Genetic Markers of Adaptation of Plasmodium falciparum to Transmission by American Vectors Identified in the Genomes of Parasites from Haiti and South America.

The malaria parasite, Plasmodium falciparum, was introduced into Hispaniola and other regions of the Americas through the slave trade spanning the 16th through the 19th centuries. During this period, more than 12 million Africans were brought across the Atlantic to the Caribbean and other regions of the Americas. Since malaria is holoendemic in West Africa, a substantial percentage of these individuals carried the parasite. St. Domingue on Hispaniola, now modern-day Haiti, was a major port of disembarkation, and malaria is still actively transmitted there. We undertook a detailed study of the phylogenetics of the Haitian parasites and those from Colombia and Peru utilizing whole-genome sequencing. Principal-component and phylogenetic analyses, based upon single nucleotide polymorphisms (SNPs) in protein coding regions, indicate that, despite the potential for millions of introductions from Africa, the Haitian parasites share an ancestral relationship within a well-supported monophyletic clade with parasites from South America, while belonging to a distinct lineage. This result, in stark contrast to the historical record of parasite introductions, is best explained by a severe population bottleneck experienced by the parasites introduced into the Americas. Here, evidence is presented for targeted selection of rare African alleles in genes which are expressed in the mosquito stages of the parasite's life cycle. These genetic markers support the hypothesis that the severe population bottleneck was caused by the required adaptation of the parasite to transmission by new definitive hosts among the Anopheles (Nyssorhynchus) spp. found in the Caribbean and South America.IMPORTANCE Historical data suggest that millions of P. falciparum parasite lineages were introduced into the Americas during the trans-Atlantic slave trade, which would suggest a paraphyletic origin of the extant isolates in the Western Hemisphere. Our analyses of whole-genome variants show that the American parasites belong to a well-supported monophyletic clade. We hypothesize that the required adaptation to American vectors created a severe bottleneck, reducing the effective introduction to a few lineages. In support of this hypothesis, we discovered genes expressed in the mosquito stages of the life cycle that have alleles with multiple, high-frequency or fixed, nonsynonymous mutations in the American populations which are rarely found in African isolates. These alleles appear to be in gene products critical for transmission through the anopheline vector. Thus, these results may inform efforts to develop novel transmission-blocking vaccines by identifying parasite proteins functionally interacting with the vector that are important for successful transmission. Further, to the best of our knowledge, these are the first whole-genome data available from Haitian P. falciparum isolates. Defining the genome of these parasites provides genetic markers useful for mapping parasite populations and monitoring parasite movements/introductions.

High prevalence of asymptomatic malaria infections: a cross-sectional study in rural areas in six departments in Haiti.

BACKGROUND: Public health measures are poised for transition from malaria control to malaria elimination on the island of Hispaniola. Assessment of the reservoir of asymptomatic infections from which acute malaria cases may derive is critical to plan and evaluate elimination efforts. Current field technology is ill suited for detecting sub-microscopic infections, thus highly sensitive survey methods capable of detecting virtually all infections are needed. In this study the prevalence of infection with Plasmodium falciparum was determined in patients seeking medical care primarily for non-febrile conditions in six departments in Haiti using a newly designed qRT-PCR-based assay. METHODS: Three different methods of parasite detection were compared to assess their utility in approximating the prevalence of P. falciparum infections in the population: malaria rapid diagnostic test (RDT) designed to detect histidine-rich protein 2 (HRP2), thick smear microscopy, and a quantitative reverse transcription polymerase chain reaction (qRT-PCR) assay based upon the small sub-unit ribosomal RNA. The limit of detection of the qRT-PCR assay utilized was 0.0003 parasite/µL of blood. Venous blood was obtained from a total of 563 subjects from six departments in Haiti, all of whom were seeking medical attention without complaints consistent with malaria. Each subject was questioned for knowledge and behaviour using demographic and epidemiological survey to identify risk factors for disease transmission. RESULTS: Among the 563 samples tested, ten and 16 were found positive for malaria by RDT and microscopy, respectively. Using the qRT-PCR test to assess the infection status of these subjects, an additional 92 were identified for a total of 108. Based upon the qRT-PCR assay results, a wide variation in prevalence of infection in asymptomatic subjects was seen between geographic locations ranging from 4-41%. The prevalence of infection was highest in the Grand Anse, Nord and Sud-Est Departments, and demographic data from questionnaires provide evidence for focal disease transmission. CONCLUSIONS: The qRT-PCR assay is sufficiently sensitive to identify an unexpectedly large number of asymptomatic, submicroscopic infections. Identifying and clearing these infections presents a significant challenge to both control and elimination efforts, but the qRT-PCR assay offers a reliable method to identify them.

