Background
Malaria is the most critical human parasitic disease caused by Plasmodium, it is a serious threat to human health, and there were about 214 million cases of malaria and 438,000 deaths from it in 2015, of which 90% occurred in Africa [
1]. In China, an action plan for malaria elimination was launched in 2010, and the Henan government carried out the action the same year. Indigenous
P. falciparum was successfully eliminated in 1988 and no indigenous malaria cases have been reported in Henan Province since 2012 [
2]. However, imported malaria cases have increased year after year.
P. falciparum which was imported from Africa, has been mainly responsible for the increasing impacts [
3,
4].
The effectiveness of antimalarial medicines is a powerful guarantee for malaria control and elimination. Artemisinin-based combination therapies (ACTs) were recommended as the first-line treatment against uncomplicated
P. falciparum infection in 2006 by the World Health Organization (WHO) [
5]. Artemisinin has proven to be the most successful antimalarial drug over 10 years, and the morbidity and mortality of malaria have fallen dramatically due to the use of ACT in highly endemic areas of the world [
6]. However, as with other drugs, the curative effect of ACT has declined gradually along with its use. The emergence of
P. falciparum resistance to artemisinin and its derivatives was first reported in 2008 in Western Cambodia [
7]. In 2009, Dondorp et al. [
8] also reported that the susceptibility of
P. falciparum in vivo to ACT was reduced. Then, ACT resistance became prevalent in the Greater Mekong Subregion (GMS) [
9‐
11]. K13-propeller, as a molecular marker of artemisinin-resistance, was identified by Ariey in 2014 [
12]. Since then, numerous studies have been conducted about K13-propeller mutations. The K13-propeller mutations associated with artemisinin-resistance were mainly found in Southeast Asia, with C580Y being the predominant one. At the same time, many studies were carried out in Africa. While few resistance-associated mutations have been found in Africa [
13], there have been numerous mutations found in the K13-propeller. In 2015, Feng et al. [
14] reported that C580Y and R539T were observed, and the most prevalent mutation was C580Y, with the rate of 2.7% in the samples from Ghana.
As a proposed molecular marker of ART resistance, the K13-propeller was recently identified and has been studied in an increasing number of reports. Mutations in the K13-propeller were first reported in 2008 in western Cambodia [
11]. More mutations in this gene have been also subsequently found in resistant parasites in samples from Vietnam and Burma. To date, more than 200 nonsynonymous mutations in the K13-propeller gene have been reported, of which mutations of N458Y, Y493H, R539T, I543T, R561H, and C580Y were validated to be associated with ART resistance, and M476I and M579I were also reported to be associated with resistance in vivo or in vitro tests [
15,
16]. In this study, we evaluated the prevalence of polymorphisms in the K13-propeller gene from imported
P. falciparum patients who returned from Africa to Henan Province during 2012- 2015.
Discussion
In this study, the sequencing of the K13-propeller gene from 483
P.
falciparum samples collected from Africa identified 23 point mutations in 24 samples. We observed 4 synonymous and 19 nonsynonymous mutations, of which 8 mutations had been reported before and 15 had yet to be described [
18‐
21]. All of the samples were from 27 countries in Africa, and 24 samples with mutations were distributed in 11 countries. The K13-propeller mutations were most prevalent in Equatorial Guinea, Angola, and Nigeria; P574L and R539T were detected in the samples from Equatorial Guinea and Angola. In our samples, we could not detect C580Y in the 23 isolates from Ghana, a possible reason for this might be that the samples from Ghana were small. The results in our study were not consistent with the report by Feng et al. [
14] and other reports with no mutations associated with artemisinin resistance in Africa [
17,
22], but the low mutation rate agreed with other reports in samples from Africa [
23,
24]. The findings in our study indicated that the mutants of the K13-propeller gene alleles exist in migrant workers returning from Africa, which required us to focus on these individuals and strengthen the early monitoring of the K13-propeller.
In this study, the total rate of mutation was 4.97% and the major mutations were from West Africa, South Africa, and Central Africa. The difference of the mutations in these regions was not significant. In the 102 samples from Angola, one K13-propeller resistance-confirmed mutation, R539T was observed in one sample and the mutation rate was 0.98%. We also detected another resistance-confirmed mutation, P574L, in one isolate from Equatorial Guinea and the rate was 1.54% (1/65). The other mutations associated with ART resistance were not found in our study, but the extensive distribution of the K13-propeller mutations and the emergence of the mutations (P574L and R539T) being directly related to ART resistance suggests that there are potential ART-resistant genes in Africa that could make ART-resistant mutations spread all over the world. Routine monitoring must continue in order to ensure that the recommended ACTs are effective, that timely changes to national treatment policies can be implemented, and that ART resistance can be detected early.
The mutations of the K13-propeller detected in our study mainly came from Equatorial Guinea, Angola, and other West African, South African, and Central African countries. Furthermore, the mutations corresponding to the most prevalent mutations in Cambodia were not observed in East Africa. Historically, the emergence of drug-resistant
P. falciparum strains (to chloroquine and sulphadoxine-pyrimethamine) first occurred in Southeast Asia, spread to East Africa, and then moved outwards to the rest of the African continent [
25]. But in our study, this did not seem to be so. The mutations might be due to increased international travel and migration.
In China, ACTs have been used against uncomplicated
P. falciparum infection since 2009 [
26‐
28]. So far no evidence has indicated that there was ART resistance in China. However, in recent years, more than 90% of the registered malaria cases were imported cases in China [
29,
30]. To understand the distribution of antimalarial drug resistance is essential for the prevention, control, and elimination of malaria in China. Early surveillance of the occurrence and spreading of antimalarial drug resistance would be greatly enhanced by the application of valid antimalarial resistance molecular markers [
31].
Since 2010 Henan Province has been in the malaria elimination stage, with all reports of the disease being imported and over 90% coming from migrant workers returning from Africa after 2012. Angola, Nigeria, and Equatorial Guinea were the top three countries from which the patients returned [
32,
33]. In our study, 483 patients returned from 27 countries in Africa, and half of them came back from: Angola (102), Nigeria (72), and Equatorial Guinea (65). Although C580Y was not observed and the two other mutations that are associated with ART resistance were at low frequencies, this study showed that the mutated K13-propeller gene was in the migrant workers who returned from Africa, requiring our attention to the emergence of the resistance to ACTs in Africa. The use of the molecular marker K13-propeller is fundamental for surveillance in malaria control programs, in order to prolong the life span of the ACTs in Africa. Surveillance and population studies are essential for the early detection and subsequent prevention of the spread of drug resistance [
34]. It is also important to change the treatment policy in a timely manner, and the information will be useful for developing and updating antimalarial guidance. Therefore, surveillance should continuously be strengthened in migrant workers returning to Henan Province, and the data may be used to enhance molecular surveillance of antimalarial resistance and informed decisions in the rational treatment policy in Henan Province.
Conclusions
We observed 23 point mutations, including 4 synonymous mutations and 19 nonsynonymous mutations, in the K13-propeller in migrant workers who had returned from Africa. C580Y was not detected, but R539T and P574L were found in 483 samples from Africa. It was meaningful to study artemisinin resistance in returning migrant workers in Henan Province, and these data should help provide a reasonable treatment policy in Henan Province.
Acknowledgements
The authors thank ZQX and the workers from City level CDC, who participated in the study.