Ecology of China’s pilot cities for creating healthy aquatic communities: heterogeneity, niches and environmental factors
Changsen Zhao A B and Shengtian Yang AA College of Water Sciences, Beijing Key Laboratory of Urban Hydrological Cycle and Sponge City Technology, Beijing Normal University, 19 Xinjiekouwai Street, Beijing, 100875, PR China.
B Corresponding author. Email: zhaochangsen@bnu.edu.cn
Marine and Freshwater Research 70(5) 611-614 https://doi.org/10.1071/MF19108
Submitted: 25 March 2019 Accepted: 15 April 2019 Published: 6 May 2019
Abstract
Globally, climate change and human activities have greatly stressed the health of water ecological communities (WECs) in cities, and WEC restoration is therefore a critical issue, especially for developing cities. To restore healthy WECs and support humans into the future, the Ministry of Water Resources, China, proposed a project to build cities with healthy WECs. Jinan was designated the first pilot city for this project. The exploration of methodologies on WEC restoration in pilot cities is important because it can provide reliable theoretical evidence and methodological references for researchers and managers, and serve as an important decision-making basis for ecological resources management and remediation of fresh waters. In this Research Front, we have brought together studies on aquatic ecosystems of the first pilot cities project to build healthy WECs in China, including studies on the health, temporospatial heterogeneity and niches of WECs, as well as environmental factors. These studies can significantly increase our understanding of the ecology of the aquatic systems in China’s pilot cities. It is anticipated that this ecosystem knowledge will help assess the effects of climate- and human-induced stress changes, and form the basis for making aquatic ecosystem protection and restoration decisions across the globe.
Additional keywords: China project to build cities with healthy water ecological communities, Jinan City, water ecological communities, WEC.
References
Andersen, J. H., Carstensen, J., Conley, D. J., Dromph, K., Fleming‐Lehtinen, V., Gustafsson, B. G., and Murray, C. (2017). Long‐term temporal and spatial trends in eutrophication status of the Baltic Sea. Biological Reviews of the Cambridge Philosophical Society 92, 135–149.| Long‐term temporal and spatial trends in eutrophication status of the Baltic Sea.Crossref | GoogleScholarGoogle Scholar | 26467655PubMed |
Cai, X., Marston, L., and Ge, Y. (2015). Decision support for integrated river basin management – scientific research challenges. Science China. Earth Sciences 58, 16–24.
| Decision support for integrated river basin management – scientific research challenges.Crossref | GoogleScholarGoogle Scholar |
Chen, Y., and Yin, L. (2008). Community composition and niche change characteristics of dominant species in the wind-breaking and sand-fixing forest, Xinjiang, China. Journal of Plant Ecology 32, 1126–1133.
Dickerson, K. D., Medley, K. A., and Havel, J. E. (2010). Spatial variation in zooplankton community structure is related to hydrologic flow units in the Missouri River, USA. River Research and Applications 26, 605–618.
Dodson, S. I., Newman, A. L., Will-wolf, S., Alexander, M. L., Woodford, M. P., and Egeren, S. (2008). The relationship between zooplankton community structure and lake characteristics in temperate lakes (Northern Wisconsin, USA). Journal of Plankton Research 31, 93–100.
| The relationship between zooplankton community structure and lake characteristics in temperate lakes (Northern Wisconsin, USA).Crossref | GoogleScholarGoogle Scholar |
Dukes, J. S. (2001). Biodiversity and invasibility in grassland microcosms. Oecologia 126, 563–568.
| Biodiversity and invasibility in grassland microcosms.Crossref | GoogleScholarGoogle Scholar | 28547241PubMed |
Fu, B. J., Yu, D. D., and Lv, N. (2017). An indicator system for biodiversity and ecosystem services evaluation in China. Acta Ecologica Sinica 37, 341–348.
