Reduced heterozygosity at intragenic and flanking microsatellites of pfcrt gene establishes natural selection based molecular evolution of chloroquine-resistant Plasmodium falciparum in India

The positive selection of a nucleotide substitution in exon 2 of Plasmodium falciparum chloroquine resistance transporter (pfcrt) gene (mutation responsible for chloroquine resistance) causes a reduction in variation of neutral loci close to the gene. This reduction in allelic diversity around flanking regions of pfcrt gene was reported in worldwide chloroquine resistant isolates and referred as selective sweep. In Plasmodium falciparum isolates of India, the selective sweep in flanking loci of pfcrt gene is well established, however, high allelic diversity observed in intragenic microsatellites of pfcrt gene implied an ongoing genetic recombination. To understand, if molecular evolution of chloroquine-resistant P. falciparum isolates in India follow a selective sweep model, we analyzed genetic diversity at both seven intragenic and seven flanking microsatellites of pfcrt (−24 to +106 kb) gene in chloroquine sensitive and resistant parasites originating from high and low transmission areas. We observed low expected heterozygosity at all loci of resistant pfcrt-haplotypes (H_e = 0–0.77) compared to the wild-type (H_e = 0.38–0.96). Resistant SVMNT from high transmission areas showed significantly higher mean H_e (P = 0.03, t-test) at both intragenic and pfcrt-flanking loci (−24 to +22 kb) in comparison to low transmission areas. Our observation of reduction in variation at both intragenic and flanking loci of mutant pfcrt gene confirmed the selective sweep model of natural selection in chloroquine resistant P. falciparum isolates in India.     

DNA sequence polymorphisms of the pfmdr1 gene and association of mutations with the pfcrt gene in Indian Plasmodium falciparum isolates

Mutations in the Plasmodium falciparum multidrug resistance (pfmdr1) gene are known to provide compensatory fitness benefits to the chloroquine (CQ)-resistant malaria parasites and are often associated with specific mutations in the P. falciparum CQ resistant transporter (pfcrt) gene. Prevalence of the specific mutations in these two genes across different malaria endemic regions was mostly studies. However, reports on mutations in the pfmdr1 gene and their genetic associations with mutations in the pfcrt gene in Indian P. falciparum field isolates are scarce. We have sequenced a 560 bp region of pfmdr1 coding sequence in 64 P. falciparum isolates collected from different malaria endemic populations in India. Twenty out of these 64 isolates were laboratory cultured with known in vitro CQ sensitiveness (10 sensitive and 10 resistant). Three low frequency mutations (two non-synonymous and one synonymous) in the pfmdr1 gene were segregating in Indian isolates in addition to the predominant Y₈₆ and Y₁₈₄ ones, with high haplotype and nucleotide diversity in the field isolates in comparison to the cultured ones. No statistically significant genetic association between the mutations in the pfmdr1 and pfcrt gene could be detected; almost all observed associations were intragenic in nature. The results on the genetic diversity of the pfmdr1 gene were discussed in term of evolutionary perspectives in Indian P. falciparum, with possible future potential of gaining further insights on this gene in view of evolving malaria parasites resistant to artemisinin partner drugs.     

Microsatellite analysis of chloroquine resistance associated alleles and neutral loci reveal genetic structure of Indian Plasmodium falciparum

Efforts to control malignant malaria caused by Plasmodium falciparum are hampered by the parasite’s acquisition of resistance to antimalarial drugs, e.g., chloroquine. This necessitates evaluating the spread of chloroquine resistance in any malaria-endemic area. India displays highly variable malaria epidemiology and also shares porous international borders with malaria-endemic Southeast Asian countries having multi-drug resistant malaria. Malaria epidemiology in India is believed to be affected by two major factors: high genetic diversity and evolving drug resistance in P. falciparum. How transmission intensity of malaria can influence the genetic structure of chloroquine-resistant P. falciparum population in India is unknown. Here, genetic diversity within and among P. falciparum populations is analyzed with respect to their prevalence and chloroquine resistance observed in 13 different locations in India. Microsatellites developed for P. falciparum, including three putatively neutral and seven microsatellites thought to be under a hitchhiking effect due to chloroquine selection were used. Genetic hitchhiking is observed in five of seven microsatellites flanking the gene responsible for chloroquine resistance. Genetic admixture analysis and F-statistics detected genetically distinct groups in accordance with transmission intensity of different locations and the probable use of chloroquine. A large genetic break between the chloroquine-resistant parasite of the Northeast-East-Island group and Southwest group (F_ST = 0.253, P < 0.001) suggests a long period of isolation or a possibility of different origin between them. A pattern of significant isolation by distance was observed in low transmission areas (r = 0.49, P = 0.003, N = 83, Mantel test). An unanticipated pattern of spread of hitchhiking suggests genetic structure for Indian P. falciparum population. Overall, the study suggests that transmission intensity can be an efficient driver for genetic differentiation at both neutral and adaptive loci across India.     