Enzymatic Characterization of Recombinant Food Vacuole Plasmepsin 4 from the Rodent Malaria Parasite Plasmodium berghei.

The rodent malaria parasite Plasmodium berghei is a practical model organism for experimental studies of human malaria. Plasmepsins are a class of aspartic proteinase isoforms that exert multiple pathological effects in malaria parasites. Plasmepsins residing in the food vacuole (FV) of the parasite hydrolyze hemoglobin in red blood cells. In this study, we cloned PbPM4, the FV plasmepsin gene of P. berghei that encoded an N-terminally truncated pro-segment and the mature enzyme from genomic DNA. We over-expressed this PbPM4 zymogen as inclusion bodies (IB) in Escherichia coli, and purified the protein following in vitro IB refolding. Auto-maturation of the PbPM4 zymogen to mature enzyme was carried out at pH 4.5, 5.0, and 5.5. Interestingly, we found that the PbPM4 zymogen exhibited catalytic activity regardless of the presence of the pro-segment. We determined the optimal catalytic conditions for PbPM4 and studied enzyme kinetics on substrates and inhibitors of aspartic proteinases. Using combinatorial chemistry-based peptide libraries, we studied the active site preferences of PbPM4 at subsites S1, S2, S3, S1', S2' and S3'. Based on these results, we designed and synthesized a selective peptidomimetic compound and tested its inhibition of PbPM4, seven FV plasmepsins from human malaria parasites, and human cathepsin D (hcatD). We showed that this compound exhibited a >10-fold selectivity to PbPM4 and human malaria parasite plasmepsin 4 orthologs versus hcatD. Data from this study furthesr our understanding of enzymatic characteristics of the plasmepsin family and provides leads for anti-malarial drug design.

Survey of Plasmodium falciparum multidrug resistance-1 and chloroquine resistance transporter alleles in Haiti.

BACKGROUND: In Haiti where chloroquine (CQ) is widely used for malaria treatment, reports of resistance are scarce. However, recent identification of CQ resistance genotypes in one site is suggestive of an emerging problem. Additional studies are needed to evaluate genetic mutations associated with CQ resistance, especially in the Plasmodium falciparum multi-drug resistance-1 gene (pfmdr1) while expanding the already available information on P. falciparum CQ transporter gene (pfcrt) in Haiti. METHODS: Blood samples were collected on Whatman filter cards (FTA) from eight clinics spread across Haiti. Following the confirmation of P. falciparum in the samples, PCR protocols were used to amplify regions of pfmdr1and pfcrt codons of interest, (86, 184, 1034, 1042, and 1246) and (72-76), respectively. Sequencing and site-specific restriction enzyme digestions were used to analyse these DNA fragments for the presence of single nucleotide polymorphisms (SNPs) known to confer resistance to anti-malarial drugs. RESULTS: P. falciparum infection was confirmed in160 samples by amplifying a segment of the P. falciparum 18S small subunit ribosomal RNA gene (pfssurrna). The sequence of pfmdr1 in 54 of these samples was determined between codons 86,184 codons 1034, 1042 and 1246. No sequence differences from that of the NF54 clone 3D7 were found among the 54 samples except at codon 184, where a non-silent mutation was found in all samples predicted to alter the amino acid sequence replacing tyrosine with phenylalanine (Y184F). This altered sequence was also confirmed by restriction enzyme digestion. The sequence of pfmdr1 at codons 86, 184, 1034 and 1042 encoded the NFSN haplotype. The sequence of pfcrt codons 72-76 from 79 samples was determined and found to encode CVMNK, consistent with a CQ sensitive genotype. CONCLUSION: The presence of the Y184F mutation in pfmdr1 of P. falciparum parasites in Haiti may have implications for resistance to antimalarial drugs. The absence of mutation in pfcrt at codon 76 among 79 isolates tested suggests that sensitivity to CQ in Haiti remains common. Wide-spread screening of the pfmdr1 and pfcrt especially among patients experiencing treatment failure may be a useful tool in early detection of the emergence of antimalarial drug resistance in Haiti.

