Abstract
Abstract A chinese hamster ovary (CHO) fibroblast, transfected with murine MHC class II genes, inefficiently stimulated CD4+ Th cells specific for OVA, hen egg lysozyme (HEL), and pork insulin which contain disulfide bonds. However, the fibroblasts elicited a T cell response to lambda repressor, which lacks disulfide bonds, and efficiently presented synthetic peptides. A somatic cell hybrid WALC, generated by fusing the hamster fibroblast with a murine L cell fibroblast, very efficiently processed OVA and HEL, suggesting that impaired processing was genetically complemented and was a recessive trait. The hamster fibroblasts were capable of processing two distinct denatured forms of OVA and carboxymethylated HEL, either as effectively or more efficiently than the B lymphoma cell. The CHO cells also displayed diminished disulfide reduction of an endocytosed [125I]tyramine linked to poly-(D-lysine) through a disulfide spacer compared with that of the cell hybrid, providing direct evidence for defective reductive cleavage by the CHO cells. Diminished aspartic acid-mediated proteolysis of Ag could not account for the phenotype, because cell lysates and separated organelles from the fibroblast possessed higher acidic aspartyl proteolytic activity than lysates and organelles from a B lymphoma cell. Thus, CHO cells exhibit a defect in processing Ag with disulfide bonds which is consistent with the impaired intracellular reduction of the disulfide bonds in endocytosed macromolecules.
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