Polymorphisms in Pfcrt and Pfmdr-1 genes after five years withdrawal of chloroquine for the treatment of Plasmodium falciparum malaria in West Bengal,India

BackgroundThe emergence of resistant power against different antimalarial agents particularly by Plasmodium falciparum is a challenge to combat malaria. Regular monitoring is essential not only to determine the efficacy and development of resistance by the parasite but also to detect early sign of regaining sensitivity to any anti-malarial agent that has been withdrawn for a long period. Studies on molecular markers associated with antimalarial drug resistance of prevailing Plasmodium population play an important role in this aspect. The present protocol was designed to study the polymorphisms in pfcrt and pfmdr-1 gene to determine any sign of regaining sensitivity to chloroquine among P. falciparum after five years of artemisinin combination therapy (ACT) implementation.MethodsClinical isolates were collected from P. falciparum positive patients attending the malaria clinic of Calcutta School of Tropical Medicine during December 2014 to December 2015. Genomic parasitic DNA was extracted and subjected to sequencing of pfcrt and pfmdr-1 gene directly from purified PCR products.ResultsA total of 89 isolates were sequenced for pfcrt and 73 isolates for pfmdr-1 genes. In pfcrt gene mutant K76T was detected in all isolates and all were SVMNT haplotype. Out of three important polymorphisms in pfmdr-1 gene mutant Y184F was detected among all isolates. One synonymous G182G and one non-synonymous S232F/Y, mutation were detected in 99% isolates.ConclusionAll isolates carrying mutant K76T in pfcrt gene, considered as hall mark for CQ resistance, indicate that there is no sign of regaining CQ sensitivity among the prevailing P. falciparum population of the study area after five years of ACT implementation.     

Analysis of genetic diversity in the chloroquine-resistant gene Pfcrt in field Plasmodium falciparum isolates from five regions of the southern Cameroon

Understanding the population genetics of genes which shape resistance to antimalarial drugs can help in devising novel control strategies. The high spread of the resistant strains of the malaria parasite Plasmodium falciparum pose a greater challenge than before to the control programs across the world. Specific mutations in the P. falciparum chloroquine resistant transporter gene “Pfcrt” have been associated with resistance to not only chloroquine, but also to amodiaquine, one of the artemisinin partners used in Cameroon for the treatment of uncomplicated malaria. We here present data on genetic variation at the Single Nucleotide Polymorphisms (SNPs) level in the Pfcrt gene in five distinct geographical settings of the Southern-Cameroon (the most malaria endemic part), i.e. Ebolowa, Yaounde, Bertoua, Douala and Kye-ossi (a city bordering Cameroon and two others African countries). Two novel mutations, hitherto unreported (in Cameroon) were found in the Pfcrt gene and variable genetic diversity was observed across the populations. High linkage disequilibrium was found between few SNPs including one of the novel mutations suggesting a synergistic work for conferring/maintaining a higher level of resistance. The inference of evolutionary pattern of this gene in Cameroon based on the genetic diversity data depicts a signature of Darwinian positive natural selection on these loci. Observation of novel mutations might traduce new variants in chloroquine/or amodiaquine resistance (proposal awaiting an experimental verification) and signal of positive selection can be the result of drug pressure exerted by misuse of chloroquine (though officially banned from the country) and/or amodiaquine. Our findings thus, provide a baseline understanding of the evolution of a malaria drug resistant gene in Cameroon and suggest a successful establishment of chloroquine-resistant strains which requires urgent attention of the malaria control program in Cameroon.     

