Otali D, Novak R J, Wan W, Bu S, Moellering D R, De Luca M
Department of Biology, University of Alabama at Birmingham, Campbell Hall 464, 1720 2ndAve. South, Birmingham, AL 35294-1170, USA.
Division of Infectious Diseases, Department of Medicine, William C Gorgas Center for Geographic Medicine, University of Alabama at Birmingham, 845 19th St. South, Birmingham, AL 35294-2170, USA.
Bull Entomol Res. 2014 Jun;104(3):323-33. doi: 10.1017/S0007485314000091. Epub 2014 Feb 21.
Control of the malaria vector An. gambiae is still largely obtained through chemical intervention using pyrethroids, such as permethrin. However, strains of An. gambiae that are resistant to the toxic effects of pyrethroids have become widespread in several endemic areas over the last decade. The objective of this study was to assess differences in five life-history traits (larval developmental time and the body weight, fecundity, hatch rate, and longevity of adult females) and energy metabolism between a strain of An. gambiae that is resistant to permethrin (RSP), due to knockdown resistance and enhanced metabolic detoxification, and a permethrin susceptible strain reared under laboratory conditions. We also quantified the expression levels of five antioxidant enzyme genes: GSTe3, CAT, GPXH1, SOD1, and SOD2. We found that the RSP strain had a longer developmental time than the susceptible strain. Additionally, RSP adult females had higher wet body weight and increased water and glycogen levels. Compared to permethrin susceptible females, RSP females displayed reduced metabolic rate and mitochondrial coupling efficiency and higher mitochondrial ROS production. Furthermore, despite higher levels of GSTe3 and CAT transcripts, RSP females had a shorter adult life span than susceptible females. Collectively, these results suggest that permethrin resistance alleles might affect energy metabolism, oxidative stress, and adult survival of An. gambiae. However, because the strains used in this study differ in their genetic backgrounds, the results need to be interpreted with caution and replicated in other strains to have significant implications for malaria transmission and vector control.
疟蚊媒介冈比亚按蚊的控制目前在很大程度上仍通过使用拟除虫菊酯(如氯菊酯)的化学干预来实现。然而,在过去十年中,对拟除虫菊酯毒性产生抗性的冈比亚按蚊品系已在几个流行地区广泛传播。本研究的目的是评估由于击倒抗性和增强的代谢解毒作用而对氯菊酯具有抗性的冈比亚按蚊品系(RSP)与在实验室条件下饲养的氯菊酯敏感品系之间在五个生活史特征(幼虫发育时间、成虫体重、繁殖力、孵化率和成年雌蚊寿命)以及能量代谢方面的差异。我们还对五个抗氧化酶基因(GSTe3、CAT、GPXH1、SOD1和SOD2)的表达水平进行了定量分析。我们发现,RSP品系的发育时间比敏感品系更长。此外,RSP成年雌蚊的湿体重更高,水分和糖原水平增加。与氯菊酯敏感雌蚊相比,RSP雌蚊的代谢率和线粒体偶联效率降低,线粒体活性氧生成增加。此外,尽管RSP雌蚊的GSTe3和CAT转录本水平较高,但其成年寿命却比敏感雌蚊短。总体而言,这些结果表明,氯菊酯抗性等位基因可能会影响冈比亚按蚊的能量代谢、氧化应激和成虫存活。然而,由于本研究中使用的品系在遗传背景上存在差异,这些结果需要谨慎解读,并在其他品系中进行重复验证,才能对疟疾传播和媒介控制产生重大影响。