Xeno-monitoring of molecular drivers of artemisinin and partner drug resistance in P. falciparum populations in malaria vectors across Cameroon

Author:

Nkemngo Francis N.ORCID,Mugenzi Leon M.J.,Tchouakui Magellan,Nguiffo-Nguete Daniel,Wondji Murielle J.,Mbakam Bertrand,Tchoupo Micareme,Ndo Cyrille,Wanji Samuel,Wondji Charles S.ORCID

Abstract

AbstractBackgroundMonitoring of drug resistance in Plasmodium populations is crucial for malaria control. This has primarily been performed in humans and rarely in mosquitoes where parasites genetic recombination occurs. Here, we characterized the Plasmodium spp populations in wild Anopheles vectors by analyzing the genetic diversity of the P. falciparum kelch13 and mdr1 gene fragments implicated in artemisinin and partner drug resistance across Cameroon in three major malaria vectors.MethodsAnopheles mosquitoes were collected across nine localities in Cameroon and dissected into the head/thorax (H/T) and abdomen (Abd) after species identification. A TaqMan assay was performed to detect Plasmodium infection. Fragments of the Kelch 13 and mdr1 genes were amplified in P. falciparum positive samples and directly sequenced to assess their drug resistance polymorphisms and genetic diversity profile.ResultsThe study revealed a high Plasmodium infection rate in the major Anopheles vectors across Cameroon. Notably, An. funestus vector recorded the highest sporozoite (8.02%) and oocyst (14.41%) infection rates. A high P. falciparum sporozoite rate (80.08%) alongside epidemiological signatures of significant P. malariae (15.94%) circulation were recorded in these vectors. Low genetic diversity with six (A578S, R575I, G450R, L663L, G453D, N458D) and eight (H53H, V62L, V77E, N86Y, G102G, L132I, H143H, Y184F) point mutations were observed in the k13 and mdr1 backbones respectively. Remarkably, the R575I (4.44%) k13 and Y184F (64.2%) mdr1 mutations were the predominant variants in the P. falciparum populations.ConclusionThe emerging signal of the R575I polymorphism in the Pfk13 propeller backbone entails the regular surveillance of molecular markers to inform evidence-based policy decisions. Moreover, the high frequency of the 86N184F allele highlights concerns on the plausible decline in efficacy of artemisinin-combination therapies (ACTs); further implying that parasite genotyping from mosquitoes can provide a more relevant scale for quantifying resistance epidemiology in the field.

Publisher

Cold Spring Harbor Laboratory

Reference76 articles.

1. WHO, World malaria report 2021. World Health Organization (2021) ­ https://www.who.int/publications-detail-redirect/9789240015791. 2021.

2. Nkemngo, F. , et al., Multiple insecticide resistance and Plasmodium infection in the principal malaria vectors Anopheles funestus and Anopheles gambiae in a forested locality close to the Yaoundé airport, Cameroon [version 2; peer review: 2 approved]. Wellcome Open Research, 2020. 5(146).

3. Review of malaria situation in Cameroon: technical viewpoint on challenges and prospects for disease elimination;Parasites & Vectors,2019

4. The PMI VectorLink Project, A.A., The President’s Malaria Initiative (PMI)-VectorLink Project. The PMI VectorLink Cameroon Annual Entomology Report. October 2018– September 2019. Rockville, MD 2020.

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