Abstract
Malarial dipeptidyl aminopeptidases (DPAPs) are cysteine proteases important for parasite development thus making them attractive drug targets. In order to develop inhibitors specific to the parasite enzymes, it is necessary to map the determinants of substrate specificity of the parasite enzymes and its mammalian homologue cathepsin C (CatC). Here, we screened peptide‐based libraries of substrates and covalent inhibitors to characterize the differences in specificity between parasite DPAPs and CatC, and used this information to develop highly selective DPAP1 and DPAP3 inhibitors. Interestingly, while the primary amino acid specificity of a protease is often used to develop potent inhibitors, we show that equally potent and highly specific inhibitors can be developed based on the sequences of nonoptimal peptide substrates. Finally, our homology modelling and docking studies provide potential structural explanations of the differences in specificity between DPAP1, DPAP3, and CatC, and between substrates and inhibitors in the case of DPAP3. Overall, this study illustrates that focusing the development of protease inhibitors solely on substrate specificity might overlook important structural features that can be exploited to develop highly potent and selective compounds.
Highlights
Malaria is a devastating infectious parasitic disease causing nearly half a million deaths every year [1]
Note that D-Phg is the only DAA in P2 that is cleaved by DPAP3, albeit poorly
This study provides the first characterization of the specificity of DPAP3, a cysteine protease important for efficient invasion of red blood cell (RBC) by the malaria parasite [21]
Summary
Malaria is a devastating infectious parasitic disease causing nearly half a million deaths every year [1]. Malaria is caused by parasites of the Plasmodium genus and is transmitted by Anopheles mosquitoes during a blood meal. Parasites reproduce sexually, multiply and travel to the salivary glands from where they are transmitted to the human host. Over the last 15 years, the world has seen a very significant drop in malaria incidence, mainly due to the global distribution of insecticide-impregnated bed nets and the use of artemisinin-based combination therapies as the standard of care for uncomplicated malaria [2]. Malaria remains a major global health burden with half of the world population at risk and around 200 million clinical cases per year. Mosquitoes are becoming increasingly resistant to insecticides [3], and artemisinin resistance is on the rise [4], making the identification of antimalarial targets and the development of drugs with novel mechanisms of action are extremely urgent [5]
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