The key environmental factors driving the succession of phytoplankton functional groups in Hongfeng Reservoir, southwest China

Libin HAN; Qiuhua LI; Wensheng CHEN; Xing WANG; Shihui ZHOU; Mengshu HAN; Anton BRANCELJ

doi:10.1007/s00343-021-1120-z

Your Location：

Home >

Browse articles >

The key environmental factors driving the succession of phytoplankton functional groups in Hongfeng Reservoir, southwest China

Ecology | Updated：2023-05-20

- The key environmental factors driving the succession of phytoplankton functional groups in Hongfeng Reservoir, southwest China
- Journal of Oceanology and Limnology Vol. 40, Issue 4, Pages: 1472-1484(2022)
- Affiliations：
  
  1.Key Laboratory for Information System of Mountainous Area and Protection of Ecological Environment of Guizhou Province, Guizhou Normal University, Guiyang 550001, China
  2.Guizhou International Science&Technology Cooperation Base-International Joint Research Centre for Aquatic Ecology, Guizhou Normal University, Guiyang 550001, China
  3.Key Laboratory for Information and Computing Science of Guizhou Province, Guizhou Normal University, Guiyang 550001, China
  4.National Institute of Biology, Vecna pot 111, Ljubljana 1000, Slovenia
- Author bio：
  
  Qiuhua LI, E-mail: qiuhua2002@126.com
- Funds：
- DOI：10.1007/s00343-021-1120-z
  CLC：
- Received：11 April 2021，
  
  Accepted：16 August 2021，
  
  Online First：23 September 2021，
  
  Published：2022-07
- Accepted：
Scan QR Code
Libin HAN, Qiuhua LI, Wensheng CHEN, et al. The key environmental factors driving the succession of phytoplankton functional groups in Hongfeng Reservoir, southwest China[J]. Journal of Oceanology and Limnology, 2022, 40(4): 1472-1484.
DOI：

Libin HAN, Qiuhua LI, Wensheng CHEN, et al. The key environmental factors driving the succession of phytoplankton functional groups in Hongfeng Reservoir, southwest China[J]. Journal of Oceanology and Limnology, 2022, 40(4): 1472-1484. DOI： 10.1007/s00343-021-1120-z.

摘要

Abstract

Reservoirs are an important water source in many densely populated areas in southwest China. Phytoplankton play an essential role in maintaining the structure and function of reservoir ecosystems. Understanding the succession in phytoplankton communities and the factors driving it are essential for effective water quality management in drinking water reservoirs. In this study

water samples were collected monthly at the surface layers from March 2016 to December 2019 in Hongfeng Reservoir

southwest China. The relationship between functional group succession was analyzed based on nonmetric multidimensional scaling analysis (NMDS)

redundancy analysis (RDA)

succession rate

and other analysis methods. The results showed distinct shifts in the community structure of phytoplankton functional groups within study period. The

Cyclotella

sp. was dominant in 2016 and 2017

and

Pseudanabaena limnetica

was the dominant group in 2018 and 2019. It appears that the phytoplankton composition and biomass are closely related to the water temperature and nutrient status in this reservoir. The results clearly showed that the permanganate index (COD

) was the key factor of dramatic phytoplankton functional group succession

and the change in succession rates was closely caused by total nitrogen concentration (TN). Therefore

the succession pattern and key factors of Hongfeng Reservoir revealed in this study were important guidance for the management of drinking water reservoirs in southwest China. A reasonable limit on exogenous nutrient input should be a priority

especially in high water temperature period.

关键词

Keywords

references

Biggs B J F, Stevenson R J, Lowe R L. 1998. A habitat matrix conceptual model for stream periphyton. Archiv für Hydrobiologie , 143 (1): 21–56..

Cao J, Hou Z Y, Li Z K, Chu Z S, Yang P P, Zheng B H. 2018. Succession of phytoplankton functional groups and their driving factors in a subtropical plateau lake. Science of the Total Environment , 631–632 : 1127–1137..

Crossetti L O, de M Bicudo C E. 2008. Adaptations in phytoplankton life strategies to imposed change in a shallow urban tropical eutrophic reservoir, Garças Reservoir, over 8 years. Hydrobiologia , 614 (1): 91–105..

de S Cardoso L, da Motta Marques D. 2003. Rate of change of the phytoplankton community in Itapeva Lake (north coast of Rio Grande do Sul, Brazil), based on the wind driven hydrodynamic regime. Hydrobiologia , 497 (1–3): 1–12..

