Angiotensin II restricted analogs with biological activity in the erythrocytic cycle of Plasmodium falciparum

The anti‐plasmodial activity of conformationally restricted analogs of angiotensin II against Plasmodium gallinaceum has been described. To observe activity against another Plasmodium species, invasion of red blood cells by Plasmodium falciparum was analyzed. Analogs restricted with lactam or disulfide bridges were synthesized to determine their effects and constraints in the peptide–parasite interaction. The analogs were synthesized using tert‐butoxycarbonyl and fluoromethoxycarbonyl solid phase methods, purified by liquid chromatography, and characterized by mass spectrometry. Results indicated that the lactam bridge restricted analogs 1 (Glu‐Asp‐Arg‐Orn ‐Val‐Tyr‐Ile‐His‐Pro‐Phe) and 3 (Asp‐Glu‐Arg‐Val‐Orn ‐Tyr‐Ile‐His‐Pro‐Phe) showed activity toward inhibition of ring formation stage of P. falciparum erythrocytic cycle, preventing invasion in about 40% of the erythrocytes. The disulfide‐bridged analog 10 (Cys‐Asp‐Arg‐Cys ‐Val‐Tyr‐Ile‐His‐Pro‐Phe) was less effective yet significant, showing a 25% decrease in infection of new erythrocytes. In all cases, the peptides presented no pressor activity, and hydrophobic interactions between the aromatic and alkyl amino acid side chains were preserved, a factor proven important in efficacy against P. gallinaceum. In contrast, hydrophilic interactions between the Asp¹ carboxyl and Arg² guanidyl groups proved not to be as important as they were in the case of P. gallinaceum, while interactions between the Arg² guanidyl and Tyr⁴ hydroxyl groups were not important in either case. The β‐turn conformation was predominant in all of the active peptides, proving importance in anti‐plasmodial activity. This approach provides insight for understanding the importance of each amino acid residue on the native angiotensin II structure and a new direction for the design of potential chemotherapeutic agents. Copyright © 2014 European Peptide Society and John Wiley & Sons, Ltd.     

Global Analysis of Apicomplexan Protein S‐Acyl Transferases Reveals an Enzyme Essential for Invasion

The advent of techniques to study palmitoylation on a whole proteome scale has revealed that it is an important reversible modification that plays a role in regulating multiple biological processes. Palmitoylation can control the affinity of a protein for lipid membranes, which allows it to impact protein trafficking, stability, folding, signalling and interactions. The publication of the palmitome of the schizont stage of Plasmodium falciparum implicated a role for palmitoylation in host cell invasion, protein export and organelle biogenesis. However, nothing is known so far about the repertoire of protein S‐acyl transferases (PATs) that catalyse this modification in Apicomplexa. We undertook a comprehensive analysis of the repertoire of Asp‐His‐His‐Cys cysteine‐rich domain (DHHC‐CRD) PAT family in Toxoplasma gondii and Plasmodium berghei by assessing their localization and essentiality. Unlike functional redundancies reported in other eukaryotes, some apicomplexan‐specific DHHCs are essential for parasite growth, and several are targeted to organelles unique to this phylum. Of particular interest is DHHC7, which localizes to rhoptry organelles in all parasites tested, including the major human pathogen P. falciparum. TgDHHC7 interferes with the localization of the rhoptry palmitoylated protein TgARO and affects the apical positioning of the rhoptry organelles. This PAT has a major impact on T. gondii host cell invasion, but not on the parasite's ability to egress.     

