Your search keyword '"Insecticide resistance management"' showing total 321 results

1. Dendritic mesoporous silica-delivered siRNAs nano insecticides to prevent Sogatella furcifera by inhibiting metabolic detoxification and reproduction.

Author

Gong, Changwei, Wang, Wei, Ma, Yanxin, Zhan, Xiaoxu, Peng, Anchun, Pu, Jian, Yang, Jizhi, and Wang, Xuegui

Abstract

Background: Migratory insect infestation caused by Sogatella furcifera is a serious threat to rice production. The most effective method available for S. furcifera control is intensive insecticide spraying, which cause widespread resistance. RNA interference (RNAi) insecticides hold enormous potential in managing pest resistance. However, the instability and the poor efficiency of cross-kingdom RNA trafficking are key obstacles for the application in agricultural pest management. Methods: We present dendritic mesoporous silica nanoparticles (DMSNs)-based nanocarrier for delivering siRNA and nitenpyram to inhibit the metabolic detoxification and development of S. furcifera, thereby preventing its proliferation. Results: This nano complex (denoted as N@UK-siRNA/DMSNs) significantly enhanced the stability of siRNA (efficacy lasting 21 days) and released cargos in GSH or planthopper bodily fluid with a maximum release rate of 84.99%. Moreover, the released UK-siRNA targeting two transcription factors (Ultraspiracle and Krüppel-homolog 1) downregulated the developmental genes Ultraspiracle (0.09-fold) and Krüppel-homolog 1 (0.284-fold), and downstream detoxification genes ABC SfABCH4 (0.016-fold) and P450 CYP6FJ3 (0.367-fold). Conclusion: The N@UK-siRNA/DMSNs inhibited pest development and detoxification, significantly enhancing susceptibility to nitenpyram to nanogram level (LC50 is 250–252 ng/mL), resulting in a 5.37–7.13-fold synergistic ratio. This work proposes a comprehensive management strategy for controlling S. furcifera to ensure the green and safe production of rice. Schematic fabrication of the N@UK-siRNA/DMSNs and the molecular mechanism resolution of improving the sensitivity of S. furcifera to nitenpyram. The nitenpyram and UK-siRNA are assembled onto the DMSNs by interfacial modification. With phloem and xylem pathway, the N@UK-siRNA/DMSNs could transport bi-directionally to the feeding sites of S. furcifera and then release nitenpyram and UK-siRNA in S. furcifera in response to glutathione (GSH). The UK-siRNA released from N@UK-siRNA/DMSNs would downregulate the developmental genes USP and Kr-H1. The releasing nitenpyram would competitively bind to acetylcholine (ACh) receptors, inhibiting the transmission of nerve impulses [ABSTRACT FROM AUTHOR]

Published

2024

2. Evaluating foliar insecticides and economic thresholds for Tychius picirostris (Coleoptera: Curculionidae) management in Oregon white clover seed production.

Author

Tiwari, Grace, Kaur, Navneet, Anderson, Nicole P, Tanner, K Christy, Lightle, Danielle M, Willette, Alison R, Donovan, Brian C, and Dorman, Seth J

Subjects

INSECTICIDE application, WHITE clover, SEED crops, INSECTICIDE resistance, BIFENTHRIN, INSECTICIDES

Abstract

The clover seed weevil, Tychius picirostris Fabricius (Coleoptera: Curculionidae), is a major pest in Oregon white clover seed crops. Reliance on synthetic pyrethroid insecticides and limited availability of diverse modes of action (MoAs) has increased insecticide resistance selection in regional T. picirostris populations, emphasizing the need to evaluate novel chemistries and rotational strategies for effective insecticide resistance management (IRM). The efficacy of 8 foliar insecticide formulations for managing T. picirostris adult and larval life stages was determined in small and large-plot field trials across 2 crop years. In both years, bifenthrin (Brigade 2EC), the grower's standard, showed negligible adult and larval suppression. Insecticide formulations with isocycloseram and cyantraniliprole active ingredients reduced adult and larval populations when applied at BBCH 59–60 (prebloom) and BBCH 65–66 (full bloom) growth stages, respectively. While differences in T. picirostris abundance were observed among insecticide treatments, seed yield differences were not detected in large-plot trials. Larval abundance was correlated with reduced seed yield, and an economic threshold of ≥3 larvae per 30 inflorescences was determined as a conservative larval threshold to justify foliar applications of diamide insecticides. Additional commercial white clover seed fields were surveyed to compare larval scouting techniques, including a standard Berlese funnel and a grower's do-it-yourself funnel. Both larval extraction techniques were correlated and provided similar estimates of larval abundance. These findings demonstrate new MoAs, optimal insecticide application timing, and larval monitoring methods that can be incorporated into an effective T. picirostris IRM program in white clover seed crops. [ABSTRACT FROM AUTHOR]

Published

2024

3. Dendritic mesoporous silica-delivered siRNAs nano insecticides to prevent Sogatella furcifera by inhibiting metabolic detoxification and reproduction

Author

Changwei Gong, Wei Wang, Yanxin Ma, Xiaoxu Zhan, Anchun Peng, Jian Pu, Jizhi Yang, and Xuegui Wang

Subjects

Sogatella furcifera, Insecticide resistance management, RNAi pesticides, Insecticides delivery, Dendritic mesoporous silica nanoparticles, Biotechnology, TP248.13-248.65, Medical technology, R855-855.5

Abstract

Abstract Background Migratory insect infestation caused by Sogatella furcifera is a serious threat to rice production. The most effective method available for S. furcifera control is intensive insecticide spraying, which cause widespread resistance. RNA interference (RNAi) insecticides hold enormous potential in managing pest resistance. However, the instability and the poor efficiency of cross-kingdom RNA trafficking are key obstacles for the application in agricultural pest management. Methods We present dendritic mesoporous silica nanoparticles (DMSNs)-based nanocarrier for delivering siRNA and nitenpyram to inhibit the metabolic detoxification and development of S. furcifera, thereby preventing its proliferation. Results This nano complex (denoted as N@UK-siRNA/DMSNs) significantly enhanced the stability of siRNA (efficacy lasting 21 days) and released cargos in GSH or planthopper bodily fluid with a maximum release rate of 84.99%. Moreover, the released UK-siRNA targeting two transcription factors (Ultraspiracle and Krüppel-homolog 1) downregulated the developmental genes Ultraspiracle (0.09-fold) and Krüppel-homolog 1 (0.284-fold), and downstream detoxification genes ABC SfABCH4 (0.016-fold) and P450 CYP6FJ3 (0.367-fold). Conclusion The N@UK-siRNA/DMSNs inhibited pest development and detoxification, significantly enhancing susceptibility to nitenpyram to nanogram level (LC50 is 250–252 ng/mL), resulting in a 5.37–7.13-fold synergistic ratio. This work proposes a comprehensive management strategy for controlling S. furcifera to ensure the green and safe production of rice. Graphical Abstract Schematic fabrication of the N@UK-siRNA/DMSNs and the molecular mechanism resolution of improving the sensitivity of S. furcifera to nitenpyram. The nitenpyram and UK-siRNA are assembled onto the DMSNs by interfacial modification. With phloem and xylem pathway, the N@UK-siRNA/DMSNs could transport bi-directionally to the feeding sites of S. furcifera and then release nitenpyram and UK-siRNA in S. furcifera in response to glutathione (GSH). The UK-siRNA released from N@UK-siRNA/DMSNs would downregulate the developmental genes USP and Kr-H1. The releasing nitenpyram would competitively bind to acetylcholine (ACh) receptors, inhibiting the transmission of nerve impulses

Published

2024

4. Baseline susceptibility of an A1 quarantine pest - the South American tomato pinworm Tuta absoluta (Lepidoptera: Gelechiidae) to insecticides: past incidents and future probabilities in line to implementing successful pest management.

Author

Muthu Lakshmi Bavithra, Chandra Mohan, Murugan, Marimuthu, Balasubramani, Venkatasamy, Harish, Sankarasubramanian, and Prakash, Kolanchi

Subjects

PEST control, INSECTICIDE resistance, INSECT pests, FARMERS, INTRODUCED insects, INSECTICIDES

Abstract

Tomato is a widely cultivated crop significant for its economic and nutritional benefits. The South American tomato pinworm, Tuta absoluta, originated in Peru South America and has invaded many nations, causing up to 100% yield loss in tomatoes. The pest was classified as a quarantine pest by the European Plant Protection Organization, before invading the Spain region. Later, this quarantine pest also invaded other regions of Europe, Africa and Asian countries. Invasive insect pests cause global economic losses of 70 billion dollars annually. Among the several management measures suggested against pests, insecticides are the primary method in practice among growers due to significant results, easier operations, and other crucial advantages. Anyhow, repeatedapplication of insecticides has caused the pest to evolve resistance against most of the insecticides in vogue, resulting in a chain of events like management failures, using increased doses of insecticides, intensified chemical residues in the food chain, and irreparable environmental contamination. Major insecticides globally used to control T. absoluta belong to organophosphates, synthetic pyrethroids, neonicotinoids, diamides, avermectins, spinosyns, and oxadizines. Understanding the baseline susceptibility of pests to insecticides helps for better pest management options and is the same for T. absoluta populations to insecticides. The current review paper discusses the T. absoluta distribution, biology, spread, host range, baseline insecticide susceptibility, global insecticide resistance status, and possible management inputs based on our understanding of insecticide susceptibility. The pest can be managed with integrated insecticide resistance management including molecular approaches. [ABSTRACT FROM AUTHOR]

Published

2024

5. Baseline susceptibility of an A1 quarantine pest - the South American tomato pinworm Tuta absoluta (Lepidoptera: Gelechiidae) to insecticides: past incidents and future probabilities in line to implementing successful pest management

Author

Chandra Mohan Muthu Lakshmi Bavithra, Marimuthu Murugan, Venkatasamy Balasubramani, Sankarasubramanian Harish, and Kolanchi Prakash

Subjects

tomato pinworm, baseline susceptibility, insecticide resistance, resistance ratio, insecticide resistance management, Plant culture, SB1-1110

Abstract

Tomato is a widely cultivated crop significant for its economic and nutritional benefits. The South American tomato pinworm, Tuta absoluta, originated in Peru South America and has invaded many nations, causing up to 100% yield loss in tomatoes. The pest was classified as a quarantine pest by the European Plant Protection Organization, before invading the Spain region. Later, this quarantine pest also invaded other regions of Europe, Africa and Asian countries. Invasive insect pests cause global economic losses of 70 billion dollars annually. Among the several management measures suggested against pests, insecticides are the primary method in practice among growers due to significant results, easier operations, and other crucial advantages. Anyhow, repeated application of insecticides has caused the pest to evolve resistance against most of the insecticides in vogue, resulting in a chain of events like management failures, using increased doses of insecticides, intensified chemical residues in the food chain, and irreparable environmental contamination. Major insecticides globally used to control T. absoluta belong to organophosphates, synthetic pyrethroids, neonicotinoids, diamides, avermectins, spinosyns, and oxadizines. Understanding the baseline susceptibility of pests to insecticides helps for better pest management options and is the same for T. absoluta populations to insecticides. The current review paper discusses the T. absoluta distribution, biology, spread, host range, baseline insecticide susceptibility, global insecticide resistance status, and possible management inputs based on our understanding of insecticide susceptibility. The pest can be managed with integrated insecticide resistance management including molecular approaches.

