NEW MULTIPLEX SNP GENOTYPING ASSAY TO SIMUTANEOUSLY SCREEN FOR EIGHT VOLTAGE-GATED SODIUM CHANNEL MUTATIONS IN AEDES AEGYPTI

Journal of the Florida Mosquito Control Association Pub Date : 2024-03-21 DOI:10.32473/jfmca.71.1.135292

Kyle J. Kosinski, Ana Romero-Weaver, Valerie T. Nguyen, Derrick K. Mathias, Eva A. Buckner, Yoo Sook Lee

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Abstract

Aedes aegypti has been implicated as the vector responsible for transmission of dengue, chikungunya, and Zika viruses during disease outbreaks in Florida within the past 15 years. Recently, locally acquired dengue cases have increased dramatically, with more than 450 cases documented in Florida since 2019. This mosquito is known to be resistant to pyrethroid-based insecticides in Florida. Resistance of insects to pyrethroids due to knockdown resistance (kdr) is the result of single nucleotide polymorphisms (SNPs) in the voltage-gated sodium channel gene (vgsc). Recently, two novel SNPs, F174I and E478K, and four known SNPs, V410L, S723T, D1763Y, and Q1853R were reported circulating in Floridian Ae. aegypti populations for the first time. The present study provides a more comprehensive estimate of these SNP frequencies through the screening of a larger number of Floridian Ae. aegypti samples using a new custom multiplex SNP assay we developed using the Agena Biosciences iPLEX Assay platform to facilitate the rapid screening of multiple SNPs at an affordable cost. Our assay was successful in screening 162 Ae. aegypti mosquitoes for 8 SNPs from 4 counties in Southern Florida (Broward, Collier, Palm Beach, and Monroe Counties). This new assay can be used for studies examining the association between genetic mutations and pyrethroid-resistant phenotypes in Ae. aegypti populations such as increased time of survival after insecticide exposure.

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新型多重 snp 基因分型测定法可同时筛查埃及伊蚊的八种电压门控钠通道突变

在过去 15 年佛罗里达州爆发的疾病中，埃及伊蚊被认为是传播登革热、基孔肯雅和寨卡病毒的病媒。最近，当地感染登革热的病例急剧增加，自 2019 年以来，佛罗里达州记录在案的病例已超过 450 例。据了解，这种蚊子对佛罗里达州的除虫菊酯类杀虫剂具有抗药性。昆虫对拟除虫菊酯的抗性是由电压门控钠通道基因（vgsc）中的单核苷酸多态性（SNPs）导致的。最近，首次报道了两个新的 SNPs（F174I 和 E478K）和四个已知的 SNPs（V410L、S723T、D1763Y 和 Q1853R）在佛罗里达埃及蝇种群中循环。本研究通过使用我们利用 Agena Biosciences iPLEX 分析平台开发的新型定制多重 SNP 分析方法，对更多的弗洛里达埃及蝇样本进行了筛查，从而更全面地估计了这些 SNP 频率。我们的检测方法成功筛查了来自佛罗里达州南部 4 个县（布劳沃德县、科利尔县、棕榈滩县和门罗县）的 162 只埃及姬蚊的 8 个 SNP。这种新测定法可用于研究埃及姬蚊种群中基因突变与除虫菊酯抗性表型之间的关联，如暴露于杀虫剂后存活时间的延长。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of the Florida Mosquito Control Association

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