Haines-Young, R., and Potschin, M. (2010). The links between biodiversity, ecosystem services and human well-being. Ecosystem Ecology: a New Synthesis 1, 110–139.
| The links between biodiversity, ecosystem services and human well-being.Crossref | GoogleScholarGoogle Scholar |
Harvey, E., Gounand, I., Ward, C. L., and Altermatt, F. (2017). Bridging ecology and conservation: from ecological networks to ecosystem function. Journal of Applied Ecology 54, 371–379.
| Bridging ecology and conservation: from ecological networks to ecosystem function.Crossref | GoogleScholarGoogle Scholar |
Hughes, S. J., Santos, J., Ferreira, T., and Mendes, A. (2010). Evaluating the response of biological assemblages as potential indicators for restoration measures in an intermittent Mediterranean river. Environmental Management 46, 285–301.
| Evaluating the response of biological assemblages as potential indicators for restoration measures in an intermittent Mediterranean river.Crossref | GoogleScholarGoogle Scholar | 20640421PubMed |
Jenerette, G. D., Harlan, S. L., Buyantuev, A., Stefanov, W. L., Declet-Barreto, J., Ruddell, B. L., Myint, S. W., Kaplan, S., and Li, X. (2016). Micro-scale urban surface temperatures are related to land-cover features and residential heat related health impacts in Phoenix, AZ, USA. Landscape Ecology 31, 745–760.
| Micro-scale urban surface temperatures are related to land-cover features and residential heat related health impacts in Phoenix, AZ, USA.Crossref | GoogleScholarGoogle Scholar |
Jinan People’s Government (2013). Implementation plans for creating healthy water ecological communities in Jinan City from 2013 to 2015. Jinan People’s Government publication 1. Available at http://www.jinan.gov.cn/art/2013/1/22/art_2612_2044544.html [In Chinese, verified 16 April 2019].
Kagalou, I. I., Kosiori, A., and Leonardos, I. D. (2010). Assessing the zooplankton community and environmental factors in a Mediterranean wetland. Environmental Monitoring and Assessment 170, 445–455.
| Assessing the zooplankton community and environmental factors in a Mediterranean wetland.Crossref | GoogleScholarGoogle Scholar | 19936952PubMed |
Liu, Y., Yu, N., Feng, D. X., Xiong, Z. Q., Jiang, X. Q., Li, E. C., and Chen, L. Q. (2010). Annual variations of zooplankton community structure in Shanghai downtown rivers. Shengtaixue Zazhi 29, 370–376.
Liu, C. M., Zhao, C. S., Xia, J., Sun, C. L., Wang, R., and Liu, T. (2011). An instream ecological flow method for data-scarce regulated rivers. Journal of Hydrology 398, 17–25.
| An instream ecological flow method for data-scarce regulated rivers.Crossref | GoogleScholarGoogle Scholar |
McCann, K. (2007). Protecting biostructure. Nature 446, 29.
| Protecting biostructure.Crossref | GoogleScholarGoogle Scholar | 17330028PubMed |
McCauley, D. J., Pinsky, M. L., Palumbi, S. R., Estes, J. A., Joyce, F. H., and Warner, R. R. (2015). Marine defaunation: animal loss in the global ocean. Science 347, 1255641.
| Marine defaunation: animal loss in the global ocean.Crossref | GoogleScholarGoogle Scholar | 25593191PubMed |
Ministry of Water Resources (2013a). Accelerating construction of cities with healthy water ecological communities. Water Resources publication 1. Available at http://210.73.66.144:4601/law?fn=chl393s896.txt [In Chinese, verified 16 April 2019].
Ministry of Water Resources (2013b). Application for pilot cities to create healthy water ecological communities. Water Resources publication 145. Available at http://210.73.66.144:4601/law?fn=chl392s503.txt [In Chinese, verified 16 April 2019].
Ministry of Water Resources (2013c). Accelerating restoration of healthy water ecological communities in pilot cities of China. Water Resources publication 233. Available at http://210.73.66.144:4601/law?fn=chl394s650.txt [In Chinese, verified 16 April 2019].
