| Abstract: | When healthy HeLa cells were exposed to an intracellular acting cytocidal protein extracted from vaccinia virus-infected cells, or non-toxic diphtheria A fragment, there was no detectable drop in cell viability. However, when the cells were treated with vaccinia cytocidal protein, low non-toxic doses of whole diphtheria toxin, or high doses of non-toxic diphtheria A fragment in the presence of 0.85 M MgSO4 for 15 min, to induce intra-cytoplasmic uptake, 25–30% of the cells died.This partial killing effect was shown to be due to a heterogeneous cytoplasmic uptake of the cytotoxic protein; induced protein uptake occurred in only 25–30% of the cell population. It was not found possible to correlate this cell sub-population with a genetically determined cell sub-population, cells in a specific stage of the active cell division cycle or, inactive G0-like cells. Electron microscopic studies of cells after 0.85 M MgSO4 treatment showed increased vacuolation and uptake of horse-radish peroxidase into such newly formed vacuoles was demonstrated. Light microscope studies indicated that this induced vacuolation was also not homogeneous within the population, which led to the possibility that excessive induced vacuolation and eventual cytoplasmic entry of macromolecules were linked phenomena. This hypothesis was supported by studies on rabbit kidney (RK), and baby hamster kidney (BHK) cells, which showed similar degrees of vacuole inducibility and toxin susceptibilities as HeLa cells, and by studies on HEp-2 cells, Chang conjunctival cells (W-K derivative), and McCoy cells, which showed no MgSO4-induced vacuolation and were totally resistant to vaccinia cytocidal protein and diphtheria toxin A fragment in the presence of hypertonic MgSO4. Evidence was obtained which indicated that excessive vacuolation is also linked with aberrant vacuolar fusion events within the cell after treatment with hypertonic MgSO4. |
