Acyclic nucleoside phosphonates with unnatural nucleobases,favipiravir and allopurinol,designed as potential inhibitors of the human and Plasmodium falciparum 6-oxopurine phosphoribosyltransferases

Hypoxanthine-guanine-xanthine phosphoribosyltransferase (HGXPRT) is a key enzyme of the purine salvage pathway and its activity is crucial for the survival of certain parasites e.g. Plasmodium falciparum (Pf). Acyclic nucleoside phosphonates (ANPs) containing either guanine or hypoxanthine as the purine base are inhibitors of this enzyme. In this part of a SAR study, these two naturally-occurring nucleobases attached to an acyclic moiety were replaced by allopurinol or favipiravir. Both allopurinol and favipiravir ANPs were prepared via Mitsunobu reaction. The alkylation of favipiravir was optimized to yield both N- and O- regioisomers but the N-regioisomers were unstable under deprotection conditions. Thus, only the ANPs containing the O-isomer of favipiravir and those containing allopurinol were evaluated as potential inhibitors of human HGPRT and PfHGXPRT. Two ANPs with allopurinol as the base have K_i values of 10?μM and 30?μM for PfHGXPRT but do not inhibit human HGPRT activity at concentrations of 100–150?μM.     

Synthesis of 5'-methylthio coformycins: specific inhibitors for malarial adenosine deaminase

Transition state theory suggests that enzymatic rate acceleration (kcat/knon) is related to the stabilization of the transition state for a given reaction. Chemically stable analogues of a transition state complex are predicted to convert catalytic energy into binding energy. Because transition state stabilization is a function of catalytic efficiency, differences in substrate specificity can be exploited in the design of tight-binding transition state analogue inhibitors. Coformycin and 2'-deoxycoformycin are natural product transition state analogue inhibitors of adenosine deaminases (ADAs). These compounds mimic the tetrahedral geometry of the ADA transition state and bind with picomolar dissociation constants to enzymes from bovine, human, and protozoan sources. The purine salvage pathway in malaria parasites is unique in that Plasmodium falciparum ADA (PfADA) catalyzes the deamination of both adenosine and 5'-methylthioadenosine. In contrast, neither human adenosine deaminase (HsADA) nor the bovine enzyme (BtADA) can deaminate 5'-methylthioadenosine. 5'-Methylthiocoformycin and 5'-methylthio-2'-deoxycoformycin were synthesized to be specific transition state mimics of the P. falciparum enzyme. These analogues inhibited PfADA with dissociation constants of 430 and 790 pM, respectively. Remarkably, they gave no detectable inhibition of the human and bovine enzymes. Adenosine deamination is involved in the essential pathway of purine salvage in P. falciparum, and prior studies have shown that inhibition of purine salvage results in parasite death. Inhibitors of HsADA are known to be toxic to humans, and the availability of parasite-specific ADA inhibitors may prevent this side-effect. The potent and P. falciparum-specific inhibitors described here have potential for development as antimalarials without inhibition of host ADA.     

Structure-function Relationships in Human Hypoxanthine-guanine Phosphoribosyltransferase （HGPRT） by Random Mutagenesis

Introduction Hypoxanthine guaninephosphoribosyltransferase(HGPRT,EC2.4.2.8)isakeyenzymeofthepurine salvagepathway,whichallowsrecyclingofpurinebases intoDNAandRNA.Itiswidelydistributedinnature andhasbeenstudiedbothinprokaryotesandeu karyotes.Inhumans,acomp…     

The new permeability pathways: targets and selective routes for the development of new antimalarial agents

The malaria parasite, Plasmodium falciparum, spends part of its complex life cycle within the red blood cells of a human host. During this time, the parasite alters the permeability of the red blood cell's plasma membrane to allow the uptake of nutrients, the removal of "waste" and volume and ion regulation of the infected cell. The increased permeability is due to the induction of new permeability pathways (NPP), which are obvious chemotherapeutic antimalarial targets and/or selective routes for drugs, which target the internal parasite. This review covers our present understanding of the NPP, the methods used to screen for putative inhibitors of the NPP, the current repertoire of NPP inhibitors and the problems that need to be addressed to realise the potential of the NPP as antimalarial targets. In addition, the review will cover the use of the NPP as specific drug delivery routes.     