The disulfide oxidoreductase SdbA is active in Streptococcus gordonii using a single C‐terminal cysteine of the CXXC motif

Recently, we identified a novel disulfide oxidoreductase, SdbA, in the oral bacterium Streptococcus gordonii. Disulfide oxidoreductases form disulfide bonds in nascent proteins using a CXXC catalytic motif. Typically, the N‐terminal cysteine interacts with substrates, whereas the C‐terminal cysteine is buried and only reacts with the first cysteine of the motif. In this study, we investigated the SdbA C⁸⁶P⁸⁷D⁸⁸C⁸⁹ catalytic motif. In vitro, SdbA single cysteine variants at the N or C‐terminal position (SdbA_C86P and SdbA_C89A) were active but displayed different susceptibility to oxidation, and N‐terminal cysteine was prone to sulfenylation. In S. gordonii, mutants with a single N‐terminal cysteine were inactive and formed unstable disulfide adducts with other proteins. Activity was partially restored by inactivation of pyruvate oxidase, a hydrogen peroxide generator. Presence of the C‐terminal cysteine alone (in the SdbA_C86P variant) could complement the ΔsdbA mutant and restore disulfide bond formation in recombinant and natural protein substrates. These results provide evidence that certain disulfide oxidoreductases can catalyze disulfide bond formation using a single cysteine of the CXXC motif, including the buried C‐terminal cysteine.     

Tyrosinase‐Mediated Formation of a Reactive Quinone from the Depigmenting Agents, 4‐tert‐Butylphenol and 4‐tert‐Butylcatechol

Exposure of the skin to certain phenols or catechols such as 4‐tert‐butylphenol (TBP) and 4‐tert‐butylcatechol (TBC) may cause leukoderma. These substances are used in the polymer industry and numerous cases have been reported. Several theories of the mechanism for chemical leukoderma have been suggested. In the present study, TBP and TBC are shown to be oxidised by tyrosinase. The oxidation of TBC yields a quinone that is further investigated on its reactions with cysteine or glutathione (GSH). The products formed are isolated and identified by mass spectrometry and nuclear magnetic resonance as being 4‐tert‐butyl‐6‐S‐cysteinylcatechol (cys‐TBC) and 4‐tert‐butyl‐6‐S‐glutathionylcatechol (GS‐TBC). The reactive quinone is a strongly electrophilic substance that rapidly reacts with GSH. A depletion of the GSH defence system may give conditions where the quinone lives long enough to effect its toxic properties. The influence of the reactive tert‐butylquinone on enzymatic activities is demonstrated by the inhibition of glyceraldehyde‐3‐phosphate dehydrogenase.     

Identification of a flavin‐containing S‐oxygenating monooxygenase involved in alliin biosynthesis in garlic

S‐Alk(en)yl‐l ‐cysteine sulfoxides are cysteine‐derived secondary metabolites highly accumulated in the genus Allium. Despite pharmaceutical importance, the enzymes that contribute to the biosynthesis of S‐alk‐(en)yl‐l ‐cysteine sulfoxides in Allium plants remain largely unknown. Here, we report the identification of a flavin‐containing monooxygenase, AsFMO1, in garlic (Allium sativum), which is responsible for the S‐oxygenation reaction in the biosynthesis of S‐allyl‐l ‐cysteine sulfoxide (alliin). Recombinant AsFMO1 protein catalyzed the stereoselective S‐oxygenation of S‐allyl‐l ‐cysteine to nearly exclusively yield (R_CS_S)‐S‐allylcysteine sulfoxide, which has identical stereochemistry to the major natural form of alliin in garlic. The S‐oxygenation reaction catalyzed by AsFMO1 was dependent on the presence of nicotinamide adenine dinucleotide phosphate (NADPH) and flavin adenine dinucleotide (FAD), consistent with other known flavin‐containing monooxygenases. AsFMO1 preferred S‐allyl‐l ‐cysteine to γ‐glutamyl‐S‐allyl‐l ‐cysteine as the S‐oxygenation substrate, suggesting that in garlic, the S‐oxygenation of alliin biosynthetic intermediates primarily occurs after deglutamylation. The transient expression of green fluorescent protein (GFP) fusion proteins indicated that AsFMO1 is localized in the cytosol. AsFMO1 mRNA was accumulated in storage leaves of pre‐emergent nearly sprouting bulbs, and in various tissues of sprouted bulbs with green foliage leaves. Taken together, our results suggest that AsFMO1 functions as an S‐allyl‐l ‐cysteine S‐oxygenase, and contributes to the production of alliin both through the conversion of stored γ‐glutamyl‐S‐allyl‐l ‐cysteine to alliin in storage leaves during sprouting and through the de novo biosynthesis of alliin in green foliage leaves.     

