Oral streptococci subvert the host innate immune response through hydrogen peroxide.

In periodontal health, oral streptococci constitute up to 80% of the plaque biofilm. Yet, destructive inflammatory events of the periodontium are rare. This observation suggests that oral streptococci may possess mechanisms to co-exist with the host. However, the mechanisms employed by oral streptococci to modulate the innate immune response have not been well studied. One of the key virulence factors produced by oral streptococci is hydrogen peroxide (H2O2). In mammalian cells, H2O2 triggers the activation of nuclear factor erythroid 2-related factor 2 (Nrf2), a key pathway mediating antioxidant defence. This study aimed to determine (1) if H2O2 producing oral streptococci activated the Nrf2 pathway in macrophages, and (2) if the activation of Nrf2 influenced the innate immune response. We found that oral streptococci downregulated the innate immune response in a H2O2 dependent manner through the activation of the Nrf2. The activation of the Nrf2 signalling pathway led to the inhibition of nuclear factor kappa-light-chain-enhancer of activated B cells (NFĸB), the key transcription factor regulating pro-inflammatory response. This study showed for the first time that oral streptococci are unlikely passive bystanders but could play an active role in the maintenance of periodontal health by preventing overt inflammation.

Co-chaperones of Hsp90 in Plasmodium falciparum and their concerted roles in cellular regulation.

Co-chaperones are well-known regulators of heat shock protein 90 (Hsp90). Hsp90 is a molecular chaperone that is essential in the eukaryotes for the folding and activation of numerous proteins involved in important cellular processes such as signal transduction, growth and developmental regulation. Co-chaperones assist Hsp90 in the protein folding process by modulating conformational changes to promote client protein interaction and functional maturation. With the recognition of Plasmodium falciparum Hsp90 (PfHsp90) as a potential antimalarial drug target, there is obvious interest in the study of its co-chaperones in their partnership in regulating cellular processes in malaria parasite. Previous studies on PfHsp90 have identified more than 10 co-chaperones in P. falciparum genome. However, many of them remained annotated as putative proteins as their functionality has not been validated experimentally. So far, only five co-chaperones, PfHop, Pfp23, PfAha1, PfPP5 and PfFKBP35 have been characterized and shown to interact with PfHsp90. This review will summarize current knowledge on the co-chaperones in P. falciparum and discuss their regulatory roles on PfHsp90. As certain eukaryotic co-chaperones have also been implicated in altering the affinity of Hsp90 for its inhibitor, this review will also examine plasmodial co-chaperones' potential influence on approaches towards designing antimalarials targeting PfHsp90.

Plasmodium falciparum possesses a unique dual-specificity serine/threonine and tyrosine kinase, Pfnek3.

Despite the absence of classical tyrosine kinases encrypted in the kinome of Plasmodium falciparum, biochemical analyses have detected significant tyrosine phosphorylation in its cell lysates. Supporting such phosphorylation is critical for parasite development. These observations have thus raised queries regarding the plasmodial enzymes accountable for tyrosine kinase activities in vivo. In the current investigation, immunoblot analysis intriguingly demonstrated that Pfnek3, a plasmodial mitogen-activated protein kinase kinase (MAPKK), displayed both serine/threonine and tyrosine kinase activities in autophosphorylation reactions as well as in phosphorylation of the exogenous myelin basic protein substrate. The results obtained strongly support Pfnek3 as a novel dual-specificity kinase of the malarial parasite, even though it displays a HGDLKSTN motif in the catalytic loop that resembles the consensus HRDLKxxN signature found in the serine/threonine kinases. Notably, its serine/threonine and tyrosine kinase activities were found to be distinctly influenced by Mg(2+) and Mn(2+) cofactors. Further probing into the regulatory mechanism of Pfnek3 also revealed tyrosine phosphorylation to be a crucial factor that stimulates its kinase activity. Through biocomputational analyses and functional assays, tyrosine residues Y117, Y122, Y172, and Y238 were proposed as phosphorylation sites essential for mediating the catalytic activities of Pfnek3. The discovery of Pfnek3's dual role in phosphorylation marks its importance in closing the loop for cellular regulation in P. falciparum, which remains elusive to date.

