Process and mechanism of termite impact on soil and plant.

Q3 Environmental Science
Chuan Jiang, Xiao-Ling Zeng, Yan-Qiang Jin, De-Feng Feng, Fang-Mei Lin, Yuan-Yang Chen, Jian-Wei Tang, Cheng-Gang Liu
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引用次数: 0

Abstract

Termites, as a kind of nesting social insects, are often confused as worldwide "pests" because some of their groups have great destructive effects. The vast majority of termites can regulate ecosystem functions and ser-vices by participating in biogeochemical cycles, known as "ecosystem engineers". We reviewed studies on the effects of termites on the physical, chemical and biological characteristics of mound soil ecosystems and the composition and diversity of plant communities. Termites could form unique soil "biogenic aggregates" and "resource heterogeneity patches", which affect microbial community structure, extracellular enzyme activity, physicochemical property and greenhouse gas emission, thereby affecting plant growth, community composition and structure, and vegetation productivity. However, this effect significantly differed among termite groups and functional groups, and was dependent on regional soil environment and microclimate conditions. Meanwhile, termite-mound could effectively improve ecosystem adaptation or resistance to environmental stress through the above process. Future research should focus on the following directions: 1) studying the trophic cascading effect of termite-centered soil multilevel biological network and the potential effect on biogeochemical cycle from microscale (aggregate level) to macroscale (landscape level); 2) exploring the potential of termite mound soil as a fertility amendment in tropical regions, and mining beneficial microbial functional genes to develop related products for termite control.

白蚁影响土壤和植物的过程和机制。
白蚁作为一种筑巢的社会性昆虫,常常被混淆为世界性的 "害虫",因为它们中的一些群体具有巨大的破坏作用。绝大多数白蚁可以通过参与生物地球化学循环来调节生态系统的功能和服务,被称为 "生态系统工程师"。我们回顾了有关白蚁对土丘土壤生态系统的物理、化学和生物特征以及植物群落的组成和多样性的影响的研究。白蚁可形成独特的土壤 "生物聚集体 "和 "资源异质性斑块",影响微生物群落结构、胞外酶活性、理化性质和温室气体排放,从而影响植物生长、群落组成和结构以及植被生产力。然而,这种影响在不同的白蚁群和功能群之间存在明显差异,并取决于区域土壤环境和小气候条件。同时,白蚁冢可通过上述过程有效提高生态系统对环境压力的适应性或抵抗力。未来的研究应重点关注以下几个方向:1)研究以白蚁为中心的土壤多级生物网络的营养级联效应,以及对生物地球化学循环从微观(聚集水平)到宏观(景观水平)的潜在影响;2)探索白蚁冢土壤作为热带地区肥力改良剂的潜力,挖掘有益微生物功能基因,开发相关白蚁防治产品。
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来源期刊
应用生态学报
应用生态学报 Environmental Science-Ecology
CiteScore
2.50
自引率
0.00%
发文量
11393
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