Assessment of the effects of lethal and sublethal exposure to dinotefuran on the wheat aphid Rhopalosiphum padi (Linnaeus).

The wheat aphid Rhopalosiphum padi (Linnaeus) (Hemiptera: Aphididae) is a devastating pest of wheat crops worldwide. Dinotefuran, a novel neonicotinoid insecticide, has been used to prevent piercing-sucking agricultural insects, such as R. padi. This research showed that the dinotefuran not only caused direct mortality but also affected the physiology of R. padi via sublethal effects. In this study, residual film bioassay results indicated that there were no significant differences in the toxicity of dinotefuran between field in 2017 and laboratory strains. However, the longevity, fecundity and female preoviposition of the F0 generation were significantly decreased by exposure to different sublethal doses (L10, L20 and L30) of dinotefuran. In contrast, the fecundity and female preoviposition of the F1 generation were significantly increased by the sublethal treatment L20, although this dose reduced net reproductive rate, intrinsic rate of increase and finite rate of increase. These findings are the first laboratory evidence of hormesis attributable to low dinotefuran doses. Developmental duration of nymphs was significantly increased by the sublethal doses L20 and L30 but not L10. Sublethal exposure to dinotefuran can increase the transgenerational population growth of R. padi and affected demographic parameters of the target insect. This study provides useful data for developing management strategies for R. padi involving the use of dinotefuran.

Genome Analysis of Cytochrome in Dinotefuran-Treated Apolygus lucorum (Meyer-Dür).

In this study, two CYP genes, CYP395G1 and CYP4EY1, were analyzed in Apolygus lucorum (Hemiptera: Miridae). The expression pattern in different developmental stages of both CYP395G1 and CYP4EY1 revealed that first instar nymphs possessed the highest gene-transcript levels. After 12 h of dinotefuran treatments, the expression levels of CYP395G1 increased by 1.92-fold, while the CYP4EY1 expression decreased. It was observed that the sensitivities of dinotefuran to laboratory strains from F0 to F9 and the mRNA expression levels of CYP395G1 in the F9 dinotefuran selected strain were higher when compared to the control strain. The results suggest that CYP395G1 was possibly a candidate P450 that was involved in dinotefuran detoxification. The dinotefuran resistant strain of A. lucorum was difficult to increase, due to its special molecular structure of dinotefuran compared with other neonicotinoids.

Molecular characterization and functional expression of voltage-gated sodium channel variants in Apolygus lucorum (Meyer-Dür).

BACKGROUND: Apolygus lucorum (Meyer-Dür) is a serious worldwide agricultural pest, especially for Bt cotton in China. Pyrethroids, neonicotinoids and organophosphates are the most effective insecticides to control piercing and sucking insects, including A. lucorum. The voltage-gated sodium channel (Nav ) is major target site of pyrethroids. Extensive alternative splicing and RNA editing, two major post-transcriptional mechanisms, contribute to generate different functional sodium channel variants. In our research, we characterized the sodium channel variants of A. lucorum. RESULTS: In this study, we isolated numerous sodium channel variants that cover the entire coding region of the VGSC gene from A. lucorum. All clones could be grouped into 47 splice types based on the presence of nine alternative exons (exons j, n, o, a, p, b, s, q and t). Exons j, b and t were located independently, while exons n, o, a and p were located adjacently, as were exons s and q. We also found 35 nucleotide changes in different positions in individual variants, of which 18 nucleotide changes were A-to-I RNA editing, 11 nucleotide changes were likely due to U-to-C or C-to-U editing, and the others were likely natural sequence polymorphisms in the population. Furthermore, we expressed all of the variants in Xenopus oocytes. Eighteen of them were expressed in oocytes and sensitive to tetrodotoxin. CONCLUSION: Our results provide a functional basis for understanding how A. lucorum sodium channel variants work in regulating channel expression, pharmacology and gating properties for agricultural insects. Apolygus lucorum is widely distributed in cotton production. Our results suggest how AlNav (the sodium channel of A.lucorum) variants work in regulating channel expression, pharmacology and sodium channel gating for agricultural insects in the future. © 2020 Society of Chemical Industry.