Molecular Surveillance for Imported Antimicrobial Resistant Plasmodium falciparum,Ontario, Canada

Single-nucleotide polymorphisms at several loci have been correlated with Plasmodium falciparum drug resistance. We examined the prevalence of resistance markers in P. falciparum from imported malaria cases in Canada during 3 time periods, 2008–2009, 2013–2014, and 2017–2018. We evaluated single-nucleotide polymorphisms at atpase6 (pfATPase6), pfcrt (chloroquine resistance transporter), cytb (cytochrome b), dhfr (dihydrofolate reductase), dhps (dihydropteroate synthetase), mdr1 (multidrug resistance protein) and mdr1 copy number, and kelch13 (kelch protein gene on chromosome 13). Over time, we observed increasing mutant genotypes for dhfr S108N and dhps A613T and decreasing mutant genotypes for mdr1 N86Y, D1246Y, pfcrt K76T, and pfcrt 74–75; we identified no kelch13 mutations. We observed fewer mutations indicative of chloroquine resistance over time, which may reflect reduced chloroquine pressure in specimens from travelers to Africa. Mutations conferring proguanil resistance increased over time. Minor genotypes confirm the heterogeneous nature of infection and may affect treatment success.     

Chloroquine-Resistant Haplotype Plasmodium falciparum Parasites, Haiti

Plasmodium falciparum parasites have been endemic to Haiti for >40 years without evidence of chloroquine (CQ) resistance. In 2006 and 2007, we obtained blood smears for rapid diagnostic tests (RDTs) and filter paper blots of blood from 821 persons by passive and active case detection. P. falciparum infections diagnosed for 79 persons by blood smear or RDT were confirmed by PCR for the small subunit rRNA gene of P. falciparum. Amplification of the P. falciparum CQ resistance transporter (pfcrt) gene yielded 10 samples with amplicons resistant to cleavage by ApoI. A total of 5 of 9 samples had threonine at position 76 of pfcrt, which is consistent with CQ resistance (haplotypes at positions 72–76 were CVIET [n = 4] and CVMNT [n = 1]); 4 had only the wild-type haplotype associated with CQ susceptibility (CVMNK). These results indicate that CQ-resistant haplotype P. falciparum malaria parasites are present in Haiti.     

Limited genetic variation in the Plasmodium falciparum heme detoxification protein (HDP)

Malaria parasites infecting host red blood cells degrade hemoglobin by detoxifying heme into hemozoin. This conversion of heme to hemozoin is performed by a potent protein called heme detoxification protein (HDP), making HDP an attractive target for antimalarial drug development. We studied the genetic variation in Plasmodium falciparum HDP and also investigated if HDP due to its involvement in the heme detoxification pathway is under any potential chloroquine (CQ) selection pressure. We sequenced the complete HDP gene encompassing three exons and two introns (AT and ATTT repeats in intron 1; AT repeats in intron 2) from five P. falciparum laboratory strains with known CQ sensitivity and 50 field isolates from Venezuela (n = 26) and Kenya (n = 24), with high levels of CQ resistance. Sequencing revealed two mutations, C41F and F91L in exon 1 and exon 2, respectively. The F41 mutation was present only in the CQ sensitive (CQS) HB3 strain. However, all the isolates harbored the 91L mutation, except for the CQS 3D7 strain. The sequencing of the intron 2 region revealed no variation in the number of AT repeats. In contrast, there was a wide variation in the AT and ATTT repeats in intron 1. Overall with respect to the intron 1 repeats, the Venezuelan isolates (Expected heterozygosity, He = 0.685) showed less genetic variation as compared to the Kenyan isolates (He = 0.986). Furthermore, we also genotyped the 72–76 codons of the pfcrt gene but did not observe any correlation of the pfcrt CQ resistant genotypes (SVMNT or CVIET) with variation in the HDP, thus indicating HDP not to be under any CQ selection pressure. In conclusion, HDP is a conserved target for future antimalarial development.     

