Investigating the Function and Therapeutic Potential of the GCN5b Bromodomain in Toxoplasma Gondii

Abstract

The obligate intracellular protozoan parasite Toxoplasma gondii is a medically relevant pathogen that has infected a third of the world’s population. Toxoplasma is the causative agent of toxoplasmosis, which can have severe repercussions such as encephalitis and even death in immunocompromised patients. Current treatments for toxoplasmosis only target acute infection and can be toxic to patients, resulting in complications including allergy and bone marrow suppression. Thus, the identification of novel drug targets and therapies for toxoplasmosis is vital. Epigenetic modulators of lysine acetylation, including ‘writers,’ ‘erasers,’ and ‘readers,’ have been identified as promising drug targets for protozoan parasites. The lysine acetyltransferase (KAT) GCN5b appears to be an essential gene for Toxoplasma viability. The KAT domain of GCN5b is essential to GCN5b function and is targetable by small molecule inhibitors. While the acetyltransferase activity of this gene is well-characterized, the functionality of its C-terminal bromodomain (BRD) remains to be understood. Bromodomains are readers of lysine acetylation, and recently, bromodomain inhibitors have shown promise in a number of human diseases, as well as in protozoan parasites. We hypothesized that the GCN5b bromodomain is critical for Toxoplasma viability. The data reported herein suggest that the GCN5b bromodomain is important for tachyzoite viability and may serve as a novel therapeutic target in Toxoplasma.