Oleuropein activates autophagy to circumvent anti-plasmodial defense.

Antimalarial drug resistance and unavailability of effective vaccine warrant for newer drugs and drug targets. Hence, anti-inflammatory activity of phyto-compound (oleuropein; OLP) was determined in antigen (LPS)-stimulated human THP-1 macrophages (macrophage model of inflammation; MMI). Reduction in the inflammation was controlled by the PI3K-Akt1 signaling to establish the "immune-homeostasis." Also, OLP treatment influenced the cell death/autophagy axis leading to the modulated inflammation for extended cell survival. The findings with MII prompted us to detect the antimalarial activity of OLP in the wild type (3D7), D10-expressing GFP-Atg18 parasite, and chloroquine-resistant (Dd2) parasite. OLP did not show the parasite inhibition in the routine in vitro culture of P. falciparum whereas OLP increased the antimalarial activity of artesunate. The molecular docking of autophagy-related proteins, investigations with MMI, and parasite inhibition assays indicated that the host activated the autophagy to survive OLP pressure. The challenge model of P. berghei infection showed to induce autophagy for circumventing anti-plasmodial defenses.

The Ionic and hydrophobic interactions are required for the auto activation of cysteine proteases of Plasmodium falciparum.

The Plasmodium falciparum cysteine proteases falcipain-2 and falcipain-3 are major hemoglobinases and potential antimalarial drug targets. Our previous studies demonstrated that these enzymes are equipped with specific domains for specific functions. Structural and functional analysis of falcipains showed that they have unique domains including a refolding domain and a hemoglobin binding domain. As with many proteases, falcipain-2 and falcipain-3 are synthesized as inactive zymogens. However, it is not known how these enzymes get activated for hemoglobin hydrolysis. In this study, we are presenting the first evidence that salt bridges and hydrophobic interactions are required for the auto activation of cysteine proteases of P.falciparum. To investigate the mechanism of activation of these enzymes, we expressed the wild type protein as well as different mutants in E.coli. Refolding was assessed by circular dichroism. Both CD and trans activation data showed that the wild type enzymes and mutants are rich in secondary structures with similar folds. Our study revealed that prodomain-mature domain of falcipain-2 and falcipain-3 interacts via salt bridges and hydrophobic interactions. We mutated specific residues of falcipain-2 and falcipain-3, and evaluated their ability to undergo auto processing. Mutagenesis result showed that two salt bridges (Arg¹85- Glu²²¹, Glu²¹°- Lys4°³) in falcipain-2, and one salt bridge (Arg²°²-Glu²³8) in falcipain-3, play crucial roles in the activation of these enzymes. Further study revealed that hydrophobic interactions present both in falcipain-2 (Phe²¹4 Trp449 Trp45³) and falcipain-3 (Phe²³¹ Trp457 Trp46¹) also play important roles in the activation of these enzymes. Our results revealed the interactions involved in auto processing of two major hemoglobinases of malaria parasite.

Falcipain cysteine proteases require bipartite motifs for trafficking to the Plasmodium falciparum food vacuole.

The Plasmodium falciparum cysteine proteases falcipain-2 and falcipain-3 hydrolyze hemoglobin in an acidic food vacuole to provide amino acids for erythrocytic malaria parasites. Trafficking to the food vacuole has not been well characterized. To study trafficking of falcipains, which include large membrane-spanning prodomains, we utilized chimeras with portions of the proteases fused to green fluorescent protein. The prodomains of falcipain-2 and falcipain-3 were sufficient to target green fluorescent protein to the food vacuole. Using serial truncations, deletions, and point mutations, we showed that both a 20-amino acid stretch of the lumenal portion and a 10-amino acid stretch of the cytoplasmic portion of the falcipain-2 prodomain were required for efficient food vacuolar trafficking. Mutants with altered trafficking were arrested at the plasma membrane, implicating trafficking via this structure. Our results indicate that falcipains utilize a previously undescribed bipartite motif-dependent mechanism for targeting to a hydrolytic organelle, suggesting inhibition of this unique mechanism as a new means of antimalarial chemotherapy.

A chimeric cysteine protease of Plasmodium berghei engineered to resemble the Plasmodium falciparum protease falcipain-2.