A unique methodology for detecting the spread of chloroquine-resistant strains of Plasmodium falciparum,in previously unreported areas,by analyzing anophelines of malaria endemic zones of Orissa,India

Generally, clinical data is referred to study drug-resistance patterns of Plasmodium falciparum in an area. This is only possible after a clear manifestation of drug-resistance parasites inside the human host, and thereafter detection by healthcare persons. The detection of spread of drug-resistant P. falciparum in a population, before any pathological symptoms detected in humans is possible by analyzing the anopheline vectors, transmitting malaria. In the present study we implemented a new strategy to detect the spread of chloroquine-resistant (CQR) strains of P. falciparum by the major malaria vectors prevalent in selected endemic regions of Orissa, India. We screened P. falciparum positive vectors by using polymerase chain reaction (PCR)-based assay and thereafter detected K76T mutation in the Pfcrt gene, the chloroquine-resistance marker, of parasites present within the vectors. This study showed higher transmission rate of chloroquine-resistant P. falciparum parasites by Anopheles culicifacies and Anopheles fluviatilis. This study will help in assigning chloroquine-resistant P. falciparum sporozoite transmission potential of malaria vectors and suggest that by adopting the mentioned methodologies, we can detect the spreading of the drug-resistant P. falciparum in its transmission. This approach of studying the anophelines during regular vector collection and epidemiological analysis will give the knowledge of chloroquine-resistance pattern of P. falciparum of an area and help in devising effective malaria control strategy.     

Genetic structure of Plasmodium falciparum populations between lowland and highland sites and antimalarial drug resistance in Western Kenya

Human travel to malaria endemic lowlands from epidemic highlands has been shown to increase the risk of malaria infections in the highlands. In order to gain insight on the impact of human travel, we examined prevalence, genetic variability and population genetic structure of Plasmodium falciparum in asymptomatic children from one highland site and three surrounding malaria endemic lowland sites in Western Kenya, using multilocus microsatellite genotyping. We further analyzed the frequencies of mutations at the genes conferring resistance to chloroquine and sulfadoxine–pyrimethamine. We found a significant decrease in malaria prevalence in the highland site from 2006 to 2007, 1 year after the introduction of the artemisinin-based combination therapy as first-line treatment for uncomplicated malaria and the scale-up of insecticide-treated bed nets. Population genetic diversity, measured by the number of observed and effective microsatellite alleles and Nei's unbiased genetic diversity, was high and comparable for both highland and lowland populations. Analysis of molecular variance did not detect a significant genetic structure across highland and lowland regions. Similarly, mutations at key antimalarial-resistance codons of the pfcrt, pfmdr1, pfdhfr and pfdhps genes were found at comparable high frequencies in all four sites. High level of gene flow and lack of significant genetic structure in malaria parasites between highland and lowland areas suggest the importance of human travel in shaping parasite population structure.     

Population genetics,sequence diversity and selection in the gene encoding the Plasmodium falciparum apical membrane antigen 1 in clinical isolates from the south-east of Iran

The Plasmodium falciparum apical membrane antigen1 (AMA1) is a leading malaria vaccine candidate antigen. In the present investigation, for the first time, the almost full length of the ama1 gene covering domain I (DI), DII and DIII was PCR amplified and sequenced in 21 P. falciparum isolates collected from the southeastern parts of Iran. The result showed the low genetic diversity of Iranian PfAMA1 with 11 PfAMA1 haplotypes in which nine out of 11 haplotypes are novel and have been reported for the first time. The Iranian P. falciparum population indicated a moderate level of genetic differentiation. The difference among the rates of non-synonymous and synonymous mutations, Tajima’s D and McDonald–Kreitman tests suggested that the diversity at DI is due to positive natural selection. In addition, recombination contributes to the diversity of Iranian PfAMA1 and this is supported by the decline of the linkage disequilibrium index R² with increasing the nucleotide distance. The highly polymorphic residues (positions: 187, 197, 200, 230 and 243) were polymorphic; however, most of the SNPs in non-polymorphic residues were conserved except the residue at position 395. Nevertheless, no mutation was found in the DII loop of the Iranian PfAMA1, indicating that it is subjected to purifying selection. In conclusion, the low genetic diversity in PfAMA1 among Iranian isolates supports and provides valuable information for the development of a PfAMA1-based malaria vaccine.     

