How alien pests invade new areas has always been a hot topic in invasion biology. The spread of the Bactrocera dorsalis from southern to northern China involved changes in food sources. In this paper, in controlled conditions, we take Bactrocera dorsalis as an example to study how plant host transformation affects gut bacteria by feeding it its favorite host oranges in the south, its favorite host peaches and apples in the north, and feeding it cucumbers as a non-favorite host plant, thereby further affecting their fitness during invasion. The result showed that, after three generations of feeding on cucumbers, Bactrocera dorsalis took longer to develop as a larva while its longevity and fecundity decreased and pre-adult mortality increased. Feeding it cucumbers significantly reduced the overall diversity of gut microbiota of Bactrocera dorsalis. The relative abundance of Enterobacter necessary for survival decreased, while the Empedobacter and Enterococcus increased, resulting in decreased carbohydrate transport and metabolism and increased lipid transport and metabolism. Feeding Bactrocera dorsalis Empedobacter brevis and Enterococcus faecalis resulted in a 26% increase in pre-adult mortality and a 2-3 d increase in adult preoviposition period (APOP). Additionally, Enterococcus faecalis decreased the longevity of female and male adults by 17 and 12 d, respectively, and decreased fecundity by 11%. We inferred that the shifted plant hosts played an important role in posing serious harm to Bactrocera dorsalis invading from the south to the north. Therefore, after an invasion of Bactrocera dorsalis into northern China, it is difficult to colonize cucumbers for a long time, but there is still a risk of short-term harm. The findings of this study have established that the interactions between an insect\'s food source and gut bacteria may have an important effect on insect invasions.

The Oriental fruit fly, Bactrocera dorsalis (Hendel), is a highly invasive pest of quarantine importance affecting the global fruit trade. In managing B. dorsalis, methods like cultural, biological, chemical, sterile insect technique (SIT), and semiochemical-mediated attract-and-kill are in use with varying success. The SIT approach is the method of choice for a chemical-free, long-term suppression of B. dorsalis, followed in many countries across the globe. The nonspecific mutations caused by irradiation affect the overall fitness of flies, thus requiring a more precise method for a heritable, fitness-not-compromising approach. In this regard, CRISPR/Cas9-mediated genome editing enables the creation of mutations at the precise genomic location/s through RNA-guided dsDNA cleavage. Of late, DNA-free editing employing ribonucleoprotein complex (RNP) is preferred to validate the target genes at G0 stage embryos in insects. It requires characterizing genomic edits from adults after completing their life cycle, which may entail a few days to months, depending on longevity. Additionally, edit characterization is required from each individual, as edits are unique. Therefore, all RNP-microinjected individuals must be maintained until the end of their life cycle, irrespective of editing. To overcome this impediment, we predetermine the genomic edits from the shed tissues, such as pupal cases, to maintain only edited individuals. In this study, we have shown the utility of pupal cases from five males and females of B. dorsalis to predetermine the genomic edits, which corroborated the edits from the respective adults.