Okun, N., and Mehner, T. (2005). Interactions between juvenile roach or perch and their invertebrate prey in littoral reed versus open water enclosures. Ecology Freshwater Fish 14, 150–160.
| Interactions between juvenile roach or perch and their invertebrate prey in littoral reed versus open water enclosures.Crossref | GoogleScholarGoogle Scholar |
Parkes, M. W., and Horwitz, P. (2008). Water, ecology and health: ecosystems as settings for promoting health and sustainability. Health Promotion International 24, 94–102.
| Water, ecology and health: ecosystems as settings for promoting health and sustainability.Crossref | GoogleScholarGoogle Scholar |
Sabo, J. L., Finlay, J. C., Kennedy, T., and Post, D. M. (2010). The role of discharge variation in scaling of drainage area and food chain length in rivers. Science 330, 965–967.
| The role of discharge variation in scaling of drainage area and food chain length in rivers.Crossref | GoogleScholarGoogle Scholar | 20947729PubMed |
Shao, N. F., Yang, S. T., Sun, Y., Gai, Y., Zhao, C. S., Wang, F., Yin, X., and Dong, B. (2019). Assessing aquatic ecosystem health through the analysis of plankton biodiversity. Marine and Freshwater Research 70, 647–655.
| Assessing aquatic ecosystem health through the analysis of plankton biodiversity.Crossref | GoogleScholarGoogle Scholar |
Suding, K., Higgs, E., Palmer, M., Callicott, J. B., Anderson, C. B., Baker, M., Gutrich, J. T., Hondule, K. L., LaFevor, M. C., Larson, B. M., Randall, A., Ruhl, J. B., and Schwarts, K. Z. S. (2015). Committing to ecological restoration. Science 348, 638–640.
| Committing to ecological restoration.Crossref | GoogleScholarGoogle Scholar | 25953995PubMed |
Swyngedouw, E., Kaika, M., and Castro, E. (2002). Urban water: a political-ecology perspective. Built Environment 1978, 124–137.
Van Egeren, S. J., Dodson, S. I., Torke, B., and Maxted, J. T. (2011). The relative significance of environmental and anthropogenic factors affecting zooplankton community structure in Southeast Wisconsin Till Plain lakes. Hydrobiologia 668, 137–146.
| The relative significance of environmental and anthropogenic factors affecting zooplankton community structure in Southeast Wisconsin Till Plain lakes.Crossref | GoogleScholarGoogle Scholar |
Visintainer, T. A., Bollens, S. M., and Simenstad, C. (2006). Community composition and diet of fishes as a function of tidal channel geomorphology. Marine Ecology Progress Series 321, 227–243.
| Community composition and diet of fishes as a function of tidal channel geomorphology.Crossref | GoogleScholarGoogle Scholar |
Yang, S., Pan, T., Wang, X., Sun, Y., Zhang, Y., Zhao, C., Gai, Y., Wang, Z., and Zhang, H. (2019a). Dominant aquatic species and their hydrological niches in freshwater ecosystems in a developing city. Marine and Freshwater Research 70, 615–624.
| Dominant aquatic species and their hydrological niches in freshwater ecosystems in a developing city.Crossref | GoogleScholarGoogle Scholar |
Yang, S., Yang, Y., Sun, C., Gai, Y., Zhang, Y., Zhao, C., Dong, B., Feng, P., and Zhang, Z. (2019b). Temporospatial variation in ecosystem configuration in a pilot city for the Water Ecological Civilisation Project, China. Marine and Freshwater Research 70, 625–636.
| Temporospatial variation in ecosystem configuration in a pilot city for the Water Ecological Civilisation Project, China.Crossref | GoogleScholarGoogle Scholar |
Yang, S., Pan, X., Sun, C., Shang, S., Zhang, C., Zhao, C. S., Dong, B., and Zhang, Z. (2019c). Analysing the ecological niche of water quality of key species in the aquatic ecosystem in Jinan City. Marine and Freshwater Research 70, 656–669.
| Analysing the ecological niche of water quality of key species in the aquatic ecosystem in Jinan City.Crossref | GoogleScholarGoogle Scholar |
Zhao, C. (2014). Water science is the basis of water ecosystem restoration. Guangming Daily, 13 August 2014, 02 edition. Available at http://epaper.gmw.cn/gmrb/html/2014-08/13/nw.D110000gmrb_20140813_5-02.htm?div=-1 [In Chinese, verified 16 April 2019].
