Targeting malaria protein kinases.

Malaria is one of the most impacting public health problems in tropical and subtropical areas of the globe, with approximately 200 million cases worldwide annually. In the absence of an effective vaccine, rapid treatment is vital for effective malaria control. However, parasite resistance to currently available drugs underscores the urgent need for identifying new antimalarial therapies with new mechanisms of action. Among potential drug targets for developing new antimalarial candidates, protein kinases are attractive. These enzymes catalyze the phosphorylation of several proteins, thereby regulating a variety of cellular processes and playing crucial roles in the development of all stages of the malaria parasite life cycle. Moreover, the large phylogenetic distance between Plasmodium species and its human host is reflected in marked differences in structure and function of malaria protein kinases between the homologs of both species, indicating that selectivity can be attained. In this review, we describe the functions of the different types of Plasmodium kinases and highlight the main recent advances in the discovery of kinase inhibitors as potential new antimalarial drug candidates.

Simple and sensitive antimalarial drug screening in vitro and in vivo using transgenic luciferase expressing Plasmodium berghei parasites.

We report two improved assays for in vitro and in vivo screening of chemicals with potential anti-malarial activity against the blood stages of the rodent malaria parasite Plasmodiumberghei. These assays are based on the determination of luciferase activity (luminescence) in small blood samples containing transgenic blood stage parasites that express luciferase under the control of a promoter that is either schizont-specific (ama-1) or constitutive (eef1alphaa). Assay 1, the in vitro drug luminescence (ITDL) assay, measured the success of schizont maturation in the presence of candidate drugs quantifying luciferase activity in mature schizonts only (ama-1 promoter). The ITDL assay generated drug-inhibition curves and EC(50) values comparable to those obtained with standard in vitro drug-susceptibility assays. The second assay, the in vivo drug-luminescence (IVDL) assay, measured parasite growth in vivo in a standard 4-day suppressive drug test, monitored by measuring the constitutive luciferase activity of circulating parasites (eef1alphaa promoter). The IVDL assay generates growth-curves that are identical to those obtained by manual counting of parasites in Giemsa-stained smears. The reading of luminescence assays is rapid, requires a minimal number of handling steps and no experience with parasite morphology or handling fluorescence-activated cell sorters, produces no radioactive waste and test-plates can be stored for prolonged periods before processing. Both tests are suitable for use in larger-scale in vitro and in vivo screening of drugs. The standard methodology of anti-malarial drug screening and validation, which includes testing in rodent models of malaria, can be improved by the incorporation of such assays.

Studies on antimalarial drug susceptibility in Colombia, in relation to Pfmdr1 and Pfcrt.

In Colombia, Plasmodium resistance to antimalarials such as chloroquine and antifolates is a serious problem. As a result, the national Colombian health authorities are monitoring the efficacy of alternative drugs and schemes. The study of genetic polymorphisms related with drug resistance is required in the region. In vitro responses to chloroquine, quinine, mefloquine, amodiaquine, desethylamodiaquine, artesunate and dihydroartesunate were carried out by HRP ELISA. SNP analysis in Pfcrt and Pfmdr1 genes was performed by PCR-RFLP in 77 samples from the North West region of Colombia. In vitro resistance to chloroquine was high (74%), followed by mefloquine (30%) and desethylamodiaquine (30%). A positive correlation between the IC(50) of paired drugs was also detected. The allele Pfmdr1 N86 (wild) was present in 100% of the samples and 1246Y (mutant) in 92%. However, their presence did not correlate with in vitro drug resistance. Presence of the mutations K76T and N75E in Pfcrt was confirmed in all samples. Analysis of 4 codons (72, 74, 75 and 76) in pfcrt confirmed the presence of the haplotypes CMET in 91% and SMET in 9% of the samples.

A primer-introduced restriction analysis-polymerase chain reaction method to detect knockdown resistance mutations in Anopheles gambiae.

