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W2888821508 endingPage "1963" @default.
W2888821508 startingPage "1946" @default.
W2888821508 abstract "The sterile insect technique (SIT) as an eco-friendly and reliable strategy has been used to control populations of insect pests of agricultural, veterinary and human health importance. Successful applications of SIT rely on the high-level ecological fitness of sterile males. A suitable and stable gut microbiome can contribute to the ecological fitness of insect by influencing their physiology, biochemistry and development processes. Here, we show that a shift in the gut bacterial composition and structure by sterilizing irradiation, characterized by a decrease in the major gut microbiota community Enterobacteriaceae, an expansion of the minor members (e.g., Bacillaceae) and a higher richness and diversity, is tightly linked to radiation-induced ecological fitness (male mating competitiveness, flight capacity, survival rate and life span) decline in Bactrocera dorsalis (Hendel) sterile males. Function prediction of gut microbiota indicated that changes in microbiome taxonomy tend to drive microbiome functional shifts. A higher nutrient consumption of the flourishing minor gut microbiota may cause a decline in nutrients and energy metabolic activity of host and then result in the reduced ecological fitness of irradiated flies. Furthermore, we found that a gut bacterial strain Klebsiella oxytoca (BD177) can restore ecological fitness by improving food intake and increasing haemolymph sugar and amino acid levels of irradiated B. dorsalis flies. Our findings suggest that gut symbiont-based probiotics can be used as agents for reversing radiation-induced ecological fitness decrease." @default.
W2888821508 created "2018-09-07" @default.
W2888821508 creator A5003501299 @default.
W2888821508 creator A5039400029 @default.
W2888821508 creator A5054173720 @default.
W2888821508 creator A5071330532 @default.
W2888821508 creator A5072029769 @default.
W2888821508 creator A5077779717 @default.
W2888821508 creator A5078470085 @default.
W2888821508 creator A5088038316 @default.
W2888821508 date "2018-10-09" @default.
W2888821508 modified "2023-10-14" @default.
W2888821508 title "Intestinal probiotics restore the ecological fitness decline of <i>Bactrocera dorsalis</i> by irradiation" @default.
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W2888821508 doi "https://doi.org/10.1111/eva.12698" @default.
W2888821508 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/6231467" @default.
W2888821508 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/30459840" @default.
W2888821508 hasPublicationYear "2018" @default.
W2888821508 type Work @default.