Mutation analysis in pfmdr1 and pfmrp1 as potential candidate genes for artemisinin resistance in Plasmodium falciparum clinical isolates 4 years after implementation of artemisinin combination therapy in Iran

The emergence and spread of Plasmodium falciparum resistant to the commonly used anti-malarial drugs is a major challenge in the control and elimination of malaria. The present study provides information on genetic analysis in multidrug resistance 1 (pfmdr1) (N86Y/Y184F/S1034C/N1042D/F1226Y/D1246Y) and multidrug resistance protein 1 (pfmrp1) (H191Y/S437A/I876V/F1390I/K1466R) genes that are probably associated with artemisinin as well as chloroquine resistance transporter (pfcrt) 76T in P. falciparum clinical isolates (N = 200) exposed to artemisinin-based combination therapy (ACT) 4 years after its adoption in Iran. Also, the copy number of pfmdr1 gene was screened for its association with pfmdr1 mutations to incriminate artemisinin resistance. By using nested PCR-RFLP and sequencing analysis, none of the samples had any mutation at codons 1034, 1042, 1226 and 1246 of pfmdr1, while 86Y and 184F mutations were detected in 46% and 2% of the examined samples, respectively. Also, no significant difference was identified among analyzed samples collected before (baseline, 2002–2005) and after adoption of ACT (2007–2010) (P > 0.05). As with pfmrp1 gene, the mutations at positions 191Y (76.5%), 437A (69.5%), 876V (64.5%) and 1390I (17%) were detected and no samples displayed mutation at codon 1466R. In total, 42.5% of the examined isolates carried both pfmdr1 86Y and pfcrt 76T and none of the parasites simultaneously harbored pfcrt 76T, pfmdr1 86Y, 184F and pfmrp1 191Y, 437A, 876V, 1390I mutations. In addition, the copy number of pfmdr1 gene (N = 1) was similar as a sensitive isolate, 3D7, to artemisinin. In summary, none of the potential mutations associated with artemisinin and its derivatives resistance was significantly changed 4 years after adoption of ACT in Iran.     

The Plasmodium gaboni genome illuminates allelic dimorphism of immunologically important surface antigens in P. falciparum

In the deadly human malaria parasite Plasmodium falciparum, several major merozoite surface proteins (MSPs) show a striking pattern of allelic diversity called allelic dimorphism (AD). In AD, the vast majority of observed alleles fall into two highly divergent allelic classes, with recombinant alleles being rare or not observed, presumably due to repression by natural selection (recombination suppression, or RS). The three AD loci, merozoite surface proteins (MSPs) 1, 2, and 6, along with MSP3, which also exhibits RS among four allelic classes, can be collectively called AD/RS. The causes of AD/RS and the evolutionary history of allelic diversity at these loci remain mysterious. The few available sequences from a single closely related chimpanzee parasite, P. reichenowi, have suggested that for 3/4 loci, AD/RS is an ancient state that has been retained in P. falciparum since well before the P. falciparum–P. reichenowi ancestor. On the other hand, based on comparative sequence analysis, we recently suggested that (i) AD/RS P. falciparum loci have undergone interallelic recombination over longer evolutionary times (on the timescale of recent speciation events), and thus (ii) AD/RS may be a recent phenomenon. The recent publication of genomic sequencing efforts for P. gaboni, an outgroup to P. falciparum and P. reichenowi, allows for improved reconstruction of the evolutionary history of these loci. In this work, I report genic sequence for P. gaboni for all four AD/RS P. falciparum loci (MSP1, 2, 3, and 6). Comparison of these sequences with available P. falciparum and P. reichenowi data strengthens the evidence for interallelic recombination over the evolutionary history of these species and also strengthens the case that AD/RS at these loci is ancient. Combined with previous results, these data provide evidence that AD/RS at different loci has evolved at several different times in the evolutionary history of P. falciparum: (i) before the P. gaboni–P. falciparum divergence, for much of MSP1 and MSP3; (ii) between the P. gaboni–P. falciparum and P. reichenowi–P. falciparum divergences, for the 5′ end of the AD region of MSP6 and block 3 of MSP1; (iii) near the P. reichenowi–P. falciparum divergence, for the 3′ end of the AD region of MSP6; and (iv) after the P. reichenowi–P. falciparum divergence, for MSP2. Based on these results, I suggest a new hypothesis for long-term evolutionary maintenance of AD/RS by recombination within allelic groups.     