The cysteine proteases falcipain-2 and falcipain-3 are hemoglobinases and potential targets for chemotherapy directed against Plasmodium falciparum, the most important human malaria parasite. Most in vivo evaluations of candidate antimalarials are conducted in murine malaria models, and falcipain homologs from rodent malaria parasites differ importantly from falcipain-2 and falcipain-3. We expressed berghepain-2, the single homolog of falcipain-2 and falcipain-3 of the rodent parasite P. berghei, in Escherichia coli, and characterized the refolded active enzyme. Berghepain-2 was biochemically very similar to the previously characterized rodent plasmodial protease vinckepain-2, but differed from falcipain-2 and falcipain-3 in its fine substrate and inhibitor specificity. We then used homology modeling and evolutionary trace analysis to predict key amino acids that mediate functional differences between falcipain-2 and berghepain-2. Thirteen amino acids were sequentially altered to replace berghepain-2 residues with those in falcipain-2. Mutant enzymes varied in activity and sensitivity to inhibitors. A berghepain-2 mutant with eight substitutions retained good activity and demonstrated fine substrate and inhibitor sensitivity more similar to that of falcipain-2 than berghepain-2. These results suggest that, to facilitate drug discovery, we can produce mutant animal model malaria parasites with biochemical properties more like those of the key drug target, P. falciparum.

Gene disruptions demonstrate independent roles for the four falcipain cysteine proteases of Plasmodium falciparum.

Erythrocytic stages of the malaria parasite Plasmodium falciparum express four related papain-family cysteine proteases, termed falcipains. Falcipain-2 and falcipain-3 are food vacuole hemoglobinases, but determination of the specific roles of these and other falcipains has been incomplete. To better characterize biological roles, we attempted disruption of each falcipain gene in the same strain (3D7) of P. falciparum. Disruption of falcipain-1, falcipain-2, and falcipain-2' was achieved. In each case knockouts multiplied at the same rate as wild-type parasites. The morphologies of erythrocytic falcipain-1 and falcipain-2' knockout parasites were indistinguishable from those of wild-type parasites. In contrast, consistent with previous results, falcipain-2 knockout trophozoites developed swollen, hemoglobin-filled food vacuoles, indicative of a block in hemoglobin hydrolysis and were, compared to wild-type parasites, twice as sensitive to cysteine protease inhibitors and over 1000 times more sensitive to an aspartic protease inhibitor. The falcipain-3 gene could not be disrupted, but replacement with a tagged functional copy was readily achieved, strongly suggesting that falcipain-3 is essential to erythrocytic parasites. Our data suggest key roles for falcipain-2 and falcipain-3 in the development of erythrocytic malaria parasites and a complex interplay between P. falciparum cysteine and aspartic proteases.

Structural basis for unique mechanisms of folding and hemoglobin binding by a malarial protease.

Falcipain-2 (FP2), the major cysteine protease of the human malaria parasite Plasmodium falciparum, is a hemoglobinase and promising drug target. Here we report the crystal structure of FP2 in complex with a protease inhibitor, cystatin. The FP2 structure reveals two previously undescribed cysteine protease structural motifs, designated FP2(nose) and FP2(arm), in addition to details of the active site that will help focus inhibitor design. Unlike most cysteine proteases, FP2 does not require a prodomain but only the short FP2(nose) motif to correctly fold and gain catalytic activity. Our structure and mutagenesis data suggest a molecular basis for this unique mechanism by highlighting the functional role of two Tyr within FP2(nose) and a conserved Glu outside this motif. The FP2(arm) motif is required for hemoglobinase activity. The structure reveals topographic features and a negative charge cluster surrounding FP2(arm) that suggest it may serve as an exo-site for hemoglobin binding. Motifs similar to FP2(nose) and FP2(arm) are found only in related plasmodial proteases, suggesting that they confer malaria-specific functions.

Plasmodium falciparum: biochemical characterization of the cysteine protease falcipain-2'.