In the major malaria vector Anopheles gambiae Giles, two point mutations at the voltage-gated sodium channel have been associated with knockdown resistance (kdr) to DDT and pyrethroid insecticides. Simple allele-specific polymerase chain reaction (PCR) assays to detect these single-nucleotide polymorphisms are prone to lack of specificity and therefore alternative techniques have been proposed. However, these may not be easily implemented in many laboratories from malaria endemic regions. Here, we describe a primer-introduced restriction analysis (PIRA)-PCR method to detect kdr mutations in An. gambiae. This method unambiguously identified all six genotypes for the kdr locus in a sample of 113 field-collected mosquitoes for which kdr genotypes had been confirmed by DNA sequencing. Co-occurrence of both kdr alleles was found in sites from Equatorial Guinea and Gabon and the L1014F mutation was detected in M-form individuals from Angola. The PIRA-PCR proved to be a reliable, robust, and simpler alternative for the detection of kdr mutations in this malaria vector.

Malaria parasites can develop stable resistance to artemisinin but lack mutations in candidate genes atp6 (encoding the sarcoplasmic and endoplasmic reticulum Ca2+ ATPase), tctp, mdr1, and cg10.

Resistance of Plasmodium falciparum to drugs such as chloroquine and sulfadoxine-pyrimethamine is a major problem in malaria control. Artemisinin (ART) derivatives, particularly in combination with other drugs, are thus increasingly used to treat malaria, reducing the probability that parasites resistant to the components will emerge. Although stable resistance to artemisinin has yet to be reported from laboratory or field studies, its emergence would be disastrous because of the lack of alternative treatments. Here, we report for the first time, to our knowledge, genetically stable and transmissible ART and artesunate (ATN)-resistant malaria parasites. Each of two lines of the rodent malaria parasite Plosmodium chabaudi chabaudi, grown in the presence of increasing concentrations of ART or ATN, showed 15-fold and 6-fold increased resistance to ART and ATN, respectively. Resistance remained stable after cloning, freeze-thawing, after passage in the absence of drug, and transmission through mosquitoes. The nucleotide sequences of the possible genetic modulators of ART resistance (mdr1, cg10, tctp, and atp6) of sensitive and resistant parasites were compared. No mutations in these genes were identified. In addition we investigated whether changes in the copy number of these genes could account for resistance but found that resistant parasites retained the same number of copies as their sensitive progenitors. We believe that this is the first report of a malaria parasite with genetically stable and transmissible resistance to artemisinin or its derivatives.

Detection of atovaquone and Malarone resistance conferring mutations in Plasmodium falciparum cytochrome b gene (cytb).

Clinical treatment failures of the hydroxynaphthoquinone atovaquone or its combination with proguanil (Malarone) in Plasmodium falciparum malaria has been recently documented. These events have been associated to single nucleotide polymorphisms (SNPs) in the parasite cytochrome b gene (cytb). In this report we describe a set of nest PCR-RFLP methods developed for the fast detection of all known cytb mutations associated to resistance to these drugs. The methods were successfully applied for the analysis of phenol-chloroform extracted DNA samples from patients not cured by Malarone, and from an established parasite clone. Further, the protocol for the detection of the A803C mutation was applied to 164 DNA field samples extracted through crude methanol-based protocols, originated from several malaria settings. The PCR-RFLP methods here presented can be used as a valuable for the clinical detection and study of Malarone and atovaquone P. falciparum resistance.

Antimalarial drugs clear resistant parasites from partially immune hosts.

Circumstantial evidence in human malaria suggests that elimination of parasites by drug treatment meets higher success rates in individuals having some background immunity. In this study, using the rodent malaria model Plasmodium chabaudi, we show that drug-resistant parasites can be cleared by drugs when the host is partially immune.

Plasmodium falciparum: gene mutations and amplification of dihydrofolate reductase genes in parasites grown in vitro in presence of pyrimethamine.

