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Molecular markers in Plasmodium falciparum linked to resistance to anti-malarial drugs in samples imported from Africa over an eight-year period (2002-2010): impact of the introduction of artemisinin combination therapy

Aranzazu Amor1*, Carlos Toro1, Amalia Fernández-Martínez2, Margarita Baquero1, Agustín Benito2 and Pedro Berzosa2

Author Affiliations

1 Department of Microbiology and Parasitology, Hospital Carlos III, C/Sinesio Delgado 10, Madrid 28029, Spain

2 Malaria Laboratory, National Centre of Tropical Medicine, Carlos III Institute of Health, C/Melchor Fernández Almagro 3, pabellón 13, Madrid 28029, Spain

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Malaria Journal 2012, 11:100  doi:10.1186/1475-2875-11-100


The electronic version of this article is the complete one and can be found online at: http://www.malariajournal.com/content/11/1/100


Received:21 November 2011
Accepted:30 March 2012
Published:30 March 2012

© 2012 Amor et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Drug resistance is a major problem to control Plasmodium falciparum infection in endemic countries. During last decade, African countries have changed first-line treatment to artemisinin-based combinations therapy (ACT); sulphadoxine-pyrimethamine (SP) is recommended for Intermittent Preventive Therapy (IPT). Molecular markers related to P falciparum resistance were analysed for the period of transition from SP to ACT, in isolates imported from Africa.

Methods

A first group of samples was taken in the period between June 2002 and June 2006 (n = 113); a second group in the period between November 2008 and August 2010 (n = 46). Several alleles were analysed by nested PCR-RFLP: 51, 59, 108, 164, in the pfdhfr gene; 436, 437, 540, 581, in the pfdhps gene; 86, 1246, in the pfmdr1 gene and 76, in the pfcrt gene. The prevalence of alleles in the groups was compared with the chi-squared or Fisher's exact tests.

Results

The pfdhfr N51I, C59R and S108N were over to 90% in the two groups; all samples had the I164. In the pfdhps, 437 G and 581 G, increased up to 80% and 10.9% (p = 0.024), respectively in the second group. The 540 G decreases (24% to 16.%) and the 436A disappears at the end of the follow-up (p = 0.004) in the second group. The 76I-pfcrt stayed over 95% in the two groups. Prevalence of 86Y-pfmdr1 decreased over eight years.

Conclusions

Pharmacological pressure affects the resistance strains prevalence. As for SP, the disappearance of 436A and the decrease in 540 G suggest that these mutations are not fixed. On the other hand, studies carried out after ACT introduction show there was a selection of strains carrying the SNPs N86Y, D1246Y in pfmdr1. In this work, the prevalence of pfmdr1- D1246Y is increasing, perhaps as a result of selective pressure by ACT. Continued surveillance is essential to monitor the effectiveness of treatments.

Background

Malaria treatment is an essential tool to control Plasmodium falciparum disease in endemic countries. Resistance to currently available drugs is one of his main problems [1]. Several mutations linked to resistance have been described in different genes of P. falciparum genome. These mutations take place spontaneously in the parasite, though pharmacological pressure is one of the most important factors involved in their spread [2].

Resistance to chloroquine appears nowadays in all regions where P. falciparum is present in Africa [3]. The main determinant of chloroquine resistance is the K76I mutation of the pfcrt gene, which left to in vivo and in vitro resistance [4]. In addition, the N86Y and D1246Y mutations in the pfmdr1 gene, together with the occurrence of mutations in the pfcrt gene, reduce susceptibility to chloroquine [5].

Use of sulphadoxine-pyrimethamine (SP) began in Africa in the early 1980s and was adopted as first-line treatment for non-severe malaria in many sub-Saharan countries. In the last decade, the high resistance levels reached across the continent have led to a change in treatment policies. SP is currently recommended by the World Health Organization (WHO) for intermittent preventive therapy (IPT) in pregnant woman (IPTp) and infants (IPTi) [6].