The Plasmodium falciparum cysteine proteases falcipain-2 and falcipain-3 are hemoglobinases and potential antimalarial drug targets. The falcipain-2' gene was identified recently and is nearly identical in sequence to falcipain-2. The product of this gene has not been studied previously. The mature protease domain of falcipain-2' was expressed in Escherichia coli, purified, and refolded to active enzyme. Functional analysis revealed similar biochemical properties to those of falcipain-2, including pH optima (pH 5.5-7.0), reducing requirements, and substrate preference. Studies with cysteine protease inhibitors showed similar inhibition of falcipain-2 and falcipain-2', although specificities were not identical. Considering activity against the presumed biological substrate, both enzymes readily hydrolyzed hemoglobin. Our results confirm that falcipain-2' is an active hemoglobinase and suggest that falcipain-2 and falcipain-2' play similar roles in erythrocytic parasites but that, for promising cysteine protease inhibitors, it will be important to confirm activity against this additional target.

The Plasmodium falciparum cysteine protease falcipain-2 captures its substrate, hemoglobin, via a unique motif.

Falcipain-2 (FP2) is a papain family cysteine protease and important hemoglobinase of erythrocytic Plasmodium falciparum parasites. Inhibitors of FP2 block hemoglobin hydrolysis and parasite development, suggesting that this enzyme is a promising target for antimalarial chemotherapy. FP2 and related plasmodial cysteine proteases have an unusual 14-aa motif near the C terminus of the catalytic domain. Recent solution of the structure of FP2 showed this motif to form a beta-hairpin that is distant from the enzyme active site and protrudes out from the protein. To evaluate the function of this motif, we compared the activity of the wild-type enzyme with that of a mutant lacking 10 aa of the motif (Delta10FP2). Delta10FP2 had nearly identical activity to that of the wild-type enzyme against peptide substrates and the protein substrates casein and gelatin. However, Delta10FP2 demonstrated negligible activity against hemoglobin or globin. FP2 that was inhibited with trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane (FP2E-64) formed a complex with hemoglobin, but Delta10FP2E-64 did not, indicating that the motif mediates binding to hemoglobin independent of the active site. A peptide encoding the motif blocked hemoglobin hydrolysis, but not the hydrolysis of casein. Kinetics for the inhibition of Delta10FP2 were very similar to those for FP2 with peptidyl and protein inhibitors, but Delta10FP2 was poorly inhibited by the inhibitory prodomain of FP2. Our results indicate that FP2 utilizes an unusual motif for two specific functions, interaction with hemoglobin, its natural substrate, and interaction with the prodomain, its natural inhibitor.

Plasmodium falciparum cysteine protease falcipain-1 is not essential in erythrocytic stage malaria parasites.

Among potential new targets for antimalarial chemotherapy are Plasmodium falciparum cysteine proteases, known as falcipains. Falcipain-2 and falcipain-3 are food vacuole hemoglobinases that may have additional functions. The function of falcipain-1 remains uncertain. To better characterize the role of falcipain-1 in erythrocytic parasites, we disrupted the falcipain-1 gene and characterized recombinant parasites. Disruption of the falcipain-1 gene was confirmed with Southern blots, and loss of expression of falcipain-1 was confirmed with immunoblots and by loss of labeling with a specific protease inhibitor. Compared with wild-type parasites, falcipain-1 knockout parasites developed normally, with the same morphology, multiplication rate, and invasion efficiency, and without significant differences in sensitivity to cysteine protease inhibitors. In wild-type and knockout parasites, cysteine protease inhibitors blocked hemoglobin hydrolysis in trophozoites, with a subsequent block in rupture of erythrocytes by mature schizonts, but they did not inhibit erythrocyte invasion by merozoites. Our results indicate that although falcipain-1 is expressed by erythrocytic parasites, it is not essential for normal development during this stage or for erythrocyte invasion.

Gene disruption confirms a critical role for the cysteine protease falcipain-2 in hemoglobin hydrolysis by Plasmodium falciparum.

