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BACKGROUND: Knockdown resistance (kdr) is one of the primary resistance mechanisms present in anopheline species. Although this mutation is largely spread across the Anopheles gambiae s.l. members, its prevalence in other species is still not well documented. METHODS: The present study investigated the distribution and allelic frequencies of kdr in An. gambiae s.l., An. pharoensis, and An. ziemanni samples collected in 2022 and 2023 in nine sites spread across five ecogeographical settings in Cameroon. Members of the An. gambiae complex were identified molecularly by polymerase chain reaction (PCR). kdr L1014F and L1014S alleles were screened by PCR and confirmed by sequencing. RESULTS: An. gambiae (49.9%), An. coluzzii (36.5%), and An. arabiensis (13%) were identified, and the frequency of the kdr L1014F was high in both An. gambiae and An. coluzzii in all sites. The kdr L1014F allele was detected for the first time in 8 out of 14 An. ziemanni samples examined and in 5 out of 22 An. pharoensis samples examined. The kdr L1014S allele was scarce and found only in the heterozygote "RS" state in An. arabiensis and An. gambiae in Yangah and Santchou. CONCLUSIONS: The present study sheds light on the rapid expansion of the kdr L1014F allele in malaria vectors in Cameroon and stresses the need for surveillance activities also targeting secondary malaria vectors to improve the control of malaria transmission.

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Microbial communities play an important role in the fitness of mosquito hosts. However, the factors shaping microbial communities in wild populations, with regard to interactions among microbial species, are still largely unknown. Previous research has demonstrated that two of the most studied mosquito symbionts, the bacteria Wolbachia and Asaia, seem to compete or not compete, depending on the genetic background of the reference mosquito host. The large diversity of Wolbachia-Asaia strain combinations that infect natural populations of mosquitoes may offer a relevant opportunity to select suitable phenotypes for the suppression of pathogen transmission and for the manipulation of host reproduction. We surveyed Wolbachia and Asaia in 44 mosquito populations belonging to 11 different species of the genera Anopheles, Aedes, and Culex using qualitative PCR. Through quantitative PCR, the amounts of both bacteria were assessed in different mosquito organs, and through metagenomics, we determined the microbiota compositions in some selected mosquito populations. We show that variation in microbial community structure is likely associated with the species/strain of mosquito, its geographical position, and tissue localization. Together, our results shed light on the interactions among different bacterial species in the microbial communities of mosquito vectors, and this can aid the development and/or improvement of methods for symbiotic control of insect vectors.

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The main objectives of developing vaccines to prevent malaria transmission are malaria control and preventing the reemergence of the disease in endemic regions. Molecular and in silico characterization of a candidate molecule is the first step in the vaccine design process. Determining the sequence and amplification of full-length cDNA copies from the mRNA transcripts is often challenging. The methods in this chapter provide a protocol for the rapid amplification of cDNA ends (RACE) and genome walking. Carboxypeptidase B2 enzyme from A. stephensi (CPBAs-2) was selected as the target molecule and the steps in its characterization and in silico analysis are explained in this chapter.

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Plasmodium falciparum is the parasite responsible for the disease malaria. In vitro cultivation of mature gametocytes of P. falciparum plays a central role in evaluating and developing the transmission-blocking drugs and sexual stage vaccines. These types of preventive molecules are crucial for controlling malaria in the future. Among different Plasmodium species that are involved in human malaria, only P. falciparum is cultivable. Therefore, an efficient method is required for in vitro culture of P. falciparum producing mature and infective gametocytes. This chapter describes a reliable and efficient protocol for the production of adult and infective gametocytes that is suitable for small- and large-scale culture.

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