Novel N-(4-Piperidinyl)benzamide antimalarials with mammalian protein farnesyltransferase inhibitory activity

Protein farnesyltransferase of Plasmodium falciparum is a potential target in the treatment of malaria for which increased drug resistance is observed. The design, synthesis and evaluation of a series of N-(4-piperidinyl)benzamides is reported. The most potent compounds showed in vitro activity against the parasite at submicromolar concentrations.     

Design of new plasmepsin inhibitors: a virtual high throughput screening approach on the EGEE grid

Though different species of the genus Plasmodium may be responsible for malaria, the variant caused by P. falciparum is often very dangerous and even fatal if untreated. Hemoglobin degradation is one of the key metabolic processes for the survival of the Plasmodium parasite in its host. Plasmepsins, a family of aspartic proteases encoded by the Plasmodium genome, play a prominent role in host hemoglobin cleavage. In this paper we demonstrate the use of virtual screening, in particular molecular docking, employed at a very large scale to identify novel inhibitors for plasmepsins II and IV. A large grid infrastructure, the EGEE grid, was used to address the problem of large computation resources required for docking hundreds of thousands of chemical compounds on different plasmepsin targets of P. falciparum. A large compound library of about 1 million chemical compounds was docked on 5 different targets of plasmepsins using two different docking software, namely FlexX and AutoDock. Several strategies were employed to analyze the results of this virtual screening approach including docking scores, ideal binding modes, and interactions to key residues of the protein. Three different classes of structures with thiourea, diphenylurea, and guanidino scaffolds were identified to be promising hits. While the identification of diphenylurea compounds is in accordance with the literature and thus provides a sort of "positive control", the identification of novel compounds with a guanidino scaffold proves that high throughput docking can be effectively used to identify novel potential inhibitors of P. falciparum plasmepsins. Thus, with the work presented here, we do not only demonstrate the relevance of computational grids in drug discovery but also identify several promising small molecules which have the potential to serve as candidate inhibitors for P. falciparum plasmepsins. With the use of the EGEE grid infrastructure for the virtual screening campaign against the malaria causing parasite P. falciparum we have demonstrated that resource sharing on an eScience infrastructure such as EGEE provides a new model for doing collaborative research to fight diseases of the poor.     

Cationic detergents enable the separation of membrane proteins of Plasmodium falciparum-infected erythrocytes by 2D gel electrophoresis

The intraerythrocytic stage of Plasmodium falciparum alters the characteristics of its host cell by exporting selected plasmodial proteins. Although it is clear that the physicochemical and immunobiological properties of the host cell are modulated during parasite development, the involved plasmodial proteins and their mode of action are not completely known. Using cetyltrimethylammonium bromide (CTAB) or benzyldimethyl-n-hexadecylammonium chloride (16-BAC) for the first dimension and SDS for the second dimension, we separated proteins from membranes of human erythrocytes and of erythrocytes infected with the malaria parasite P. falciparum. Protein spots were analyzed by MALDI-TOF/TOF MS and annotated in respective 2D master gels. By using the alternative 2D approach, characteristic host cell membrane proteins and, more importantly, membrane-associated and exported plasmodial proteins were identified that might play a role in parasite-induced host cell modulation.     

Polyphosphate content and fine structure of acidocalcisomes of Plasmodium falciparum.

Although acidocalcisomes have been well characterized morphologically in other apicomplexan parasites, no such characterization has been done in Plasmodium spp. Here, we report that Plasmodium falciparum merozoites possess electron-dense organelles rich in phosphorus and calcium, as detected by X-ray microanalysis of intact cells, which are similar to the acidocalcisomes of other apicomplexans, but of more irregular form. In agreement with these results malaria parasites possess large amounts of short- and long-chain polyphosphate (polyP), which are associated with acidocalcisomes in other organisms. PolyP levels were highest in the trophozoite stage of the parasite. Treatment of isolated trophozoites with chloroquine resulted in a significant hydrolysis of polyP. Taken together, these results provide evidence that acidocalcisomes from Plasmodium falciparum do not differ significantly from acidocalcisomes of other apicomplexan parasites.     