A thiol‐disulfide oxidoreductase of the Gram‐positive pathogen Corynebacterium diphtheriae is essential for viability,pilus assembly,toxin production and virulence

The Gram‐positive pathogen Corynebacterium diphtheriae exports through the Sec apparatus many extracellular proteins that include the key virulence factors diphtheria toxin and the adhesive pili. How these proteins attain their native conformations after translocation as unfolded precursors remains elusive. The fact that the majority of these exported proteins contain multiple cysteine residues and that several membrane‐bound oxidoreductases are encoded in the corynebacterial genome suggests the existence of an oxidative protein‐folding pathway in this organism. Here we show that the shaft pilin SpaA harbors a disulfide bond in vivo and alanine substitution of these cysteines abrogates SpaA polymerization and leads to the secretion of degraded SpaA peptides. We then identified a thiol‐disulfide oxidoreductase (MdbA), whose structure exhibits a conserved thioredoxin‐like domain with a CPHC active site. Remarkably, deletion of mdbA results in a severe temperature‐sensitive cell division phenotype. This mutant also fails to assemble pilus structures and is greatly defective in toxin production. Consistent with these defects, the ΔmdbA mutant is attenuated in a guinea pig model of diphtheritic toxemia. Given its diverse cellular functions in cell division, pilus assembly and toxin production, we propose that MdbA is a component of the general oxidative folding machine in C. diphtheriae.     

In vitro folding of methionine‐arginine human lyspro‐proinsulin S‐sulfonate—Disulfide formation pathways and factors controlling yield

We investigated the in vitro folding of an oxidized proinsulin (methionine‐arginine human lyspro‐proinsulin S‐sulfonate), using cysteine as a reducing agent at 5°C and high pH (10.5–11). Folding intermediates were detected and characterized by means of matrix‐assisted laser desorption ionization mass spectrometry (MALDI‐MS), reversed‐phase chromatography (RPC), size‐exclusion chromatography, and gel electrophoresis. The folding kinetics and yield depended on the protein and cysteine concentrations. RPC coupled with MALDI‐MS analyses indicated a sequential formation of intermediates with one, two, and three disulfide bonds. The MALDI‐MS analysis of Glu‐C digested, purified intermediates indicated that an intra‐A‐chain disulfide bond formed first among A6, A7, and A11. Various non‐native intra‐A (A20 with A6, A7, or A11), intra‐B (between B7 and B19), and inter‐A‐B disulfide bonds were observed in the intermediates with two disulfide bonds. The intermediates with three disulfide bonds had mainly the non‐native intra‐A and intra‐B bonds. At a cysteine‐to‐proinsulin‐SH ratio of 3.5, all intermediates with the non‐native disulfide bonds were converted to properly folded proinsulin via disulfide bond reshuffling, which was the slowest step. Aggregation via the formation of intermolecular disulfide bonds of early intermediates was the major cause of yield loss. At a higher cysteine‐to‐proinsulin‐SH ratio, some intermediates and folded MR‐KPB‐hPI were reduced to proteins with thiolate anions, which caused unfolding and even more yield loss than what resulted from aggregation of the early intermediates. Reducing protein concentration, while keeping an optimal cysteine‐to‐protein ratio, can improve folding yield significantly. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Plasmodium falciparum acyl carrier protein crystal structures in disulfide‐linked and reduced states and their prevalence during blood stage growth