Features of the Streptomyces hygroscopicus HtpG reveal how partial geldanamycin resistance can arise with mutation to the ATP binding pocket of a eukaryotic Hsp90.

Much attention is focused on the benzoquinone ansamycins as anticancer agents, with several derivatives of the natural product geldanamycin (GdA) now in clinical trials. These drugs are selective inhibitors of Hsp90, a molecular chaperone vital for many of the activities that drive cancer progression. Mutational changes to their interaction site, the extremely conserved ATP binding site of Hsp90, would mostly be predicted to inactivate the chaperone. As a result, drug resistance should not arise readily this way. Nevertheless, Streptomyces hygroscopicus, the actinomycete that produces GdA, has evolved an Hsp90 family protein (HtpG) that lacks GdA binding. It is altered in certain of the highly conserved amino acids making contacts to this antibiotic in crystal structures of GdA bound to eukaryotic forms of Hsp90. Two of these amino acid changes, located on one side of the nucleotide-binding cleft, weakened GdA/Hsp90 binding and conferred partial GdA resistance when inserted into the endogenous Hsp90 of yeast cells. Crystal structures revealed their main effect to be a weakening of interactions with the C-12 methoxy group of the GdA ansamycin ring. This is the first study to demonstrate that partial GdA resistance is possible by mutation within the ATP binding pocket of Hsp90.

Designing new ß-lactams: implications from their targets, resistance factors and synthesizing enzymes.

Penicillins and cephalosporins are ß-lactam antibiotics widely used to treat bacterial infectious diseases. They mainly target the cell wall biosynthesis pathway to inhibit bacterial growth. The targets, known as penicillin-binding proteins, are enzymes involved in the polymerization of glycan chains, cross-linking them during bacterial cell wall formation. However, the dispensation of these antibiotics has been concomitant with increasing incidence of resistance to them. Reportedly, this is due to the evolvement of two resistance mechanisms in the bacterial pathogens. One is the production of ß -lactamases that cleave the ß -lactam rings of penicillin and cephalosporin antibiotics, rendering them ineffective against the pathogens. Another is the modification of the targets, resulting in their inability to bind ß -lactam antibiotics. Nevertheless, ß -lactam antibiotics remain clinically relevant due to their high target specificity in bacteria and low toxicity to humans. Thus, to overcome the continuing emergence of resistance in pathogens, more efficacious ß -lactams have to be developed and cephalosporins are often preferred over penicillins due to two alkyl sites in the cephalosporin core structure amenable for modification. Transformed ß -lactams are expected to have improved antimicrobial spectra and pharmacokinetics. This is illustrated by the development of two cephalosporins, namely ceftobiprole and ceftaroline, which have shown good antimicrobial activities and are currently undergoing clinical trials. This review will discuss computer-aided studies of three enzymes closely related to cephalosporins: (1) its synthesizing enzyme, deacetoxycephalosporin C synthase, (2) its targets, the penicillin-binding proteins, and (3) its degrading enzyme, the ß -lactamases, and their implications in the development of new cephalosporins.

Atypical caseinolytic protease homolog from Plasmodium falciparum possesses unusual substrate preference and a functional nuclear localization signal.

Although ATP-dependent caseinolytic protease (Clp) complexes are important for regulating the pathogenicity, survival, and development of many pathogens, their physiological roles in the pathogenicity of malarial parasites remain unknown. This study reports the cloning, authentication, and characterization of a putative Clp protease subunit from Plasmodium falciparum (PfClpP). Heterologous expression studies showed that signal peptide hindered the soluble expression of the full-length PfClpP. Biochemical analyses of the recombinant PfClpP showed that it did not cleave the known ClpP substrate, succinyl-leucine-tyrosine-7-amido-4-methylcoumarin hydrochloride (AMC). Instead, PfClpP readily hydrolyzed a different substrate, glycine-arginine-AMC. The distinctive substrate preference of PfClpP suggests structural uniqueness in its substrate-binding sites that might be exploitable in anti-malarial drug development. Whether PfClpP resembles most eukaryotic ClpPs in being localized to the mitochondria and chloroplasts was also investigated using a mammalian surrogate host system. The results observed showed that green-fluorescence protein tagged PfClpP proteins were localized to the nucleus. PfClpP may have a unique and specialized role in the plasmodial nucleus. Taken together, this study has shown that PfClpP has a unique peptide cleavage function that is localized at the plasmodial nucleus, probably positioned to elicit a regulatory role in the parasite's pathogenicity.

