Cyanobacterial blooms that form in response to climate warming and nutrient enrichment in freshwater lakes have become a global environmental challenge. Historical legacy effects and the mechanisms underlying cyanobacterial community succession are not well understood, especially for plateau lakes that are important global freshwater resources. This study investigated the temporal dynamics of cyanobacterial communities over centuries in response to nutrient enrichment and climate warming in low-latitude plateau lakes using high-throughput DNA sequencing of sedimentary DNA combined with traditional paleolimnological analyses. Our results confirmed that nutrients and climate warming drive shifts in cyanobacterial communities over time. Cyanobacterial community turnover was pronounced with regime shifts toward new ecological states, occurring after exceeding a tipping point of aquatic total phosphorus (TP). The inferred species interactions, niche differentiation, and identity of keystone taxa significantly changed after crossing the aquatic TP ecological threshold, as demonstrated by network analysis of cyanobacterial taxa. Further, the contribution of aquatic TP to cyanobacterial community dynamics was greater than that of air temperature when lakes were in an oligotrophic state. In contrast, as the aquatic TP threshold was exceeded, the contribution to community dynamics by air temperature increased and potentially surpassed that of aquatic TP. Overall, these results provide new evidence for how past nutrient levels in lacustrine ecosystems influence contemporary cyanobacterial community responses to global warming in low-latitude plateau lakes.
Anthropogenic pressures can threaten
lake and reservoir ecosystems,
leading to harmful algal blooms that have become globally widespread.
However, patterns of phytoplankton diversity change and community
assembly over long-term scales remain unknown. Here, we explore biodiversity
patterns in eukaryotic algal (EA) and cyanobacterial (CYA) communities
over a century by sequencing DNA preserved in the sediment cores of
seven lakes and reservoirs in the North Temperate Zone. Comparisons
within lakes revealed temporal algal community homogenization in mesotrophic
lakes, eutrophic lakes, and reservoirs over the last century but no
systematic losses of α-diversity. Temporal homogenization of
EA and CYA communities continued into the modern day probably due
to time-lags related to historical legacies, even if lakes go through
a eutrophication phase followed by a reoligotrophication phase. Further,
algal community assembly in lakes and reservoirs was mediated by both
deterministic and stochastic processes, while homogeneous selection
played a relatively important role in recent decades due to intensified
anthropogenic activities and climate warming. Overall, these results
expand our understanding of global change effects on algal community
diversity and succession in lakes and reservoirs that exhibit different
successional trajectories while also providing a baseline framework
to assess their potential responses to future environmental change.
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