Acyl Carrier Protein (ACP) has a single reactive sulfhydryl necessary for function in covalently binding nascent fatty acids during biosynthesis. In Plasmodium falciparum, the causative agent of the most lethal form of malaria, fatty acid biosynthesis occurs in the apicoplast organelle during the liver stage of the parasite life cycle. During the blood stage, fatty acid biosynthesis is inactive and the redox state of the apicoplast has not been determined. We solved the crystal structure of ACP from P. falciparum in reduced and disulfide‐linked forms, and observe the surprising result that the disulfide in the PfACP cross‐linked dimer is sequestered from bulk solvent in a tight molecular interface. We assessed solvent accessibility of the disulfide with small molecule reducing agents and found that the disulfide is protected from BME but less so for other common reducing agents. We examined cultured P. falciparum parasites to determine which form of PfACP is prevalent during the blood stages. We readily detected monomeric PfACP in parasite lysate, but do not observe the disulfide‐linked form, even under conditions of oxidative stress. To demonstrate that PfACP contains a free sulfhydryl and is not acylated or in the apo state, we treated blood stage parasites with the disulfide forming reagent diamide. We found that the effects of diamide are reversed with reducing agent. Together, these results suggest that the apicoplast is a reducing compartment, as suggested by models of P. falciparum metabolism, and that PfACP is maintained in a reduced state during blood stage growth. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

New synthesis of somatostatin according to the S-tert-butylthiocysteine procedure

To exemplify the usefulness of the S-tert-butylthio group for a reversible blocking of the cysteine thiol function in peptide synthesis, fully protected dihydrosomatostatin was prepared by the fragment-condensation procedure. The experimental results confirm the excellent stability of the asymmetric disulfide under the normal conditions of peptide synthesis and prove that the selective, acid-catalyzed nucleophil removal—as well as by mercaptans—of the 2-nitrophenylsulfenyl group proceeds smoothly in the presence of this thiol protection. Thus, the strategy of overall acid-labile side-chain protection in combination with the N^α-2-nitrophenylsulfenyl group for the chain-elongation steps can be successfully applied to the synthesis of cysteine-containing peptides using their S-tert-butylthio derivatives. Removal of the acid-labile groups, followed by reductive cleavage of the asymmetric disulfides and successive air oxidation, allowed a clean conversion of protected dihydrosomatostatin into somatostatin at a high degree of purity and in good yields.     

Design,Synthesis, and Biological Evaluation of Peptidomimetic N‐Substituted Cbz‐4‐Hyp‐Hpa‐Amides as Novel Inhibitors of Plasmodium falciparum

A new series of peptidomimetic N‐substituted Cbz‐4‐Hyp‐Hpa‐amides were designed, synthesized, and evaluated for inhibition of the Plasmodium falciparum. Substituents on the N‐atom of the amide group were selected alkyl‐, allyl‐, aryl‐, 2‐hydroxyethyl‐, 2‐cyanoethyl‐, cyanomethyl‐, 2‐hydroxyethyl‐, 2,2‐diethoxyethyl‐, or 2‐ethoxy‐2‐oxoethylamino groups, and about of 40 new compounds were synthesized and evaluated for antiplasmodial activity in vitro. Antimalarial activity has been investigated as for the final peptide mimetics, and their immediate predecessors, carrying TBDMS or TBDPS protecting groups on 4‐hydroxyproline residue and 18 derivatives exhibited toxicity against P. falciparum. Of these agents, compound 23e was shown to have potent antimalarial activity with IC₅₀ 528 ng/ml.     

Plasmodium yoelii inhibitor of cysteine proteases is exported to exomembrane structures and interacts with yoelipain‐2 during asexual blood‐stage development

Plasmodium falciparum (Pf) blood stages express falstatin, an inhibitor of cysteine proteases (ICP), which is implicated in regulating proteolysis during red blood cell infection. Recent data using the Plasmodium berghei rodent malaria model suggested an additional role for ICP in the infection of hepatocytes by sporozoites and during liver‐stage development. Here we further characterize the role of ICP in vivo during infection with Plasmodium yoelii (Py) and Pf. We found that Py‐ICP was refractory to targeted gene deletion indicating an essential function during asexual blood‐stage replication, but significant downregulation of ICP using a regulated system did not impact blood‐stage growth. Py‐ICP localized to vesicles within the asexual blood‐stage parasite cytoplasm, as well as the parasitophorous vacuole, and was exported to dynamic exomembrane structures in the infected RBC. In sporozoites, expression was observed in rhoptries, in addition to intracellular vesicles distinct from TRAP containing micronemes. During liver‐stage development, Py‐ICP was confined to the parasite compartment until the final phase of liver‐stage development when, after parasitophorous vacuolemembrane breakdown, it was released into the infected hepatocyte. Finally, we identified the cysteine protease yoelipain‐2 as a binding partner of Py‐ICP during blood‐stage infection. These data show that ICP may be important in regulating proteolytic processes during blood‐stage development, and is likely playing a role in liver stage‐hepatocyte interactions at the time of exoerythrocytic merozoite release.     