Published

2024

6. Trapping and killing performance of a PermaNet 2.0 hybrid mosquito trapping bednet: an experimental hut evaluation [version 3; peer review: 2 approved]

Author

France-Paraudie A. Kouadio, Fodjo K. Behi, Christabelle G. Sadia, and Chouaibou Seidou Mouhamadou

Subjects

Malaria Vector Control, Insecticide Resistance Management, Mosquito Trapping Long Lasting Insecticidal Bednet, eng, Medicine, Science

Abstract

Background Despite the huge global effort , there has been an increase in malaria morbidity and mortality in sub-Saharan Africa since 2015, from 212 million cases and 429,000 deaths in 2015 to 241 million cases and 627,000 deaths in 2020 mainly because of resistance to insecticide. Therefore, advancing innovative approaches is the only sustainable way to fight malaria. Methods Taking advantage of the behavior of mosquitoes around the net, which is almost 70-90% concentrated on the roof, we have developed a two-compartment mosquito bednet, the so-called T-Net for mass mosquito trapping and killing. In the current study, we investigated in an experimental hut trial, the efficacy of trapping-long-lasting insecticide-treated nets (T-LLINs) against Anopheles gambiae s.l. in an insecticide resistance context. Five different arms have been considered in this study including three positive control arms e.g. PermaNet 2.0 LLIN, Tsara boost LLIN and Interceptor generation 2 (IG2) LLIN), one negative control arm using insecticide-free bednet, and one candidate arm using a hybrid-treated trapping bednet made with PermaNet 2.0 LLIN mounted with an insecticide-free compartment (T-LLIN). Results The highest average daily mortality was recorded with the T-LLIN. In total, 678 mosquitoes were killed by T-LLIN among the 760 collected, i.e. 89.2%. Out of these, 317 were found in the trap compartment, representing 46.75% of mortality directly attributable to the mechanical effect of this net. This added value made it possible to quantify the increased in the killing effect that this net would have over the positive control arms: this would be 58.5% higher than the killing effect of PN2.0, 38% higher than that of Tsara boost and 31.5% higher than that of IG2. Conclusion The current study shows potential to maximize the efficiency of the WHO-recommended LLINs by an addition of an insecticide-free trap compartment on top of the net.

Published

2024

7. Editorial: The side effects of insecticides on insects and the adaptation mechanisms of insects to insecticides.

Author

Youhui Gong, Ting Li, Hussain, Adil, Xiaoming Xia, Qiangli Shang, and Ali, Asad

Subjects

INSECT adaptation, INSECTICIDES, PESTICIDE resistance, EMAMECTIN benzoate, BOTANY, RICE diseases & pests

Published

2023

8. Evidence-based insecticide resistance in South American tomato leaf miner, Phthorimaea absoluta (Meyrick) under laboratory selection.

Author

Prasannakumar, N. R., Jyothi, N., Prasadbabu, K., Ramkumar, G., Asokan, R., Saroja, S., and Sridhar, V.

Subjects

*INSECTICIDE resistance, *LEAFMINERS, *INTEGRATED pest control, *INSECTICIDES, *CYTOCHROME P-450, *TOMATOES

Abstract

The South American tomato moth, Phthorimaea absoluta (Meyrick), is one of the key pests of tomato in India. Since its report in 2014, chemical control has been the main means of tackling this pest, both in the open field and protected cultivation. Despite regular insecticidal sprays, many outbreaks were reported from major tomato-growing regions of South India during 2019–2020. A study was conducted to investigate the effect of insecticide resistance on biology, biochemical enzymes, and gene expression in various P. absoluta field populations viz., Bangalore, Kolar, Madurai, Salem, and Anantapur to commonly used insecticides such as flubendiamide, cyantraniliprole, and indoxacarb. Increased levels of insecticide resistance ratios (RR) were recorded in P. absoluta populations of different locations. A significant increase in cytochrome P450 monooxygenase (CYP/MFO) and esterase levels was noticed in the resistant population compared to susceptible one. Through molecular studies, we identified four new CYP genes viz., CYP248f (flubendiamide), CYP272c, CYP724c (cyantraniliprole), and CYP648i (indoxacarb). The expression levels of these genes significantly increased as the folds of resistance increased from G1 to G20 (generation), indicating involvement of the identified genes in insecticide resistance development in P. absoluta. In addition, the resistant populations showed decreased fecundity, increased larval development period, and adult longevity, resulting in more crop damage. The information generated in the present study thus helps in understanding the development of insecticide resistance by P. absoluta and suggests the farmers and researchers to use insecticides wisely by adopting insecticide resistance management as a strategy under integrated pest management. [ABSTRACT FROM AUTHOR]

Published

2023

9. Chemical Control and Insecticide Resistance in Spodoptera frugiperda (Lepidoptera: Noctuidae).

Author

Van den Berg, Johnnie and du Plessis, Hannalene

Subjects

FALL armyworm, INSECTICIDE resistance, INSECTICIDES, NOCTUIDAE, INTEGRATED pest control, TRANSGENIC plants

Abstract

Insecticides and genetically modified Bt crops are the main tools for control of the fall armyworm, Spodoptera frugiperda (J.E. Smith). Since its invasion of Africa, the Far East, and Australia where Bt crops are largely absent, insecticide use has increased and reduced susceptibility to several insecticides used for decades in its native distribution area have been reported. Poor efficacy at field-level is sometimes incorrectly ascribed to pest resistance, while numerous other factors influence efficacy at field-level. In this paper, we review the history of insecticide resistance in S. frugiperda and discuss the influence that life history traits, migration ecology, and chemical control practices may have on control efficacy and resistance evolution. The indirect role that poor national policies have on pesticide use practices, and indirectly on control efficacy and selection pressure is discussed. Evidence shows that local selection for resistance drives resistance evolution. Integrated pest management, rather than reliance on a single tactic, is the best way to suppress S. frugiperda numbers and the over-use of insecticides which selects for resistance. [ABSTRACT FROM AUTHOR]

Published

2022

10. Pyrethroid Susceptibility in Field Populations of Picture-Winged Flies (Diptera: Ulidiidae) Infesting Fresh Market Sweet Corn in Florida.

Author

Resende, Eric Schwan, Beuzelin, Julien M, Dunkley, Victoria E, Paula-Moraes, Silvana V, Seal, Dakshina R, and Nuessly, Gregg S

Subjects

SWEET corn, PEST control, DIPTERA, INSECT pests, CORN, PYRETHROIDS, CORN pests, INSECTICIDE resistance

Abstract

Picture-winged flies (Diptera: Ulidiidae) are the most damaging insect pests of sweet corn (Zea mays L.) produced in Florida for the fresh market. Management of these pests, referred to as corn silk flies, relies on frequent pyrethroid applications targeting adults. In response to the need for an insecticide resistance management (IRM) program for corn silk flies in this highly intensive crop system, glass vial bioassays were conducted to determine the susceptibility of 12 corn silk fly populations to the pyrethroid beta-cyfluthrin. Two Euxesta eluta Loew and nine Euxesta stigmatias Loew populations were obtained by collecting infested ears in commercial and experimental fields in 2020 and 2021. One E. eluta laboratory colony was used as a susceptible reference population. The E. eluta reference colony was the most susceptible population, with an LC50 value of 0.01 µg/vial. The E. stigmatias field populations were generally less susceptible to beta-cyfluthrin than the E. eluta field populations, with the highest LC50 values attaining 3.51 µg/vial and 0.19 µg/vial, respectively. In addition, the five E. stigmatias populations from commercial sweet corn fields were as much as 17.6 times less susceptible than the four E. stigmatias populations from nontreated fields. Results suggest that E. stigmatias is less susceptible to pyrethroids than E. eluta. Results also suggest that corn silk flies in commercial sweet corn fields are selected for reduced pyrethroid susceptibility throughout the growing season. This study successfully used the glass vial bioassay method for corn silk flies, providing a new tool to initiate an IRM program. [ABSTRACT FROM AUTHOR]

Published

2022

11. Monitoring, cross‐resistance, inheritance, and fitness costs of brown planthoppers, Nilaparvata lugens, resistance to pymetrozine in China.

Author

Song, Xin‐Yu, Peng, Yu‐Xuan, Wang, Li‐Xiang, Ye, Wen‐Nan, Pei, Xin‐Guo, Zhang, Yan‐Chao, Zhang, Shuai, Gao, Cong‐Fen, and Wu, Shun‐Fan

Subjects

NILAPARVATA lugens, PLANTHOPPERS, HEREDITY, PEST control, RICE quality, COST

Abstract

BACKGROUND: The brown planthopper, Nilaparvata lugens, is considered the most destructive pest of rice in many Asian countries including China. Use of pymetrozine in insect resistance management (IRM) has been one strategy to control this pest. In this study, we reported the status of pymetrozine resistance in Nilaparvata lugens (Stål) collected from China over the period 2017–2021 and selected a strain of N. lugens resistant to pymetrozine and evaluated the cross‐resistance, inheritance and fitness costs of the resistance. RESULTS: Monitoring data (2017–2021) showed that field populations of N. lugens in China developed moderate‐ to high‐level pymetrozine resistance during these 5 years. By continuous selection with pymetrozine in the lab, the pymetrozine selected N. lugens strain (Pym‐R98) developed a 225.2‐fold resistance compared to a susceptible strain. The Pym‐R98 strain showed high cross‐resistance to dinotefuran (66.6‐fold) and low cross‐resistance to nitenpyram (5.2‐fold) and sulfoxaflor (5.8‐fold). Inheritance pattern analysis of Pym‐R93 revealed that resistance to pymetrozine was polygenic, autosomal and incompletely dominant. Fitness costs of pymetrozine resistance were present in Pym‐R90 and WA2020 strains with a relative fitness of 0.72 and 0.60, respectively. The developmental duration of Pym‐R90 and WA2020 was significantly longer and hatchability was significantly lower compared to pymetrozine‐susceptible strain (Pym‐S). CONCLUSIONS: N. lugens has developed high level of resistance to pymetrozine. Pymetrozine‐resistance brown planthopper had cross‐resistance with some of neonicotinoids such as dinotefuran, nitenpyram and sulfoxaflor. The autosomal, incompletely dominant and polygenic resistance to pymetrozine in N. lugens and the fitness costs associated with this resistance can be exploited in IRM strategies to preserve the lifetime of pymetrozine for control of N. lugens in China. © 2022 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2022

12. Identification and detection of the V1848I indoxacarb resistance mutation in the beet armyworm, Spodoptera exigua.

Author

Zhang, Xianxia, Zhang, Ruiming, Yu, Mengqi, Liu, Rui, Liu, Naijing, Teng, Haiyuan, Pei, Yakun, Hu, Zhaonong, and Zuo, Yayun

Subjects

*BEET armyworm, *DIAMONDBACK moth, *BIOLOGICAL assay, *CYTOCHROME P-450, *AGRICULTURAL pests, *GLUTATHIONE transferase, *SODIUM channels

