栖息地干扰推动了湖泊退化后水生植物对微生物群落的反馈作用

IF 4.8 Q1 ENVIRONMENTAL SCIENCES
Hongwei Yu, Quanlin Lu, Xiaofeng Cao, Yajun Wang, Yan Xu, Guo Yu, Jianfeng Peng, Jing Qi*, Chengzhi Hu and Jiuhui Qu, 
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引用次数: 0

摘要

全球范围内加剧的湖泊系统退化归因于高强度干扰,并成为湖泊生物多样性和生态系统稳定性下降的重要驱动因素。然而,生态演替后水生植物与微生物之间反馈机制的潜在变化仍不清楚。本研究利用 Illumina MiSeq 测序技术和薄膜分析中的扩散梯度,深入研究了水生植物在不同生长阶段对沉积物细菌多样性和营养动态的影响。我们的研究结果表明,在过去的 25 年中,研究区域的地表温度从 20 °C上升到 28 °C,优势物种已转变为 Stuckenia pectinata。建构物种在其器官的化学计量特性上表现出反应性变化,以适应环境变化。pectinata的生长可能会影响沉积物-水界面的NH4+-N、NO3--N、P和Fe的扩散通量。此外,环境过滤和竞争的决定性过程可能改变了果胶虫根瘤层中的微生物,温度和水深是季节性微生物变化的主要驱动因素。这些关于湖泊生态系统中多种压力因素的驱动-响应关系的结果可能有助于开发以恢复水生植物为重点的工程项目。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Habitat Disturbance Drives the Feedback of Aquatic Plants on the Microbial Community after Lake Degradation

Habitat Disturbance Drives the Feedback of Aquatic Plants on the Microbial Community after Lake Degradation

Globally intensified lake system degradation has been attributed to high-intensity disturbance and emerged as a significant driver of the declines in lake biodiversity and ecosystem stability. However, potential alterations in feedback mechanisms between aquatic plants and microorganisms after ecological succession are still unclear. This study delves into the influence of aquatic plants on sediment bacterial diversity and nutrient dynamics across different growth phases using Illumina MiSeq sequencing and diffusive gradients in thin film analysis. Our results indicate that the surface temperature of the research area has increased from 20 to 28 °C over the past 25 years, and the dominant species has shifted to Stuckenia pectinata. Constructive species show responsive changes in their organ’s stoichiometric characteristics to adapt to environmental changes. The growth of S. pectinata could affect the diffusion fluxes of NH4+–N, NO3–N, P, and Fe at the sediment–water interface. Morever, the deterministic processes of environmental filtering and competition may have altered the microorganisms in the rhizosphere of S. pectinata, temperature, and water depth were major drivers of seasonal microbial changes. These results in the driver-response relationship of multiple stressors in the lake ecosystem may contribute to the development of engineering projects focusing on restoring aquatic plants.

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