Effect of Temperature on Insecticide Susceptibility in knockdown resistant Aedes aegypti

Description

Aedes aegypti are vectors for common arthropod-borne-diseases (arboviruses) such as Zika, yellow fever, dengue, and chikungunya, which are of significant public health concern. The management of vectors is critical to mitigating the incidence, reemergence, and expansion of these diseases. Vector

Aedes aegypti are vectors for common arthropod-borne-diseases (arboviruses) such as Zika, yellow fever, dengue, and chikungunya, which are of significant public health concern. The management of vectors is critical to mitigating the incidence, reemergence, and expansion of these diseases. Vector control has been complicated by the emergence of insecticide resistance within vectors, which threatens the effectiveness of control efforts. Furthermore, vector management is also complicated by the interaction between insecticide susceptibility and abiotic factors, such as temperature. While it is well-documented that environmental factors affect insecticide susceptibility, it is poorly understood how insecticide resistant vectors with different genetic backgrounds respond to insecticides at different temperatures. This study aims to establish the relationship between deltamethrin susceptibility at varying temperatures across Ae. aegypti lines that differ in their susceptibility due to knockdown resistance (kdr) mechanism. This was done through exposures using the “WHO tube test method” using simulated climate environments (22°C, 27 °C, and 32 °C) on mosquitoes of varying resistance at 1016 and homozygous resistance at 1534. This experiment is still ongoing. This study found that IICC was the most resistant genotype, VVCC the least resistant, and VICC and intermediate. There was found to be no statistically significant relationship between temperature and insecticide susceptibility across kdr genotypes.

Date Created
2023-05
Agent

Investigating the life history traits of three kdr insecticide resistant strains of Aedes aegypti

Description

Vector-borne diseases, such as Zika, chikungunya, dengue, and yellow fever, cause a significant portion of the global infectious disease problem, thereby representing an enormous public health threat worldwide. The threat has become more concerning as Aedes aegypti, who serve as

Vector-borne diseases, such as Zika, chikungunya, dengue, and yellow fever, cause a significant portion of the global infectious disease problem, thereby representing an enormous public health threat worldwide. The threat has become more concerning as Aedes aegypti, who serve as primary vectors for these infectious diseases, continue to thrive in highly populated, urban environments. To solve this problem, insecticides have commonly been used, but this has brought forward additional issues. The overreliance on insecticides has resulted in insecticide resistant individuals emerging within once susceptible populations. Insecticide resistance in Ae. aegypti is a worldwide problem because it compromises the ability to control Ae. aegypti populations, thus increasing the spread of vector-borne diseases. With pyrethroids being commonly used worldwide, the mechanisms behind the knock-down resistance (kdr) are essential to investigate. Investigating the fitness of kdr resistant Ae. aegypti is essential in order to better understand their ability to reproduce and survive in a natural environment. Kdr resistant mutations are known to come with fitness costs: a highly energetic cost or a significant disadvantage that diminishes an aspect of the individual’s fitness. Although it is known that resistance comes with a cost, many research gaps remain. Still, it is unknown whether resistant genotypes differ in larval development times, immature survival, and adult qualities (body weight and wing length). As such, this study observed the impact of the larval development of Ae. aegypti genotypes with varying resistance at loci 1016 and 1534 of the voltage gated sodium channels. The 1016 kdr mutation results in a valine to isoleucine amino acid substitution at position 1016 (V1016I), and the 1534 kdr mutation results in a phenylalanine to cysteine amino acid substitution at position 1534 (F1534C). All strains included in this study were homozygous resistant for the 1534 mutation, while genotype varied at the 1016 locus. Mosquito strains were named after their genotype and are VVCC, VICC, and IICC. Mosquito larvae of each genotype were placed at three temperatures (22℃, 27℃, 32℃) and time to pupation, emergence, immature mortality, sex ratio, dry weight, and wing length was measured. In congruence with previous data, larval pupation and emergence occurred at a faster rate in hotter temperatures (32℃) than in colder temperatures (22℃) for all genotypes. Furthermore, the observed data shows that male mosquitos generally emerged before female mosquitos, regardless of temperature or strain. Interestingly, there were no significant differences between different genotypes in any of the fitness parameters, although the times to pupation suggest a potential trend of increased developmental time with increased resistivity. Ultimately, this data brings important implications to come up with better solutions in vector control programs in order to decrease the likelihood of adult mosquitoes becoming infected and delivering more infective bites. The study also brings light into on where future studies should take place, such as immature competition experiments, and reproductive fitness parameters in order to provide a more complete picture of the life history traits of Ae. aegypti with kdr mutations.

Date Created
2023-05
Agent

Evaluating the Effects of Temperature on the Toxicity of Insecticides That Target Arbovirus Vectors in the Phoenix Metropolitan Area

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Description
Despite its well-documented preference for much more humid climates, the yellow fever mosquito, or Aedes aegypti, has inhabited Arizona since 1951. Their presence is of great concern as they can transmit many deadly diseases, including yellow fever, chikungunya, Zika, and

Despite its well-documented preference for much more humid climates, the yellow fever mosquito, or Aedes aegypti, has inhabited Arizona since 1951. Their presence is of great concern as they can transmit many deadly diseases, including yellow fever, chikungunya, Zika, and dengue fever, putting the residents of the Phoenix Metropolitan Area at risk. Maricopa County Vector Control has made an extensive effort to reduce this risk mainly through the act of fogging insecticides during the night in areas where mosquito numbers exceed a threshold. However, given the well-known temperature-toxicity relationships in insect species, fogging at night may be less or more effective —depending on the relationship— due to the colder temperatures at these times. Additionally, insecticide resistance testing has always been performed at temperatures not usually experienced during fogging, adding to the uncertainty on how useful those test outcomes are. This study took the first steps in determining the effects of temperature on the toxicity of a commonly used insecticide, deltamethrin, on Aedes aegypti by developing a dose response curve on a lab strain at a standard lab temperature of 25°C by performing a CDC bottle bioassay. The diagnostic dose was found to be 50 μg/mL and the lethal dose, 50% (LD50, the dose required to kill half of the test mosquitoes) was found to be 9 μg/mL. Future testing would need to be completed to compare the deltamethrin dose response curve developed in this study with deltamethrin dose response curves at various different temperatures.
Date Created
2020-05
Agent