Regulation of Plasmodium falciparum Pfnek3 relies on phosphorylation at its activation loop and at threonine 82.

A mitogen-activated protein kinase (MAPK), Pfmap2, has been identified in Plasmodium falciparum. However, its bona fide activator remains elusive as no MAPK kinase (MAPKK) homologues have been found so far. Instead, Pfnek3, a NIMA (never in mitosis, Aspergillus)-related kinase, was earlier reported to display a MAPKK-like activity due to its activating effect on Pfmap2. In this study, the regulatory mechanism of Pfnek3 was investigated. Pfnek3 was found to possess a SSEQSS motif within its activation loop that fulfills the consensus SXXXS/T phospho-activating sequence of MAPKKs. Functional analyses of the SSEQSS motif by site-directed mutagenesis revealed that phosphorylation of residues S221 and S226 is essential for mediating Pfnek3 activity. Moreover, via tandem mass-spectrometry, residue T82 was uncovered as an additional phosphorylation site involved in Pfnek3 activation. Collectively, these results provide valuable insights into the potential in vivo regulation of Pfnek3, with residues T82, S221 and S226 functioning as phospho-activating sites.

Directed evolution and rational approaches to improving Streptomyces clavuligerus deacetoxycephalosporin C synthase for cephalosporin production.

It is approximately 60 years since the discovery of cephalosporin C in Cephalosporium acremonium. Streptomycetes have since been found to produce the structurally related cephamycin C. Studies on the biosynthetic pathways of these two compounds revealed a common pathway including a step governed by deacetoxycephalosporin C synthase which catalyses the ring-expansion of penicillin N to deacetoxycephalosporin C. Because of the therapeutic importance of cephalosporins, this enzyme has been extensively studied for its ability to produce these antibiotics. Although, on the basis of earlier studies, its substrate specificity was believed to be extremely narrow, relentless efforts in optimizing the in-vitro enzyme assay conditions showed that it is able to convert a wide range of penicillin substrates differing in their side chains. It is a member of 2-oxoglutarate-dependent dioxygenase protein family, which requires the iron(II) ion as a co-factor and 2-oxoglutarate and molecular oxygen as co-substrates. It has highly conserved HXDX( n ) H and RXS motifs to bind the co-factor and co-substrate, respectively. With advances in technology, the genes encoding this enzyme from various sources have been cloned and heterologously expressed for comparative analyses and mutagenesis studies. A high level of recombinant protein expression has also enabled crystallization of this enzyme for structure determination. This review will summarize some of the earlier biochemical characterization and describe the mechanistic action of this enzyme revealed by recent structural studies. This review will also discuss some of the approaches used to identify the amino acid residues involved in binding the penicillin substrate and to modify its substrate preference for possible industrial application.

Structural basis of the radicicol resistance displayed by a fungal hsp90.

Heat shock protein 90 (Hsp90) is a promising cancer drug target, as multiple oncogenic proteins are destabilized simultaneously when it loses its activity in tumor cells. Highly selective Hsp90 inhibitors, including the natural antibiotics geldanamycin (GdA) and radicicol (RAD), inactivate this essential molecular chaperone by occupying its nucleotide binding site. Often cancer drug therapy is compromised by the development of resistance, but a resistance to these Hsp90 inhibitors should not arise readily by mutation of those amino acids within Hsp90 that facilitate inhibitor binding, as these are required for the essential ATP binding/ATPase steps of the chaperone cycle and are tightly conserved. Despite this, the Hsp90 of a RAD-producing fungus is shown to possess an unusually low binding affinity for RAD but not GdA. Within its nucleotide binding site a normally conserved leucine is replaced by isoleucine, though the chaperone ATPase activity is not severely affected. Inserted into the Hsp90 of yeast, this conservative leucine to isoleucine substitution recreated this lowered affinity for RAD in vitro. It also generated a substantially enhanced resistance to RAD in vivo. Co-crystal structures reveal that the change to isoleucine is associated with a localized increase in the hydration of an Hsp90-bound RAD but not GdA. To the best of our knowledge, this is the first demonstration that it is possible for Hsp90 inhibitor resistance to arise by subtle alteration to the structure of Hsp90 itself.