Ehrlichia ruminantium in Amblyomma variegatum and domestic ruminants in the Caribbean.

The highly sensitive nested pCS20 polymerase chain reaction assay for Ehrlichia ruminantium was negative on 506 Amblyomma variegatum from Caribbean islands where clinical heartwater has not been reported, mainly the United States Virgin Islands (18), Dominica (170), Montserrat (5), Nevis (34), St. Kitts (262), and St. Lucia (17). Positive results were obtained with positive controls (Crystal Springs strain) and A. variegatum from countries in Africa where infections are endemic, mainly Tanzania (1/37) and Burkino Faso (2/29). Positive major antigenic protein-1 enzyme-linked immunosorbent assays for E. ruminantium were obtained on convenience samples of sera from apparently healthy cattle, sheep, and goats on Dominica (0/95, 0%; 3/135, 2%; 2/57, 4%), Grenada (0/4, 0%; 1/98, 1%; 1/86, 1%), Montserrat (0/12, 0%; 0/28, 2%; 5/139, 4%), Nevis (0/45, 0%; 0/157, 0%; 0/90, 0%), Puerto Rico (0/422, 0%; 0, 0%), St. Kitts (3/86, 4%; 1/25, 0%; 0/26, 0%), and St. Lucia (0/184, 0%; 0/15, 0%; 0, 0%), respectively. The pCS20 polymerase chain reaction results indicate E. ruminantium is not present on islands where clinical heartwater does not occur. The occasional positive major antigenic protein-1B enzyme-linked immunosorbent assay results appear, then, to be false-positive reactions, and serology appears to be of limited use in testing for E. ruminantium in the Caribbean, as is the case in Africa.

Rickettsia africae in Amblyomma variegatum and domestic ruminants on eight Caribbean islands.

We used PCRs with omp A primers to determine if spotted fever group rickettsiae occurred in Amblyomma variegatum from 6 Caribbean islands. Positive amplicons were obtained from ticks from the U.S. Virgin Islands (9/18; 50%), Dominica (39/171; 30%), Montserrat (2/5; 40%), Nevis (17/34; 50%), St. Kitts (46/227; 20%), and St. Lucia (1/14; 7%). Sequences for a convenience sample of reaction products obtained from A. variegatum on St. Kitts (7), American Virgin Islands (4), Montserrat (2), and St. Lucia (1) were 100% homologous with that of Rickettsia africae , the agent of African tick-bite fever. To determine if transmission of R. africae occurred, we used Rickettsia rickettsii antigen in IFA tests and found positive titers (≥ 1/80) with sera from cattle, goats, and sheep from Dominica (24/95 [25%], 2/136 [2%], 0/58 [0%]), Nevis (12/45 [27%], 5/157 [3%], 0/90 [0%]), St. Kitts (2/43 [5%], 1/25 [4%), 1/35 [3%]), and St. Lucia (6/184 [3%] cattle), respectively. No seropositive animals were found in Grenada (0/4, 0/98/, 0/86), Montserrat (0/12, 0/26, 0/52), or Puerto Rico (0/80 cattle). Our study indicates that R. africae and African tick-bite fever are widespread in the Caribbean.

Apical surface expression of aspartic protease Plasmepsin 4, a potential transmission-blocking target of the plasmodium ookinete.

To invade its definitive host, the mosquito, the malaria parasite must cross the midgut peritrophic matrix that is composed of chitin cross-linked by chitin-binding proteins and then develop into an oocyst on the midgut basal lamina. Previous evidence indicates that Plasmodium ookinete-secreted chitinase is important in midgut invasion. The mechanistic role of other ookinete-secreted enzymes in midgut invasion has not been previously examined. De novo mass spectrometry sequencing of a protein obtained by benzamidine affinity column of Plasmodium gallinaceum ookinete axenic culture supernatant demonstrated the presence of an ookinete-secreted plasmepsin, an aspartic protease previously only known to be present in the digestive vacuole of asexual stage malaria parasites. This plasmepsin, the ortholog of Plasmodium falciparum plasmepsin 4, was designated PgPM4. PgPM4 and PgCHT2 (the P. gallinaceum ortholog of P. falciparum chitinase PfCHT1) are both localized on the ookinete apical surface, and both are present in micronemes. Aspartic protease inhibitors (peptidomimetic and natural product), calpain inhibitors, and anti-PgPM4 monoclonal antibodies significantly reduced parasite infectivity for mosquitoes. These results suggest that plasmepsin 4, previously known only to function in the digestive vacuole of asexual blood stage Plasmodium, plays a role in how the ookinete interacts with the mosquito midgut interactions as it becomes an oocyst. These data are the first to delineate a role for an aspartic protease in mediating Plasmodium invasion of the mosquito and demonstrate the potential for plasmepsin 4 as a malaria transmission-blocking vaccine target.

