Evidence for Catalytic Roles for Plasmodium falciparum Aminopeptidase P in the Food Vacuole and Cytosol

The metalloenzyme aminopeptidase P catalyzes the hydrolysis of amino acids from the amino termini of peptides with a prolyl residue in the second position. The human malaria parasite Plasmodium falciparum expresses a homolog of aminopeptidase P during its asexual intraerythrocytic cycle. P. falciparum aminopeptidase P (PfAPP) shares with mammalian cytosolic aminopeptidase P a three-domain, homodimeric organization and is most active with Mn(II) as the cofactor. A distinguishing feature of PfAPP is a 120-amino acid amino-terminal extension that appears to be removed from the mature protein. PfAPP is present in the food vacuole and cytosol of the parasite, a distribution that suggests roles in vacuolar hemoglobin catabolism and cytosolic peptide turnover. To evaluate the plausibility of these putative functions, the stability and kinetic properties of recombinant PfAPP were evaluated at the acidic pH of the food vacuole and at the near-neutral pH of the cytosol. PfAPP exhibited high stability at 37 °C in the pH range 5.0–7.5. In contrast, recombinant human cytosolic APP1 was unstable and formed a high molecular weight aggregate at acidic pH. At both acidic and slightly basic pH values, PfAPP efficiently hydrolyzed the amino-terminal X-Pro bond of the nonapeptide bradykinin and of two globin pentapeptides that are potential in vivo substrates. These results provide support for roles for PfAPP in peptide catabolism in both the food vacuole and the cytosol and suggest that PfAPP has evolved a dual distribution in response to the metabolic needs of the intraerythrocytic parasite.Malaria remains one of the most deadly global infectious diseases with an estimated 500 million clinical cases and 2 million deaths annually (1, 2). Clinical manifestations of the disease arise as the protozoan malaria parasite replicates asexually within human erythrocytes. Five species of the genus Plasmodium infect humans. The cytoadherent properties of red blood cells infected with Plasmodium falciparum, coupled with the ability of the parasite to reach high parasitemia, make it the most virulent species. The emergence of strains of P. falciparum that are resistant to affordable anti-malarial drugs such as chloroquine has complicated efforts to manage malaria, and new drugs are urgently needed.Aminopeptidases catalyze the hydrolysis of amino acids from the amino termini of proteins and peptides. They participate in a wide range of biological processes, including peptide catabolism, protein maturation, antigen presentation on immune cells, and regulation of hormone activity. During the asexual erythrocytic replication cycle of the malaria parasite, aminopeptidases contribute to the catabolism of peptides generated by two major proteolytic pathways. One of these is initiated at the proteasome, a multifunctional protease that plays an important role in the turnover of ubiquitinated cellular proteins in the cytosol (3–5). In addition, the parasite transports host red blood cell cytosol (consisting primarily of hemoglobin) to an acidic degradative organelle, the food vacuole, where it is degraded in a proteasome-independent pathway (6, 7). As up to 75% of the host cell hemoglobin is catabolized during the intraerythrocytic cycle (8, 9), flux through the vacuolar pathway is substantial. Three aminopeptidases have been identified as key players in recycling amino acids from peptides generated by the proteasomal and vacuolar catabolic pathways: leucine aminopeptidase, aminopeptidase N (PfA-M1), and aminopeptidase P (10–14). The latter two enzymes have been found in the food vacuole and therefore may play a direct role in hemoglobin catabolism (11). An aspartyl aminopeptidase is also expressed in asexual stage parasites and hydrolyzes amino-terminal aspartyl and glutamyl substrates (15); however, disruption of its gene does not prevent efficient intraerythrocytic replication (11).Aminopeptidase P (APP)² homologs exhibit high specificity for proline in the second position of the substrate (the P1′ position in the nomenclature of Schechter and Berger (16)) and catalyze the hydrolysis of the X-Pro amide bond, where X is any aminoacyl residue (17). Because of the cyclic nature of the proline side chain, X-Pro-containing peptides are not easily accommodated in the active sites of broad specificity aminopeptidases (17). In mammals, three APP isozymes have been identified. APP1 is found in the cytosolic fraction of cell lysates and has been characterized from a variety of tissues (18–20). Although this enzyme has not, to our knowledge, been localized in intact cells, the apparent lack of specific targeting information is consistent with a role in cytosolic peptide turnover. Active cytosolic forms of APP have been reported in plants (21), fruit flies (22), the microsporidian parasite Encephalitozoon cuniculi (23), and in intestinal cells in Caenorhabditis elegans (24), where it is believed to play a role in the catabolism of peptides produced from ingested bacteria. Mammalian APP2 is a glycosylated ectoenzyme anchored into the membrane of endothelial and epithelial cells with a glycosylphosphatidylinositol attachment (25). The best characterized role of APP2 is the inactivation of the plasma hormone bradykinin, a nonapeptide, through cleavage of the Arg-Pro amino-terminal peptide bond (26, 27). Inhibition of APP2 potentiates the vasodilatory and cardioprotective properties of bradykinin, and APP2 has been considered a target for the development of cardiovascular drugs (28–30). A third isoform, APP3, has been identified in the human genome and may be a mitochondrial enzyme but has not yet been characterized (31). Prokaryotic APP homologs contribute to intracellular peptide turnover (32).P. falciparum aminopeptidase P (PfAPP) appears to be important for intraerythrocytic growth, as parasites with a disrupted PfAPP gene could not be isolated (11). We have previously localized a PfAPP-yellow fluorescent protein fusion to the food vacuole and the cytosol of the parasite (11). The cytosolic pool of PfAPP probably fulfills a role in peptide turnover and amino acid recycling that is orthologous to those of the cytosolic enzymes described above. In contrast, there is no report to our knowledge of an aminopeptidase P homolog functioning in an acidic environment akin to the malarial food vacuole. Moreover, characterization of mammalian aminopeptidase P homologs typically reveals a pH optimum of 7–8 with relatively little, if any, activity in the pH range 5.0–5.5 (18–20). Although we have previously detected PfAPP activity at acidic pH (11), the catalytic efficiency of the enzyme has not been characterized. Thus, at the outset of this study it was not clear whether PfAPP has a significant catalytic role in the food vacuole.Here we have localized untagged, native PfAPP in the parasite and have confirmed the dual cytosolic/vacuolar distribution of the enzyme. The domain organization, quaternary structure, and metal requirement of PfAPP were characterized. To evaluate the plausibility of a catalytic role for PfAPP at acidic and near-neutral pH, its stability in the pH range 5.0–7.5 was assessed and compared with that of human cytosolic APP1, an enzyme that does not, to our knowledge, have a physiological role in an acidic environment. The catalytic efficiency of PfAPP at a range of pH values was characterized with three X-Pro-containing peptides, two of which are found in the sequences of human α- and β-globin and therefore represent potentially physiological substrates.