leupeptins and Teratoma

Fluorescent neoglycoproteins were used to screen for the presence and sugar specificities of cell surface lectins in two human embryonal carcinoma cell lines. Efficient labeling correlated with extent of lectin-mediated uptake of neoglycoproteins, as measured by inhibition of DNA synthesis by drug-neoglycoprotein conjugates. These conjugates contain covalently linked carbohydrate moieties on the carriers to render them accessible to the membrane lectins, most effectively galactosides and alpha-glucosides. They furthermore contain chemically linked cytotoxic drugs (etoposide, cis-diamminedichloroplatinum II and methotrexate) which are intracellularly released after lysosomal breakdown of the carrier, as indicated by the effect of leupeptin. Sugars can confer a greater than 10-fold increase in cytotoxic capacity to the nonglycosylated carrier-drug conjugate, nearly reaching the level of toxicity of the freely diffusible drug. Two different neoglycoproteins, reacting with independently targeted membrane lectins, were shown to be useful in a model for combination chemotherapy. These results therefore suggest potential usefulness of custom-made glycosylated carriers in the targeting of therapeutic agents to human embryonal carcinoma cells.

Topics: Antineoplastic Agents; Cell Line; Cell Survival; Cisplatin; Etoposide; Glycoproteins; Humans; Lectins; Leupeptins; Methotrexate; Pharmaceutical Vehicles; Receptors, Cell Surface; Teratoma

Methotrexate (MTX) conjugates of a monoclonal antibody, anti-SSEA-1, containing an average of 45 mol MTX/mol of immunoglobulin M, were prepared by a carbodiimide coupling reaction. Binding experiments indicate that conjugation does not decrease the affinity of the antibody for its antigen. The conjugate strongly inhibits the growth of SSEA-1-bearing F-9 teratocarcinoma cells, with 50% inhibitory dose of 4.5 nM MTX, which makes it more active than free MTX (50% inhibitory dose of 15 nM). The drug-free antibody is not cytotoxic to F-9 cells at the concentrations used. The high efficacy of the conjugated drug may be due in part to the fact that anti-SSEA-1 antibody is an immunoglobulin M. MTX conjugated to nonspecific immunoglobulin M has little inhibitory effect (50% inhibitory dose of 150 nM). When acting on SSEA-1 negative cells, the two conjugates have only a small but identical effect. Thiamine pyrophosphate, an inhibitor of MTX transport, can prevent the cytotoxicity of the free MTX but not that of the anti-SSEA-1 conjugate. Leupeptin, an inhibitor of lysosomal protease, can partially protect F-9 cells against the antibody conjugate but not against free MTX. These results indicate that the MTX antibody conjugate binds specifically to F-9 cells, and is internalized and intracellularly degraded to release a small molecular active drug. Pretreatments of F-9 cells for 1 h with unlabeled antibody inhibits the subsequent uptake of identical concentration of labeled conjugate. The rate of internalization, however, regains almost normal values within 4 h, indicating a rapid reappearance of free antigenic sites at the cell surface.

Topics: Animals; Antibodies, Monoclonal; Glycolipids; Immunoglobulin G; Leucovorin; Leupeptins; Lewis X Antigen; Lysosomes; Methotrexate; Mice; Mice, Inbred BALB C; Teratoma; Thiamine Pyrophosphate; Tritium