Evidence for the inhibition of trypsin by thiols. The mechanism of enzyme-inhibitor complex formation.

Ehrlich ascites tumour cells contain a neutral protease, capable of solubilising fluorescein-labelled telopeptides from fluorescein-labelled polymeric collagen fibrils. The cells also contain an inhibitor for this enzyme and for trypsin. The enzymically inactive enzyme-inhibitor complex can be dissociated with the mercurial thiol agent, mersalyl, with the consequent regain of enzymic activity. The reactivated neutral protease and also trypsin can be inhibited by addition of thiols such as cysteine, mercaptoethanol and dithiothreitol. Trypsin can be protected from inactivation by the tumor inhibitor by addition of cystine or L-1-tosylamido-2-phenylethyl chloromethyl ketone(TosPheCH2Cl)-inactivated chymotrypsin. The evidence suggests that the inhibitor contains a reactive thiol group which exchanges with one or more significant disulphide bridges in trypsin and the neutral protease, resulting in enzyme-inhibitor complex formation and loss of activity. Similarly, thiols interact with these enzymes resulting in a corresponding loss of enzymic activity. The evidence obtained with Tos-PheCH2Cl-inactivated chymotrypsin, which reactivated previously inhibited trypsin and neutral protease, demonstrates that the active site of the enzyme is not involved in the interaction with the thiol of the inhibitor but that the significant disulphide bond in the enzyme is required for the maintenance of the active site conformation. This disulphide exchange mechanism is therefore a form of reversible allosteric control of proteolytic activity and has been shown to be distinct from the mechanism by which soya bean trypsin inhibitor interacts with trypsin.