Abstract

Indoxacarb is a pivotal insecticide used worldwide to manage Spodoptera exigua , a devastating agricultural pest. This active compound plays a crucial role in resistance management strategies due to its distinctive mode of action. A field population of S. exigua (SH23) from Shanghai, China, exhibited significantly reduced susceptibility to indoxacarb, with a resistance ratio of 113.84-fold in biological assays. Following two rounds of laboratory screening with indoxacarb, the resistance of the new strain (SH23-S2) escalated steeply to 876.15-fold. Genetic analyses of both the SH23 and SH23-S2 strains demonstrated autosomal inheritance and incompletely dominant resistance patterns. Synergist assays indicated a minor role of detoxification enzymes (glutathione s-transferases and cytochrome P450) of SH23-S2 strain in this resistance, implicating target-site resistance as the primary mechanism. To explore the impact of target-site resistance, segment 1–6 of domain IV (IVS1–6) of the sodium channel in S. exigua was cloned, and the sequences from susceptible and indoxacarb-resistant S. exigua were compared. The V1848I mutation, linked to indoxacarb resistance in Plutella xylostella , Tuta absoluta and Liriomyza trifolii , was identified and strongly associated with the indoxacarb-resistant phenotype in the S. exigua SH23-S2 strain, whereas the F1845Y mutation was not detected. Furthermore, a molecular test for the V1848I mutation in field populations was created using an allele-specific PCR (AS-PCR). The discovery of indoxacarb resistance mutation and the creation of diagnostic tool will enable the early detection of indoxacarb resistance, which will facilitate the implementation of targeted resistance management strategies, ultimately delaying the proliferation of resistance. [Display omitted] • SH23 population exhibited significantly reduced susceptibility to indoxacarb, with a resistance ratio of 113.84-fold. • Both the SH23 and SH23-S2 strains demonstrated autosomal inheritance and incompletely dominant resistance patterns. • The V1848I mutation linked to indoxacarb resistance was first identified in the Spodoptera exigua from China. • A molecular test for the V1848I mutation in field populations was created using an allele-specific PCR (AS-PCR). [ABSTRACT FROM AUTHOR]

Published

2024

13. A feasibility trial of genomics‐based diagnosis detecting insecticide resistance of the diamondback moth.

Author

Yamanaka, Takehiko, Kitabayashi, Satoshi, Jouraku, Akiya, Kanamori, Hiroyuki, Kuwazaki, Seigo, and Sudo, Masaaki

Subjects

DIAMONDBACK moth, INSECTICIDES, CHLORANTRANILIPROLE, CAMPAIGN management, BACILLUS thuringiensis, INSECTICIDE resistance, PYRETHROIDS

Abstract

BACKGROUND: Insecticide resistance management has been key for crop protection for over 70 years and is increasingly important because the development of new active ingredients has decreased in recent years. By monitoring the development of resistance in a timely manner, we can effectively prolong insecticide efficacy. Genomic‐based diagnosis can reliably predict resistance development if information on resistant mutations against major pesticides is available. Here, we developed a feasibility trial of genomics‐based diagnosis of insecticide resistance in diamondback moth (Plutella xylostella) populations in Nagano Prefecture, Japan. Amplicon sequencing analyses using a next‐generation sequencer (Illumina MiSeq) for major insecticides, including diamides, pyrethroids, Bacillus thuringiensis (Bt) toxin (Cry1Ac), organophosphates, and spinosyns, were conducted. RESULTS: Mutations related to the resistance of pyrethroids, organophosphates, and diamides (flubendiamide and chlorantraniliprole) prevailed, while those of a diamide (cyantraniliprole), Bt (Cry1Ac), and spinosyns were scanty, suggesting that they are still effective. The results of the genomics‐based diagnosis were generally concordant with the results of bioassays. Resistance development tendencies were generally uniform across Nagano. CONCLUSION: An insecticide‐resistance management campaign can be conducted in Nagano Prefecture with a quick genomic‐based diagnosis in early spring while bioassay is the only option for monitoring resistances whose mutations are unavailable. Our study is the first step in the future management of insecticide resistance in all significant pests. © 2022 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2022

14. Evaluation of Resistance to Abamectin in the Populations of Tuta absoluta (Lepidoptera: Gelechiidae), Collected from Isfahan Province, Iran.

Author

Azizi, M. and Khajehali, J.

Subjects

*ABAMECTIN, *GELECHIIDAE, *INSECTICIDES, *LEPIDOPTERA, *LEAFMINERS, *CYTOCHROME P-450, *TOMATO diseases & pests, *INSECTICIDE resistance

Abstract

The tomato leafminer (Tuta absoluta Meyrick) (Lepidoptera: Gelechiidae) is one of the most important pests of tomato worldwide. In this study, resistance of different populations of the tomato leaf miner from Isfahan Province was evaluated against abamectin. The median Lethal Concentrations (LC50) of different populations were estimated by bioassays using a leaf-dip method. The LC50 value of abamectin in the reference population of Isfahan University of Technology (IUT) was estimated as 5.67 mg ai L-1, while the population of Shahre-e-Abrisham 1 showed the highest (25-fold) resistance, with an LC50 value of 143.18 mg ai L-1. Pre-treatment of different populations with diethyl maleate (DEM) synergist, an inhibitor of glutathione-S-transferases (GSTs), increased significantly abamectin toxicity. GST activity was also found significantly different between resistant and reference populations. Triphenyl phosphate (TPP), an inhibitor of esterases (ESTs), reduced the LC50 value of abamctin in the populations as much as 1.73- to 3.73-fold. The activity of ESTs in these populations was also significantly different. Furthermore, inhibition of cytochrome P450 monooxygenases (CYP450s) by piperonyl butoxide (PBO) increased abamectin toxicity between 1.3- to 2.9-fold in tested populations. The highest ratios of synergism for DEM (5.86), TPP (3.73-fold), and PBO (2.91-fold) were observed in Shahre-e-Abrisham 1. It seems that GSTs and ESTs play a more important role in the resistance development against abamectin in the studied populations. High levels of resistance to abamectin in the collected populations from Isfahan Province shows the importance of insecticide resistance management based on the early detection of resistance and alternative use of insecticides. [ABSTRACT FROM AUTHOR]

Published

2022

15. There is more than chitin synthase in insect resistance to benzoylureas: molecular markers associated with teflubenzuron resistance in Spodoptera frugiperda.

Author

do Nascimento, Antonio Rogério Bezerra, Pavinato, Vitor Antonio Corrêa, Rodrigues, Juliana Gonzales, Silva-Brandão, Karina Lucas, Consoli, Fernando Luis, Michel, Andrew, and Omoto, Celso

Subjects

*FALL armyworm, *CHITIN synthase, *SINGLE nucleotide polymorphisms, *PEST control, *INSECTS, *CHITIN

Abstract

Chitin synthesis inhibitors are successfully used in pest control and an excellent option for integrated pest management programs due to their low non-target effects. However, field-evolved resistance of lepidopteran pests to chitin synthesis inhibitors and the selection of laboratory-resistant strains to these products has been already reported. Therefore, to support efficient resistance management programs it is necessary to expand the knowledge on the resistance mechanisms and potential molecular markers that detect resistant alleles. Teflubenzuron is a chitin synthesis inhibitor used to control the world widely distributed fall armyworm, Spodoptera frugiperda (J.E. Smith, 1797) (Lepidoptera: Noctuidae). Here, we report the selection and inheritance characterization of S. frugiperda strain resistant to teflubenzuron. We also evaluated the cross-resistance to other chitin-synthesis inhibitors and identified single nucleotide polymorphisms (SNPs), which can be used as molecular markers for monitoring the evolution of resistance of S. frugiperda to teflubenzuron. The resistance of the selected strain of S. frugiperda to teflubenzuron was characterized as polygenic, autosomal, and incompletely recessive. The resistance ratio observed was nearly 1,365-fold. Teflubenzuron-resistant strain showed cross-resistance to lufenuron and novaluron, but not to chlorfluazuron. We also detected a set of 72 SNPs that could support monitoring of the resistance frequency to teflubenzuron in field populations. Our data contribute to the understanding of the resistance mechanisms and the inheritance of resistance of S. frugiperda to benzoylureas. We also contribute with candidate markers as tools for monitoring the emergence and spread of teflubenzuron resistance in S. frugiperda. [ABSTRACT FROM AUTHOR]

Published

2022

16. Multiple TaqMan qPCR and droplet digital PCR (ddPCR) diagnostics for pesticide resistance monitoring and management, in the major agricultural pest Tetranychus urticae.

Author

Mavridis, Konstantinos, Papapostolou, Kyriaki Maria, Riga, Maria, Ilias, Aris, Michaelidou, Kleita, Bass, Chris, Van Leeuwen, Thomas, Tsagkarakou, Anastasia, and Vontas, John

Subjects

PESTICIDE resistance, AGRICULTURAL pests, TWO-spotted spider mite, MOLECULAR diagnosis, PHENOTYPES

Abstract

BACKGROUND Decisions on which pesticide to use in agriculture are expected to become more difficult, as the number of available chemicals is decreasing. For Tetranychus urticae (T. urticae), a major pest for which a number of candidate markers for pesticide resistance are in place, molecular diagnostics could support decision‐making for the rational use of acaricides. RESULTS: A suite of 12 TaqMan qPCR assays [G314D (GluCl1), G326E, I321T (GluCl3), G119S, F331W (Ace‐1), H92R (PSST), L1024V, F1538I (VGSC), I1017F (CHS1), G126S, S141F, P262T (cytb)], were validated against Sanger‐sequencing, and subsequently adapted for use with the ddPCR technology. The concordance correlation coefficient between the actual and ddPCR measured mutant allelic frequencies was 0.995 (95% CI = 0.991–0.998), and no systematic, proportional, or random differences were detected. The achieved Limit of Detection (LoD) was 0.1% (detection of one mutant in a background of 999 wild type mites). The ddPCR assay panel was then assessed in terms of agreement with phenotypic resistance, through a pilot application in field populations from Crete, with strong correlation and thus predictive and diagnostic value of the molecular assays in some cases (e.g., etoxazole and abamectin resistance). Molecular diagnostics were able to capture incipient resistance that was otherwise missed by phenotypic bioassays. The molecular and phenotypic resistance screening of T. urticae field populations from Crete, revealed both multi‐resistant and susceptible populations. CONCLUSION: The highly sensitive T. urticae molecular diagnostic platforms developed in this study could prove a valuable tool for pesticide resistance management. © 2021 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2022

17. Tenebenal: a meta-diamide with potential for use as a novel mode of action insecticide for public health

Author

Rosemary Susan Lees, Pauline Ambrose, Jessica Williams, John Morgan, Giorgio Praulins, Victoria A. Ingham, Chris T. Williams, Rhiannon Agnes Ellis Logan, Hanafy M. Ismail, and David Malone

Subjects

Insecticide resistance management, Anopheles gambiae, Aedes aegypti, Meta-diamide, Tenebenal™, Broflanilide, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background There is an urgent need for insecticides with novel modes of action against mosquito vectors. Broflanilide is a meta-diamide, discovered and named Tenebenal™ by Mitsui Chemicals Agro, Inc., which has been identified as a candidate insecticide for use in public health products. Methods To evaluate its potential for use in public health, Tenebenal™ was screened using an array of methodologies against Anopheles and Aedes strains. Initially it was assessed for intrinsic efficacy by topical application. Tarsal contact bioassays were then conducted to further investigate its efficacy, as well as its potency and speed of action. The potential of the compound for use in indoor residual spray (IRS) applications was investigated by testing the residual efficacy of a prototype IRS formulation on a range of typical house building substrates, and its potential for use in long-lasting insecticidal nets (LLIN) was tested using dipped net samples. Finally, bioassays using well-characterized insecticide-resistant mosquito strains and an in silico screen for mutations in the insecticide’s target site were performed to assess the risk of cross-resistance to Tenebenal™. Results Tenebenal™ was effective as a tarsal contact insecticide against both Aedes and Anopheles mosquitoes, with no apparent cross-resistance caused by mechanisms that have evolved to insecticides currently used in vector control. Topical application showed potent intrinsic activity against a Kisumu reference strain and an insecticide-resistant strain of Anopheles gambiae. Applied to filter paper in a WHO tube bioassay, Tenebenal™ was effective in killing 100% of susceptible and resistant strains of An. gambiae and Aedes aegypti at a concentration of 0.01%. The discriminating concentration of 11.91 µg/bottle shows it to be very potent relative to chemistries previously identified as having potential for vector control. Mortality occurs within 24 h of exposure, 80% of this mortality occurring within the first 10 h, a speed of kill somewhat slower than seen with pyrethroids due to the mode of action. The potential of Tenebenal™ for development in LLIN and IRS products was demonstrated. At least 12 months residual efficacy of a prototype IRS formulation applied at concentrations up to 200 mg of AI/sq m was demonstrated on a range of representative wall substrates, and up to 18 months on more inert substrates. A dipped net with an application rate of around 2 g/sq m Tenebenal™ killed 100% of exposed mosquitoes within a 3-min exposure in a WHO cone test. Conclusions Tenebenal™ is a potent insecticide against adult Aedes and Anopheles mosquitoes, including strains resistant to classes of insecticide currently used in vector control. The compound has shown great potential in laboratory assessment and warrants further investigation into development for the control of pyrethroid-resistant mosquitoes.