Recombinant plasmepsin 1 from the human malaria parasite plasmodium falciparum: enzymatic characterization, active site inhibitor design, and structural analysis.

A mutated form of truncated proplasmepsin 1 (proPfPM1) from the human malaria parasite Plasmodium falciparum, proPfPM1 K110pN, was generated and overexpressed in Escherichia coli. The automaturation process was carried out at pH 4.0 and 4.5, and the optimal catalytic pH of the resulting mature PfPM1 was determined to be pH 5.5. This mature PfPM1 showed comparable binding affinity to peptide substrates and inhibitors with the naturally occurring form isolated from parasites. The S3-S3' subsite preferences of the recombinant mature PfPM1 were explored using combinatorial chemistry based peptide libraries. On the basis of the results, a peptidomimetic inhibitor (compound 1) was designed and yielded 5-fold selectivity for binding to PfPM1 versus the homologous human cathepsin D (hcatD). The 2.8 A structure of the PfPM2-compound 1 complex is reported. Modeling studies were conducted using a series of peptidomimetic inhibitors (compounds 1-6, Table 3) and three plasmepsins: the crystal structure of PfPM2, and homology derived models of PfPM1 and PfPM4.

Analysis of binding interactions of pepsin inhibitor-3 to mammalian and malarial aspartic proteases.

The nematode Ascaris suum primarily infects pigs, but also causes disease in humans. As part of its survival mechanism in the intestinal tract of the host, the worm produces a number of protease inhibitors, including pepsin inhibitor-3 (PI3), a 17 kDa protein. Recombinant PI3 expressed in E. coli has previously been shown to be a competitive inhibitor of a subgroup of aspartic proteinases: pepsin, gastricsin and cathepsin E. The previously determined crystal structure of the complex of PI3 with porcine pepsin (p. pepsin) showed that there are two regions of contact between PI3 and the enzyme. The first three N-terminal residues (QFL) bind into the prime side of the active site cleft and a polyproline helix (139-143) in the C-terminal domain of PI3 packs against residues 289-295 that form a loop in p. pepsin. Mutational analysis of both inhibitor regions was conducted to assess their contributions to the binding affinity for p. pepsin, human pepsin (h. pepsin) and several malarial aspartic proteases, the plasmepsins. Overall, the polyproline mutations have a limited influence on the Ki values for all the enzymes tested, with the values for p. pepsin remaining in the low-nanomolar range. The largest effect was seen with a Q1L mutant, with a 200-fold decrease in Ki for plasmepsin 2 from Plasmodium falciparum (PfPM2). Thermodynamic measurements of the binding of PI3 to p. pepsin and PfPM2 showed that inhibition of the enzymes is an entropy-driven reaction. Further analysis of the Q1L mutant showed that the increase in binding affinity to PfPM2 was due to improvements in both entropy and enthalpy.

Critical roles for the digestive vacuole plasmepsins of Plasmodium falciparum in vacuolar function.

Knockout mutants of Plasmodium falciparum lacking pfpm1, pfpm2 and pfhap (triple-PM KO), and mutants lacking all four digestive vacuole (DV) plasmepsins (pfpm4, pfpm1, pfpm2 and pfhap; quadruple-PM KO), were prepared by double cross-over integration effecting chromosomal deletions of up to 14.6 kb. The triple-PM KO was similar to the parental line (3D7) in growth rate, morphology and sensitivity to proteinase inhibitors. The quadruple-PM KO showed a significantly slower rate of growth in standard medium, which manifested as delayed schizont maturation accompanied by reduced formation of haemozoin. In amino acid-limited medium, the reduction in growth rate of the quadruple-PM KO was pronounced. The sensitivity of both the triple- and quadruple-PM KOs to six different HIV aspartic proteinase inhibitors was comparable to that of 3D7, thus establishing that the DV plasmepsins were not the primary targets of the antimalarial activity of these clinically important compounds. Electron microscopic analysis revealed the presence of multilamellar bodies resembling ceroid in the DV of the quadruple-PM KO, and intermediates of the autophagic pathway accumulated as determined by Western blot analysis. Thus, the DV plasmepsins, although not essential, contribute significantly to the fitness of the parasite and are required for efficient degradation of endosomal vesicles delivered to the DV.