Relevant double mutations in bioengineered Streptomyces clavuligerus deacetoxycephalosporin C synthase result in higher binding specificities which improve penicillin bioconversion.

Streptomyces clavuligerus deacetoxycephalosporin C synthase (ScDAOCS) is an important industrial enzyme for the production of 7-aminodeacetoxycephalosporanic acid, which is a precursor for cephalosporin synthesis. Single mutations of six amino acid residues, V275, C281, N304, I305, R306, and R307, were previously shown to result in enhanced levels of ampicillin conversion, with activities ranging from 129 to 346% of the wild-type activity. In this study, these mutations were paired to investigate their effects on enzyme catalysis. The bioassay results showed that the C-terminal mutations (N304X [where X is alanine, leucine, methionine, lysine, or arginine], I305M, R306L, and R307L) in combination with C281Y substantially increased the conversion of ampicillin; the activity was up to 491% of the wild-type activity. Similar improvements were observed for converting carbenicillin (up to 1,347% of the wild-type activity) and phenethicillin (up to 1,109% of the wild-type activity). Interestingly, the N304X R306L double mutants exhibited lower activities for penicillin G conversion, and activities that were 40 to 114% of wild-type enzyme activity were detected. Based on kinetic studies using ampicillin, it was clear that the increases in the activities of the double mutants relative to those of the corresponding single mutants were due to enhanced substrate binding affinities. These results also validated the finding that the N304R and I305M mutations are ideal for increasing the substrate binding affinity and turnover rate of the enzyme, respectively. This study provided further insight into the structure-function interaction of ScDAOCS with different penicillin substrates, thus providing a useful platform for further rational modification of its enzymatic properties.

A complete library of amino acid alterations at R306 in Streptomyces clavuligerus deacetoxycephalosporin C synthase demonstrates its structural role in the ring-expansion activity.

In a previous study, the conserved arginine residue at position 306 of Streptomyces clavuligerus deacetoxycephalsoporin C synthase (scDAOCS), when mutated to leucine, resulted in 191% increase in converting ampicillin to its expanded cephalosporin moiety compared with that of the wild-type enzyme. However, the role of this residue in eliciting the improved enzymatic activity is not well understood. In this study, probing the molecular basis of amino acid substitutions at position 306 has underscored its importance for engineering various improvements in the ring expansion activity. Structural modeling using SwissPdbViewer revealed that R306 is surrounded by a hydrophobic cleft formed by residues Y184, L186, W297, I298, and V303. Hence, the improved activity achieved by the R306L mutation was probably because of better hydrophobic packing in this region. To evaluate the role of amino acids at position 306 of scDAOCS and its influence on the molecular status of the enzyme at this locality, alteration to 18 other amino acids was done by site-directed mutagenesis. The effects of each substitution on the enzyme activity were determined by bioassay using penicillin substrates: ampicillin, penicillin G, phenethicillin, and carbenicillin. Results obtained showed a drastic reduction in enzyme activity when R306 was replaced with charged or polar residues, thus emphasizing the importance of hydrophobic packing around this site. The bioassay results also illustrated that apart from leucine, substitutions to nonpolar residues, isoleucine and methionine, were able to improve the ampicillin conversion activity of scDAOCS by 168 and 113% of the wild-type enzyme activity, respectively. Similar trend of effects from each mutation was also observed for penicillin G, phenethicillin, and carbenicillin conversions. The enhanced enzyme activities were supported by spectrophotometric assay indicating that all these mutants have lower K(m) values (R306L: 1.09 mM; R306I: 2.64 mM; R306M: 5.68 mM) than the wild-type enzyme (8.33 mM), resulting in improvement in the enzyme's substrate binding affinity. Hence, this mutational study of amino acids situated at 306 of scDAOCS has provided a better understanding of the significance of specific amino acid residues at this position which can improve its ring-expansion activity when given a plethora of beta-lactam substrates to generate corresponding, possibly new, cephalosporins.