Published

2020

18. The role of windows of selection and windows of dominance in the evolution of insecticide resistance in human disease vectors

Author

Andy South, Rosemary Lees, Gala Garrod, Jessica Carson, David Malone, and Ian Hastings

Subjects

dose–response, drug resistance, insecticide resistance, insecticide resistance management, malaria, vector‐borne diseases, Evolution, QH359-425

Abstract

Abstract Persistent insecticides sprayed onto house walls, and incorporated into insecticide‐treated bednets, provide long‐acting, cost‐effective control of vector‐borne diseases such as malaria and leishmaniasis. The high concentrations that occur immediately postdeployment may kill both resistant and susceptible insects. However, insecticide concentration, and therefore killing ability, declines in the months after deployment. As concentrations decline, resistant insects start to survive, while susceptible insects are still killed. The period of time after deployment, within which the mortality of resistant individuals is lower than that of susceptible ones, has been termed the “window of selection” in other contexts. It is recognized as driving resistance in bacteria and malaria parasites, both of which are predominantly haploid. We argue that paying more attention to these mortality differences can help understand the evolution of insecticide resistance. Because insects are diploid, resistance encoded by single genes generates heterozygotes. This gives the potential for a narrower “window of dominance,” within the window of selection, where heterozygote mortality is lower than that of susceptible homozygotes. We explore the general properties of windows of selection and dominance in driving resistance. We quantify their likely effect using data from new laboratory experiments and published data from the laboratory and field. These windows can persist months or years after insecticide deployments. Differential mortalities of resistant, susceptible and heterozygous genotypes, after public health deployments, constitute a major challenge to controlling resistance. Greater attention to mortality differences by genotype would inform strategies to reduce the evolution of resistance to existing and new insecticides.

Published

2020

19. Baseline susceptibility of an A1 quarantine pest - the South American tomato pinworm Tuta absoluta (Lepidoptera: Gelechiidae) to insecticides: past incidents and future probabilities in line to implementing successful pest management.

Author

Bavithra CMML, Murugan M, Balasubramani V, Harish S, and Prakash K

Abstract

Tomato is a widely cultivated crop significant for its economic and nutritional benefits. The South American tomato pinworm, Tuta absoluta , originated in Peru South America and has invaded many nations, causing up to 100% yield loss in tomatoes. The pest was classified as a quarantine pest by the European Plant Protection Organization, before invading the Spain region. Later, this quarantine pest also invaded other regions of Europe, Africa and Asian countries. Invasive insect pests cause global economic losses of 70 billion dollars annually. Among the several management measures suggested against pests, insecticides are the primary method in practice among growers due to significant results, easier operations, and other crucial advantages. Anyhow, repeated application of insecticides has caused the pest to evolve resistance against most of the insecticides in vogue, resulting in a chain of events like management failures, using increased doses of insecticides, intensified chemical residues in the food chain, and irreparable environmental contamination. Major insecticides globally used to control T. absoluta belong to organophosphates, synthetic pyrethroids, neonicotinoids, diamides, avermectins, spinosyns, and oxadizines. Understanding the baseline susceptibility of pests to insecticides helps for better pest management options and is the same for T. absoluta populations to insecticides. The current review paper discusses the T. absoluta distribution, biology, spread, host range, baseline insecticide susceptibility, global insecticide resistance status, and possible management inputs based on our understanding of insecticide susceptibility. The pest can be managed with integrated insecticide resistance management including molecular approaches., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Bavithra, Murugan, Balasubramani, Harish and Prakash.)

Published

2024

20. Strategic Approaches for Applications of Entomopathogenic Fungi to Counter Insecticide Resistance in Agriculturally Important Insect Pests

Author

Ambethgar, V., Gehlot, Praveen, editor, and Singh, Joginder, editor

Published

2018

21. Optimal rotation of insecticides to prevent the evolution of resistance in a structured environment.

Author

Yamamura, Kohji

Subjects

INSECTICIDE application, CROPS, ROTATIONAL motion, INSECTICIDE resistance, INSECTICIDES

Abstract

Several strategies have been used in insecticide resistance management to prevent the evolution of resistance, but the spatial aspects of insecticide application are crucially important among these strategies. Here, we consider a structured environment that consists of on‐farm and off‐farm fields where crops are planted periodically in on‐farm fields during cultivation periods. We define the basic reproduction rate (R0) of resistance as the expected number of offspring of a resistant individual divided by that of a susceptible individual under the condition that the proportion of resistance is extremely small; it is measured as the quantity per cycle of the cultivation period. We calculate logeR0 using realistic dose‐survival curves under a given fitness cost of resistance genes. The evolution of resistance occurs if and only if the logeR0 value is larger than 0. Then, we propose a procedure for calculating the optimal design of rotational spraying that prevents the evolution of resistance, that is, the evolutionary stable strategy (ESS) for farmers, satisfying the mortality required for managing the abundance of insects. We consider the following controllable factors in calculating the optimal design: the dose of insecticide, the number of sprays, the number of different types of insecticides and potentially, the size of on‐farm fields. [ABSTRACT FROM AUTHOR]

Published

2021

22. Monitoring of field-evolved resistance to flonicamid, neonicotinoid, and conventional insecticides in the Oxycarenus hyalinipennis costa.

Author

Ullah, Inam, Wazir, Shabana, Abbas, Naeem, Naeem, Muhammad, Abdullah, Khalid, Mahmood, Zahid, Rashid, Mamoon-ur, and Hafez, Abdulwahab M.

Abstract

Oxycarenus hyalinipennis Costa is a polyphagous insect pest and can develop insecticide resistance. The resistance of O. hyalinipennis to neonicotinoids (clothianidin and dinotefuran), flonicamid, and conventional insecticides; carbamates (methomyl and carbosulfon), organophosphates (chlorpyrifos and malathion), and pyrethroids (cypermethrin and zeta-cypermethrin) was evaluated. The O. hyalinipennis populations were sampled from four locations in Pakistan and performed bioassays against the insecticides by leaf dip protocol. The O. hyalinipennis’ populations showed low resistance to carbosulfan (resistance ratio (RR) = 2.06–6.34) and methomyl (RR = 2.78–7.27), moderate to high resistance to chlorpyrifos (RR = 30–45), malathion (RR = 20.29–88.19), and flonicamid (RR = 14.24–46.97), in comparison with the susceptible strain. Susceptibility to low resistance against cypermethrin (RR = 1.27–2.82), zeta-cypermethrin (RR = 2.62–3.38), and clothianidin (RR = 1.74–3.40), and low to moderate resistance to dinotefuran (RR = 3.84–13.43) in the field populations, was observed compared to the susceptible strain. A rotational usage of carbamates and pyrethroids with an integrated pest management tool should be considered to deal with O. hyalinipennis’ insecticide resistance. [ABSTRACT FROM AUTHOR]

Published

2021

23. Status of insecticide resistance in Anopheles gambiae (s.l.) of The Gambia

Author

Kevin Ochieng’ Opondo, Musa Jawara, Saihou Cham, Ebrima Jatta, Lamin Jarju, Muhammed Camara, Fatou Sanneh, Pa Modou Gaye, Lamin Jadama, Sainey Ceesay, Ebrima Njie, Benoit Sessinou Assogba, Balla Kandeh, and Umberto D’Alessandro

Subjects

Anopheles gambiae, Insecticide resistance, Insecticide resistance management, kdr, Ace-1, Malaria, Infectious and parasitic diseases, RC109-216

Abstract

Abstract Background Vector control activities, namely long-lasting insecticidal nets (LLIN) and indoor residual spraying (IRS), have contributed significantly to the decreasing malaria burden observed in The Gambia since 2008. Nevertheless, insecticide resistance may threaten such success; it is important to regularly assess the susceptibility of local malaria vectors to available insecticides. Methods In the transmission seasons of 2016 and 2017, Anopheles gambiae (s.l.) larvae were sampled in or around the nine vector surveillance sentinel sites of the Gambia National Malaria Control Programme (GNMCP) and in a few additional sampling points. Using WHO susceptibility bioassays, female adult mosquitoes were exposed to insecticide-impregnated papers. Molecular identification of sibling species and insecticide resistance molecular markers was done on a subset of 2000 female mosquitoes. Results A total of 4666 wild-caught female adult mosquitoes were exposed to either permethrin (n = 665), deltamethrin (n = 744), DDT (n = 1021), bendiocarb (n = 990) or pirimiphos-methyl (n = 630) insecticide-impregnated papers and control papers (n = 616). Among the 2000 anophelines, 1511 (80.7%) were Anopheles arabiensis, 204 (10.9%) Anopheles coluzzii, 75 (4%) Anopheles gambiae (s.s.), and 83 (4.4%) An. gambiae (s.s.) and An. coluzzii hybrids. There was a significant variation in the composition and species distribution by regions and year, P = 0.009. Deltamethrin, permethrin and DDT resistance was found in An. arabiensis, especially in the coastal region, and was mediated by Vgsc-1014F/S mutations (odds ratio = 34, P = 0.014). There was suspected resistance to pirimiphos-methyl (actellic 300CS) in the North Bank Region although only one survivor had the Ace-1-119S mutation. Conclusions As no confirmed resistance to bendiocarb and actellic 300CS was detected, the national malaria control programme can continue using these insecticides for IRS. Nevertheless, the detection of Ace-1 119S mutation warrants extensive monitoring. The source of insecticide pressure driving insecticide resistance to pyrethroids and DDT detected at the coastal region should be further investigated in order to properly manage the spread of resistance in The Gambia.

