Enhanced capacity of a leaf beetle to combat dual stress from entomopathogens and herbicides mediated by associated microbiota

IF 3.5 1区 生物学 Q1 ZOOLOGY
Yuxin ZHANG, Handan XU, Chengjie TU, Runhua HAN, Jing LUO, Letian XU
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Abstract

Herbicides have demonstrated their impact on insect fitness by affecting their associated microbiota or altering the virulence of entomopathogenic fungi toward insects. However, limited research has explored the implications of herbicide stress on the intricate tripartite interaction among insects, associated bacterial communities, and entomopathogens. In this study, we initially demonstrated that associated bacteria confer a leaf beetle, Plagiodera versicolora, with the capability to resist the entomopathogenic fungus Aspergillus nomius infection, a capability sustained even under herbicide glyphosate stress. Further analysis of the associated microbiota revealed a significant alteration in abundance and composition due to glyphosate treatment. The dominant bacterium, post A. nomius infection or following a combination of glyphosate treatments, exhibited strong suppressive effects on fungal growth. Additionally, glyphosate markedly inhibited the pathogenic associated bacterium Pseudomonas though it inhibited P. versicolora’s immunity, ultimately enhancing the beetle's tolerance to A. nomius. In summary, our findings suggest that the leaf beetle's associated microbiota bestow an augmented resilience against the dual stressors of both the entomopathogen and glyphosate. These results provide insight into the effects of herbicide residues on interactions among insects, associated bacteria, and entomopathogenic fungi, holding significant implications for pest control and ecosystem assessment.

Abstract Image

在相关微生物群的介导下,叶甲虫对抗昆虫病原体和除草剂双重压力的能力增强。
除草剂通过影响昆虫的相关微生物群或改变昆虫病原真菌对昆虫的毒力,对昆虫的适应性产生了影响。然而,对除草剂胁迫对昆虫、相关细菌群落和昆虫病原菌之间错综复杂的三方相互作用的影响的探索还很有限。在这项研究中,我们初步证明了伴生细菌赋予叶甲虫 Plagiodera versicolora 抵抗昆虫病原真菌 Aspergillus nomius 感染的能力,这种能力即使在除草剂草甘膦胁迫下也能保持。对相关微生物群的进一步分析表明,草甘膦处理对微生物群的丰度和组成产生了显著影响。在 A. nomius 感染后或草甘膦综合处理后,优势细菌对真菌的生长有很强的抑制作用。此外,草甘膦虽然抑制了 P. versicolora 的免疫力,但却明显抑制了与病原相关的假单胞菌,最终增强了甲虫对 A. nomius 的耐受性。总之,我们的研究结果表明,叶甲虫的相关微生物群能增强对昆虫病原体和草甘膦双重压力的抗逆性。这些结果让我们深入了解了除草剂残留对昆虫、相关细菌和昆虫病原真菌之间相互作用的影响,对害虫控制和生态系统评估具有重要意义。
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来源期刊
CiteScore
6.40
自引率
12.10%
发文量
81
审稿时长
>12 weeks
期刊介绍: The official journal of the International Society of Zoological Sciences focuses on zoology as an integrative discipline encompassing all aspects of animal life. It presents a broader perspective of many levels of zoological inquiry, both spatial and temporal, and encourages cooperation between zoology and other disciplines including, but not limited to, physics, computer science, social science, ethics, teaching, paleontology, molecular biology, physiology, behavior, ecology and the built environment. It also looks at the animal-human interaction through exploring animal-plant interactions, microbe/pathogen effects and global changes on the environment and human society. Integrative topics of greatest interest to INZ include: (1) Animals & climate change (2) Animals & pollution (3) Animals & infectious diseases (4) Animals & biological invasions (5) Animal-plant interactions (6) Zoogeography & paleontology (7) Neurons, genes & behavior (8) Molecular ecology & evolution (9) Physiological adaptations
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