Elucidation of active site residues of Arabidopsis thaliana flavonol synthase provides a molecular platform for engineering flavonols.

Arabidopsis thaliana flavonol synthase (aFLS) catalyzes the production of quercetin, which is known to possess multiple medicinal properties. aFLS is classified as a 2-oxoglutarate dependent dioxygenase as it requires ferrous iron and 2-oxoglutarate for catalysis. In this study, the putative residues for binding ferrous iron (H221, D223 and H277), 2-oxoglutarate (R287 and S289) and dihydroquercetin (H132, F134, K202, F293 and E295) were identified via computational analyses. To verify the proposed roles of the identified residues, 15 aFLS mutants were constructed and their activities were examined via a spectroscopic assay designed in this study. Mutations at H221, D223, H277 and R287 completely abolished enzymes activities, supporting their importance in binding ferrous iron and 2-oxoglutarate. However, mutations at the proposed substrate binding residues affected the enzyme catalysis differently such that the activities of K202 and F293 mutants drastically decreased to approximately 10% of the wild-type whereas the H132F mutant exhibited approximately 20% higher activity than the wild-type. Kinetic analyses established an improved substrate binding affinity in H132F mutant (Km: 0.027+/-0.0028 mM) compared to wild-type (Km: 0.059+/-0.0063 mM). These observations support the notion that aFLS can be selectively mutated to improve the catalytic activity of the enzyme for quercetin production.

Pfnek3 functions as an atypical MAPKK in Plasmodium falciparum.

Eukaryotes generally rely on signal transduction by mitogen-activated protein kinases (MAPKs) for activating their regulatory pathways. However, the presence of a complete MAPK cascade in Plasmodium falciparum is debatable because a search of the entire genome did not portray known MAPK kinase (MAPKK) sequences. Via homology PCR experiments, only two copies of plasmodial MAPK homologues (Pfmap1 and Pfmap2) have been identified but their upstream activators remain unknown. In an earlier experiment, Pfnek3 was found to be an unusual activator of Pfmap2 in in vitro experiments, despite its molecular identity as a malarial protein kinase from the NIMA (Never in Mitosis, Aspergillus) family. In this study, the role of Pfnek3 as a likely upstream MAPKK is defined through molecular and biochemical characterization. Since a previous report proposes a TSH motif as an activation site of Pfmap2, its site-directed mutants, T290A, S291A, and H292K were constructed to elucidate the involvement of Pfnek3 in phosphorylating and activating Pfmap2 in a battery of kinase assays. The results suggested that residue T290 is the site of phosphorylation by Pfnek3. This supposition was further supported by liquid chromatography mass spectrometry. Although P. falciparum does not appear to possess a conventional MAPK cascade, they may rely on other kinases such as Pfnek3 to carry out similar phosphorylation to activate its signaling pathways.

Molecular basis for thermal properties of Streptomyces thermovulgaris fumarase C hinge at hydrophilic amino acids R163, E170 and S347.

Industrially, the use of high temperatures (40-60 degrees C) in the L: -malate production process could result in rapid inactivation of the mesophilic fumarases, warranting constant replenishment of the biocatalyst. Thus, a thermostable fumarase C that is active and stable at high temperatures would be ideal. Biochemical studies using recombinant fumarase C from thermophilic Streptomyces thermovulgaris (stFUMC) indicated that it was optimally active at 50 degrees C and highly stable even after 24 h of incubation at 40 degrees C. The same gene from mesophilic Streptomyces coelicolor (scfumC) was also cloned and expressed as soluble proteins for comparison in thermal properties of both enzymes. In contrast to stFUMC, scFUMC exhibited a lower temperature optima of 30 degrees C and was rapidly denatured at 50 degrees C. The specific activity of stFUMC was also higher than that of scFUMC by 20-fold. After primary sequence comparison, three hydrophilic amino acid residues, R163, E170 and S347, were forged into the thermolabile scFUMC either singly or in combination for the investigation of their contributions in the thermal properties of the mutant enzymes. Of the mutants studied, the A347S scFUMC mutant resulted in the highest increase in optimum temperature of 10 degrees C and a fourfold enhancement in specific activity. G163R/G170E and G163R/G170E/A347S scFUMC mutants are more thermostable than wild-type scFUMC. These findings support stFUMC as a highly efficient, thermostable fumarase C with industrial potential and suggest that R163, E170 and S347 are involved in the enhancement of thermal properties in fumarase C.