Published

2019

24. Acute and Chronic Toxicity of Indoxacarb in Two Populations of Plutella xylostella (Lepidoptera: Plutellidae).

Author

Lemes, Amanda A F, Sipriano-Nascimento, Thamiris P, Vieira, Natalia F, Cardoso, Camila P, Vacari, Alessandra M, and Bortoli, Sergio A De

Subjects

DIAMONDBACK moth, PLUTELLIDAE, INSECTICIDE application, FERTILITY, INSECTICIDES

Abstract

The diamondback moth, Plutella xylostella (Linnaeus, 1758), is one of the main pests of brassicas, and various insecticides, such as indoxacarb, are used to control it. However, frequent insecticide applications favor the selection of resistant individuals. Thus, the residual and sublethal effects of indoxacarb in two populations of P. xylostella , one collected in the field (FP) and one from the laboratory (LP), were evaluated and compared. The objective of this research was to investigate the toxicity of indoxacarb at residual and sublethal levels in a field population of P. xylostella from Brazil and a population from the laboratory. Leaf-dip bioassays showed high toxicity, with LC50 values after 48 h of 3.7 and 6.9 mg/liter for the LP and FP, respectively. Sublethal effects were indicated by significant reduction in the survival of larvae, pupae, and offspring. There was an increase in foliar consumption and a decrease in adult survival in the LP, and a decrease in fecundity in the FP. For the LP and FP population, the mean values for R 0, r m , and λ for the control treatment were significantly higher than for the treatment groups (CL15 and CL25). Exposure of larvae to sublethal indoxacarb concentrations significantly reduced larval and pupal survival. Larval and pupal survival decreased as the indoxacarb concentration increased. Fecundity was significantly lower for the FP at LC15 (96.2 eggs per female) and LC25 (69.2 eggs per female) concentrations compared with the other treatments. [ABSTRACT FROM AUTHOR]

Published

2021

25. ResistanceSim: development and acceptability study of a serious game to improve understanding of insecticide resistance management in vector control programmes

Author

Edward K. Thomsen, Charlotte Hemingway, Andy South, Kirsten A. Duda, Claire Dormann, Robert Farmer, Michael Coleman, and Marlize Coleman

Subjects

Serious games, Insecticide resistance management, Insecticide resistance, Vector control, Capacity building, Training, Arctic medicine. Tropical medicine, RC955-962, Infectious and parasitic diseases, RC109-216

Abstract

Abstract The use of insecticides is the cornerstone of effective malaria vector control. However, the last two decades has seen the ubiquitous use of insecticides, predominantly pyrethroids, causing widespread insecticide resistance and compromising the effectiveness of vector control. Considerable efforts to develop new active ingredients and interventions are underway. However, it is essential to deploy strategies to mitigate the impact of insecticide resistance now, both to maintain the efficacy of currently available tools as well as to ensure the sustainability of new tools as they come to market. Although the World Health Organization disseminated best practice guidelines for insecticide resistance management (IRM), Rollback Malaria’s Vector Control Working Group identified the lack of practical knowledge of IRM as the primary gap in the translation of evidence into policy. ResistanceSim is a capacity strengthening tool designed to address this gap. The development process involved frequent stakeholder consultation, including two separate workshops. These workshops defined the learning objectives, target audience, and the role of mathematical models in the game. Software development phases were interspersed with frequent user testing, resulting in an iterative design process. User feedback was evaluated via questionnaires with Likert-scale and open-ended questions. The game was regularly evaluated by subject-area experts through meetings of an external advisory panel. Through these processes, a series of learning domains were identified and a set of specific learning objectives for each domain were defined to be communicated to vector control programme personnel. A simple “game model” was proposed that produces realistic outputs based on player strategy and also runs in real-time. Early testing sessions revealed numerous usability issues that prevented adequate player engagement. After extensive revisions, later testing sessions indicated that the tool would be a valuable addition to IRM training.

Published

2018

26. Insights from agriculture for the management of insecticide resistance in disease vectors

Author

Eleanore D. Sternberg and Matthew B. Thomas

Subjects

global plan for insecticide resistance management in malaria vectors, insecticide resistance, insecticide resistance management, integrated vector management, malaria, vector‐borne diseases, Evolution, QH359-425

Abstract

Abstract Key to contemporary management of diseases such as malaria, dengue, and filariasis is control of the insect vectors responsible for transmission. Insecticide‐based interventions have contributed to declines in disease burdens in many areas, but this progress could be threatened by the emergence of insecticide resistance in vector populations. Insecticide resistance is likewise a major concern in agriculture, where insect pests can cause substantial yield losses. Here, we explore overlaps between understanding and managing insecticide resistance in agriculture and in public health. We have used the Global Plan for Insecticide Resistance Management in malaria vectors, developed under the auspices of the World Health Organization Global Malaria Program, as a framework for this exploration because it serves as one of the few cohesive documents for managing a global insecticide resistance crisis. Generally, this comparison highlights some fundamental differences between insect control in agriculture and in public health. Moreover, we emphasize that the success of insecticide resistance management strategies is strongly dependent on the biological specifics of each system. We suggest that the biological, operational, and regulatory differences between agriculture and public health limit the wholesale transfer of knowledge and practices from one system to the other. Nonetheless, there are some valuable insights from agriculture that could assist in advancing the existing Global Plan for Insecticide Resistance Management framework.

Published

2018

27. Evaluating insecticide resistance across African districts to aid malaria control decisions.

Author

Moyes, Catherine L., Athinya, Duncan K., Seethaler, Tara, Battle, Katherine E., Sinka, Marianne, Hadi, Melinda P., Hemingway, Janet, Coleman, Michael, and Hancock, Penelope A.

Subjects

*INSECTICIDE resistance, *MALARIA, *ANOPHELES gambiae, *VECTOR control, *FORECASTING

Abstract

Malaria vector control may be compromised by resistance to insecticides in vector populations. Actions to mitigate against resistance rely on surveillance using standard susceptibility tests, but there are large gaps in the monitoring data across Africa. Using a published geostatistical ensemble model, we have generated maps that bridge these gaps and consider the likelihood that resistance exceeds recommended thresholds. Our results show that this model provides more accurate next-year predictions than two simpler approaches. We have used the model to generate district-level maps for the probability that pyrethroid resistance in Anopheles gambiae s.l. exceeds the World Health Organization thresholds for susceptibility and confirmed resistance. In addition, we have mapped the three criteria for the deployment of piperonyl butoxide-treated nets that mitigate against the effects of metabolic resistance to pyrethroids. This includes a critical review of the evidence for presence of cytochrome P450-mediated metabolic resistance mechanisms across Africa. The maps for pyrethroid resistance are available on the IR Mapper website, where they can be viewed alongside the latest survey data. [ABSTRACT FROM AUTHOR]

Published

2020

28. Insecticide residue longevity for on‐site screening of Drosophila suzukii (Matsumura) resistance.

Author

Disi, Joseph Onwusemu, Van Timmeren, Steven, Gress, Brian, Zalom, Frank, Isaacs, Rufus, and Sial, Ashfaq

Subjects

INSECTICIDE residues, DROSOPHILA suzukii, CYPERMETHRIN, LONGEVITY, MOTIVATIONAL interviewing, INSECTICIDE resistance, FRUIT ripening, MALATHION

Abstract

BACKGROUND Preventative application of insecticides reduces marketable yield losses caused by Drosophila suzukii females that selectively lay eggs into ripe and ripening fruits. However, repeated applications of insecticides increase the risk of resistance development. It is therefore critical to test field‐collected flies on‐site to assess the level of sensitivity of D. suzukii to insecticides to monitor resistance, before it becomes a widespread issue. This requires that insecticide‐treated vials be readily available to conduct bioassays. Thus, bioassays were conducted using malathion‐, methomyl‐, zeta‐cypermethrin‐, phosmet‐, spinetoram‐ and spinosad‐treated scintillation vials at 1 to 28 days after treatment to assess how residue age affects insecticide toxicity in scintillation vials. The impact of temperature on residue longevity was also assessed. RESULTS: Insecticide‐treated vials stored for 28 days provided reliable estimates of susceptibility of D. suzukii to some of the tested insecticides. The toxicity of malathion remained consistently high throughout the experiment followed by methomyl. However, toxicities of zeta‐cypermethrin, phosmet were variable whereas those of the spinosyns declined relatively quickly. Overall, storage temperature did not affect the residual toxicity of most of the tested insecticides except zeta‐cypermethrin. CONCLUSION: These findings suggest that the toxicity of insecticide residues in treated vials remains active for ≤28 d for malathion and ≤21 and 28 days in methomyl‐treated vials stored at 4 °C in Georgia and Michigan, respectively. However, the toxicities of spinosad, zeta‐cypermethrin and phosmet were less consistent. Hence, vials treated with these insecticides should be freshly made to be effective for screening D. suzukii field populations for resistance. © 2020 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2020

29. ‘What I cannot create, I do not understand’: functionally validated synergism of metabolic and target site insecticide resistance.

Author

Samantsidis, George-Rafael, Panteleri, Rafaela, Denecke, Shane, Kounadi, Stella, Christou, Iason, Nauen, Ralf, Douris, Vassilis, and Vontas, John

Subjects

*INSECTICIDE resistance, *AEDES aegypti, *GENETIC transformation, *SODIUM channels, *CRISPRS, *MALARIA

Abstract

The putative synergistic action of target-site mutations and enhanced detoxification in pyrethroid resistance in insects has been hypothesized as a major evolutionary mechanism responsible for dramatic consequences in malaria incidence and crop production. Combining genetic transformation and CRISPR/Cas9 genome modification, we generated transgenic Drosophila lines expressing pyrethroid metabolizing P450 enzymes in a genetic background along with engineered mutations in the voltage-gated sodium channel (para) known to confer target-site resistance. Genotypes expressing the yellow fever mosquito Aedes aegypti Cyp9J28 while also bearing the paraV1016G mutation displayed substantially greater resistance ratio (RR) against deltamethrin than the product of each individual mechanism (RRcombined: 19.85 > RRCyp9J28: 1.77 × RRV1016G: 3.00). Genotypes expressing Brassicogethes aeneus pollen beetle Cyp6BQ23 and also bearing the paraL1014F (kdr) mutation, displayed an almost multiplicative RR (RRcombined: 75.19 ≥ RRCyp6BQ23: 5.74 × RRL1014F: 12.74). Reduced pyrethroid affinity at the target site, delaying saturation while simultaneously extending the duration of P450-driven detoxification, is proposed as a possible underlying mechanism. Combinations of target site and P450 resistance loci might be unfavourable in field populations in the absence of insecticide selection, as they exert some fitness disadvantage in development time and fecundity. These are major considerations from the insecticide resistance management viewpoint in both public health and agriculture. [ABSTRACT FROM AUTHOR]

Published

2020

30. The role of windows of selection and windows of dominance in the evolution of insecticide resistance in human disease vectors.

Author

South, Andy, Lees, Rosemary, Garrod, Gala, Carson, Jessica, Malone, David, and Hastings, Ian

Subjects

*DISEASE vectors, *NATURAL immunity, *INSECTICIDE resistance, *SOCIAL dominance, *PLASMODIUM

Abstract

Persistent insecticides sprayed onto house walls, and incorporated into insecticide‐treated bednets, provide long‐acting, cost‐effective control of vector‐borne diseases such as malaria and leishmaniasis. The high concentrations that occur immediately postdeployment may kill both resistant and susceptible insects. However, insecticide concentration, and therefore killing ability, declines in the months after deployment. As concentrations decline, resistant insects start to survive, while susceptible insects are still killed. The period of time after deployment, within which the mortality of resistant individuals is lower than that of susceptible ones, has been termed the "window of selection" in other contexts. It is recognized as driving resistance in bacteria and malaria parasites, both of which are predominantly haploid. We argue that paying more attention to these mortality differences can help understand the evolution of insecticide resistance. Because insects are diploid, resistance encoded by single genes generates heterozygotes. This gives the potential for a narrower "window of dominance," within the window of selection, where heterozygote mortality is lower than that of susceptible homozygotes. We explore the general properties of windows of selection and dominance in driving resistance. We quantify their likely effect using data from new laboratory experiments and published data from the laboratory and field. These windows can persist months or years after insecticide deployments. Differential mortalities of resistant, susceptible and heterozygous genotypes, after public health deployments, constitute a major challenge to controlling resistance. Greater attention to mortality differences by genotype would inform strategies to reduce the evolution of resistance to existing and new insecticides. [ABSTRACT FROM AUTHOR]

Published

2020

31. Molecular Study on Field Evolved Resistance of Red Palm Weevil (Rhynchophorus ferruginous) and its Management through RNAi.