A comparative QM/MM simulation study of the reaction mechanisms of human and Plasmodium falciparum HG(X)PRTases

QM/MM hybrid potential free-energy simulations are performed to compare the reaction mechanisms of human hypoxanthine guanine phosphoribosyl transferase (HGPRTase) and the corresponding enyzme from Plasmodium falciparum (Pf), hypoxanthine guanine xanthine phosphoribosyl transferase (HGXPRTase). These enzymes share 44% of sequence identity but display very different affinities for xanthine. The calculations show that in both enzymes phosphoribosyl transfer proceeds via a dissociative mechanism from an anionic form of the substrate. Nevertheless, there are significant differences in the geometries of critical structures along the reaction paths which it may be possible to exploit for the design of specific inhibitors against the Pf enzyme.     

Spatial distribution of heme species in erythrocytes infected with Plasmodium falciparum by use of resonance Raman imaging and multivariate analysis

The multivariate algorithm hierarchical cluster analysis is applied to sets of resonance Raman spectra collected from human erythrocytes infected with the malaria parasite Plasmodium falciparum. The images obtained yield information about the distribution of hemoglobin and hemozoin (or malaria pigment) within the parasitized cells and about their molecular structure. This method has the advantage of conveying more information than other imaging approaches based on resonance Raman spectroscopy, and it is a promising tool to study the hemozoin formation process and its interaction with antimalarial drugs within unstained, well-preserved parasites.     

Synthesis and antimalarial activity of novel dihydro-artemisinin derivatives

The Plasmodium falciparum cysteine protease falcipain-2, one of the most promising targets for antimalarial drug design, plays a key role in parasite survival as a major peptide hydrolase within the hemoglobin degradation pathway. In this work, a series of novel dihydroartemisinin derivatives based on (thio)semicarbazone scaffold were designed and synthesized as potential falcipain-2 inhibitors. The in vitro biological assay indicated that most of the target compounds showed excellent inhibition activity against P. falciparum falcipain-2, with IC(50) values in the 0.29-10.63 μM range. Molecular docking studies were performed to investigate the binding affinities and interaction modes for the inhibitors. The preliminary SARs were summarized and could serve as a foundation for further investigation in the development of antimalarial drugs.     

Artemisinin

Artemisinin is the most modern active pharmaceutical ingredient (API) for the treatment of malaria, an infectious disease, which accompanied humans throughout history. The amplification of DNA‐fragments of the pathogen, extracted from an infant skeleton, by use of the polymerase chain reaction (PCR) and comparison with the meanwhile sequenced genome of Plasmodium falciparum provided direct evidence for malaria epidemics in antiquity. The elucidation of the lifecycle of the parasite was a prerequisite for the development and comprehension of efficient therapies, e. g. the administration of schizonticides, like quinine or chloroquine, but also more modern drugs, like artemisinin.     

Tomentosones A and B, hexacyclic phloroglucinol derivatives from the Thai shrub Rhodomyrtus tomentosa

Two phloroglucinols named tomentosones A and B (1 and 2) that each possess a novel hexacyclic ring system were isolated from the CH(2)Cl(2) extract of Rhodomyrtus tomentosa leaves. Their structures were elucidated from analyses of 2D NMR spectroscopic data. Tomentosone A inhibited the growth of chloroquine-resistant and -sensitive strains of the malaria parasite Plasmodium falciparum, with IC(50) values of 1.49 μM and 1.0 μM, respectively, while tomentosone B was significantly less active.     

Single Tryptophan of Disordered Loop from Plasmodium falciparum Purine Nucleoside Phosphorylase: Involvement in Catalysis and Microenvironment

Among various tropical diseases, malaria is a major life-threatening disease caused by Plasmodium parasite. Plasmodium falciparum is responsible for the deadliest form of malaria, so-called cerebral malaria. Purine nucleoside phosphorylase from P. falciparum is a homohexamer containing single tryptophan residue per subunit that accepts inosine and guanosine but not adenosine for its activity. This enzyme has been exploited as drug target against malaria disease. It is important to draw together significant knowledge about inherent properties of this enzyme which will be helpful in better understanding of this drug target. The enzyme shows disorder to order transition during catalysis. The single tryptophan residue residing in conserved region of transition loop is present in purine nucleoside phosphorylases throughout the Plasmodium genus. This active site loop motif is conserved among nucleoside phosphorylases from apicomplexan parasites. Modification of tryptophan residue by N-bromosuccinamide resulted in complete loss of activity showing its importance in catalysis. Inosine was not able to protect enzyme against N-bromosuccinamide modification. Extrinsic fluorescence studies revealed that tryptophan might not be involved in substrate binding. The tryptophan residue localised in electronegative environment showed collisional and static quenching in the presence of quenchers of different polarities.     

