PROJECT SUMMARY Severe malaria due to infection by Plasmodium falciparum is a serious threat to global health with over a million deaths per year. New antimalarial agents are needed due to widespread resistance to existing therapies. A promising antimalarial drug target is the MEP pathway of isoprenoid biosynthesis, which is not found in humans. We have used forward genetic screening to identify malaria parasites resistant to MEP pathway inhibition. We have thus identified a new family of metabolic regulators in malaria, the HAD proteins. We now propose to determine the mechanism by which loss of HAD phosphatases confers drug resistance (Aim 1); establish the biological functions of HADs in parasite development (Aim 2); and use a new MEP pathway inhibitor to identify and characterize additional mechanisms of resistance (Aim 3). We will identify P. falciparum genes and pathways that genetically interact with the essential MEP pathway and our strong preliminary results support this approach. In addition, our results will inform our understanding of the basic biology of the HAD family of metabolic regulators and will determine whether HAD-mediated drug resistance can be transmitted.