Environmental DNA Reveals Multitrophic Insight into the Mechanism of Community Stability Changes in Shallow Eutrophic Lakes

Current management of eutrophic lakes primarily targets nutrient reduction and algal bloom control, often overlooking the organismal mechanisms that drive changes in community stability across multitrophic levels. This study employed environmental DNA (eDNA) to examine the seasonal dynamics of multitrophic communities in the typical shallow eutrophic lakes of Dianchi (plateau) and Taihu (plain), exploring how eutrophication stress influences community composition, organismal networks, and stability. We found that plateau and plain lakes had their respective dominant taxa and diversity changes across seasons. The structure of organismal networks composed of dominant taxa varied significantly across lakes and seasons, among which Taihu Lake exhibited 17.9% higher connectivity and 8.2% greater robustness compared to Dianchi Lake. Dominant taxa and their organismal networks played a critical role in determining the stability changes in plateau and plain lakes through different pathways; 30% of the stability variation in Dianchi Lake was attributed to bottom-up effects, with algae as the core pathway, while 40% of the variation in Taihu Lake was mainly explained by top-down effects, with fish as the core pathway. These findings underscore the lake-specific mechanisms of community stability changes, providing insights into tailored management strategies for eutrophic lakes based on their unique ecological processes.