Aplidiopsamine A, an antiplasmodial alkaloid from the temperate Australian ascidian, Aplidiopsis confluata

A polyaromatic alkaloid, aplidiopsamine A was isolated from the temperate Australian ascidian, Aplidiopsis confluata, and its structure was determined from interpretation of mass, 1D and 2D NMR spectra. Aplidiopsamine A is the first alkaloid to possess the tricyclic aromatic substructure 3H-pyrrolo[2,3-c]quinoline conjugated to an adenine. Aplidiopsamine A exhibited significant inhibition of growth of chloroquine resistant and sensitive strains of the malaria parasite, Plasmodium falciparum, and minimal toxicity toward human cells.     

Intracellular targets of cyclin-dependent kinase inhibitors: identification by affinity chromatography using immobilised inhibitors

BACKGROUND: Chemical inhibitors of cyclin-dependent kinases (CDKs) have great therapeutic potential against various proliferative and neurodegenerative disorders. Olomoucine, a 2,6,9-trisubstituted purine, has been optimized for activity against CDK1/cyclin B by combinatorial and medicinal chemistry efforts to yield the purvalanol inhibitors. Although many studies support the action of purvalanols against CDKs, the actual intracellular targets of 2,6, 9-trisubstituted purines remain unverified. RESULTS: To address this issue, purvalanol B (95. ) and an N6-methylated, CDK-inactive derivative (95M. ) were immobilized on an agarose matrix. Extracts from a diverse collection of cell types and organisms were screened for proteins binding purvalanol B. In addition to validating CDKs as intracellular targets, a variety of unexpected protein kinases were recovered from the 95. matrix. Casein kinase 1 (CK1) was identified as a principal 95. matrix binding protein in Plasmodium falciparum, Leishmania mexicana, Toxoplasma gondii and Trypanosoma cruzi. Purvalanol compounds also inhibit the proliferation of these parasites, suggesting that CK1 is a valuable target for further screening with 2,6,9-trisubstituted purine libraries. CONCLUSIONS: That a simple batchwise affinity chromatography approach using two purine derivatives facilitated isolation of a small set of highly purified kinases suggests that this could be a general method for identifying intracellular targets relevant to a particular class of ligands. This method allows a close correlation to be established between the pattern of proteins bound to a small family of related compounds and the pattern of cellular responses to these compounds.     

Synthesis of 5'-methylenearisteromycin and its 2-fluoro derivative with potent antimalarial activity due to inhibition of the parasite S-adenosylhomocysteine hydrolase

5'-methylenearisteromycin 5 and its 2-fluoro derivative 6, which were designed as antimalarial agents because of their AdoHcy hydrolase inhibition, were synthesized from D-ribose, using a stereoselective intramolecular radical cyclization as the key step to construct the carbocyclic structure. These compounds were evaluated as AdoHcy hydrolase inhibitors with the recombinant human and malarial parasite enzymes. Although 5 and 6 were both potent inhibitors of the malarial parasite AdoHcy hydrolase, the 2-fluoro derivative 6 proved to be superior due to its lower inhibitory effect on the human enzyme. In addition, 6 was identified as a potent antimalarial agent using an in vitro assay system with Plasmodium falciparum.     

New antimalarial drugs

Approximately 40% of the world population live in areas with the risk of malaria. Each year, 300-500 million people suffer from acute malaria, and 0.5-2.5 million die from the disease. Although malaria has been widely eradicated in many parts of the world, the global number of cases continues to rise. The most important reason for this alarming situation is the rapid spread of malaria parasites that are resistant to antimalarial drugs, especially chloroquine, which is by far the most frequently used. The development of new antimalarial drugs has been neglected since the 1970s owing to the end colonialism, changes in the areas of military engagement, and the restricted market potential. Only in recent years, in part supported by public funding programs, has interest in the development of antimalarial drugs been renewed. New data available from the recently sequenced genome of the malaria parasite Plasmodium falciparum and the application of methods of modern drug design promise to bring significant development in the fight against this disease.