Insight into the complex and dynamic process of activation of matrix metalloproteinases.

Matrix metalloproteinases (MMPs) are important hydrolytic enzymes with profound physiological and pathological functions in living organisms. MMPs are produced in their inactive zymogenic forms, which are subsequently proteolytically activated in an elaborate set of events. The propeptide in the zymogen blocks the active site, with a cysteine side-chain thiolate from this propeptide achieving coordination with the catalytically important zinc ion in the active site. Molecular dynamics simulations, ab initio calculations, and wet chemistry experiments presented herein argue for the critical importance of a protonation event at the coordinated thiolate as a prerequisite for the departure of the propeptide from the active site. Furthermore, a catalytically important glutamate is shown to coordinate transiently to the active-site zinc ion to "mask" the positive potential of the zinc ion and lower the energy barrier for dissociation of the protonated cysteine side chain from the zinc ion. In addition, a subtle conformational change by the propeptide is needed in the course of zymogen activation. These elaborate processes take place in concert in the activation process of MMPs, and the insight into these processes presented herein sheds light on a highly regulated physiological process with profound consequences for eukaryotic organisms.

Killing of bacillus spores by aqueous dissolved oxygen, ascorbic acid, and copper ions.

An approach to decontamination of biological endospores is discussed. Specifically, the performance of an aqueous modified Fenton reagent is examined. A modified Fenton reagent formulation of cupric chloride, ascorbic acid, and sodium chloride is shown to be an effective sporicide under aerobic conditions. The traditional Fenton reaction involves the conversion of hydrogen peroxide to hydroxyl radical by aqueous ionic catalysts such as the transition metal ions. Our modified Fenton reaction involves the conversion of aqueous dissolved oxygen to hydrogen peroxide by an ionic catalyst (Cu(2+)) and then subsequent conversion to hydroxyl radicals. Results are given for the modified Fenton reagent deactivating spores of Bacillus globigii. A biocidal mechanism is proposed that is consistent with our experimental results and independently derived information found in the literature. This mechanism requires diffusion of relatively benign species into the interior of the spore, where dissolved O(2) is then converted through a series of reactions which ultimately produce hydroxyl radicals that perform the killing action.