Demir A N, Fakioğlu Ö, Dural B. 2014. Phytoplankton functional groups provide a quality assessment method by the Q assemblage index in Lake Mogan (Turkey). Turkish Journal of Botany , 38 (1): 169–179..

Hillebrand H, Dürselen C D, Kirschtel D, Pollingher U, Zohary T. 1999. Biovolume calculation for pelagic and benthic microalgae. Journal of Phycology , 35 (2): 403–424..

Ho J C, Michalak A M, Pahlevan N. 2019. Widespread global increase in intense lake phytoplankton blooms since the 1980s. Nature , 574 (7780): 667–670..

Hu H J, Wei Y X. 2006. The Freshwater Algae of China: Systematics, Taxonomy and Ecology. Science Press, Beijing, China. (in Chinese)

Jiang Z B, Liu J J, Chen J F, Chen Q Z, Yan X J, Xuan J L, Zeng J N. 2014. Responses of summer phytoplankton community to drastic environmental changes in the Changjiang (Yangtze River) estuary during the past 50 years. Water Research , 54 : 1–11..

Katsiapi M, Moustaka-Gouni M, Michaloudi E, Kormas K A. 2011. Phytoplankton and water quality in a mediterranean drinking-water reservoir (Marathonas Reservoir, Greece). Environmental Monitoring and Assessment , 181 (1–4): 563–575..

Kim H G, Hong S, Kim D K, Joo G J. 2020. Drivers shaping episodic and gradual changes in phytoplankton community succession: taxonomic versus functional groups. Science of the Total Environment , 734 : 138940..

Kozak A, Budzyńska A, Dondajewska-Pielka R, Kowalczewska-Madura K, Gołdyn R. 2020. Functional groups of phytoplankton and their relationship with environmental factors in the restored Uzarzewskie Lake. Water , 12 (2): 313..

Lewis Jr W M. 1978. Analysis of succession in a tropical phytoplankton community and a new measure of succession rate. The American Naturalist , 112 (984): 401–414..

Li Q H, Shang L H, Gao T J, Zhang L, Ou T, Huang G J, Chen C, Li C X. 2014. Use of principal component scores in multiple linear regression models for simulation of chlorophyll- a and phytoplankton abundance at a karst deep reservoir, southwest of China. Acta Ecologica Sinica , 34 (1): 72–78..

Li Q H, Xiao J, Ou T, Han M S, Wang J F, Chen J G, Li Y L, Salmaso N. 2018. Impact of water level fluctuations on the development of phytoplankton in a large subtropical reservoir: implications for the management of cyanobacteria. Environmental Science and Pollution Research , 25 (2): 1306–1318..

Lv H, Yang J, Liu L M, Yu X Q, Yu Z, Chiang P. 2014. Temperature and nutrients are significant drivers of seasonal shift in phytoplankton community from a drinking water reservoir, subtropical China. Environmental Science and Pollution Research , 21 (9): 5917–5928..

Niu Y, Shen H, Chen J, Xie P, Yang X, Tao M, Ma Z M, Qi M. 2011. Phytoplankton community succession shaping bacterioplankton community composition in Lake Taihu, China. Water Research , 45 (14): 4169–4182..

Nwankwegu A S, Li Y P, Huang Y N, Wei J, Norgbey E, Ji D B, Pu Y S, Nuamah L A, Yang Z J, Jiang Y F, Paerl H W. 2020. Nitrate repletion during spring bloom intensifies phytoplankton iron demand in Yangtze River tributary, China. Environmental Pollution , 264 : 114626..

Padisák J, Crossetti L O, Naselli-Flores L. 2009. Use and misuse in the application of the phytoplankton functional classification: a critical review with updates. Hydrobiologia , 621 (1): 1–19..

Rangel L M, Soares M C S, Paiva R, Silva L H S. 2016. Morphology-based functional groups as effective indicators of phytoplankton dynamics in a tropical cyanobacteria-dominated transitional river-reservoir system. Ecological Indicators , 64 : 217–227..

Reynolds C S, Huszar V, Kruk C, Naselli-Flores L, Melo S. 2002. Towards a functional classification of the freshwater phytoplankton. Journal of Plankton Research , 24 (5): 417–428..