Author

Ahmad, Jam Nazeer, Manzoor, Mujahid, Aslam, Zubair, and Ahmad, Samina Jam Nazeer

Abstract

Molecular and proteomic study was conducted on field evolved resistance of Red Palm Weevil (Rhynchophorus ferruginous) against Parathyroid group of insecticide (Cypermethrin). Cytochrome P450 genes have been associated with insecticides resistance. Field collected population of R. ferruginous from different provinces of Pakistan was investigated for insecticides resistance development against P450 gene. Insect bioassay indicated highly significant level of LC50 values among laboratory reared and field collected population against Cypermethrin. The laboratory reared resistant population, Sindh and South Punjab collected population showed high LC50 values as compared to susceptible, Baluchistan and KPK population. The expression of P450 gene through PCR showed enhanced level of P450 gene in different Instars as well as collected population. The dsRNA specific for CYP450 gene was designed and targeted through dsRNA in thoracic region of R. ferruginous through micro-injection. Gene expression and proteomic study confirmed the down regulation of P450 gene and associated protein in dsRNA treated population. The application of ds RNA specific for CYP450 also reduced insecticide resistance in R. ferruginous. The developmental parameters were highly affected in RPW treated with dsRNA as compared to control samples treated with water or dsGFP. These results support the RNAi application as a suitable tool for the management of insecticide resistance and control of R. ferruginous. [ABSTRACT FROM AUTHOR]

Published

2020

32. Long‐term field insecticide susceptibility data and laboratory experiments reveal evidence for cross resistance to other neonicotinoids in the imidacloprid‐resistant brown planthopper Nilaparvata lugens.

Author

Fujii, Tomohisa, Sanada‐Morimura, Sachiyo, Oe, Takaho, Ide, Manami, Van Thanh, Dinh, Van Chien, Ho, Van Tuong, Phan, Loc, Phung Minh, Cuong, Le Quoc, Liu, Ze‐Wen, Zhu, Zeng‐Rong, Li, Jian‐Hong, Wu, Gang, Huang, Shou‐Horng, Estoy, Gerardo F, Sonoda, Shoji, and Matsumura, Masaya

Subjects

NEONICOTINOIDS, THIAMETHOXAM, NILAPARVATA lugens, INSECTICIDES, IMIDACLOPRID, CLOTHIANIDIN, INSECT pests, INSECTICIDE resistance

Abstract

BACKGROUND: Long‐term monitoring data is helpful to understand the fluctuation of susceptibility and pattern of cross resistance in insecticide resistance management. After the occurrence of imidacloprid resistance, the brown planthopper (BPH) has gradually developed resistance to thiamethoxam and clothianidin since 2010, but not to dinotefuran and nitenpyram. Here, we analyzed susceptibilities data of five neonicotinoids during 2005–2017 in East Asia and Vietnam to conduct cross‐resistance patterns among neonicotinoids. To determine the factors of development of cross resistance in laboratory bioassays, we used the imidacloprid resistant and control strains that were selected from filed populations in the Philippines and Vietnam. RESULTS: The Linear Mixed Models (LMM) analyses of insecticide susceptibility data showed that the slope values of imidacloprid resistance effects were 0.68 and 1.09 for resistance to thiamethoxam and clothianidin, respectively. Laboratory bioassay results showed that the LD50 values for thiamethoxam and clothianidin in resistant strains (1.4–5.5 μg g−1) were 3.2–16.4 times higher than those in the control strains (0.28–1.5 μg g−1). However, the increase in the LD50 values for imidacloprid was not related to that for dinotefuran and nitenpyram based on the results of the LMM analysis and laboratory bioassay. CONCLUSION: Our results demonstrate that the development of imidacloprid resistance result in strong‐cross resistance to some neonicotinoids, thiamethoxam and clothianidin, but not to others, dinotefuran and nitenpyram. We anticipate that our findings will be a starting point for understanding mechanism of the different trend of cross resistance by analyzing long‐term susceptibility data and laboratory bioassays in insect pests. © 2019 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2020

33. Low-Dose Insecticide Combinations for Colorado Potato Beetle Control

Author

Renata Bažok, Jamie O’Keeffe, Ivana Jurada, Zrinka Drmić, Martina Kadoić Balaško, and Maja Čačija

Subjects

biological control, Leptinotarsa decemlineata Say, insecticide resistance management, reduced-risk insecticides, integrated pest management (IPM), Agriculture (General), S1-972

Abstract

Colorado potato beetle (CPB) is the most notorious and problematic insect defoliator pest of potato. It is well known for its ability to develop resistance to chemical insecticides, so novel treatment methods must be developed. A possible solution is the application of newer groups of insecticides (biotechnical and biological insecticides) which are more selective and to which resistance has not yet been recorded. This work investigated the use of ecologically acceptable insecticide treatments: azadirachtin, spinosad and spinetoram, and their combinations against CPB larvae in laboratory and field conditions. Reduced dosing and combinational treatments were used to determine if effective protection against CPB could be achieved while also improving economic results. Our results from laboratory trials showed that combinations of low-dose azadirachtin (25%) and low-dose spinetoram (5%) are suitable for use in CPB integrated pest management. The results of the field trial showed that the use of 50% reduced dosage of spinosad and spinetoram resulted in high efficacy (89–99%) and can be recommended as a treatment method that provides effective control of CPB, improved economic results, and a positive environmental impact. Based on the advantages that these treatments offer compared to chemical insecticides, further work is recommended to determine if these combinational treatments used in other dosages or in combinations with some other ecologically acceptable insecticides can provide satisfactory control of CPB.

Published

2021

34. Review and Meta-Analysis of the Evidence for Choosing between Specific Pyrethroids for Programmatic Purposes

Author

Natalie Lissenden, Mara D. Kont, John Essandoh, Hanafy M. Ismail, Thomas S. Churcher, Ben Lambert, Audrey Lenhart, Philip J. McCall, Catherine L. Moyes, Mark J. I. Paine, Giorgio Praulins, David Weetman, and Rosemary S. Lees

Subjects

pyrethroid, pyrethroid resistance, insecticide resistance, insecticide resistance management, vector control, malaria, Science

Abstract

Pyrethroid resistance is widespread in malaria vectors. However, differential mortality in discriminating dose assays to different pyrethroids is often observed in wild populations. When this occurs, it is unclear if this differential mortality should be interpreted as an indication of differential levels of susceptibility within the pyrethroid class, and if so, if countries should consider selecting one specific pyrethroid for programmatic use over another. A review of evidence from molecular studies, resistance testing with laboratory colonies and wild populations, and mosquito behavioural assays were conducted to answer these questions. Evidence suggested that in areas where pyrethroid resistance exists, different results in insecticide susceptibility assays with specific pyrethroids currently in common use (deltamethrin, permethrin, α-cypermethrin, and λ-cyhalothrin) are not necessarily indicative of an operationally relevant difference in potential performance. Consequently, it is not advisable to use rotation between these pyrethroids as an insecticide-resistance management strategy. Less commonly used pyrethroids (bifenthrin and etofenprox) may have sufficiently different modes of action, though further work is needed to examine how this may apply to insecticide resistance management.

Published

2021

35. Monitoring Resistance of Euschistus heros (Fabricius) (Hemiptera: Pentatomidae) to Insecticides by Using Encapsulated Artificial Diet Bioassay

Author

Cristiane Maria Tibola, Leandro Silva, Fernanda Sgubin, and Celso Omoto

Subjects

Euschistus heros, bioassay, Neotropical brown stink bug, insecticide resistance management, IRM, Science

Abstract

The novel ingestion bioassay method was developed for detecting and monitoring resistance of Euschistus heros by encapsulating an artificial liquid diet using Parafilm®. This methodology was compared with the tarsal contact (vial test) and topical application methods for thiamethoxam, imidacloprid, and lambda-cyhalothrin. The best bioassay method for the neonicotinoid insecticides thiamethoxam and imidacloprid was ingestion. For pyrethroid insecticide lambda-cyhalothrin, the best result was obtained by topical application. Using the best bioassay method for each insecticide, the susceptibility to these insecticides was monitored in 30 populations of E. heros collected from soybean crops in Brazil from 2018 to 2020. High variations in susceptibility to thiamethoxam (resistance ratios, 1.6–22 times), imidacloprid (resistance ratios, 1.6–22 times), and lambda-cyhalothrin (resistance ratios, 5–40 times) were detected among the evaluated E. heros populations. In order to monitor the susceptibility of E. heros to insecticides, diagnostic concentrations were defined based on the LC99 of the susceptible reference population: 5.65 µL of a.i./mL for thiamethoxam, 12.45 µL of a.i./mL for imidacloprid, and 0.20 µg of a.i./insect for lambda-cyhalothrin. Subsequently, we select an E. heros strain resistant to neonicotinoid insecticides and another to lambda-cyhalothrin. The resistance ratios obtained after seven selection cycles were 66, 41 and 44 times for thiamethoxam, imidacloprid and lambda-cyhalothrin, respectively.

Published

2021

36. Trapping and killing performance of a PermaNet 2.0 hybrid mosquito trapping bednet: an experimental hut evaluation.

Author

Mouhamadou CS, Kouadio FA, Sadia CG, and Behi FK

Abstract

Background: Despite the huge global effort , there has been an increase in malaria morbidity and mortality in sub-Saharan Africa since 2015, from 212 million cases and 429,000 deaths in 2015 to 241 million cases and 627,000 deaths in 2020 mainly because of resistance to insecticide. Therefore, advancing innovative approaches is the only sustainable way to fight malaria., Methods: Taking advantage of the behavior of mosquitoes around the net, which is almost 70-90% concentrated on the roof, we have developed a two-compartment mosquito bednet, the so-called T-Net for mass mosquito trapping and killing. In the current study, we investigated in an experimental hut trial, the efficacy of trapping-long-lasting insecticide-treated nets (T-LLINs) against Anopheles gambiae s.l. in an insecticide resistance context. Five different arms have been considered in this study including three positive control arms e.g. PermaNet 2.0 LLIN, Tsara boost LLIN and Interceptor generation 2 (IG2) LLIN), one negative control arm using insecticide-free bednet, and one candidate arm using a hybrid-treated trapping bednet made with PermaNet 2.0 LLIN mounted with an insecticide-free compartment (T-LLIN)., Results: The highest average daily mortality was recorded with the T-LLIN. In total, 678 mosquitoes were killed by T-LLIN among the 760 collected, i.e. 89.2%. Out of these, 317 were found in the trap compartment, representing 46.75% of mortality directly attributable to the mechanical effect of this net. This added value made it possible to quantify the increased in the killing effect that this net would have over the positive control arms: this would be 58.5% higher than the killing effect of PN2.0, 38% higher than that of Tsara boost and 31.5% higher than that of IG2., Conclusion: The current study shows potential to maximize the efficiency of the WHO-recommended LLINs by an addition of an insecticide-free trap compartment on top of the net., Competing Interests: No competing interests were disclosed., (Copyright: © 2024 Mouhamadou CS et al.)

Published

2024

37. INSECTICIDE RESISTANCE MANAGEMENT STRATEGY FOR Aedes aegypti L. AND Anopheles gambiae G. THROUGH PREDICTION OF POTENTIAL CHORION PEROXIDASE INHIBITORS USING COMPUTER AIDED DRUG DESIGNING APPROACH (CAAD).