Erythrocytic malaria parasites degrade hemoglobin in an acidic food vacuole to acquire free amino acids and maintain parasite homeostasis. Hemoglobin hydrolysis appears to be a cooperative process requiring cysteine proteases (falcipains) and aspartic proteases (plasmepsins), but the specific roles of different enzymes in this process are unknown. We previously showed that falcipain-2 is a major trophozoite food vacuole cysteine protease. To characterize the specific role of falcipain-2, we disrupted the falcipain-2 gene and assessed the effect of this alteration. Falcipain-2-knockout trophozoites had markedly diminished cysteine protease activity and swollen, dark staining food vacuoles, consistent with a block in hemoglobin hydrolysis, as caused by cysteine protease inhibitors. However, more mature stages of knockout parasites were indistinguishable from wild-type parasites and developed normally. The knockout parasites had decreased and delayed expression of falcipain-2, which appeared to be directed by increased transcription of a second copy of the gene (falcipain-2'). Expression of other falcipains and plasmepsins was similar in wild-type and knockout parasites. Compared with wild-type, knockout parasites were about 3 times more sensitive to the cysteine protease inhibitors E-64 and leupeptin, and over 50-fold more sensitive to the aspartic protease inhibitor pepstatin. Our results assign a specific function for falcipain-2, the hydrolysis of hemoglobin in trophozoites. In addition, they highlight the cooperative action of cysteine and aspartic proteases in hemoglobin degradation by malaria parasites.

Independent intramolecular mediators of folding, activity, and inhibition for the Plasmodium falciparum cysteine protease falcipain-2.

The Plasmodium falciparum cysteine protease falcipain-2 is a trophozoite hemoglobinase and potential antimalarial drug target. Unlike other studied papain family proteases, falcipain-2 does not require its prodomain for folding to active enzyme. Rather, folding is mediated by an amino-terminal extension of the mature protease. As in related enzymes, the prodomain is a potent inhibitor of falcipain-2. We now report further functional evaluation of the domains of falcipain-2 and related plasmodial proteases. The minimum requirement for folding of falcipain-2 and four related plasmodial cysteine proteases was inclusion of a 14-15-residue amino-terminal folding domain, beginning with a conserved Tyr. Chimeras of the falcipain-2 catalytic domain with extensions from six other plasmodial proteases folded normally and had kinetic parameters (k(cat)/K(m) 124,000-195,000 M(-1) s(-1)) similar to those of recombinant falcipain-2 (k(cat)/K(m) 120,000 M(-1) s(-1)), indicating that the folding domain is functionally conserved across the falcipain-2 subfamily. Correct folding also occurred when the catalytic domain was refolded with a separate prodomain-folding domain construct but not with an isolated folding domain peptide. Thus, the prodomain mediated interaction between the other two domains when they were not covalently bound. The prodomain-catalytic domain interaction was independent of the active site, because it was blocked by free inactive catalytic domain but not by the active site-binding peptide leupeptin. The folded catalytic domain retained activity after purification from the prodomain-folding domain construct (k(cat)/K(m) 168,000 M(-1) s(-1)), indicating that the folding domain is not required for activity once folding has been achieved. Activity was lost after nonreducing gelatin SDS-PAGE but not native gelatin PAGE, indicating that correct disulfide bonds are insufficient to direct appropriate folding. Our results identify unique features of the falcipain-2 subfamily with independent mediation of activity, folding, and inhibition.

Identification and biochemical characterization of vivapains, cysteine proteases of the malaria parasite Plasmodium vivax.

Cysteine proteases play important roles in the life cycles of malaria parasites. Cysteine protease inhibitors block haemoglobin hydrolysis and development in Plasmodium falciparum, suggesting that the cysteine proteases of this major human pathogen, termed falcipains, are appropriate therapeutic targets. To expand our understanding of plasmodial proteases to Plasmodium vivax, the other prevalent human malaria parasite, we identified and cloned genes encoding the P. vivax cysteine proteases, vivapain-2 and vivapain-3, and functionally expressed the proteases in Escherichia coli. The vivapain-2 and vivapain-3 genes predicted papain-family cysteine proteases, which shared a number of unusual features with falcipain-2 and falcipain-3, including large prodomains and short N-terminal extensions on the catalytic domain. Recombinant vivapain-2 and vivapain-3 shared properties with the falcipains, including acidic pH optima, requirements for reducing conditions for activity and hydrolysis of substrates with positively charged residues at P1 and Leu at P2. Both enzymes hydrolysed native haemoglobin at acidic pH and the erythrocyte cytoskeletal protein 4.1 at neutral pH, suggesting similar biological roles to the falcipains. Considering inhibitor profiles, the vivapains were inhibited by fluoromethylketone and vinyl sulphone inhibitors that also inhibited falcipains and have demonstrated potent antimalarial activity.

Critical role of amino acid 23 in mediating activity and specificity of vinckepain-2, a papain-family cysteine protease of rodent malaria parasites.

