Abstract
Enzymes of the serine hydrolase superfamily are ubiquitous, highly versatile catalysts that mediate a wide variety of metabolic reactions in eukaryotic cells, while also being amenable to selective inhibition. We have employed a fluorophosphonate-based affinity capture probe and mass spectrometry to explore the expression profile and metabolic roles of the 56-member P. falciparum serine hydrolase superfamily in the asexual erythrocytic stage of P. falciparum. This approach provided a detailed census of active serine hydrolases in the asexual parasite, with identification of 21 active serine hydrolases from α/β hydrolase, patatin, and rhomboid protease families. To gain insight into their functional roles and substrates, the pan-lipase inhibitor isopropyl dodecylfluorophosphonate was employed for competitive activity-based protein profiling, leading to the identification of seven serine hydrolases with potential lipolytic activity. We demonstrated how a chemoproteomic approach can provide clues to the specificity of serine hydrolases by using a panel of neutral lipase inhibitors to identify an enzyme that reacts potently with a covalent monoacylglycerol lipase inhibitor. In combination with existing phenotypic data, our studies define a set of serine hydrolases that likely mediate critical metabolic reactions in asexual parasites and enable rational prioritization of future functional characterization and inhibitor development efforts.
Highlights
Enzymes of the serine hydrolase superfamily are ubiquitous, highly versatile catalysts that mediate a wide variety of metabolic reactions in eukaryotic cells, while being amenable to selective inhibition
We have previously shown that TAMRA-fluorophosphonate (TAMRA-FP) is an effective probe for labelling serine hydrolases in lysates of intraerythrocytic asexual P. falciparum parasites that have been isolated with the sterol glycoside saponin[11]
We have demonstrated the utility of desthiobiotin-FP for a proteomic characterization of active serine hydrolases in the late asexual stage of erythrocytic P. falciparum
Summary
Enzymes of the serine hydrolase superfamily are ubiquitous, highly versatile catalysts that mediate a wide variety of metabolic reactions in eukaryotic cells, while being amenable to selective inhibition. We have employed a fluorophosphonate-based affinity capture probe and mass spectrometry to explore the expression profile and metabolic roles of the 56-member P. falciparum serine hydrolase superfamily in the asexual erythrocytic stage of P. falciparum. This approach provided a detailed census of active serine hydrolases in the asexual parasite, with identification of 21 active serine hydrolases from α/β hydrolase, patatin, and rhomboid protease families. The nucleophilicity of the serine hydroxyl group has been leveraged to develop chemical biology reagents for characterizing enzymes of the serine hydrolase superfamily on a proteomic scale Prominent among these are fluorophosphonate (FP)-based activity-based probes, which react with the active site serine www.nature.com/scientificreports a SAP b. A fluorophore-containing probe permits fluorescence-based visualization of labelled enzymes[8], whereas appending a (desthio)biotin moiety provides an affinity handle for purification and identification by mass spectrometry[9,10]
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