Loss in efficacy of either component of SP brings about a reduction in the efficacy of the combination [7]. Resistance to pyrimethamine is related with single nucleotide polymorphisms (SNPs) at codons A16V, N51I, C59R, S108N/T and I164L of the pfdhfr gene. Although the C50R mutation is usually found in South America, it has recently been described in Africa [8]. The I164L mutation is hardly ever seen in Africa, and its association with resistance in this continent is doubtful [9]. In the dhps gene, five SNPs, namely, S436A/F, A437G, K540E, A581G and A613S/T, have been reported to be linked to P. falciparum resistance to sulphadoxine. An increase in the number of mutations in both, pfdhfr and pfdhps, genes leads to an increase in clinical resistance. In Africa, the pfdhfr triple mutant, 51I-59R-108 N, together with the pfdhps double mutant, 437 G-540E, the so called dhfr/dhps quintuple mutation predicts treatment failure with SP [10].

Nowadays, artemisinin combination therapy (ACT) is used as a first-line treatment in uncomplicated malaria in African countries with artemether-lumefantrine (AL) and artesunate-amodiaquine (AS/AQ) being the combinations used [11]. The SNPs in the pfcrt and pfmdr1 genes are related with the efficacy of amodiaquine, which is structurally related to chloroquine although in vivo and in vitro data suggest that cross-resistance between both molecules is incomplete [12]. The wild-type alleles of the pfmdr1 gene, N86 and D1246, are linked to a decrease in the in vitro response to lumefantrine and artemisinin [13]. After the introduction of AL, an in vivo association has been established with re-infections by strains with wild-type pfmdr1 alleles and the wild-type pfcrt allele, K76 [14].

The Hospital Carlos III (Madrid, Spain) is a tropical disease reference centre. Its Tropical Medicine and Paediatrics Departments, attends to immigrants and travellers. SNPs in P. falciparum linked to resistance were analysed in patients proceeding from African countries. Samples were collected over a period of eight years, during a transition phase from high SP coverage to treatment with ACT. This study sought to ascertain the prevalence of anti-malarial drug resistant strains during this period, and measure the impact of pharmacological pressure.

Methods

Biological samples

Blood samples were collected from 200 patients with P falciparum infection, who had come to Spain from eighteen African countries (Figure 1). After microscopic diagnosis, identification to species level was performed by polymerase chain reaction (PCR). DNA was extracted from 200 μl of blood using QIAamp DNA Blood Minikits® (QIAGEN, Hilden, Germany). Samples were classified in two groups, the first including those collected between June 2002 to June 2006, and the second one including those collected between November 2008 to August 2010.

thumbnailFigure 1. African countries of origin of samples.

Molecular assays

Multiplex PCR was performed to diagnose the malaria species [15]. Nested polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) was used to analyse the presence/absence of mutations at codons 51, 59, 108 and 164 of the pfdhfr gene, codons 436, 437, 540 and 581 of the pfdhps gene, codons 86 and 1246 of the pfmdr1 gene, and codon 76 of the pfcrt gene [16]. In the same way of other works,, mixed populations were deemed mutants [17].

Statistical analysis

All analyses were performed using the SPSS statistical software package, version 15.0. The prevalence of mutations in the groups was compared using the chi-squared (χ2) or Fisher's exact test. Statistical significance was set at p ≤ 0.05.

Results

The typing efficiency for each codon was as follows: 100% of samples for the pfdhfr-51- 59; 99.5% for pfdhfr-108 and pfdhps-436,-437; 99% for pfdhps-540-581; 98% for pfcrt-76; 97.5% for pfmdr1-1246; 96% for pfmdr1-86 and 95% for pfdhfr-164.

Changes in the prevalence of typed alleles over the two periods are shown in the Table 1.

Table 1. Molecular markers of resistance (%)

Pfdhfr-pfdhps

The frequency of the combination of pfdhfr mutated alleles with more than one mutation increased across the Continent, with the most frequent being the pfdhfr triple mutant, 51I-59R-108 N. In the pfdhps gene, the most frequent genotype was 437 G, followed by the double mutant, 437 G-540E, though this one decreased slightly owing to the fall in the 540E mutation. The pfdhps double mutant, 437 G-581 G, also increased (p = 0.03).

Mutations in both pfdhfr and pfdhps genes were observed in 76% of patients (n = 152). At the end of the study, the most prevalent were: the quadruple mutant, 51I-59R-108 N-437 G, followed by the quintuple mutant, 51I-59R-108 N-437 G-540E, and the quintuple ones 51I-59R-108 N-437 G-581 G, which increases his prevalence (p = 0.03).