Utilization of host‐derived cysteine‐containing peptides overcomes the restricted sulphur metabolism of Campylobacter jejuni

The non‐glycolytic food‐borne pathogen Campylobacter jejuni successfully colonizes the intestine of various hosts in spite of its restricted metabolic properties. While several amino acids are known to be used by C. jejuni as energy sources, none of these have been found to be essential for growth. Here we demonstrated through phenotype microarray analysis that cysteine utilization increases the metabolic activity of C. jejuni. Furthermore, cysteine was crucial for its growth as C. jejuni was unable to synthesize it from sulphate or methionine. Our study showed that C. jejuni compensates this limited anabolic capacity by utilizing sulphide, thiosulphate, glutathione and the dipeptides γGlu–Cys, Cys–Gly and Gly–Cys as sulphur sources and cysteine precursors. A panel of C. jejuni mutants in putative peptidases and peptide transporters were generated and tested for their participation in the catabolism of the cysteine‐containing peptides, and the predicted transporter protein CJJ81176_0236 was discovered to facilitate the growth with the dipeptide Cys–Gly, Ile–Arg and Ile–Trp. It was named Campylobacter peptide transporter A (CptA) and is the first representative of the oligopeptide transporter OPT family demonstrated to participate in the glutathione‐derivative Cys–Gly catabolism in prokaryotes. Our study provides new insights into how host‐ and microbiota‐derived substrates like sulphide, thiosulphate and short peptides are used by C. jejuni to compensate its restricted metabolic capacities.     

Computational studies on the water‐catalyzed stereoinversion mechanism of glutamic acid residues in peptides and proteins

In contrast with the common belief that all the amino acid residues in higher organisms are l ‐forms, d ‐amino acid residues have been recently detected in various aging tissues. Aspartic acid (Asp) residues are known to be the most prone to stereoinvert via cyclic imide intermediate. Although the glutamic acid (Glu) is similar in chemical structure to Asp, little has been reported to detect d ‐Glu residues in human proteins. In this study, we investigated the mechanism of the Glu‐residue stereoinversion catalyzed by water molecules using B3LYP/6‐31+G(d,p) density functional theory calculations. We propose that the Glu‐residue stereoinversion proceeds via a cyclic imide intermediate, i.e., glutarimide (GI). All calculations were performed by using a model compound in which a Glu residue was capped with acetyl and methylamino groups on the N‐ and C‐termini, respectively. We found that two water molecules catalyze the three steps involved in the GI formation: iminolization, cyclization, and dehydration. The activation energy required for the Glu residue to form a GI intermediate was estimated to be 32.3 kcal mol^?1, which was higher than that of the experimental Asp‐residue stereoinversion. This calculation result suggests that the Glu‐residue stereoinversion is not favored under the physiological condition.     

Characterization of (Boc‐Cys/Sec‐NHMe)2 and (Boc‐Cys/Sec‐OMe)2: Evidence of local conformational difference between disulfide and diselenide