Zhao, C. S., Yang, S. T., Liu, C. M., Dou, T. W., Yang, Z. L., Yang, Z. Y., Liu, X. L., Xiang, H., Nie, S. Y., Zhang, J. L., and Mitrovic, S. M. (2015a). Linking hydrologic, physical and chemical habitat environments for the potential assessment of fish community rehabilitation in a developing city. Journal of Hydrology 523, 384–397.
| Linking hydrologic, physical and chemical habitat environments for the potential assessment of fish community rehabilitation in a developing city.Crossref | GoogleScholarGoogle Scholar |
Zhao, C. S., Yang, S. T., Xiang, H., Liu, C. M., Zhang, H. T., Yang, Z. L., Yang, Y., Zhang, Y., Sund, Y., Mitrovic, S. M., Yue, Q., and Lime, R. P. (2015b). Hydrologic and water-quality rehabilitation of environments for suitable fish habitat. Journal of Hydrology 530, 799–814.
| Hydrologic and water-quality rehabilitation of environments for suitable fish habitat.Crossref | GoogleScholarGoogle Scholar |
Zhao, C. S., Shao, N. F., Yang, S. T., Xiang, H., Lou, H. Z., Sun, Y., Yang, Z. Y., Zhang, Y., Yu, X. Y., Zhang, C. B., and Yu, Q. (2018a). Identifying the principal driving factors of water ecosystem dependence and the corresponding indicator species in a Pilot City, China. Journal of Hydrology 556, 488–499.
| Identifying the principal driving factors of water ecosystem dependence and the corresponding indicator species in a Pilot City, China.Crossref | GoogleScholarGoogle Scholar |
Zhao, C., Yu, X., Yang, S., Wang, X., Sun, C., Zhang, Y., Dong, B., and Shao, N. (2018b). Heterogeneity of aquatic ecosystems in a developing city for construction of civilized freshwater ecology, China. Ecohydrology 11, e1990.
| Heterogeneity of aquatic ecosystems in a developing city for construction of civilized freshwater ecology, China.Crossref | GoogleScholarGoogle Scholar |
Zhao, C. S., Yang, Y., Yang, S. T., Xiang, H., Wang, F., Chen, X., Zhang, H. M., and Yu, Q. (2019a). Impact of spatial variations in water quality and hydrological factors on the food-web structure in urban aquatic environments. Water Research 153, 121–133.
| Impact of spatial variations in water quality and hydrological factors on the food-web structure in urban aquatic environments.Crossref | GoogleScholarGoogle Scholar | 30708191PubMed |
Zhao, C. S., Yang, Y., Yang, S. T., Xiang, H., Zhang, Y., Wang, Z. Y., Chen, X., and Mitrovic, S. M. (2019b). Predicting future river health in a minimally influenced mountainous area under climate change. The Science of the Total Environment 656, 1373–1385.
| Predicting future river health in a minimally influenced mountainous area under climate change.Crossref | GoogleScholarGoogle Scholar | 30625666PubMed |
Zhao, C. S., Yang, Y., Yang, S., Gai, Y., Zhang, C., Zhang, H., Xu, T., Yin, X., and Zhang, Z. (2019c). Factors driving temporospatial heterogeneity of fish community health in Jinan City, China. Marine and Freshwater Research 70, 637–646.
| Factors driving temporospatial heterogeneity of fish community health in Jinan City, China.Crossref | GoogleScholarGoogle Scholar |
Zhao, C., Pan, T., Yang, S., Sun, Y., Zhang, Y., Ge, Y., Dong, B., Zhang, Z., and Zhang, H. (2019d). Quantifying the response of aquatic biodiversity to variations in river hydrology and water quality in a healthy water ecology pilot city, China. Marine and Freshwater Research 70, 670–681.
| Quantifying the response of aquatic biodiversity to variations in river hydrology and water quality in a healthy water ecology pilot city, China.Crossref | GoogleScholarGoogle Scholar |