Effects on growth, hemoglobin metabolism and paralogous gene expression resulting from disruption of genes encoding the digestive vacuole plasmepsins of Plasmodium falciparum.

Four of the plasmepsins of Plasmodium falciparum are localised in the digestive vacuole (DV) of the asexual blood stage parasite (PfPM1, PfPM2, PfPM4 and PfHAP), and each of these aspartic proteinases has been successfully targeted by gene disruption. This study describes further characterisation of the single-plasmepsin knockout mutants, and the creation and characterisation of double-plasmepsin knockout mutants lacking complete copies of pfpm2 and pfpm1 or pfhap and pfpm2. Double-plasmepsin knockout mutants were created by transfecting pre-existing knockout mutants with a second plasmid knockout construct. PCR and Southern blot analysis demonstrate the integration of a large concatamer of each plasmid construct into the targeted gene. All mutants have been characterised to assess the involvement of the DV plasmepsins in sustaining growth during the asexual blood stage. Analyses reaffirmed that knockout mutants Deltapfpm1 and Deltapfpm4 had lower replication rates in the asexual erythrocytic stage than the parental line (Dd2), but double-plasmepsin knockout mutants lacking intact copies of either pfpm2 and pfpm1, or pfpm2 and pfhap, had normal growth rates compared with Dd2. The amount of crystalline hemozoin produced per parasite during the asexual cycle was measured in each single-plasmepsin knockout to estimate the effect of each DV plasmepsin on hemoglobin digestion. Only Deltapfpm4 had a statistically significant reduction in hemozoin accumulation, indicating that hemoglobin digestion was impaired in this mutant. In the single-plasmepsin knockouts, no statistically significant differences were found in the steady state levels of mRNA from the remaining intact DV plasmepsin genes. Disruption of a DV plasmepsin gene does not affect the accumulation of mRNA encoding the remaining paralogous plasmepsins, and Western blot analysis confirmed that the accumulation of the paralogous plasmepsins in each knockout mutant was similar among all clones examined.

Malignant cystic nephroma.

AIM: To describe a malignant cystic nephroma in an asymptomatic man. METHODS: Case report and review of the literature. RESULTS: A 60 year old white male presented with an incidentally discovered right perirenal mass. An MRI demonstrated a large perinephric encapsulated mass with diffuse heterogeneity. Patient underwent a radical nephrectomy and retroperitoneal node dissection. Histopathological analyses of the resected specimen revealed malignant cystic nephroma. CONCLUSION: This represents the first published report of this rare tumor in an adult patient.

Structure of the aspartic protease plasmepsin 4 from the malarial parasite Plasmodium malariae bound to an allophenylnorstatine-based inhibitor.

The malarial parasite continues to be one of the leading causes of death in many developing countries. With the development of resistance to the currently available treatments, the discovery of new therapeutics is imperative. Currently, the plasmepsin enzymes found in the food vacuole of the parasite are a chief target for drug development. Allophenylnorstatine-based compounds originally designed to inhibit HIV-1 protease have shown efficacy against all four plasmepsin enzymes found in the food vacuole of Plasmodium falciparum. In this study, the first crystal structure of P. malariae plasmepsin 4 (PmPM4) bound to the allophenylnorstatine-based compound KNI-764 is described at 3.3 Angstroms resolution. The PmPM4-inhibitor complex crystallized in the orthorhombic space group P2(1)2(1)2, with unit-cell parameters a = 95.9, b = 112.6, c = 90.4 Angstroms, with two molecules in the asymmetric unit related by a non-crystallographic symmetry operator. The structure was refined to a final R factor of 24.7%. The complex showed the inhibitor in an unexpected binding orientation with allophenylnorstatine occupying the S1' pocket. The P2 group was found outside the S2 pocket, wedged between the flap and a juxtaposed loop. Inhibition analysis of PmPM4 also suggests the potential for allophenylnorstatine-based compounds to be effective against all species of malaria infecting humans and for the future development of a broad-based inhibitor.