Conformations of disulfide and diselenide were compared in (Boc‐Cys/Sec‐NHMe)₂ and (Boc‐Cys/Sec‐OMe)₂ using X‐ray crystallography, nuclear magnetic resonance (NMR) spectroscopy, density functional theory (DFT), and circular dichroism (CD) spectroscopy. Conformations of disulfide/diselenide in polypeptides are defined based on the sign of side chain torsion angle χ₃ (–CH₂–S/Se–S/Se–CH₂–); negative indicates left‐handed and positive indicates right‐handed orientation. In the crystals of (Boc‐Cys‐OMe)₂ and (Boc‐Sec‐OMe)₂, the disulfide exhibits a left‐handed and the diselenide a right‐handed orientation. Characterization of cystine and selenocystine derivatives in solution using ¹H‐NMR, natural abundant ⁷⁷Se NMR, 2D‐ROESY, and chemical shift analysis coupled to DMSO titration has indicated the symmetrical nature and antiparallel orientation of Cys/Sec residues about the disulfide/diselenide bridges. Structural calculations of cystine and selenocystine derivatives using DFT further support the antiparallel orientation of Cys/Sec residues about disulfide/diselenide. The far‐ultraviolet (UV) region CD spectra of cystine and selenocystine derivatives have exhibited the negative Cotton effect (CE) for disulfide and positive for diselenide confirming the difference in the conformational preference of disulfide and diselenide. In the previously reported polymorphic structure of (Boc‐Sec‐OMe)₂, the diselenide has right‐handed orientation. In the X‐ray structures of disulfide and diselenide analogues of Escherichia coli protein encoded by curli specific gene C (CgsC) retrieved from Protein Databank (PDB), disulfide has left‐handed and the diselenide right‐handed orientation. The current report provides the evidence for the local conformational difference between a disulfide and a diselenide group under unconstrained conditions, which may be useful for the rational replacement of disulfide by diselenide in polypeptide chains.     

Analysis of the interacting surface of maurotoxin with the voltage‐gated Shaker B K+ channel

Maurotoxin (MTX) is a 34‐residue toxin that was isolated initially from the venom of the scorpion Scorpio maurus palmatus. Unlike the other toxins of the α‐KTx6 family (Pi1, Pi4, Pi7, and HsTx1), MTX exhibits a unique disulfide bridge organization of the type C₁? C₅, C₂? C₆, C₃? C₄, and C₇? C₈ (instead of the conventional C₁? C₅, C₂? C₆, C₃? C₇, and C₄? C₈, herein referred to as Pi1‐like) that does not prevent its folding along the classic α/β scaffold of scorpion toxins. MTX_Pi1 is an MTX variant with a conventional pattern of disulfide bridging without any primary structure alteration of the toxin. Here, using MTX and/or MTX_Pi1 as models, we investigated how the type of folding influences toxin recognition of the Shaker B potassium channel. Amino acid residues of MTX that were studied for Shaker B recognition were selected on the basis of their homologous position in charybdotoxin, a three disulfide‐bridged scorpion toxin also active on this channel type. These residues favored either an MTX‐ or MTX_Pi1‐like folding. Our data indicate clearly that Lys²³ and Tyr³² (two out of ten amino acid residues studied) are the most important residues for Shaker B channel blockage by MTX. For activity on SKCa channels, the same amino acid residues also affect, directly or indirectly, the recognition of SK channels. The molecular modeling technique and computed docking indicate the existence of a correlation between the half cystine pairings of the mutated analogs and their activity on the Shaker B K⁺ channel. Overall, mutations in MTX could, or could not, change the reorganization of disulfide bridges of this molecule without affecting its α/β scaffold. However, changing of the peptide backbone (cross linking disulfide bridges from MTX‐like type vs MTX_Pi1‐like type) appears to have less impact on the molecule activity than mutation of certain key amino acids such as Lys²³ and Tyr³² in this toxin. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Novel Chiral Bifunctional L‐Thiazoline‐Thiourea Derivatives: Design and Application in Enantioselective Michael Reactions

Several novel chiral bifunctional L‐thiazoline‐thiourea derivatives were easily synthesized from commercially available L‐cysteine in high yield. These catalysts were subsequently applied to the enantioselective Michael addition of acetylacetone to β‐nitrostyrenes. The products with S configuration were obtained in 98% enantiomeric excess (ee) when the L‐thiazoline‐thiourea derivatives were used. A plausible transition state model is proposed to explain the observed enantioselectivities. Chirality 27:979–988, 2015. © 2015 Wiley Periodicals, Inc.     

