[1] Douglas A E. Multiorganismal insects:diversity and function of resident microorganisms[J]. Annual Review of Entomology, 2015, 60(1):17-34. [2] Su W, Liu J, Bai P,et al. Pathogenic fungi-induced susceptibility is mitigated by mutual lactobacillus plantarum in the drosophila melanogaster model[J]. BMC Microbiology, 2019, 19(6):48-55. [3] Thong-On A, Suzuki K, Noda S, et al. Isolation and characterization of anaerobic bacteria for symbiotic recycling of uric acid nitrogen in the gut of various termites[J]. Bulletin of Japanese Society of Microbial Ecology, 2012, 27(2):186-192. [4] Weiss B L, Wang J, Aksoy S, et al. Tsetse immune system maturation requires the presence of obligate symbionts in larvae[J]. PLoS Biology, 2011, 9(5):e1000619. [5] Wenzel M, Schönig I, Berchtold M, et al. Aerobic and facultatively anaerobic cellulolytic bacteria from the gut of the termite Zootermopsis angusticollis[J]. Journal of Applied Microbiology, 2010, 92(1):32-40. [6] König H. Bacillus species in the intestine of termites and other soil invertebrates[J]. Journal of Applied Microbiology, 2010, 101(3):620-627. [7] 吴玉新,张春玲,洪晓月.桃蚜与其内共生菌Buchnera之间的系统进化关系分析[J].南京农业大学学报, 2008, 31(1):51-56. [8] Davis T S, Crippen T L, Hofstetter R W, et al. Microbial volatile emissions as insect semiochemicals[J]. Journal of Chemical Ecology, 2013, 39(7):840-859. [9] Zhao L, Mota M, Vieira P,et al. Interspecific communication between pinewood nematode, its insect vector, and associated microbes[J]. Trends in Parasitology, 2014, 30(6):299-308. [10] Chandler J A, Lang J M, Bhatnagar S, et al. Bacterial communities of diverse drosophila species:ecological context of a host-microbe model system[J]. PLoS Genetics, 2011, 7:e1002272. [11] Wong C N, Chaston J M, Douglas A E. The inconstant gut microbiota of drosophila species revealed by 16S rRNA gene analysis[J]. ISME Journal, 2013, 7(10):1922-1932. [12] Bili M, Cortesero A M, Mougel C, et al. Bacterial community diversity harboured by interacting species[J]. PLoS ONE, 2016, 11(6):e0155392. [13] Paula D P, Linard B, Andow D A, et al. Detection and decay rates of prey and prey symbionts in the gut of a predator through metagenomics[J]. Molecular Ecology Resources, 2015, 15(4):880-892. [14] Ren T, Kahrl A F, Wu M, et al. Does adaptive radiation of a host lineage promote ecological diversity of its bacterial communities? A test using gut microbiota of Anolis lizards[J]. Molecular Ecology, 2016, 25(19):4793-4804. [15] 张润志,张帆.异色瓢虫生物生态学研究进展[J].应用生态学报, 2007, 18(9):2117-2126. [16] 刘静雅,李卓苗,孟玲,等.捕食外来入侵扶桑绵粉蚧对异色瓢虫生活史特征的影响[J].中国生物防治学报, 2021, 37(1):86-90. [17] Dudek K, Humińska K, Wojciechowicz J, et al. Metagenomic survey of bacteria associated with the invasive ladybird Harmonia axyridis(Coleoptera:Coccinellidae)[J]. European Journal of Entomology, 2017, 114:312-316. [18] Schmidtberg H, Shukla S P, Halitschke R, et al. Symbiont-mediated chemical defense in the invasive ladybird Harmonia axyridis[J]. Ecology and Evolution, 2019, 9(4):1715-1729. [19] R Core Team (2018) R:A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. URL https://www.R-project.org/. [20] Jing L, Guo W, Chen S, et al. Host plants influence the composition of the gut bacteria in Henosepilachna vigintioctopunctata[J]. PLoS ONE, 2019, 14(10):e0224213. [21] Pérez-Cobas A E, Maiques E, Angelova A, et al. Diet shapes the gut microbiota of the omnivorous cockroach Blattella germanica[J]. FEMS Microbiology Ecology, 2015, 91(4):fiv022. [22] Kennedy S R, Tsau S, Gillespie R, et al. Are you what you eat? A highly transient and prey influenced gut microbiome in the grey house spider Badumna longinqua[J]. Molecular Ecology, 2020, 29(5):1001-1015. [23] Bansal R, Mian M A R, Micher A P. Microbiome diversity of Aphis glycines with extensive superinfection in native and invasive populations[J]. Environmental Microbiology Reports, 2014, 6(1):57-69. [24] He B, Chen X, Yang H, et al. Microbiome structure of the aphid Myzus persicae(Sulzer) is shaped by different solanaceae plant diets[J]. Frontiers in Microbiology, 2021, 12:667257. [25] Macdonald S J, Thomas G H, Douglas A E. Genetic and metabolic determinants of nutritional phenotype in an insect-bacterial symbiosis[J]. Molecular Ecology, 2011, 20(10):2073-2084. [26] Simonet P, Duport G, Gaget K, et al. Direct flow cytometry measurements reveal a fine-tuning of symbiotic cell dynamics according to the host developmental needs in aphid symbiosis[J]. Scientific Reports, 2016, 6(1):19967. [27] Lin D, Zhang L, Shao W, et al. Phylogenetic analyses and characteristics of the microbiomes from five mealybugs (Hemiptera:Pseudococcidae)[J]. Ecology and Evolution, 2019, 9(4):1972-1984. [28] 黄芳,赵春玲,吕要斌.共生菌Tremblaya princeps在扶桑绵粉蚧个体发育中的动态变化[J].昆虫学报, 2015, 58(10):1140-1145. [29] 钟勇,马福欢,蓝翊文,等.基于宏基因组测序的扶桑绵粉蚧内共生菌多样性研究[J].生物安全学报, 2020, 29(4):273-278. [30] Douglas A E. Nutritional interactions in insect-microbial symbioses:aphids and their symbiotic bacteria Buchnera[J]. Annual Review of Entomology, 1998, 43:17-37. [31] Sergio L M, Amparo L, Andrés M, et al. Mealybugs nested endosymbiosis:going into the"matryoshka"system in Planococcus citri in depth[J]. BMC Microbiology, 2013, 13(1):74-74. [32] Mccutcheon J P, Dohlen C. An interdependent metabolic patchwork in the nested symbiosis of mealybugs[J]. Current Biology:CB, 2011, 21(16):1366-1372. [33] Chen B, Teh B S, Sun C, et al. Biodiversity and activity of the gut microbiota across the life history of the insect herbivore Spodoptera littoralis[J]. Scientific Reports, 2016, 6:29505. [34] Sergio L M, Amparo L, Andrés M, et al. The link between independent acquisition of intracellular gamma-endosymbionts and concerted evolution in Tremblaya princeps[J]. Frontiers in Microbiology, 2015, 6(6):642. |