Mammalian concanavalin A-resistant cells contain altered cell surface glycoproteins

Changes in glycoprotein fucosylation in a concanavalin A-resistant variant of a human leukemia cell line (K562)

Previous studies from this and other laboratories have shown that variants of tumor cell lines can be selected for resistance to the lytic action of natural killer (NK) cells. One of these (K562-Clone I), when made resistant to the toxic effects of Concanavalin A (Con A-R1), regained its sensitivity to NK. Comparing the plasma membranes of Clone I and Con A-R1, we observed 1) a very similar electrophoretic pattern of membrane glycoproteins identified by binding to the lectins Con A, WGA, PNA, and SBA; 2) an increase in binding of Ulex europaeus lectin to a group of glycoproteins from Con A-R1 that were sensitive to treatment with fucosidase and N-glycanase and that had a diffuse mobility ranging in apparent molecular weight from 30 to 200 kDa; and 3) a marked decrease in binding of an antibody reactive with the lactoneofucopentaose III antigen (Lewis x). This constellation of changes is an unusual pattern to follow Con A resistance and may point to a pathway of glycosylation that a leukemic cell might use to modify its recognition by the NK mechanism.

Membrane glycoprotein changes during the senescence of normal human diploid fibroblasts in culture

The plasma membrane is intimately involved in a variety of cellular phenomena and may play an important role in the aging of human cells in culture. Significant differences in human diploid fibroblast surface glycoproteins were observed with in vitro aging. Senescent cells bound more concanavalin A (Con A) than young cells and exhibited two distinct classes of binding sites. Cell surfaces of senescent cells incorporated less labelled mannose and more labelled fucose and glucosamine than young cell surfaces. Membranes prepared from older cells were also less effective than membrane preparations from young cells in incorporating mannose from GDP-mannose into a group of oligolipid intermediates, required for the synthesis of glycoproteins with asparagine-linked oligosaccharides. These results demonstrate novel quantitative changes in membrane structure and lectin reactivity in aging human diploid fibroblasts, which must reflect the fundamental physiological modifications in the cell that occur during senescence.

Changes in glycosidase activities in lectin resistant myogenesis-defective myoblast cell lines

1. Mannosidase, hexosaminidase, galactosidase and fucosidase activities were determined in cell free extracts of wild type and con A-resistant L6 myoblast cells. 2. Two mannosidase activities were detected, with pH optima of 4.6 and 6.0. The con A-resistant cells were almost devoid of intracellular mannosidase activity with optimum pH 4.6. Differences in Km and Vmax values for mannosidase activities were found when con A-resistant and wild type cells were compared. 3. A decrease in the intracellular hexosaminidase activity in the con A-resistant myoblasts was accompanied by an increase in extracellular activity. No differences were observed in the extracellular mannosidase activities of wild type and con A-resistant cells.

Characteristics of concanavalin A-resistant Chinese hamster ovary cells and certain revertants

Clones of Chinese hamster ovary (CHO) cells were isolated by single-step selection for resistance to killing Concanavalin A (ConA) and certain cellular and membrane properties were examined. The ConA-resistant isolates were only about 2-fold more resistant than wild type cells to the selecting lectin, but exhibited pleiotropic temperature-sensitivity for growth, markedly altered morphology and adherence, and significant difference in susceptibility to other agents such as colchicine. Two revertants to full temperature-resistance were isolated from different ConA-resistant mutants. One revertant clone had reacquired wild type sensitivity to ConA while the other revertant remained ConA-resistant. The two series of wild typed, ConA-resistant, and temperature revertant clones were analyzed for altered mobility of cell surface glycoproteins using lactoperoxidase/125I and galactose oxidase/(3H) borohydride labelling procedures. The ConA-resistant clones showed increased mobility on polyacrylamide gels of three classes of labelled proteins, in the molecular weight ranges 225,000, 200,000, and 130,000 daltons. These changes persisted in the temperature-revertant that remained ConA-resistant, while two of the altered protein closses were restored to wild type mobility in the revertant that regained ConA-sensitivity. Cell hybridization experiments indicated that the temperature-sensitivity phenotypes of different ConA-resistant isolates are recessive and noncomplementing, implying that the same gene is affected in each case. The reversions to temperature resistance appear to be recessive suppressor mutation in different genes.