Author

Yousafi, Qudsia, Anwar, Hafsa, Rashid, Hamid, Ali, Qurban, Khan, Muhammad Saad, Mehmood, Asim, Saleem, Shahzad, Sajid, Muhammad Wasim, Irfan, Rida, and Masroor, Ashir

Subjects

*MOSQUITO vectors, *AEDES aegypti, *ANOPHELES gambiae, *INSECTICIDE resistance, *COMPUTER-aided design, *CHORION

Abstract

Mosquitoes, Aedes aegypti L. and Anopheles gambiae G. are very important insect vectors for transmission of infectious diseases like dengue and malaria. Extensive use of insecticides provided rapid control of these insect vectors but gradually they have developed insecticide resistance. Target site insensitivity is one the main reasons for insecticide resistance development. Development of new insecticides targeting different target sites can be a useful approach for management of insecticide resistance in insect pests. Chorion peroxidase inhibitors have been predicted by using computer aided drug designing (CAAD) approach. 3D structure of chorion peroxidase of A. aegypti and A. gambiae was predicted by using I-TASSER and refined by 3Drefine and GalaxyWEB servers. Ligand binding sites were predicted by using 3DLigandSite, RaptorX and COACH servers. Ligands/Inhibitor compounds were obtained from literature and drug bank. Protein-ligand docking was performed by AutoDock Vina. The compounds with low binding energy and good interactions were selected for both species. Pharmacophore models were generated by using LigandScout. Screening of zinc library was performed against the features of designed pharmacophores. Top ten compounds with best pharmacophore fit score for each species were selected for docking with chorion peroxidase. Protein ligand interactions were determined through LIGPLOT. One lead compound showing lowest binding energy and best interactions was selected for each species, i.e., ZINC04581496 (A. aegypti) and ZINC15675298 (A. gambiae). Protein-Protein interaction was studied by STRING database to find the co-expressing proteins in network of chorion peroxidase. Ten interaction partners were found for A. aegypti while five for A. gambiae. These pharmacophore models may provide theoretical basis for designing effective insecticides for A. aegypti and A. gambiae control. The efficacy of computationally predicted lead molecules can be confirmed by testing in vitro and in vivo. [ABSTRACT FROM AUTHOR]

Published

2019

38. Stability of neonicotinoid sensitivity in Frankliniella fusca populations found in agroecosystems of the southeastern USA.

Author

Chappell, Thomas M, Huseth, Anders S, and Kennedy, George G

Subjects

TOBACCO thrips, NEONICOTINOIDS, AGRICULTURAL ecology, IMIDACLOPRID, INSECTICIDE resistance, THIAMETHOXAM, COLE crops

Abstract

BACKGROUND Insecticide resistance arises at a given location in response to selection acting on novel genotypes or standing variation, or allelic migration. Fitness costs of resistance may slow resistance evolution or result in reversion to susceptibility, but consistent and geographically widespread use of insecticides may provide sufficient selection to offset the fitness costs of resistance. Understanding this relationship is important to the success of insecticide resistance management. We report the existence of fitness costs of neonicotinoid resistance in field‐collected populations of the tobacco thrips (Frankliniella fusca), which increasingly challenge upland cotton production in the southeastern USA. RESULTS: Populations (14 of 15 in 2015; 4 of 5 in 2016) investigated showed a loss of resistance to imidacloprid after multiple generations without exposure to the insecticide. Populations studied in 2016 were each split into two colonies, and one of each pair was repeatedly exposed to imidacloprid. In three of the four populations that lost resistance, imidacloprid‐exposed colonies lost resistance significantly more slowly than did corresponding unexposed colonies. CONCLUSION: For imidacloprid resistance to be broadly increasing in the landscapes of the southeastern USA despite fitness costs of resistance, selection for resistance must be sufficient to overcome the costs. Findings encourage investigation into why costs are overcome in this system, potentially including geographic extent of neonicotinoid use or prevalence of low‐dose exposure. © 2019 Society of Chemical Industry [ABSTRACT FROM AUTHOR]

Published

2019

39. Compatibility of entomopathogenic fungi with insecticides and their efficacy for IPM of Bemisia tabaci in cotton.

Author

SAIN, Satish Kumar, MONGA, Dilip, KUMAR, Rishi, NAGRALE, Dipak T., HIREMANI, Neelakanth S., and KRANTHI, Sandhya

Subjects

*SWEETPOTATO whitefly, *INTEGRATED pest control, *ENTOMOPATHOGENIC fungi, *INSECTICIDES, *BOTANICAL insecticides, *PHYTOCHEMICALS

Abstract

Bemisia tabaci, a vector of cotton leaf curl virus disease, is among the most devastating pests causing huge economic losses due to reduced cotton yield and quality. The excessive use of chemical pesticides causes insecticide resistance. Entomopathogenic fungi (EPFs) have a role as mycoinsecticides. The combined use of these insecticides is a promising pest-control option to minimize adverse chemical effects. Thus, we have evaluated 10 EPFs under polyhouse conditions for their virulence against whitefly nymphs and their compatibility with chemical and botanical insecticides. The highest overall biological efficacy index was recorded with Ij-102, followed by Bb-4511, and Ij-089. An in vitro compatibility study was conducted to evaluate the effect of botanical and chemical pesticides on mycelial growth and spore production using the poisoned food technique. The effect of pesticides on the reduction of mycelial growth and conidial production ranged from -169 to 94.1% and -25.6 to 87.6%, respectively. However, Ij-089, Ij-102, Ma-1299, and Bb-4511 were found to be the most compatible with the chemical and botanicals evaluated. Comparatively, spiromesifen, diafenthiuron, buprofezin, pyriproxyfen, and flonicamid were more compatible with EPFs at half doses, as compared to the other chemical pesticides, namely imidacloprid, fipronil, profenophos, and triazophos. These results might provide the basis for future work and indicate that applications of EPFs showing the best virulence and compatibility have the maximum likelihood for the management of B. tabaci in the field in an integrated pest management system. [ABSTRACT FROM AUTHOR]

Published

2019

40. Residual toxicity of insecticides used against the Asian citrus psyllid and resistance management strategies with thiamethoxam and abamectin.

Author

Vanaclocha, Pilar, Jones, Moneen M., Tansey, James A., Monzó, César, Chen, Xulin, and Stansly, Philip A.

Subjects

*THIAMETHOXAM, *INSECTICIDES, *CITRUS greening disease, *ABAMECTIN, *CITRUS, *DIMETHOATE, *INSECTICIDE resistance

Abstract

The Asian citrus psyllid (ACP) is the key pest of citrus due to its role as vector of huanglongbing. ACP control mostly relies on frequent insecticide applications therefore increasing selection for insecticide resistance. Optimization of field application rates and rotation of insecticide modes of action (MoA) would minimize this risk. Baseline toxicity responses of ACP to commonly used insecticides provide a basis for defining application field rates and are thus needed to track potential development of resistance. Residual toxicities of 12 insecticides were evaluated through quantal response bioassays. The development of ACP resistance in response to monthly applications of two insecticides with different MoAs, abamectin and thiamethoxam, applied separately, in rotation or as mixtures was also tested. Highest residual toxicities were found for the abamectin + thiamethoxam mixture. In general, nymphs were more sensitive than adults to residues. Nymphs were 10 and 28 times more sensitive than adults to residues of thiamethoxam and imidacloprid, respectively. We found a wide range among ratios of maximum label field concentrations and estimated LC90s. Highest label rates for malathion and dimethoate were more than 30 times greater than LC90s, in contrast to abamectin, zeta-cypermethrin and fenpyroximate which were 4-7 times lower. Abamectin appeared to synergize the mixture of it with thiamethoxam. We observed resistance to both active ingredients, especially abamectin, after 8 months of sequential applications of both insecticides individually or in mixture. Rapid resistance development of the mixture relative to rotation was attributed to loss of the synergetic effect of abamectin on thiamethoxam. [ABSTRACT FROM AUTHOR]

Published

2019

41. Baseline Susceptibility of Spodoptera frugiperda (Lepidoptera: Noctuidae) to SfMNPV and Evaluation of Cross-Resistance to Major Insecticides and Bt Proteins.

Author

Bentivenha, José P F, Rodrigues, Juliana G, Lima, Marcelo F, Marçon, Paula, Popham, Holly J R, and Omoto, Celso

Subjects

FALL armyworm, INSECTICIDE resistance, BACTERIAL proteins

Abstract

The resistance evolution of Spodoptera frugiperda (J.E. Smith) to insecticides and Bt proteins along with the intensive crop production systems adopted in Brazil make it challenging to implement integrated pest management. The adoption of alternative methods to manage pests is fundamental to the implementation of favorable integrated pest management and insect resistance management. Spodoptera frugiperda multiple nucleopolyhedrovirus (SfMNPV) is a valuable tool for S. frugiperda control. The characterization of the baseline susceptibility of S. frugiperda populations and cross-resistance involving SfMNPV and major insecticides and Bt proteins have not yet been conducted. The objective of this study was to characterize the baseline susceptibility of S. frugiperda populations from five Brazilian States to SfMNPV (Cartugen, AgBiTech, Fort Worth, TX). Possible cross-resistance to insecticides and Bt proteins among resistant S. frugiperda strains was also assessed. There were no differences in the susceptibility of the studied populations to SfMNPV. The estimated diagnostic concentration may be utilized in future monitoring studies to SfMNPV. The SfMNPV presented no cross-resistance to the chemical insecticides and to the Bt proteins tested. Our results provide evidence of the biological activity and high potential of SfMNPV as a distinct insecticidal mode of action for use in rotation with other tools. This biological insecticide is known to have a favorable toxicological and ecotoxicological profile and will be a valuable tool in insect resistance management and integrated pest management programs for control of S. frugiperda. [ABSTRACT FROM AUTHOR]

Published

2019

42. Exploring lethal and sublethal effects of conventional insecticides and insect growth regulators on a picture-winged fly (Diptera: Ulidiidae) pest of sweet corn.

Author

Schwan Resende, Eric, Beuzelin, Julien M., Dunkley, Victoria E., Paula-Moraes, Silvana V., Seal, Dakshina R., and Nuessly, Gregg S.

