Internalization of erythrocyte acylpeptide hydrolase is required for asexual replication of Plasmodium falciparum

Abstract

ABSTRACTThe human malaria parasite Plasmodium falciparum causes disease as it replicates within the host’s erythrocytes. We have found that an erythrocyte serine hydrolase, acylpeptide hydrolase (APEH), accumulates within developing asexual parasites. Internalization of APEH was associated with a proteolytic event that reduced the size of the catalytic polypeptide from 80 to 55 kDa, which suggests that the enzyme resides in the food vacuole. A triazole urea APEH inhibitor, termed AA74-1, was employed to characterize the role of parasite-internalized APEH. In vitro, AA74-1 was a potent and highly selective inhibitor of both host erythrocyte and parasite-internalized APEH. When added to cultures of parasite-infected erythrocytes, AA74-1 was a relatively poor inhibitor of replication over one asexual replication cycle; however, its potency increased dramatically after a second cycle. This enhancement of potency was not abrogated by the addition of exogenous isopentenyl pyrophosphate, which distinguishes it from the well-characterized “delayed death” phenomenon that is observed with inhibitors that target the parasite apicoplast. Analysis of inhibition by AA74-1 in vivo revealed that a concentration of 100 nM was sufficient to quantitatively inhibit erythrocyte APEH. In contrast, the parasite-internalized APEH pool was inefficiently inhibited at concentrations up to 100-fold higher. Together, these findings provide evidence for an essential catalytic role for parasite-internalized APEH and suggest a model for AA74-1 growth inhibition whereby depletion of parasite APEH activity requires the internalization of inactive host cell APEH over two replication cycles.IMPORTANCENearly half a million deaths were attributed to malaria in 2017. Protozoan parasites of the genus Plasmodium cause disease in humans while replicating asexually within the host’s erythrocytes, with P. falciparum responsible for most of the mortality. Understanding how Plasmodium spp. has adapted to its unique host erythrocyte environment is important for developing malaria control strategies. Here, we demonstrate that P. falciparum co-opts a host erythrocyte serine hydrolase termed acylpeptide hydrolase. By showing that the parasite requires acylpeptide hydrolase activity for replication, we expand our knowledge of host cell factors that contribute to robust parasite growth.