Functional analysis of Ornithine decarboxylase in manipulating the wing dimorphism in Nilaparvata lugens (Stål) (Hemiptera: Delphacidae).

The brown planthopper (BPH, Nilaparvata lugens), a major insect pest of rice, can make a shift in wing dimorphism to adapt to complex external environments. Our previous study showed that NlODC (Ornithine decarboxylase in N. lugens) was involved in wing dimorphism of the brown planthopper. Here, further experiments were conducted to reveal possible molecular mechanism of NlODC in manipulating the wing dimorphism. We found that the long-winged rate (LWR) of BPH was significantly reduced after RNAi of NlODC or injection of DFMO (D, L-α-Difluoromethylornithine), and LWR of males and females significantly decreased by 21.7% and 34.6%, respectively. Meanwhile, we also examined the contents of three polyamines under DFMO treatment and found that the contents of putrescine and spermidine were significantly lower compared to the control. After 3rd instar nymphs were injected with putrescine and spermidine, LWR was increased significantly in both cases, and putrescine was a little bit more effective, with 5.6% increase in males and 11.4% in females. Three days after injection of dsNlODC, injection of putrescine and spermidine rescued LWR to the normal levels. In the regulation of wing differentiation in BPH, NlODC mutually antagonistic to NlAkt may act through other signaling pathways rather than the classical insulin signaling pathway. This study illuminated a physiological function of an ODC gene involved in wing differentiation in insects, which could be a potential target for pest control.

sgRNA structure optimization and PTG/Cas9 system synergistically boost gene knockout efficiency in an insect.

Knockouts mediated by CRISPR/Cas9 technology are widely used to study insect gene functions, but the efficiency in Hemiptera is low. New strategies are urgently needed to improve gene knockout efficiency. This study initially explored the impact of modifying the fundamental backbone structure of single guide RNA (sgRNA) on knockout efficiency. The results indicated that both in vitro and in vivo transcription of sgRNA structures (Loop5bp + MT/C type) increased average knockout efficiency by 0.61-fold compared to the original sgRNA. In addition, the PTG/Cas9 system was observed to induce a 0.64-fold increase in average knockout efficiency using the original sgRNA. Notably, an integrated PTG/Cas9 system (iPTG/Cas9 system), the integration of optimized sgRNA structures (Loop5bp + MT/C type) into the conventional PTG/Cas9 system, demonstrated a synergistic effect, resulting in a 1.45-fold increase in average knockout efficiency compared to the original sgRNA structure. The iPTG/Cas9 system was effectively used to simultaneously knockout two different target sites within a single gene and to co-knockout two genes. This study represents the first application of the iPTG/Cas9 system to establish a double knockout system in Hemiptera, offering a promising approach to enhance knockout efficiency in species with low efficiency and improve genetic manipulation tools for pest control.