Cysteine proteases of Plasmodium falciparum, known as falcipains, have been identified as haemoglobinases and potential drug targets. As anti-malarial drug discovery requires the analysis of non-primate malaria, genes encoding related cysteine proteases of the rodent malaria parasites P. vinckei (vinckepain-2) and P. berghei (berghepain-2) were characterized. These genes encoded fairly typical papain-family proteases, but they contained an unusual substitution of Gly23 with Ala (papain numbering system). Vinckepain-2 was expressed in Escherichia coli, solubilized, refolded and autoprocessed to an active enzyme. The protease shared important features with the falcipains, including an acidic pH optimum, preference for reducing conditions, optimal cleavage of peptide substrates with P2 Leu and ready hydrolysis of haemoglobin. However, key differences between the plasmodial proteases were identified. In particular, vinckepain-2 showed very different kinetics against many substrates and an unusual preference for peptide substrates with P1 Gly. Replacement of Ala23 with Gly remarkably altered vinckepain-2, including loss of the P1 Gly substrate preference, markedly increased catalytic activity ( k cat/ K m increased approx. 100-fold) and more rapid autohydrolysis. The present study identifies key animal-model parasite targets. It indicates that drug discovery studies must take into account important differences between plasmodial proteases and sheds light on the critical role of amino acid 23 in catalysis by papain-family proteases.

Cysteine proteases of malaria parasites: targets for chemotherapy.

New drugs to treat malaria are urgently needed. Cysteine proteases of malaria parasites offer potential new chemotherapeutic targets. Cysteine protease inhibitors block parasite hemoglobin hydrolysis and development, indicating that cysteine proteases play a key role in hemoglobin degradation, a necessary function of erythrocytic trophozoites. These inhibitors also block the rupture of erythrocytes by mature parasites, suggesting an additional role for cysteine proteases in the hydrolysis of erythrocyte cytoskeletal proteins. Recent studies have shown that the repertoire of cysteine proteases of malaria parasites is larger than was previously realized. Plasmodium falciparum, the most virulent human malaria parasite, expresses three papain-family cysteine proteases, known as falcipains. All three proteases are expressed by trophozoites and hydrolyze hemoglobin at acidic pH, suggesting roles in this process. Falcipain-2 also hydrolyzes ankyrin at neutral pH, suggesting additional activity against erythrocyte cytoskeletal targets. Multiple orthologs of the falcipains have been identified in other plasmodial species. Analysis of orthologs from animal model rodent parasites identified similar features, but some noteworthy biochemical differences between the cysteine proteases. These differences must be taken into account in interpreting in vivo experiments. A number of small molecule cysteine protease inhibitors blocked parasite hemoglobin hydrolysis and development, and inhibitory effects against parasites generally correlated with inhibition of falcipain-2. Some compounds also cured mice infected with otherwise lethal malaria infections. Current research priorities are to better characterize the biological roles and biochemical features of the falcipains. In addition, efforts to identify optimal falcipain inhibitors as antimalarials are underway.

Folding of the Plasmodium falciparum cysteine protease falcipain-2 is mediated by a chaperone-like peptide and not the prodomain.

Papain-family cysteine proteases of the malaria parasite Plasmodium falciparum, known as falcipains, are hemoglobinases and potential drug targets. Available data suggest that papain-family proteases require prodomains for correct folding into functional conformations. However, in prior studies of falcipain-2, an Escherichia coli-expressed construct containing only a small portion of the prodomain refolded efficiently, suggesting that this enzyme differs in this regard from other papain-family enzymes. To better characterize the determinants of folding for falcipain-2, we expressed multiple pro- and mature constructs of the enzyme in E. coli and assessed their abilities to refold. Mature falcipain-2 refolded into active protease with very similar properties to those of proteins resulting from the refolding of proenzyme constructs. Deletion of a 17-amino acid amino-terminal segment of the mature protease yielded a construct incapable of correct folding, but inclusion of this segment in trans allowed folding to active falcipain-2. The prodomain was a potent, competitive, and reversible inhibitor of mature falcipain-2 (K(i) 10(-10) m). Our results identify a chaperone-like function of an amino-terminal segment of mature falcipain-2 and suggest that protease inhibition, but not the mediation of folding, is a principal function of the falcipain-2 prodomain.