Most in vitro studies on contaminants focus on the short-term effects of pollutants on cells, without regard to long-term effects and the ability of cells or microorganisms to develop a specific resistance to a pollutant. Cadmium is ubiquitous environmental contaminant. This heavy metal enters the aquatic environment mainly through vapor emissions and fallout during smelting operations. Diverse mechanisms of algal resistance to toxic metals are known. Among these, the most general mechanism is the development of metal-binding proteins. In cadmium-resistant unicellular Euglena gracilis Z algae cells, the metal did not appear to be sequestered on soluble metal-binding ligands. Previous experiments have shown that resistance development is related to a diminution of cadmium penetration into cells, implicating cell surface or membrane alteration. This research investigates the mechanisms of development of cadmium resistance in Euglena cells at the cell-surface level. Sugar chains of glycoproteins and glycolipids are a predominant feature of the surface of cells. Moreover, the cell-response to environmental changes is often orchestrated through surface macromolecules such as glycoproteins. In this study, we applied this lectin method to investigate surface carbohydrate expression during and after resistance development. Our interest was twofold: (1) to learn more about the carbohydrate composition of themore » cell-surface of Euglena; and (2) to determine whether transition from wild cells to Cd-resistant cells changes the expression of cell-surface carbohydrates. 13 refs., 2 figs., 1 tab.« less