Seasonal variations and driving factors of phytoplankton community shift in Datun Lake with long-term stress of arsenic contamination.

doi:10.13287/j.1001-9332.202105.032

Abstract

Abstract: Heavy metal is an important environmental stress that threatens water quality and ecological health of surface waters. Therefore, it is vital to identify the responses of lake community to long-term pollution for sustainable ecological restoration of polluted lakes. From June 2017 to March 2018, we conducted a seasonal survey of phytoplankton and environmental factors in Datun Lake, which had a decadal history of tailing-related arsenic contamination. Consistent with results from previous studies, phytoplankton were dominated by As-tolerant taxa such as Cyanophyta. Results of the analysis of similarities and analysis of variance showed that there were significant temporal variations in phytoplankton community structure and biomass, but without spatial variation. Results of the Pearson correlation analysis demonstrated that the total phytoplankton biomass was positively related to lake-water soluble orthophosphate and arsenic, which was consistent with the differential effect of arsenic on algae growth (e.g. promotion at low concentration and suppression at high concentration). The increases of phosphate might alleviate the toxic impacts of arsenic on phytoplankton. Redundancy analysis showed that the soluble nutrients and arsenic were significant factors driving phytoplankton community variations. The results of variation partitioning demonstrated that nutrients and water temperature explained 17.6% and 3.8% of community variations, respectively, with strong interaction with arsenic (15.1%). Arsenic did not affect phytoplankton community assembly, indicating that the dominant algae were tolerant to arsenic and thus highly insensitive to the arsenic stress. Therefore, the seasonal variations of phytoplankton dominated by As-tolerant algae in Datun demonstrated that the low-As promotion effect on phytoplankton should be considered in ecological restoration of polluted lakes.

Key words: arsenic, phytoplankton, biomass, community structure, environmental factor

SHANG Li, CHEN Li, ZHANG Tao, ZHENG Xin, ZHAO Shuai-ying, KONG Ling-yang, CHEN Guang-jie. Seasonal variations and driving factors of phytoplankton community shift in Datun Lake with long-term stress of arsenic contamination.[J]. Chinese Journal of Applied Ecology, 2021, 32(5): 1845-1853.

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