Identification and characterization of subpopulations of the free alpha-subunit that vary in their ability to combine with chorionic gonadotropin-beta

Abstract

The free (uncombined) alpha-subunit of hCG is secreted in excess over alpha beta dimer from both malignant and nonmalignant trophoblast cells and is secreted ectopically from a variety of other malignant cell types. The free alpha-subunits from various sources are distinguishable from those that combine because they migrate more heterogeneously and more slowly on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) than dimer alpha. We have previously identified three posttranslational modifications that may contribute to the altered mobility of the free alpha-subunit and to its inability to combine with the beta-subunit: 1) preferential phosphorylation of the free alpha-subunit, 2) O-glycosylation of free alpha, and 3) differences in the processing of the asparagine-linked oligosaccharides between the free and combinable forms. We have purified three populations of the alpha-subunit from the JAR choriocarcinoma cell line and from ChaGo, a bronchogenic carcinoma cell line that ectopically synthesizes only the alpha-subunit, in order to identify the posttranslational modifications that contribute to the altered mobility on SDS-PAGE. Fractionation of the oligosaccharides released from the alpha forms with peptide N-glycosidase has shown that the faster migrating alpha forms on SDS-PAGE have less completely processed oligosaccharide chains. Twenty-two to 25% of the JAR free alpha and 35-41% of the ChaGo alpha forms that migrate the fastest on SDS-PAGE recombine with beta in an in vitro recombination assay under conditions where 62% of the dimer alpha form recombines. In contrast, only 5-12% and 16-21% of the JAR free alpha and ChaGo alpha forms, respectively, that migrate the slowest on SDS-PAGE recombine with beta. The form of JAR free alpha least capable of combining with beta contains on O-linked glycan on Thr-39. This same site is a substrate for phosphorylation by JAR cells. However, most of ChaGo alpha fails to recombine with beta even though ChaGo alpha contains little O-linked carbohydrate. These results suggest that the larger asparagine-linked complex glycans on the slower migrating alpha forms are the major limiting factor for subunit combination. Although these modifications may not be rate limiting for combination in the rough endoplasmic reticulum, they may prevent dimerization of the free subunits later in the secretory pathway.