Reynolds C S. 1998. What factors influence the species composition of phytoplankton in lakes of different trophic status?. Hydrobiologia , 369 : 11–26..

Romanov R E, Kirillov V V. 2012. Analysis of the seasonal dynamics of river phytoplankton based on succession rate indices for key event identification. Hydrobiologia , 695 (1): 293–304..

Salmaso N. 1996. Seasonal variation in the composition and rate of change of the phytoplankton community in a deep subalpine lake (Lake Garda, northern Italy). An application of nonmetric multidimensional scaling and cluster analysis. Hydrobiologia , 337 (1–3): 49–68..

Tang J W, Zhuang M Q, Xing X L, Zhang X H, Guan F. 2007. Analysis of variation of algae and organic matter in raw water transformation using 3-D fluorescence spectroscopy. Advances in Water Science , 18 (4): 609–613. (in Chinese with English abstract).

The State Environmental Protection Administration. 2002. Water and Wastewater Monitoring and Analysis Method. 4 th edn. China Environmental Science Press, Beijing, China. (in Chinese)

Williams N J, Goldman C R. 1975. Succession rates in lake phytoplankton communities: with 1 figure in the text. SIL Proceedings, 1922–2010 , 19 (2): 808–811..

Yang B, Jiang Y J, He W, Liu W X, Kong X Z, Jørgensen S E, Xu F L. 2016. The tempo-spatial variations of phytoplankton diversities and their correlation with trophic state levels in a large eutrophic Chinese lake. Ecological Indicators , 66 : 153–162..

Yao L G, Zhao X M, Zhou G J, Liang R C, Gou T, Xia B C, Li S Y, Liu C. 2020. Seasonal succession of phytoplankton functional groups and driving factors of cyanobacterial blooms in a subtropical reservoir in South China. Water , 12 (4): 1167..

Yao X, Zhang Y L, Zhu G W, Qin B Q, Feng L Q, Cai L L, Gao G. 2011. Resolving the variability of CDOM fluorescence to differentiate the sources and fate of DOM in Lake Taihu and its tributaries. Chemosphere , 82 (2): 145–155..

Zhao H J, Wang L, Yang L L, Yuan L W, Peng D C. 2015. Relationship between phytoplankton and environmental factors in landscape water supplemented with reclaimed water. Ecological Indicators , 58 : 113–121..

Zhu G H, Noman A, Narale D D, Feng W H, Pujari L, Sun J. 2020. Evaluation of ecosystem health and potential human health hazards in the Hangzhou Bay and Qiantang Estuary region through multiple assessment approaches. Environmental Pollution , 264 : 114791..

Views

Downloads

CSCD

Alert me when the article has been cited

Submit

Tools

Publicity Resources

Temporal and spatial distribution of phytoplankton functional groups and role of environment factors in a deep subtropical reservoir

Seasonal variation of plankton communities influenced by environmental factors in an artificial lake

Spatial heterogeneity in a deep artificial lake plankton community revealed by PCR-DGGE fingerprinting

Study on Temperature Field Characteristics of2.5D Braided Composites

Wall Corrosion Morphology Prediction of Hall ThrustersUsing Semi-Empirical Method

Related Author

Fengfeng CHEN

Shulin JIAO

Jingfu WANG

Jing'an CHEN

Qiuhua LI

Lei LI

Tanglin Zhang

Qingyun Yan

Related Institution

State Key Laboratory of Environmental Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences

School of Geography and Environmental Science, Guizhou Normal University

School of Public Health, Guizhou Medical University

Key Laboratory of Biodiversity and Conservation of Aquatic Organisms Institute of Hydrobiology Chinese Academy of Sciences

Graduate University of Chinese Academy of Sciences

Address：Editorial Office of JOL, 88 Haijun Rd. Qingdao, 266000, China
Tel：+86-532-82898754 Email：jol@qdio.ac.cn
Technical support is provided by Beijing Founder electronics co., LTD 京ICP备09064830号-19 京公网安备11010802024621
It is recommended to read the content of this site in Chrome&IE9+. Please switch to extreme mode in browser 360.
Cookies We use cookies to help provide and enhance our service and tailor content. By continuing, you agree to the use of cookies.

⁰