.

In the wild-type strains, 156 and 168, of Paramecium primaurelia, the alleles G156 and G168 expressed at medium temperature specify two immunologically distinguishable surface antigens 156G and 168G, whose phenotypic expression shows allelic exclusion, the majority of heterozygotes being phenotypically [156G] while a small minority is phenotypically [156G-168G]. At high temperature, the antigens coded by another locus, generally the D locus, are expressed. This system, displaying both intergenic and interallelic exclusion, provides favourable material to analyze the respective roles of the genome, of the antigens expressed and of the environmental conditions, in particular temperature, on the regulation of the expression of surface antigens. This analysis was carried out by studying the variations of the expression of surface antigens as a function of temperature, culture medium and previously expressed antigens in different genetic situations (a) in homozygotes: the wild-type strains 156 and 168, and the isogenized strains "G156 isogenic 168 carrying the G156 allele in a 168 genetic background; (b) in heterozygotes of the two phenotypic classes of heterozygotes, [156G] and [156G-168G]. The results show that (1) the thermal stability of the expression of a given surface antigen and its rate of re-appearance at the cell surface depend on its own specificity; (2) in heterozygotes [156G-168G], the stability of the expression of the antigen 156G is modified and "adjusted" to that of the less stable surface antigen 168G, and (3) the surface antigen itself exerts a positive control on the maintenance of its own expression. An interpretative model of "transmembranous control" is proposed to account for the regulation of the expression of surface antigens in Paramecium.     

Predicted complementarity determining regions of the T cell antigen receptor determine antigen specificity.

The antigen receptor on T cells (TCR) has been predicted to have a structure similar to a membrane-anchored form of an immunoglobulin F(ab) fragment. Virtually all of the conserved amino acids that are important for inter- and intramolecular interactions in the VH-VL pair are also conserved in the TCR V alpha and V beta chains. A molecular model of the TCR has been constructed by homology and we have used the information from this, as well as the earlier structural predictions of others, to study the basis for specificity. Specifically, regions of a TCR cloned from an antigen-specific T cell were stitched into the corresponding framework of a second TCR. Results indicate that the substitution of amino acid sequences corresponding to the complementarity determining regions (CDRs) of immunoglobulin can convey the specificity for antigen and major histocompatibility complex molecules. These data are consistent with a role, but not an exclusive role, for CDR3 in antigen peptide recognition.     

Biosynthesis and glycosylation of the carcinoembryonic antigen.

Human gastric adenocarcinoma MKN-45 cells were found to synthesize actively carcinoembryonic antigen (CEA). The biosynthesis and carbohydrate processing of CEA were studied in these cells by means of metabolic labelling followed by immunoadsorption with a specific polyclonal-antibody preparation and gel electrophoresis. Pulse-chase studies with [14C]leucine and [3H]mannose (shortest pulse 3 min) showed that N-linked oligosaccharide side chains are added to the protein co-translationally, producing a high-mannose immature CEA; the average molecular mass of this form is 145 kDa. The protein is later translocated to the Golgi apparatus and here undergoes additional processing; these modifications are visible in our system as a broadening of the CEA band and require about 4 h. The upper limit of mature CEA band reaches 200 kDa, but radioactivity is maximally incorporated at 168 kDa. The extent of co-translational glycosylation was measured by treating the cells with tunicamycin; in the presence of this inhibitor, a 74 kDa aglyco-CEA was produced and was still recognized by the antibody. Monensin, an ionophore which interferes with glycoprotein maturation and terminal sugar addition, blocked broadening of the CEA band, producing a sharp 141 kDa peak. In conclusion, CEA appears to be synthesized as a 145 kDa high-mannose immature form, the protein core accounting for about half of its molecular mass. Full maturation results in a broad band at 168 kDa.