Increased ecto-metallopeptidase activity in cells undergoing apoptosis.

Release from the cell surface of a variety of growth factors, cytokines, and proteases follows exposure to genetically stressful agents capable of inducing apoptosis and necrosis. Increased ectoprotease activity is responsible for their release. We show that increased activity of several metalloproteases on the HeLa cell surface occurs after stresses due to UVC, actinomycin D, cycloheximide, and cisplatinum, which induce the release of transforming growth factor-alpha (TGFalpha) and other bioactive molecules. The ectoprotease activities increase preferentially on apoptotic cells, while little change occurs in viable cells. Gross decreases, except for the putative TGFalphaase activity, accompany necrosis. These changes may contribute to tissue repair and the absence of an inflammatory reaction to apoptotic cell death. They appear to be due to preferential enzyme activation or to retention by cells undergoing significant categorical decreases in protein content.

Effect of UV irradiation on cell surface protease activity and amino acid uptake.

The surface of most cells includes a coterie of resident proteins which act as receptors for a wide variety of ligands and other proteins which are potentially bioactive on cell-cell contact (juxtacrine effects), or else are released by enzyme activity to influence cell behaviour by autocrine or paracrine mechanisms. We previously found that UVC irradiation stimulates the release of TGFalpha from its membrane-bound preprocursor form whereby it acts as a stimulus to rapid, reparative cell multiplication; clearly this runs the risk hastening mitosis before UV-induced DNA damage is fully corrected, which in turn may increase the likelihood of residual lesions persisting and hence of new mutations being generated. We found that sublethal UVC irradiation (10 J m(-2)) of HeLa cell cultures also resulted in activation of ecto-aminopeptidase and ecto-endopeptidases which were maximal 16 and 20-24 h after irradiation, respectively. Both of these classes of protease were shown to be metalloproteases using a nonapeptide substrate (called P9) which is cognate to the N-terminal cleavage site of preproTGFalpha except for a reporter 125I-tyrosine [Piva et al., J. Cell. Biochem. 64 (1997) 353-368]. We now show that the N-terminal tyrosine cleaved from P9 by cell surface aminopeptidase activity, was found to be taken up by the cell resulting in its 10-25-fold concentration intracellularly, some two- to threefold higher than from a reservoir source, and may represent a novel salvage pathway for recovery of essential amino acids. Aminopeptidase activity was found to be both temperature- and FBS-dependent but was not reliant on ATP for its activity. Tyrosine transport across the cell membrane was also temperature and FBS-dependent but required ATP for maximal activity. UVC irradiation enhanced aminopeptidase activity but not tyrosine uptake by the cultures. The fraction of HeLa cells undergoing apoptosis increased in those cultures which were exposed to higher doses of UVC. The levels of ecto-aminopeptidase and ecto-endopeptidase activity in apoptotic cells were elevated compared to viable cells receiving the same dose of UVC. These results suggest that increased levels of cell surface protease activity in apoptotic cells would increase the amounts of free amino acids and growth factors in the extracellular medium and hence stimulate the proliferation of surrounding cells to replace those killed by UV irradiation.

Reversal of the multidrug resistance phenotype with cremophor EL, a common vehicle for water-insoluble vitamins and drugs.

A polyethoxylated castor oil, Cremophor EL, which is used as a vehicle for p.o. and i.v. administration of water-insoluble compounds in humans, can reverse the multidrug resistance (MDR) phenotype at doses which are likely to be readily achievable clinically. Using flow cytofluorometric analysis of daunorubicin (DNR) uptake as a measure of the expression of the MDR phenotype, Cremophor EL (1:10(3] in the growth medium increased intracellular DNR in an MDR cell line, R100 cells, to levels similar to that observed in the drug-sensitive parental cells, CCRF-CEM. A similar Cremophor EL-induced increase in DNR uptake was also observed in an unrelated MDR cell line derived from K562 cells. Cremophor EL (less than or equal to 3:10(4] did not inhibit the growth of CCRF-CEM cells or its vinblastine-resistant derivative, R100 cells, but would significantly increase the sensitivity of R100 cells to both vinblastine and DNR. Also Cremophor EL did not increase the sensitivity of normal bone marrow progenitor cells cultured in vitro to high concentrations of vinblastine. Cremophor EL may prove to be a relatively pharmacologically inactive addition to chemotherapeutic protocols which may be able to reverse the MDR phenotype in tumors and also help to prevent the selection of MDR cell variants from within a tumor cell population during chemotherapy.