Can short-term and small-scale experiments reflect nutrient limitation on phytoplankton in natural lakes

Whether it is necessary to reduce nitrogen (N) and/or phosphorus (P) input to mitigate lake eutrophication is controversial. The controversy stems mainly from differences in time and space in previous studies that support the contrasting ideas. To test the response of phytoplankton to various combin...

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Published inChinese journal of oceanology and limnology Vol. 35; no. 3; pp. 546 - 556
Main Author 王海军 李艳 冯伟松 于清 肖绪诚 梁小民 邵建春 马硕楠 王洪铸
Format Journal Article
LanguageEnglish
Published Heidelberg Science Press 01.05.2017
Springer Nature B.V
Subjects
Biology
Cyanobacteria
Earth and Environmental Science
Earth Sciences
Ecosystems
Eutrophication
Freshwater
Inland waters
Lakes
Limnology
Marine
Nitrogen
nitrogen fixation
nitrogen-fixing cyanobacteria
nutrient content
Nutrients
Oceanography
Phosphorus
Phytoplankton
Plankton
Ponds
stems
Tanks
小规模
水槽实验
浮游植物
湖泊富营养化
短期
自然生态条件
自然生态系统
营养限制
mesocosm experiment
extrapolation
eutrophication
nutrient control
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Summary:Whether it is necessary to reduce nitrogen (N) and/or phosphorus (P) input to mitigate lake eutrophication is controversial. The controversy stems mainly from differences in time and space in previous studies that support the contrasting ideas. To test the response of phytoplankton to various combinations of nutrient control strategies in mesocosms and the possibility of reflecting the conditions in natural ecosystems with short-term experiments, a 9-month experiment was carried out in eight 800-L tanks with four nutrient level combinations (+N+P, -N+P, +N-P, and -N-P), with an 18-month whole-ecosystem experiment in eight -800-m2 ponds as the reference. Phytoplankton abundance was determined by P not N, regardless of the initial TN/TP level, which was in contrast to the nutrient limitation predicted by the N/P theory. Net natural N inputs were calculated to be 4.9, 6.8, 1.5, and 3.0 g in treatments +N+P, -N+P, +N-P, and -N-P, respectively, suggesting that N deficiency and P addition may promote natural N inputs to support phytoplankton development. However, the compensation process was slow, as suggested by an observed increase in TN after 3 weeks in -N+P and 2 months in -N-P in the tank experiment, and after 3 months in -N+P and -3 months in -N-P in our pond experiment. Obviously, such a slow process cannot be simulated in short-term experiments. The natural N inputs cannot be explained by planktonic N-fixation because N-fixing cyanobacteria were scarce, which was probably because there was a limited pool of species in the tanks. Therefore, based on our results we argue that extrapolating short-term, small-scale experiments to large natural ecosystems does not give reliable, accurate results.
Bibliography:WANG Haijun 1,LI Yan1, 2, FENG Weisong 1, YU Qing 1, 2, XIAO Xucheng 1, 2, LIANa Xiaomin 1, SHAO Jianchun 3, MA Shuonan 1, 2, WANG Hongzhu 1 (1State Key Laboratory of Freshwater Ecology and Biotechnology, Institute of Hydrobiology, Chinese Academy of Sciences Wuhan 430072, China ;2 University of Chinese Academy of Sciences, Beifing 100049, China ;3 Huazhong Agricultural University, Wuhan 430070, China)
Whether it is necessary to reduce nitrogen (N) and/or phosphorus (P) input to mitigate lake eutrophication is controversial. The controversy stems mainly from differences in time and space in previous studies that support the contrasting ideas. To test the response of phytoplankton to various combinations of nutrient control strategies in mesocosms and the possibility of reflecting the conditions in natural ecosystems with short-term experiments, a 9-month experiment was carried out in eight 800-L tanks with four nutrient level combinations (+N+P, -N+P, +N-P, and -N-P), with an 18-month whole-ecosystem experiment in eight -800-m2 ponds as the reference. Phytoplankton abundance was determined by P not N, regardless of the initial TN/TP level, which was in contrast to the nutrient limitation predicted by the N/P theory. Net natural N inputs were calculated to be 4.9, 6.8, 1.5, and 3.0 g in treatments +N+P, -N+P, +N-P, and -N-P, respectively, suggesting that N deficiency and P addition may promote natural N inputs to support phytoplankton development. However, the compensation process was slow, as suggested by an observed increase in TN after 3 weeks in -N+P and 2 months in -N-P in the tank experiment, and after 3 months in -N+P and -3 months in -N-P in our pond experiment. Obviously, such a slow process cannot be simulated in short-term experiments. The natural N inputs cannot be explained by planktonic N-fixation because N-fixing cyanobacteria were scarce, which was probably because there was a limited pool of species in the tanks. Therefore, based on our results we argue that extrapolating short-term, small-scale experiments to large natural ecosystems does not give reliable, accurate results.
37-1150/P
eutrophication; nutrient control; extrapolation; mesocosm experiment
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
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ISSN:0254-4059
2096-5508
1993-5005
2523-3521
DOI:10.1007/s00343-017-5251-1