Proteolytic cleavage of lexA repressor is an early step in derepression of the SOS regulatory system of Escherichia coli. In vivo and in vitro data have indicated a role for recA protein in this specific proteolytic reaction. I show here that, under certain conditions, specific in vitro cleavage of highly-purified lexA protein can take place in the absence of recA protein. This autodigestion reaction cleaved the same alanine-glycine bond as did the recA-dependent cleavage reaction. Several lines of evidence argued that it was not due to a contaminating protease activity. Autodigestion was stimulated by alkaline pH. It occurred in the presence of EDTA but was stimulated several fold by the presence of Ca2+, Co2+, or Mg2+. The reaction appeared to be first-order, and its rate was independent of protein concentration over a wide range, strongly suggesting that it is intramolecular. Purified phage lambda repressor also broke down under similar conditions to yield products like those resulting from recA protein action. Phage lambda repressor broke down at a far slower rate than did lexA, as previously observed in the recA-catalyzed in vitro reaction and in vivo. This correlation between the two types of cleavage also extended to the reactions with mutant repressor proteins; taken together with the site specificity, it suggests that autodigestion and recA-dependent cleavage follow, at least in part, a similar reaction pathway. These findings indicate that specific cleavage of lexA protein can be catalyzed by the protein itself and suggest that recA protein plays an indirect stimulatory role, perhaps as an allosteric effector, in the recA-dependent reaction, rather than acting directly as a protease. The protease active site and the recA-recognition site lie in the central or COOH-terminal portion of the lexA protein, since a tryptic fragment containing these portions of lexA protein could take part in both reactions.
Read full abstract