PlasmoSEP: Predicting surface‐exposed proteins on the malaria parasite using semisupervised self‐training and expert‐annotated data

Accurate and comprehensive identification of surface‐exposed proteins (SEPs) in parasites is a key step in developing novel subunit vaccines. However, the reliability of MS‐based high‐throughput methods for proteome‐wide mapping of SEPs continues to be limited due to high rates of false positives (i.e., proteins mistakenly identified as surface exposed) as well as false negatives (i.e., SEPs not detected due to low expression or other technical limitations). We propose a framework called PlasmoSEP for the reliable identification of SEPs using a novel semisupervised learning algorithm that combines SEPs identified by high‐throughput experiments and expert annotation of high‐throughput data to augment labeled data for training a predictive model. Our experiments using high‐throughput data from the Plasmodium falciparum surface‐exposed proteome provide several novel high‐confidence predictions of SEPs in P. falciparum and also confirm expert annotations for several others. Furthermore, PlasmoSEP predicts that 25 of 37 experimentally identified SEPs in Plasmodium yoelii salivary gland sporozoites are likely to be SEPs. Finally, PlasmoSEP predicts several novel SEPs in P. yoelii and Plasmodium vivax malaria parasites that can be validated for further vaccine studies. Our computational framework can be easily adapted to improve the interpretation of data from high‐throughput studies.     

A Comprehensive View on (−)‐7‐Oxo‐ent‐kaur‐16‐en‐19‐oic Acid,the Major Constituent of Xylopia sericea Leaves Extract: Complete NMR Assignments,X‐Ray Crystallographic Structure,in Vitro Antimalarial Activity and Cytotoxicity

Bioguided fractionation of Xylopia sericea antiplasmodial dichloromethane leaves extract led to the isolation of (?)‐7‐oxo‐ent‐kaur‐16‐en‐19‐oic acid (C₂₀H₂₈O₃) that was identified by a combination of 1D and 2D NMR experiments (COSY, HMBC, HSQC, HSQC‐TOCSY, HSQC‐NOESY and NOESY) and by X‐ray crystallography. A feature to be pointed out is its (4R) configuration that was inferred from the NOE experiments (HSQC‐NOESY and NOESY) and X‐ray crystallography. In vitro evaluation of this rare diterpene acid against the chloroquine‐resistant strain Plasmodium falciparum W2 by the PfLDH method showed it disclosed a low antiplasmodial activity and was not cytotoxic to HepG2 cells (CC₅₀ 862.6±6.7 μm ) by the MTT assay. The unequivocal NMR signals assignments, the X‐ray crystallographic structure, the assessment to the bioactivities and the occurrence this diterpene in X. sericea are reported here for the first time.     

Co‐evolutionary analysis implies auxiliary functions of HSP110 in Plasmodium falciparum

Plasmodium falciparum encounters frequent environmental challenges during its life cycle which makes productive protein folding immensely challenging for its metastable proteome. To identify the important components of protein folding machinery involved in maintaining P. falciparum proteome, we performed a proteome‐wide phylogenetic profiling across various species. We found that except HSP110, the parasite lost all other cytosolic nucleotide exchange factors essential for regulating HSP70 which is the centrum of the protein folding network. Evolutionary and structural analysis shows that besides its canonical interaction with HSP70, PfHSP110 has acquired sequence insertions for additional dynamic interactions. Molecular co‐evolution profile depicts that the co‐evolving proteins of PfHSP110 belong to distinct pathways like genetic variation, DNA repair, fatty acid biosynthesis, protein modification/trafficking, molecular motions, and apoptosis. These proteins exhibit unique physiochemical properties like large size, high iso‐electric point, low solubility, and antigenicity, hence require PfHSP110 chaperoning to attain functional state. Co‐evolving protein interaction network suggests that PfHSP110 serves as an important hub to coordinate protein quality control, survival, and immune evasion pathways in the parasite. Overall, our findings highlight potential accessory roles of PfHSP110 that may provide survival advantage to the parasite during its lifecycle and febrile conditions. The data also open avenues for experimental validation of auxiliary functions of PfHSP110 and their exploration for design of better antimalarial strategies. Proteins 2015; 83:1513–1525. © 2015 Wiley Periodicals, Inc.