Comparative assessment on the prevalence of mutations in the Plasmodium falciparum drug-resistant genes in two different ecotypes of Odisha state,India

Considering malaria as a local and focal disease, epidemiological understanding of different ecotypes of malaria can help in devising novel control measures. One of the major hurdles in malaria control lies on the evolution and dispersal of the drug-resistant malaria parasite, Plasmodium falciparum. We herewith present data on genetic variation at the Single Nucleotide Polymorphism (SNP) level in four different genes of P. falciparum (Pfcrt, Pfmdr1, Pfdhfr, and Pfdhps) that confer resistance to different antimalarials in two different eco-epidemiological settings, i.e. Hilly-Forest (HF) and Riverine-Plain (RP), in a high malaria endemic district of Odisha state, India. Greater frequency of antimalarial resistance conferring SNPs and haplotypes was observed in all four genes in P. falciparum, and Pfdhps was the most variable gene among the four. No significant genetic differentiation could be observed in isolates from HF and RP ecotypes. Twelve novel, hitherto unreported nucleotide mutations could be observed in the Pfmdr1 and Pfdhps genes. While the Pfdhps gene presented highest haplotype diversity, the Pfcrt gene displayed the highest nucleotide diversity. When the data on all the four genes were complied, the isolates from HF ecotype were found to harbour higher average nucleotide diversity than those coming from RP ecotype. High and positive Tajima's D values were obtained for the Pfcrt and Pfdhfr genes in isolates from both the HF and RP ecotypes, with statistically significant deviation from neutrality in the RP ecotype. Different patterns of Linkage Disequilibrium (LD) among SNPs located in different drug-resistant genes were found in the isolates collected from HF and RP ecotypes. Whereas in the HF ecotype, SNPs in the Pfmdr1 and Pfdhfr were significantly associated, in the RP ecotype, SNPs located in Pfcrt were associated with Pfmdr1, Pfdhfr and Pfdhps. These findings provide a baseline understanding on how different micro eco-epidemiological settings influence evolution and spread of different drug resistance alleles. Our findings further suggest that drug resistance to chloroquine and sulfadoxine–pyrimethamine is approaching fixation level, which requires urgent attention of malaria control programme in India.     

Evidence for negative selection on the gene encoding rhoptry-associated protein 1 (RAP-1) in Plasmodium spp.

Assessing how natural selection, negative or positive, operates on genes with low polymorphism is challenging. We investigated the genetic diversity of orthologous genes encoding the rhoptry-associated protein 1 (RAP-1), a low polymorphic protein of malarial parasites that is involved in erythrocyte invasion. We applied evolutionary genetic methods to study the polymorphism in RAP-1 from Plasmodium falciparum (n = 32) and Plasmodium vivax (n = 6), the two parasites responsible for most human malaria morbidity and mortality, as well as RAP-1 orthologous in closely related malarial species found in non-human primates (NHPs). Overall, genes encoding RAP-1 are highly conserved in all Plasmodium spp. included in this investigation. We found no evidence for natural selection, positive or negative, acting on the gene encoding RAP-1 in P. falciparum or P. vivax. However, we found evidence that the orthologous genes in non-human primate parasites (Plasmodium cynomolgi, Plasmodium inui, and Plasmodium knowlesi) are under purifying (negative) selection. We discuss the importance of considering negative selection while studying genes encoding proteins with low polymorphism and how selective pressures may differ among orthologous genes in closely related malarial parasites species.     

Assessment of chloroquine sensitivity of Plasmodium falciparum in Choluteca, Honduras

During an outbreak of urban malaria in Choluteca, Honduras, the response of local isolates of Plasmodium falciparum to chloroquine was assessed. The 7-day WHO alternative standard field test was used together with three in vitro tests: the Rieckmann macro- and micromethods and a new 48-hour test which underwent its first field trial in this study. No chloroquine resistance was found in in vivo tests in 10 patients or in the in vitro tests on blood samples from 6 patients.     

Chloroquine tolerance of Ethiopian strains of P. falciparum

11 of 41 Ethiopians in hospital with P. falciparum malaria experienced a delayed recrudescence of parasitaemia following treatment with 10 mg. chloroquine base per kg. of body weight. Parasites from 25 of the 41 patients were successfully cultivated in vitro, and 9 isolates showed development in chloroquine concentrations of 0·5 to 1·0 millimicromoles per c.c. of blood. 3 isolates with development at the 1·0 millimicromole level were from patients who experienced a recrudescence of parasitaemia. In vivo and in vitro results suggest a chloroquine responsiveness of some Ethiopian isolates of P. falciparum which is between that of the sensitive Uganda I strain and the resistant Malayan (Camp.) strain; a finding not previously documented in African parasites.     