Samples of three pyrimethamine-sensitive clones of Plasmodium falciparum were grown for periods of 22-46 weeks in media containing stepwise increases in pyrimethamine concentrations and were seen to develop up to 1000-fold increases in resistance to the drug. With clone T9/94RC17, the dihydrofolate reductase (DHFR) gene was sequenced from 10 uncloned populations and 29 pure clones, all having increased resistance to pyrimethamine, and these sequences were compared with the sequence of the original pyrimethamine-sensitive clone. No changes in amino acid sequence were found to have occurred. Some resistant clones obtained by this method were then examined by pulsed-field gel electrophoresis, and the results indicated that there had been an increase in the size of chromosome 4. This was confirmed by hybridization of Southern blots with a chromosome 4-specific probe, the vacuolar ATPase subunit B gene, and a probe to DHFR. Dot-blotting with an oligonucleotide probe to DHFR confirmed that there had been increases up to 44-fold in copy number of the DHFR gene in the resistant strains. Resistant clones obtained by this procedure were then grown in medium lacking pyrimethamine for a period of nearly 2 years, and reversion nearly to the level of pyrimethamine sensitivity of the original clone T9/94RC17 was found to occur after about 16 months. Correspondingly, the chromosome 4 of the reverted population reverted to a size like that of the original sensitive clone T9/94RC17. The procedure of growing parasites in stepwise increases of pyrimethamine concentration was repeated with two other pyrimethamine-sensitive clones: TM4CB8-2.2.3 and G112CB1.1. (The DHFR gene of these clones encodes serine at position 108, in place of threonine as in clone T9/94RC17, and it was thought that this difference might conceivably affect the rate of mutation to asparagine at this position). Clones TM4CB8-2.2.3 and G112CB1.1 also responded by developing gradually increased resistance to pyrimethamine. However, in clone TM4CB8-2.2.3 a single mutation from Ile to Met at position 164 in the DHFR gene sequence was identified, and in clone G112CB1.1 there was a single mutation from Ala to Ser at position 16, but no mutations at position 108 were obtained in any of the clones studied here. In addition, chromosome 4 of clone TM4CB8-2.2.3 increased in size, presumably due to amplification of the DHFR gene. No increase in size was seen in clone G112CB1.1. We conclude that whereas some mutations producing changes in the amino acid sequence of the DHFR molecule may occur occasionally in clones or populations of P. falciparum grown in vitro in the presence of pyrimethamine, amplification of the DHFR gene following adaptation to growth in medium containing pyrimethamine occurs as a regular feature. The bearing of these findings on the development of pyrimethamine-resistant forms of malaria parasites in endemic areas is discussed.

Of mice and malaria mutants: unravelling the genetics of drug resistance using rodent malaria models.

It is well recognized that drug resistance is the most significant obstacle to gaining effective malaria control. Despite the enormous advances in the knowledge of the biochemistry and molecular biology of malaria parasites, only a few genes determining resistance to the commonly used drugs have been identified. The idea that rodent malaria parasites should be exploited more widely for such work, in view of the practical problems of studying this subject experimentally in human malaria, is presented.

Dipeptide derivatives of primaquine as transmission-blocking antimalarials: effect of aliphatic side-chain acylation on the gametocytocidal activity and on the formation of carboxyprimaquine in rat liver homogenates.

PURPOSE: Dipeptide derivatives of primaquine (PQ) with reduced oxidative deamination to the inactive metabolite carboxyprimaquine were synthesized and evaluated as a novel class of transmission-blocking antimalarials. METHODS; Antimalarial activity was studied using a model consisting of mefloquine-resistant Plasmodium berghei ANKA 25R/10, Balb C mice, and Anopheles stephensi mosquitoes. Metabolic studies were performed with rat liver homogenates, and the incubates were analyzed by HPLC. RESULTS: All dipeptide derivatives and glycyl-PQ completely inhibited the appearance of oocysts in the midguts of the mosquitoes at 15 mg/ kg, while N-acetylprimaquine was not active at this dose. However, none of the title compounds were able to block oocyst production at 3.75 mg/kg, in contrast with primaquine. Exception for sarc-gly-PQ, all remaining compounds prevented sporozoite formation in the salivary glands of mosquitoes at a dose of 3.75 mg/kg. Simultaneous hydrolysis to primaquine and gly-PQ ocurred with the following order of Vmax/Km: for primaquine formation. L-ala-gly-PQ > L-phe-gly-PQ > gly-gly-PQ; and for gly-PQ formation, L-phe-gly-PQ > L-ala-gly-PQ > gly-gly-PQ. In contrast, primaquine was not released from D-phe-gly-PQ, sarc-gly-PQ, and N-acetylprimaquine. Neither carboxyprimaquine nor 8-amino-6-methoxyquinoline were detected in any of the incubation mixtures. CONCLUSIONS: The title compounds prevent the development of the sporogonic cycle of Plasmodium berghei. Gametocytocidal activity is independent of the rate and pathway of primaquine formation. Acylation of the aliphatic side-chain effectively prevents the formation of carboxyprimaquine, but the presence of a terminal amino group appears to be essential for the gametocytocidal activity.