Cylas formicarius is one of the most important pests of sweet potato worldwide, causing considerable ecological and economic damage. To improve the effect of comprehensive management and understanding of genetic mechanisms, the genetic functions of C. formicarius have been the subject of intensive study. Using Illumina and PacBio sequencing, we obtained a chromosome-level genome assembly of adult weevils from lines inbred for 15 generations. The high-quality assembly obtained had a size of 338.84 Mb, with contig and scaffold N50 values of 14.97 Mb and 34.23 Mb, respectively. In total, 157.51 Mb of repeat sequences and 11,907 protein-coding genes were predicted. A total of 337.06 Mb of genomic sequences was located on the 11 chromosomes, and the sequence length that could be used to determine the sequence and direction accounted for 99.03% of the total length of the associated chromosome. Comparative genomic analysis showed that C. formicarius was sister to Dendroctonus ponderosae, and C. formicarius diverged from D. ponderosae approximately 138.89 million years ago (Mya). Many important gene families that were expanded in the C. formicarius genome were involved in detoxification of pesticides, tolerance to cold stress and chemosensory system. In an in-depth study, the binding assay results indicated that CforOBP4-6 had strong binding affinities for sex pheromones and other ligands. Overall, the high-quality C. formicarius genome provides a valuable resource to reveal the molecular ecological basis, genetic mechanism, evolutionary process of major agricultural pests, new ideas and new technologies for ecologically sustainable pest control.

Cylas formicarius is one of the most important pests of sweet potato worldwide, causing considerable ecological and economic damage. To improve the effect of comprehensive management and understanding of genetic mechanisms, the genetic functions of C. formicarius have been the subject of intensive study. Using Illumina and PacBio sequencing, we obtained a chromosome-level genome assembly of adult weevils from lines inbred for 15 generations. The high-quality assembly obtained had a size of 338.84 Mb, with contig and scaffold N50 values of 14.97 Mb and 34.23 Mb, respectively. In total, 157.51 Mb of repeat sequences and 11,907 protein-coding genes were predicted. A total of 337.06 Mb of genomic sequences was located on the 11 chromosomes, and the sequence length that could be used to determine the sequence and direction accounted for 99.03% of the total length of the associated chromosome. Comparative genomic analysis showed that C. formicarius was sister to Dendroctonus ponderosae, and C. formicarius diverged from D. ponderosae approximately 138.89 million years ago (Mya). Many important gene families that were expanded in the C. formicarius genome were involved in the chemosensory system. In an in-depth study, the binding assay results indicated that CforOBP4-6 had strong binding affinities for sex pheromones and other ligands. Overall, the high-quality C. formicarius genome provides a valuable resource to reveal the molecular ecological basis, genetic mechanism and evolutionary process of major agricultural pests, deepen the understanding of environmental adaptability and apparent plasticity, and provide new ideas and new technologies for ecologically sustainable pest control.

High salinity is one of the major limiting factors that reduces crop productivity and quality. Herein, we report that small SALT TOLERANCE ENHANCER1 (STE1) protein without any known conserved domains is required for tomato salt tolerance. Overexpression (OE) of SlSTE1 enhanced the tolerance to multiple chloride salts (NaCl, KCl and LiCl) and oxidative stress, along with elevated antioxidant enzyme activities, increased ABA and chlorophyll contents, and reduced MDA and ROS accumulations compared to that of WT plants. Moreover, decreased K+ efflux and increased H+ efflux were detected in the OE plants, which induced a higher K+/Na+ ratio. In contrast, SlSTE1-RNAi plants displayed decreased tolerance to salt stress. RNA-seq data revealed 1330 DEGs in the OE vs WT plants under salt stress, and the transcription of numerous and diverse genes encoding TFs, stress-related proteins, secondary metabolisms, kinases and proteins related to hormone synthesis/signalling (notably ABA and ACC), etc. was greatly elevated. Furthermore, SlSTE1-OE plants showed increased sensitivity to ABA, and the results suggest that SlSTE1 promotes ABA-dependent salt stress-responsive pathways by interacting with SlPYLs and SlSnRK2s. Collectively, our findings reveal that the small SlSTE1 protein confers salt tolerance via ABA signalling and ROS scavenging and improves ion homeostasis in tomato.