Expression and characterization of the ATP-binding domain of a malarial Plasmodium vivax gene homologous to the B-subunit of the bacterial topoisomerase DNA gyrase.

We have previously reported the presence of a DNA gyrase-like topoisomerase activity associated with the 35kb apicoplast DNA in the malarial parasite Plasmodium falciparum [Weissig V, Vetro-Widenhouse TS, Rowe TC. Topoisomerase II inhibitors induce cleavage of nuclear and 35kb plastid DNAs in the malarial parasite Plasmodium falciparum. DNA Cell Biol 1997;16:1483]. Sequences encoding polypeptides homologous to both the A and B subunits of bacterial DNA gyrase have been identified in the genome sequence of P. falciparum among data produced by the Malaria Genome Consortium and the University of Florida Malaria Gene Sequence Tag Project. Based on these findings, we have cloned and expressed a region of the Plasmodium vivax GyrB gene encoding a 43kDa polypeptide homologous to the ATP-binding domain of Escherichia coli DNA gyrase. The 43kDa PvGyrB polypeptide was found to have intrinsic ATPase activity with a K(m) of 0.27mM and a k(cat) of 0.051s(-1). The PvGyrB ATPase was also sensitive to the bacterial DNA gyrase inhibitor coumermycin. The implications of these findings are discussed.

Androgen receptor activation by G(s) signaling in prostate cancer cells.

The androgen receptor (AR) is activated in prostate cancer patients undergoing androgen ablative therapy and mediates growth of androgen-insensitive prostate cancer cells, suggesting it is activated by nonandrogenic factors. We demonstrate that activated alpha subunit of heterotrimeric guanine nucleotide-binding G(s) protein activates the AR in prostate cancer cells and also synergizes with low concentration of androgen to more fully activate the AR. The G alpha(s) activates protein kinase A, which is required for the nuclear partition and activation of AR. These data suggest a role for G alpha(s) and PKA in the transactivation of AR in prostate cancer cells under the environment of reduced androgen levels.

Crystallization and preliminary X-ray analysis of the aspartic protease plasmepsin 4 from the malarial parasite Plasmodium malariae.

Plasmepsin 4 from the malarial parasite Plasmodium malariae (PmPM4) is a member of the plasmepsins (Plasmodium pepsins), a subfamily of the pepsin-like aspartic proteases whose ortholog in the malarial parasite P. falciparum is involved in hemoglobin digestion in its digestive vacuole. Crystals of PmPM4 in complex with the small-molecule inhibitor AG1776 have been grown from a precipitant of 15% PEG 4000 and 200 mM ammonium sulfate in 100 mM sodium acetate pH 4.5. X-ray diffraction data were collected on a Rigaku rotating-anode generator from a single crystal under cryoconditions, with a maximal useful diffraction pattern to 3.3 A resolution. The crystals are shown to be orthorhombic and have been assigned to space group P2(1)2(1)2, with unit-cell parameters a = 95.88, b = 112.58, c = 90.40 A and a scaling Rsym of 0.104 for 14,334 unique reflections. Packing consideration and self-rotation function results indicate that there are two molecules per asymmetric unit. It is expected that in the near future the structure of PmPM4 will be obtained using molecular-replacement methods, obtaining phases from previously determined plasmepsin structures. Elucidation of the structure of PmPM4 in complex with inhibitors may be paramount to producing new antimalarial therapeutic agents.

Genetic disruption of the Plasmodium falciparum digestive vacuole plasmepsins demonstrates their functional redundancy.