Pfcrt

Mutation 76I of pfcrt keeps above 95% during the study period (Table 1).

pfmdr1

The prevalence of wild-type alleles of the pfmdr1 gene, N86 and D1246, increased across the eight years.

Discussion

In this study, although samples from 18 countries, patients from Central and West Africa accounted for 79.9% and 16.1% respectively of all, and those from the East of the continent were scarce (4%). Even so, there are few studies about changes molecular markers of resistance after large-scale deployment of ACT in the entire African Continent, in a long period of time. Malaria treatment is one of the mainstays of disease control programmes, and parasite resistance to anti-malarial drugs is one of its major problems. Current treatment policies are based on ACT, so as to reduce the loss of efficacy and emergence and spread of resistance resulting from pharmacological pressure and migratory movements, among other factors [18]. Surveillance during the period of treatment policies change is essential, to evaluate its impact: in cases where resistance has not yet become permanent in a population, prevalence of resistance-related alleles should decline if pharmacological pressure ceases [19]. However, up to now, molecular markers related to SP resistance appear to show no reduction after the introduction of ACT [6]. Indeed, an increase has even been observed in some regions; this has been attributed to the widespread use of other drugs, such as cotrimoxazole [20], which have cross-resistance with SP, and to the fact that the combination is widely used outside the official sector [21]. In this way, in this study the pfdhfr triple mutant, 51I-59R-108 N, became established. With regard to mutations linked to sulphadoxine resistance, in spite of a significant disappearance of 436A, there are a significant increase of the 437 G allele and, it should be stressed the emergence of mutant 581 G in Cameroon, two cases, Gabon, one case, and Equatorial Guinea, five cases, countries in which this mutation has never been previously detected. Also, a case of 581 G allele was also detected in Mali, where this mutation has been already described [22]. It has been noted that in areas where the pfdhfr triple and pfdhps double mutants are established, the emergence of mutation 581 G can endanger intermittent preventive therapies with SP. It has also been shown a selection of this mutated allele in woman receiving IPT [23,24]. At all events, to check whether significant changes are taking place in the prevalence of mutations linked to a decrease in the use of SP, and to monitor the appearance of mutations that, until now, have rarely been described in these regions (581 G), continued surveillance is needed to evaluate their impact on IPT [25,26].

For molecular markers related to anti-malarial drugs currently being used in Africa (pfcrt and pfmdr1 genes), a reduction in the prevalence of pfcrt 76I and pfmdr1 N86Y mutations in response to a decrease in chloroquine use has been observed in some regions [27]. On the other hand, the wild-type pfmdr N86 and the pfcrt K76 genotypes are associated with lower susceptibility to dihydroartemisinin in vitro [12]. In addition, studies undertaken after the introduction of ACT have shown that there is a selection of strains carrying wild-type alleles, pfmdr1 N86, pfmdr1D1246 [28] and pfcrt K76 [15]. The first has been linked to a significant decrease in in vitro sensitivity to lumefantrine and an increase of reinfections in vivo after AL treatment, a finding that renders the use of lumefantrine advisable in areas where chloroquine-resistant mutations remain high [6]. In this way, the prevalence of pfcrt 76I had risen to over 95% by the end of the study: nevertheless, the prevalence of wild-type pfmdr1 N86 shows a statistical tendency to increase and the wild-type pfmdr1D1246 raises until 91.8% ant the end of the study. It is possible that these results reflect the first step in ACT resistance.

Conclusions

This study suggests the appearance of strains related with resistance to ACT. On the other hand, the study shows the existence of mutations in some regions in the African Continent who will put in danger the use of IPTp and IPTc. In vivo surveys are the gold standard for analysis of malaria therapy resistance, but it can be concluded that surveys like the one described in the current paper could be an essential tool to assess and follow up the long-term use and efficiency of ACT and IPT.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

AA: carried out the laboratory work, data collection and analysis of the results and wrote the manuscript. AMF: was involved in laboratory work. CT revised the manuscript. MB and AB contributed to reagents and helped the study. PB: was involved in laboratory work and revised the manuscript. All authors read and approved the final manuscript.

Acknowledgements

We thank the medical and technical staff of the Department of Microbiology and Parasitology; the staff of the Departments of Tropical Medicine and Paediatrics of the Carlos III Hospital and the Network of Tropical Diseases Research Centres (Red de Investigación Cooperativa en Enfermedades Tropicales - RICET; Project RD06/0021).

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