Subjects

INSECT growth regulators, PYRETHROIDS, INSECTICIDES, SWEET corn, CORN pests, DIPTERA, CLOTHIANIDIN

Abstract

Picture-winged flies (Diptera: Ulidiidae) known as corn silk flies are intensively managed with pyrethroids in fresh market sweet corn, Zea mays L., grown in Florida. The identification of alternatives to pyrethroids is needed to increase the efficacy of insecticidal management and to allow the rotation of modes of action for insecticide resistance management (IRM). This laboratory study determined the lethal and sublethal effects of six pyrethroids, five neonicotinoids, four insect growth regulators, two diamides, one spinosyn, one avermectin, and one oxadiazine on adults of the corn silk fly, Euxesta eluta Loew, following topical or ingestion exposure. For topical exposure, pyrethroids caused the highest mortality (≥89%), followed by spinetoram (50%), whereas the remaining insecticides caused <15% mortality. For ingestion exposure, spinetoram caused 95% mortality, followed by dinotefuran, clothianidin, and thiamethoxam, which caused ≥74% mortality. The further evaluation of insecticides causing <15% mortality showed that topical exposure to abamectin reduced by 61.5% the fertility of E. eluta females expressed as the number of larvae per cumulative female-day. None of the insecticides causing <15% mortality following ingestion exposure affected E. eluta fertility. This study confirms that pyrethroids represent the main commercial insecticide option for effective foliar applications targeting adult corn silk flies. Potential alternatives to pyrethroids were highly effective only through ingestion exposure, suggesting the need for the development of management tactics promoting ingestion of insecticides. This study complements pyrethroid susceptibility monitoring for the development of an IRM program in Florida sweet corn. [Display omitted] • Pyrethroids caused high mortality in Euxesta eluta adults via topical exposure. • Spinetoram and selected neonicotinoids were highly effective only via ingestion. • Tactics promoting insecticide ingestion are needed against corn silk flies. [ABSTRACT FROM AUTHOR]

Published

2023

43. The effectiveness of non-pyrethroid insecticide-treated durable wall lining to control malaria in rural Tanzania: study protocol for a two-armed cluster randomized trial

Author

George Mtove, Joseph P. Mugasa, Louisa A. Messenger, Robert C. Malima, Peter Mangesho, Franklin Magogo, Mateusz Plucinski, Ramadhan Hashimu, Johnson Matowo, Donald Shepard, Bernard Batengana, Jackie Cook, Basiliana Emidi, Yara Halasa, Robert Kaaya, Aggrey Kihombo, Kimberly A. Lindblade, Geofrey Makenga, Robert Mpangala, Abraham Mwambuli, Ruth Mzava, Abubakary Mziray, George Olang, Richard M. Oxborough, Mohammed Seif, Edward Sambu, Aaron Samuels, Wema Sudi, John Thomas, Sophie Weston, Martin Alilio, Nancy Binkin, John Gimnig, Immo Kleinschmidt, Peter McElroy, Lawrence H. Moulton, Laura Norris, Trenton Ruebush, Meera Venkatesan, Mark Rowland, Franklin W. Mosha, and William N. Kisinza

Subjects

Insecticide-treated wall lining, Long-lasting insecticidal nets, Malaria control, Cluster randomized controlled trial, Entomological inoculation rate, Insecticide resistance management, Public aspects of medicine, RA1-1270

Abstract

Abstract Background Despite considerable reductions in malaria achieved by scaling-up long-lasting insecticidal nets (LLINs) and indoor residual spraying (IRS), maintaining sustained community protection remains operationally challenging. Increasing insecticide resistance also threatens to jeopardize the future of both strategies. Non-pyrethroid insecticide­treated wall lining (ITWL) may represent an alternate or complementary control method and a potential tool to manage insecticide resistance. To date no study has demonstrated whether ITWL can reduce malaria transmission nor provide additional protection beyond the current best practice of universal coverage (UC) of LLINs and prompt case management. Methods/design A two-arm cluster randomized controlled trial will be conducted in rural Tanzania to assess whether non-pyrethroid ITWL and UC of LLINs provide added protection against malaria infection in children, compared to UC of LLINs alone. Stratified randomization based on malaria prevalence will be used to select 22 village clusters per arm. All 44 clusters will receive LLINs and half will also have ITWL installed on interior house walls. Study children, aged 6 months to 11 years old, will be enrolled from each cluster and followed monthly to estimate cumulative incidence of malaria parasitaemia (primary endpoint), time to first malaria episode and prevalence of anaemia before and after intervention. Entomological inoculation rate will be estimated using indoor CDC light traps and outdoor tent traps followed by detection of Anopheles gambiae species, sporozoite infection, insecticide resistance and blood meal source. ITWL bioefficacy and durability will be monitored using WHO cone bioassays and household surveys, respectively. Social and cultural factors influencing community and household ITWL acceptability will be explored through focus-group discussions and in-depth interviews. Cost-effectiveness, compared between study arms, will be estimated per malaria case averted. Discussion This protocol describes the large-scale evaluation of a novel vector control product, designed to overcome some of the known limitations of existing methods. If ITWL is proven to be effective and durable under field conditions, it may warrant consideration for programmatic implementation, particularly in areas with long transmission seasons and where pyrethroid-resistant vectors predominate. Trial findings will provide crucial information for policy makers in Tanzania and other malaria-endemic countries to guide resource allocations for future control efforts. Trial registration NCT02533336 registered on 13 July 2014.

Published

2016

44. Comparison of Toxicological Bioassays for Whiteflies

Author

Tanner C. Sparks, David G. Riley, Alvin M. Simmons, and Liangzhen Guo

Subjects

Bemisia tabaci, bioassay, insecticide resistance management, IRM, toxicology, Science

Abstract

Two Bemisia tabaci populations from Georgia and Florida, USA, were tested for their response to insecticides across different toxicological bioassay methods. Five insecticides in four Insecticide Resistance Action Committee (IRAC) groups (imidacloprid (4A), dinotefuran (4A), flupyradifurone (4D), pyriproxyfen (7C) and cyantraniliprole (28)), were evaluated against a water check. The routes of application to the plant used were either leaf drench or (systemic) root drench. The four different whitefly bioassay methodologies tested were two published IRAC methods, a clip cage method, and a new tube method. A split–split experimental design was used to assess any interactions between application route, bioassay method and insecticide treatment. Application route had no significant effect on efficacy. However, bioassay method affected overall whitefly mortality, with the dish method having reduced mortality compared to other methods, except for the clip cage method. High rates of cyantraniliprole, dinotefuran and flupyradifurone insecticides resulted in the highest incidence of adult whitefly mortality. Significant interactions relative to percent adult mortality were found between the insecticide and bioassay method for both populations assayed. The clip cage method was more sensitive in terms of dose mortality response followed by the cup and tube methods. The dish method was the least responsive to insecticide dose. Other interactions are discussed.

Published

2020

45. Time for a New Look at the Relationship Between Bt Plants and Insect Natural Enemies

Author

Chen, Mao, Shelton, Anthony M., Liu, Tongxian, editor, and Kang, Le, editor

Published

2011

46. Do bednets including piperonyl butoxide offer additional protection against populations of Anopheles gambiae s.l. that are highly resistant to pyrethroids? An experimental hut evaluation in Burkina Fasov.

Author

Toe, K. H., Müller, P., Badolo, A., Traore, A., Sagnon, N., Dabiré, R. K., and Ranson, H.

Subjects

*INSECTICIDE resistance, *PYRETHROIDS, *PIPERONYL butoxide, *MOSQUITO vectors, *ANOPHELES gambiae

Abstract

Malaria control is dependent on the use of longlasting insecticidal nets (LLINs) containing pyrethroids. A new generation of LLINs containing both pyrethroids and the synergist piperonyl butoxide (PBO) has been developed in response to increasing pyrethroid resistance in African malaria vectors, but questions remain about the performance of these nets in areas where levels of pyrethroid resistance are very high. This study was conducted in two settings in southwest Burkina Faso, Vallée du Kou 5 and Tengrela, where Anopheles gambiae s.l. (Diptera: Culicidae) mortality rates in World Health Organization (WHO) discriminating dose assays were < 14% for permethrin and < 33% for deltamethrin. When mosquitoes were pre‐exposed to PBO in WHO tube assays, mortality rates increased substantially but full susceptibility was not restored. Molecular characterization revealed high levels of kdr alleles and elevated levels of P450s previously implicated in pyrethroid resistance. In cone bioassays and experimental huts, PBO LLINs outperformed the pyrethroid‐only equivalents from the same manufacturers. Blood feeding rates were 1.6–2.2‐fold lower and mortality rates were 1.69–1.78‐fold greater in huts with PBO LLINs vs. non‐PBO LLINs. This study indicates that PBO LLINs provide greater personal and community‐level protection than standard LLINs against highly pyrethroid‐resistant mosquito populations. Pyrethroid‐treated nets are widely used to prevent malaria transmission, but resistance to these insecticides is now widespread in African malaria vectors.Nets containing the pyrethroid synergist piperonyl butoxide (PBO) are available, but the relative performance of standard vs. PBO‐impregnated nets has not been assessed in different settings.This study shows that PBO‐treated nets increase mosquito mortality and reduce blood feeding success in an area in which the mosquito population is extremely resistant to pyrethroids. [ABSTRACT FROM AUTHOR]

Published

2018

47. Insights from agriculture for the management of insecticide resistance in disease vectors.

Author

Sternberg, Eleanore D. and Thomas, Matthew B.

Subjects

*INSECTICIDE resistance, *MALARIA prevention, *INSECT pest control, *INFECTIOUS disease transmission, *PUBLIC health

Abstract

Abstract: Key to contemporary management of diseases such as malaria, dengue, and filariasis is control of the insect vectors responsible for transmission. Insecticide‐based interventions have contributed to declines in disease burdens in many areas, but this progress could be threatened by the emergence of insecticide resistance in vector populations. Insecticide resistance is likewise a major concern in agriculture, where insect pests can cause substantial yield losses. Here, we explore overlaps between understanding and managing insecticide resistance in agriculture and in public health. We have used the Global Plan for Insecticide Resistance Management in malaria vectors, developed under the auspices of the World Health Organization Global Malaria Program, as a framework for this exploration because it serves as one of the few cohesive documents for managing a global insecticide resistance crisis. Generally, this comparison highlights some fundamental differences between insect control in agriculture and in public health. Moreover, we emphasize that the success of insecticide resistance management strategies is strongly dependent on the biological specifics of each system. We suggest that the biological, operational, and regulatory differences between agriculture and public health limit the wholesale transfer of knowledge and practices from one system to the other. Nonetheless, there are some valuable insights from agriculture that could assist in advancing the existing Global Plan for Insecticide Resistance Management framework. [ABSTRACT FROM AUTHOR]

Published

2018

48. IPM and Insect-Protected Transgenic Plants: Thoughts for the Future

Author

Shelton, Anthony M., Romeis, Jörg, Kennedy, George G., Romeis, Jörg, editor, Shelton, Anthony M., editor, and Kennedy, George G., editor

Published

2008

49. Optimal rotation of insecticides to prevent the evolution of resistance in a structured environment

Author

Kohji Yamamura

Subjects

Resistance (ecology), Agricultural engineering, Insecticide resistance management, Biology, Rotation, Ecology, Evolution, Behavior and Systematics

Published

2021

50. Insecticide Control of Drosophila suzukii in Commercial Sweet Cherry Crops under Cladding

Author

Bethan Shaw, Sebastian Hemer, Madeleine F. L. Cannon, Francesco Rogai, and Michelle T. Fountain

Subjects

exclusion mesh, integrated pest management, insecticide resistance management, Prunus avium, spotted wing drosophila, Science

Abstract

Drosophila suzukii Matsumura is a damaging invasive pest of sweet cherry. Using a series of laboratory leaf contact assays, semi-field, and orchard spray programs we aimed to determine the impact of insecticide programs on D. suzukii adult mortality and oviposition in cladding-protected sweet cherry crops. Tests included assessing adult D. suzukii mortality after contact with leaves sprayed either one or two weeks previously and emergence of adults from fruits. Spinosad, lambda-cyhalothrin, acetamiprid, lime, pyrethrin, deltamethrin, and cyantraniliprole all reduced fruit damage up to day 7 after application. Of these active ingredients, only spinosad, lambda-cyhalothrin, and cyantraniliprole gave satisfactory control up to 14 days. There was no significant difference in D. suzukii mortality when exposed to leaves treated either one or two weeks previously with an application of either spinosad, cyantraniliprole, or lambda-cyhalothrin; however, mortality was significantly higher than D. suzukii in contact with untreated leaves. In eight commercial orchards, fortnightly spray applications including spinosad, cyantraniliprole, and lambda-cyhalothrin gave effective control of D. suzukii until harvest with very few damaged fruits. These experiments demonstrate that currently approved plant protection products, applied to sweet cherry under protection, give at least two weeks protection from D. suzukii.

Published

2019