Pfnek3: an atypical activator of a MAP kinase in Plasmodium falciparum.

The canonical mitogen-activated protein kinase (MAPK) signal cascade was previously suggested to be atypical in the malaria parasite. This raises queries on the existence of alternative mediators of plasmodial MAPK pathways. This study describes, Pfnek3, a malarial protein kinase belonging to the NIMA (Never in Mitosis, Aspergillus) family. Endogenous Pfnek3 is expressed during late asexual to gametocyte stages and lacks some classical protein kinase sequence motifs. Moreover, Pfnek3 is phylogenetically distant from mammalian NIMA-kinases. Recombinant Pfnek3 was able to phosphorylate and stimulate a malarial MAPK (Pfmap2). Contrastingly, this was not observed with two other kinases, Pfmap1 and human MAPK1, suggesting that the Pfnek3-Pfmap2 interaction may be specific for Pfmap2 regulation. In summary, our data reveal a malarial NIMA-kinase with the potential to regulate a MAPK. Possessing biochemical properties divergent from classical mammalian NIMA-kinases, Pfnek3 could potentially be an attractive target for parasite-selective anti-malarials.

A relevant in vitro eukaryotic live-cell system for the evaluation of plasmodial protein localization.

Understanding the functional genomics and proteomics of plasmodia underpins the development of new approaches to antimalarial chemotherapy. Although genome databanks (e.g. PlasmoDB) and biocomputing tools (e.g. PlasMit, PlasmoAP, PATS) are useful in providing a global albeit predictive view of the myriad of about 5000 genes, only 40% are annotated, with few cases of endorsed subcellular localizations of the corresponding proteins in animal models. Progress in plasmodial protein trafficking has been hampered by the lack of a simple yet reliable method for studying subcellular localization of plasmodial proteins. In this study, we have used a combination of fluorescent markers, organelle-specific probes, phase contrast microscopy, and confocal microscopy to locate a selection of signal peptides from 10 plasmodial proteins in CHO-K1 cells. These eukaryotic cells serve as an in vitro living system for studying the cellular destinations of four mitochondrial-targeted TCA cycle proteins (citrate synthase, CS; isocitrate dehydrogenase, ICDH; branched chain alpha-keto-acid dehydrogenase E1alpha subunit, BCKDH; succinate dehydrogenase flavoprotein-subunit, SDH), two nuclear-targeted proteins (histone deacetylase, HDAC; RNA polymerase, RPOL), two apicoplast-targeted proteins (pyruvate kinase 2, PK2; glutamate dehydrogenase, GDH), and two cytoplasmic resident proteins (malate dehydrogenase, MDH; glycerol kinase, GK). The respective localizations of these malarial proteins have complied with the selected molecular targets, viz. mitochondrial, nuclear and cytoplasmic. Interestingly, MDH that is widely known to be resident in eukaryotic mitochondria was found to be cytoplasmic, probably due to the absence of molecular target sequences. Since the localization of plasmodial proteins is central to the authentication of their pathophysiological roles, this experimental system will serve as a useful a priori approach.

Characterization of amino acid variation at strategic positions in parasite and human proteases for selective inhibition of falcipains in Plasmodium falciparum.

Falcipains (FP) of Plasmodium falciparum are important virulence factors marked as potential targets for antimalarial drug discovery. In this study, the previously uncharacterized fp2B (PF11_0161) was shown to be highly expressed as an active enzyme during the erythrocytic stage. With three related proteases in the FP family and the existence of human homologues, it is prudent to identify clusters of residues unique to the parasite proteases that can be targeted selectively for drug design. Using bioinformatic tools, we have carefully mapped out a highly conserved and unique region constituted by I85, S149, and A151 in the plasmodial proteases that can influence the development of compounds capable of inhibiting the entire FP family. Taking drug interactions with the human homologues into consideration, these residues in FP2B were replaced with the cognate residues found in human cathepsin L (catL) for evaluation. Despite the high sequence similarity between the FP2 isozymes (97.5%), FP2B is found to be more tolerant to amino acid substitution at position 149 than FP2A. This structural disparity implied that residues mediating peptide substrate interactions are not fully conserved across the FP family and warrant attention in the design and evaluation of protease inhibitors focused on the FPs. The simultaneous substitution of the neighboring residues (I85 or A151) rendered the double mutants (S149A/I85M and S149A/A151D) completely inactive. Significantly, the mutations did not result in 'catL-like' specificity, suggesting that substrate-based inhibitors could be rationally designed against these important parasite-specific structural determinants.

