Kinetic characterization and search for inhibitors of Ohr (Organic Hydroperoxide Resistance protein) from Xylella fastidiosa

Xylella fastidiosa is a gram-negative bacterium that colonizes the xylem and is the causative agent for several plant diseases. In Brazil, the main disease caused by this bacterium is the CVC (Citrus Variegated Chlorosis), which provokes large losses to the orange production in São Paulo and Minas Gerais states. Despite the current disease control, it has not been yet developed a specific method to eliminate the bacterium. During the plant-pathogen interactions, hosts produce an exacerbated amount of oxidants, in an attempt to eliminate the pathogen. Among them, fatty acids hydroperoxides are formed by the lipoxygenase action or even by the direct reaction between lipids and oxidant species. During the evolutionary process, pathogen defense mechanisms against oxidative species have evolved. Among them, Ohr (Organic Hydroperoxide Resistance protein) that is a Cys-based, lipoyl dependent peroxidase, displaying high activity towards organic hydroperoxides. This protein probably plays a central role in oxidative stress response and presnts some particularities, which make it a potential target for drug design. The objectives of this project were to characterize possible physiological substrates of Ohr from X. fastidiosa and search for molecules capable of inhibiting its peroxidase activity. Initially, we demonstrated that Ohr reduced fatty acid hydroperoxides with high efficiency (kcat/KM ~ 106 M-1.s-1). Moreover, these hydroperoxides inactivated Ohr in a dose-dependent manner, probably due to the high affinity between them and the enzyme. However, the enzyme did not display any activity towards phospholipids (posphatidilcholine) hydroperoxides and cholesterol hydroperoxide. Besides, we elucidated the structure of Ohr in the oxidized form (disulfide bond), which gave us insights on the dynamics of structural elements in the catalytic site. Ultimately, we identified a compound that was able to inhibit the peroxidase activity of Ohr in vitro, and we gained evidences that this compound can affect the bacterial growth under oxidative stress. (AU)