The digestive vacuole plasmepsins PfPM1, PfPM2, PfPM4, and PfHAP (a histoaspartic proteinase) are 4 aspartic proteinases among 10 encoded in the Plasmodium falciparum malarial genome. These have been hypothesized to initiate and contribute significantly to hemoglobin degradation, a catabolic function essential to the survival of this intraerythrocytic parasite. Because of their perceived significance, these plasmepsins have been proposed as potential targets for antimalarial drug development. To test their essentiality, knockout constructs were prepared for each corresponding gene such that homologous recombination would result in two partial, nonfunctional gene copies. Disruption of each gene was achieved, as confirmed by PCR, Southern, and Northern blot analyses. Western and two-dimensional gel analyses revealed the absence of mature or even truncated plasmepsins corresponding to the disrupted gene. Reduced growth rates were observed with PfPM1 and PfPM4 knockouts, indicating that although these plasmepsins are not essential, they are important for parasite development. Abnormal mitochondrial morphology also appeared to accompany loss of PfPM2, and an abundant accumulation of electron-dense vesicles in the digestive vacuole was observed upon disruption of PfPM4; however, those phenotypes only manifested in about a third of the disrupted cells. The ability to compensate for loss of individual plasmepsin function may be explained by close similarity in the structure and active site of these four vacuolar enzymes. Our data imply that drug discovery efforts focused on vacuolar plasmepsins must incorporate measures to develop compounds that can inhibit two or more of this enzyme family.

Recombinant expression and enzymatic subsite characterization of plasmepsin 4 from the four Plasmodium species infecting man.

Plasmepsin 4 from Plasmodium falciparum and orthologs from Plasmodium malariae, Plasmodium ovale and Plasmodium vivax have been expressed in recombinant form, and properties of the active site of each enzyme characterized by kinetic analysis. A panel of chromogenic peptide substrates systematically substituted at the P3, P2, P2' and P3' positions was used to estimate enzyme/ligand interactions in the corresponding enzyme subsites based upon kinetic data. The kinetic parameters kcat, Km and kcat/Km were measured to identify optimal substrates for each enzyme and also sequences that were readily cleaved by the plasmepsins but poorly by host aspartic peptidases. Computer generated models were utilized to compare enzyme structures and interpret kinetic results. The orthologous plasmepsins share highly similar subsite specificities. In the S3 and S2 subsites, the plasmepsin 4 orthologs all preferred hydrophobic amino acid residues, Phe or Ile, but rejected charged residues such as Lys or Asp. In S2' and S3' subsites, these plasmepsins tolerated both hydrophobic and hydrophilic residues. Subsite specificities of the plasmepsin 4 family of orthologs are similar to those of human cathepsins D and E, except in S3' where the plasmepsins accept substrates containing Ser significantly better than either of these human aspartic proteases. Peptidomimetic methyleneamino reduced-peptide inhibitors, which have inhibition constants in the picomolar range, were prepared for each plasmepsin 4 ortholog based upon substrate preferences. A peptidomimetic inhibitor designed for plasmepsin 4 from P. falciparum having Ser in P3' had the lowest Ki of the series of inhibitors prepared, but did not significantly improve the selectivity of the inhibitor for plasmepsin 4 versus human cathepsin D.

Comparative structural analysis and kinetic properties of lactate dehydrogenases from the four species of human malarial parasites.

Parasite lactate dehydrogenase (pLDH) is a potential drug target for new antimalarials owing to parasite dependence on glycolysis for ATP production. The pLDH from all four species of human malarial parasites were cloned, expressed, and analyzed for structural and kinetic properties that might be exploited for drug development. pLDH from Plasmodium vivax, malariae, and ovale exhibit 90-92% identity to pLDH from Plasmodium falciparum. Catalytic residues are identical. Resides I250 and T246, conserved in most LDH, are replaced by proline in all pLDH. The pLDH contain the same five-amino acid insert (DKEWN) in the substrate specificity loops. Within the cofactor site, pLDH from P. falciparum and P. malariae are identical, while pLDH from P. vivax and P. ovale have one substitution. Homology modeling of pLDH from P. vivax, ovale, and malariae with the crystal structure of pLDH from P. falciparum gave nearly identical structures. Nevertheless, the kinetic properties and sensitivities to inhibitors targeted to the cofactor binding site differ significantly. Michaelis constants for pyruvate and lactate differ 8-9-fold; Michaelis constants for NADH, NAD(+), and the NAD(+) analogue 3-acetylpyridine adenine dinucleotide differ up to 4-fold. Dissociation constants for the inhibitors differ up to 21-fold. Molecular docking studies of the binding of the inhibitors to the cofactor sites of all four pLDH predict similar orientations, with the docked ligands positioned at the nicotinamide end of the cofactor site. pH studies indicate that inhibitor binding is independent of pH in the pH 6-8 range, suggesting that differences in dissociation constants for a specific inhibitor are not due to altered active site pK values among the four pLDH.