Chloroquine sensitivity of Plasmodium falciparum in Ibadan,Nigeria: II. Correlation of in vitrowith in vivo sensitivity

Plasmodium falciparum malaria was treated in 82 children with 25 mg/kg chloroquine orally over three days. They were observed for 28 days during which blood films were examined periodically for malaria parasites. Asexual forms of P. falciparum, present in the blood films of all the patients before commencing treatment, disappeared rapidly and by the third day no parasites were seen in blood films from any of them. Among the patients observed for more than three days, blood films remained negative throughout the observation period. In vitro tests of sensitivity of blood samples from 10 patients showed chloroquine concentrations of 0·5 to 0·8 nmol/ml to inhibit completely maturation from ring forms to schizonts.This suggests that P. falciparum in the Ibadan area is probably still fully sensitive to chloroquine.     

Identification of Plasmodium falciparum isolates lacking histidine-rich protein 2 and 3 in Eritrea

The histidine-rich protein 2 of Plasmodium falciparum is the most common malaria antigen targeted by rapid diagnostic tests for the specific diagnosis of P. falciparum. Recently, pfhrp2 gene deletions have been documented in P. falciparum isolates from South America and some multiple endemic countries in Africa and Asia. Parasites with such gene deletions can produce false negative diagnostic results using HRP2-based rapid diagnostic kits. In the present work, the prevalence of P. falciparum parasites lacking pfhrp2, pfhrp3, which produces a second P. falciparum antigen that is recognized by PfHRP2 -based rapid diagnostic tests, and their flanking genes was evaluated in 135 P. falciparum isolates from Gash Barka region and in 9 isolates from Debub region, in Eritrea. In the analyzed samples, 56% (81/144) of isolates were pfhrp2/pfhrp3 positive, while 9.7% (14/144) showed deletion of exon 2 of pfhrp2 gene and 43% (62/144) of isolates lacked the pfhrp3 gene. These results suggest that the pfhrp2 and pfhrp3 deletion phenomenon is present in a considerable proportion in the study areas, thus making the HRP2/3 based rapid diagnostic tests not completely reliable for malaria diagnosis in Eritrea.     

Genetic variability and population structure of Plasmodium falciparum parasite populations from different malaria ecological regions of Kenya

Transmission intensity, movement of human and vector hosts, biogeographical features, and malaria control measures are some of the important factors that determine Plasmodium falciparum parasite genetic variability and population structure. Kenya has different malaria ecologies which might require different disease intervention methods. Refined parasite population genetic studies are critical for informing malaria control and elimination strategies. This study describes the genetic diversity and population structure of P. falciparum parasites from the different malaria ecological zones in Kenya. Twelve multi-locus microsatellite (MS) loci previously described were genotyped in 225 P. falciparum isolates collected between 2012 and 2013 from five sites; three in lowland endemic regions (Kisumu, Kombewa, and Malindi) and two in highland, epidemic regions (Kisii and Kericho). Parasites from the lowland endemic and highland epidemic regions of western Kenya had high genetic diversity compared to coastal lowland endemic region of Kenya [Malindi]. The Kenyan parasites had a mean genetic differentiation index (F_ST) of 0.072 (p = 0.011). The multi-locus genetic analysis of the 12 MS revealed all the parasites had unique haplotypes. Significant linkage disequilibrium (LD) was observed in all the five parasite populations. Kisumu had the most significant index of association values (0.16; p < 0.0001) whereas Kisii had the least significant index of association values (0.03; p < 0.0001). Our data suggest high genetic diversity in Kenyan parasite population with the exception of parasite from Malindi where malaria has been on the decline. The presence of significant LD suggests that there is occurrence of inbreeding in the parasite population. Parasite populations from Kisii showed the strongest evidence for epidemic population structure whereas the rest of the regions showed panmixia. Defining the genetic diversity of the parasites in different ecological regions of Kenya after introduction of the artemether–lumefantrine is important in refining the spread of drug resistant strains and malaria transmission for more effective control and eventual elimination of malaria in Kenya.