Differences in biochemical properties of the Plasmodial falcipain-2 and berghepain-2 orthologues: implications for in vivo screens of inhibitors.

Falcipain-2A, the cysteine protease of Plasmodium falciparum has been proposed as a good drug target. This study evaluated the suitability of Plasmodium berghei as the animal model and reports the first functional expression and characterization of the falcipain-2A orthologue, berghepain-2. Comparative studies revealed that the orthologues exhibited different biochemical properties. Berghepain-2 demonstrated optimal activity at a narrower pH optima of 5.5-6 and a lack of preference for substrates with leucine at position 2. Mutagenesis studies revealed roles for residues Val63 and Arg230 of berghepain-2 in contributing to its distinctive biochemical properties. This warrants re-evaluation of employing P. berghei as the murine model for the in vivo screening of falcipain-2A inhibitors. More importantly, these findings stress the underlying importance of establishing the functionality of relevant genes of P. falciparum with concomitant relevance to its murine counterpart prior to its use as the animal model for the screening of potential antimalarials.

Molecular cloning and functional characterization of fumarases C in Neisseria species.

Fumarase is one of the key enzymes in the TCA cycle and has been implicated in virulence and survival of some microorganisms under suboptimal environmental conditions. In this study, the fumC genes that encode fumarase C (FUMCs) from Neisseria meningitidis, N. gonorrhoeae and N. subflava were identified by homology-based analysis, cloned by polymerase chain reactions and fully sequenced. The inferred primary sequence of neisserial FUMCs showed a high degree of conservation with 97.8-98.7% amino acid identity. However, phylogenetic analysis revealed that these neisserial FUMCs are divergent from class II fumarases found in other microorganisms, rat and human. The putative fumC genes were subcloned into the expression vector, pGEX-6P-1 and efficiently expressed in Esherichia coli BL21. The purified recombinant fusion proteins obtained by affinity chromatography demonstrated high catalytic activities (120-180 U/mg), thus authenticating the identities and functionalities of the cloned genes. Whether FUMC has any physiological relevance to the pathogenesisity of Neisseriae must await future gene disruption or mutagenesis studies.

Functional analysis, overexpression, and kinetic characterization of pyruvate kinase from Plasmodium falciparum.

The important role of pyruvate kinase during malarial infection has prompted the cloning of a cDNA encoding Plasmodium falciparum pyruvate kinase (pfPyrK), using mRNA from intraerythrocytic-stage malaria parasites. The full-length cDNA encodes a protein with a computed molecular weight of 55.6 kDa and an isoelectric point of 7.5. The purified recombinant pfPyrK is enzymatically active and exists as a homotetramer in its active form. The enzyme exhibits hyperbolic kinetics with respect to phosphoenolpyruvate and ADP, with K(m) of 0.19 and 0.12 mM, respectively. pfPyrK is not affected by fructose-1,6-bisphosphate, a general activating factor of pyruvate kinase for most species. Glucose-6-phosphate, an activator of the Toxoplasma gondii enzyme, does not affect pfPyrK activity. Similar to rabbit pyruvate kinase, pfPyrK is susceptible to inactivation by 1mM pyridoxal-5'-phosphate, but to a lesser extent. A screen for inhibitors to pfPyrK revealed that it is markedly inhibited by ATP and citrate. Detailed kinetic analysis revealed a transition from hyperbolic to sigmoidal kinetics for PEP in the presence of citrate, as well as competitive inhibitory behavior for ATP with respect to PEP. Citrate exhibits non-competitive inhibition with respect to ADP with a K(i) of 0.8mM. In conclusion, P. falciparum expresses an active pyruvate kinase during the intraerythrocytic-stage of its developmental cycle that may play important metabolic roles during infection.