Project description:Ahamus jianchuanensis ghost moth transcriptome

Project description:Ghost moth infected with PH and OS

Project description:Transcriptome of ghost moth infected with fungi

Project description:RNA-seq for aggressive behavior in ghost moth

Project description:Himalaya v 292 Keywords: Mutant Analysis

Project description:16SV4 sequenceing for gut and hemolymph of ghost moth

Project description:ITS sequenceing for gut and hemolymph of ghost moth

Project description:To identify novel ghost factors regulating the expression of Interferon Stimulated Genes (ISGs), we conducted genome-wide cDNA screening in Huh-7 IFIT-1 Luc cells

Project description:Gut microbiota on Tibetan plateau and low-altitude aritificial rearing ghost moth

Project description:Plastics are highly stable materials with widespread applications, but their resistance to degradation poses a significant environmental challenge, often resulting in accumulation in landfills or pollution in the form of microplastics. Biodegradation using insect larvae has recently emerged as a promising strategy to address this issue, though the molecular basis of plastic degradation in these organisms remains poorly understood due to limited genomic resources. In this study, we present a complete genome of the lesser wax moth, Achroia grisella, and tissue-specific RNA-Seq data of both the lesser and the greater wax moth, Galleria mellonella, two species known to consume various plastics. Our analyses reveal several highly expressed secretory enzymes in gut and labial tissues. Orthologous comparisons of differentially expressed genes also identified five enzymes (three hexamerins and two monooxygenases) from the lesser wax moth that have been shown or are predicted to have plastic-degrading potential in the greater wax moth. We also identified enzymes that may potentially be involved in polyethylene and polystyrene degradation based on their identities with known bacterial enzymes that have been experimentally validated and are involved in plastic degradation pathways. Together, these genomic and transcriptomic resources provide a foundation for understanding plastic degradation in wax moths and highlight candidate genes for future functional validation.