The addition of exogenous gangliosides to cultured human cells results in the cell type-specific expression of novel surface antigens by a biosynthetic process

After the observation that human mAb 32-27M reacts only with melanoma and astrocytoma cells cultured in the presence of fetal bovine serum, a novel pathway for the uptake of exogenous gangliosides, their further biosynthesis, and expression at the cell surface as novel Ag has been elucidated. The addition of fetal bovine serum to melanoma and astrocytoma cells growing in synthetic medium (insulin-transferrin-selenium) resulted in reactivity with Ab32-27M. As antibody 32-27M detects N-glycolylneuraminic acid (NeuGc)-containing gangliosides, the effect of adding a number of different gangliosides to melanoma and astrocytoma cells cultured in the synthetic medium was studied. Only the addition of NeuGc-GM3 resulted in the development of Ab32-27M reactivity. The identity of the antigenic structures developed after addition of fetal bovine serum or NeuGc-GM3 was determined by analysis of the gangliosides from both samples. The major component detected in melanoma cell lines was shown to be N-acetylneuraminic acid-NeuGc-GD3. Another, slower moving component, present in some melanomas and in astrocytomas may be N-acetylneuraminic acid-NeuGc-GD2. The cell type specificity for these processes can be most readily explained by postulating that all cells can take up exogenous gangliosides but only melanoma and astrocytoma cells have sufficiently high levels of GM3 alpha 2----8-sialyltransferase for the conversion of added NeuGc-GM3 to disialogangliosides to be effective. These results demonstrate a novel pathway for exogenous glycolipid processing that can lead to novel Ag expression but may also play a role in normal glycolipid metabolism and function.     

Biological Differences between Brackish and Fresh Water-Derived Aedes aegypti from Two Locations in the Jaffna Peninsula of Sri Lanka and the Implications for Arboviral Disease Transmission

The mainly fresh water arboviral vector Aedes aegypti L. (Diptera: Culicidae) can also undergo pre-imaginal development in brackish water of up to 15 ppt (parts per thousand) salt in coastal areas. We investigated differences in salinity tolerance, egg laying preference, egg hatching and larval development times and resistance to common insecticides in Ae. aegypti collected from brackish and fresh water habitats in Jaffna, Sri Lanka. Brackish water-derived Ae. aegypti were more tolerant of salinity than fresh water-derived Ae. aegypti and this difference was only partly reduced after their transfer to fresh water for up to five generations. Brackish water-derived Ae. aegypti did not significantly discriminate between 10 ppt salt brackish water and fresh water for oviposition, while fresh water-derived Ae. aegypti preferred fresh water. The hatching of eggs from both brackish and fresh water-derived Ae. aegypti was less efficient and the time taken for larvae to develop into pupae was prolonged in 10 ppt salt brackish water. Ae. aegypti isolated from coastal brackish water were less resistant to the organophosphate insecticide malathion than inland fresh water Ae. aegypti. Brackish and fresh water-derived Ae. aegypti however were able to mate and produce viable offspring in the laboratory. The results suggest that development in brackish water is characterised by pertinent biological changes, and that there is restricted genetic exchange between coastal brackish and inland fresh water Ae. aegypti isolates from sites 5 km apart. The findings highlight the need for monitoring Ae. aegypti developing in coastal brackish waters and extending vector control measures to their habitats.     

Biochemical analysis of a human epithelial surface antigen: differential cell expression and processing

Epithelial surface antigen (ESA) is a glycoprotein with a distribution in vivo that is largely confined to human epithelial cells. Previous studies using a mouse monoclonal antibody (MH99) detecting ESA had shown that the antigen immunoprecipitated from most epithelial cancer cell lines has two chains (38,000 and 32,000 Da) when separated under reducing conditions and only one (38,000 Da) under nonreducing conditions. We now show that the 38-kDa band observed under nonreducing conditions consists of two species, one a 38-kDa single chain protein and the other a disulfide-linked dimer consisting of the 32-kDa chain bonded to a previously unrecognized 6-kDa chain. Pulse-chase studies have shown that ESA is synthesized as a 34-kDa protein which is glycosylated to a 38-kDa glycoprotein containing both high mannose and complex carbohydrate chains. With longer chase periods, a 32-kDa species also appears. Peptide mapping, together with the pulse-chase data, suggests that the 32- and 6-kDa species are formed from the 38-kDa protein, probably by limited proteolysis. Epithelial cell lines differ in their ratios of 38/32-kDa species, some cell lines having only the 38-kDa form. Incubation of radiolabeled extracts of cells having only the 38-kDa protein with unlabeled extracts of the other cell types resulted in progressive conversion of the 38-kDa species to the 32- and 6-kDa forms. Only cell lines expressing both forms of ESA are able to carry out this cleavage of the 38-kDa protein. This is a novel mechanism for generating cell-type related differences in cell surface glycoprotein expression. Finally, sequential immunoprecipitation experiments showed that the antigen detected by Ab MH99 is closely related or identical to that detected by Ab 17-1A, a previously described colon cancer antigen.