Temporal-spatial distribution and ecological evaluation of macroinvertebrate functional feeding groups in Yongding River Basin

doi:10.13287/j.1001-9332.202212.038

Abstract

Abstract: We investigated community structure of macroinvertebrate, water environment factors, hydrological factors at 23 sampling sites of the Yongding River basin from spring 2017 (April) to autumn 2017 (November). We analyzed the composition, spatial and temporal distribution of the macroinvertebrate functional feeding groups, as well as their responses to changes in riverine habitat. A total of 78 macroinvertebrate species were identified, with 52, 50 and 53 macroinvertebrate species in spring, summer and autumn respectively. The dominant functional feeding groups were gather-collectors, followed by predators, while the proportion of scrapers, filter-collectors and shredders were extremely low. Dominant species in the three seasons were all gather-collectors, including Orthocladius, Rheotanytarsus, Cricotopus in spring, Glyptotendipes in summer, and Polypedilum, Chironomus, Orthocladius in autumn. Results of redundancy analysis showed that the functional feeding groups of macroinvertebrate community structure were mainly influenced by water temperature, flow velocity, salinity, and total phosphorus in spring, by total phosphorus, dissolved oxygen, conductivity and flow capacity in summer, and by total phosphorus and dissolved oxygen in autumn. Total phosphorus had positive correlation with gather-collectors in all three seasons, indicating that the functional feeding groups of macroinvertebrates were affected by water pollution. The evaluation based on the metrics of functional feeding groups showed that: 1) in terms of material cycle, primary productivity of Guishui River were significantly higher than other regions, and that in autumn were significantly higher than other seasons. The secondary productivity and decomposition capacity of Yanghe River were significantly higher than other regions, and those in spring were significantly higher than other seasons. The autotrophy/heterotrophy of Yanghe River was significantly lower than other regions, and that in spring were significantly higher than other seasons. 2) The longitudinal transport capacity of Sanggan River was significantly higher than other regions, and that in autumn was significantly higher than other seasons. 3) The lateral input capacity of Guishui River was significantly higher than other regions, and that in summer was significantly higher than other seasons.

Key words: Yongding River basin, functional feeding group, temporal-spatial distribution, ecological evaluation

ZHANG Yu-hang, PENG Wen-qi, PENG Shuai, ZHANG Min, ZHANG Hai-ping, XIE Ying, GE Jin-jin, YU Yang, QU Xiao-dong. Temporal-spatial distribution and ecological evaluation of macroinvertebrate functional feeding groups in Yongding River Basin[J]. Chinese Journal of Applied Ecology, 2022, 33(12): 3433-3440.

References

[1] 马陶武, 黄清辉, 王海, 等. 太湖水质评价中底栖动物综合生物指数的筛选及生物基准的确立. 生态学报, 2008, 28(3): 1192-1200
[2] 张敏, 蔡庆华, 渠晓东, 等. 三峡成库后香溪河库湾底栖动物群落演变及库湾纵向分区格局动态. 生态学报, 2017, 37(13): 4483-4494
[3] Weigel BM, Wang L, Rasmussen PW, et al. Relative influence of variables at multiple spatial scales on stream macroinvertebrates in the northern lakes and forest ecoregion, U.S.A. Freshwater Biology, 2003, 48: 1440-1461
[4] Gombeer SC, Knapen D, Bervoets L. The influence of different spatial-scale variables on caddisfly assemblages in Flemish lowland streams. Ecological Entomology, 2011, 36: 355-368
[5] Heino J, Louhi P, Muotka T. Identifying the scales of variability in stream macroinvertebrate abundance, functional composition and assemblage structure. Freshwater Biology, 2004, 49: 1230-1239
[6] Heino J. Functional biodiversity of macroinvertebrate assemblages along major ecological gradients of boreal headwater streams. Freshwater Biology, 2005, 50: 1578-1587
[7] Barbour MT. Rapid Bioassessment Protocols for Use in Wadeable Streams and Rivers: Periphyton, Benthic Macroinvertebrates and Fish. Washington DC: US Environmental Protection Agency, Office of Water, 1999: 7-20
[8] Cummins KW. Structure and function of stream ecosystems. Bioscience, 1974, 24: 631-641
[9] Brosse S, Grenouillet G, Gevrey M, et al. Small-scale gold mining erodes fish assemblage structure in small neotropical streams. Biodiversity and Conservation, 2011, 20: 1013-1026
[10] 彭松耀, 李新正. 乳山近海大型底栖动物功能摄食类群. 生态学报, 2013, 33(17): 5274-5285
[11] 沈洪艳, 曹志会, 刘军伟, 等. 太子河流域大型底栖动物功能摄食类群与环境要素的关系. 中国环境科学, 2015, 35(2): 579-590
[12] 户作亮. 永定河综合治理与生态修复战略实践. 中国水利, 2019(22): 16-18
[13] 张宇航, 彭文启, 刘培斌, 等. 永定河流域春季大型底栖动物群落结构和空间格局. 中国环境监测, 2019, 35(4): 31-39
[14] 张宇航, 张敏, 彭文启, 等. 永定河流域大型底栖动物群落分布格局及其影响因子. 应用生态学报, 2020, 31(11): 3880-3888
[15] 孔凡青, 崔文彦, 周绪申. 基于大型底栖动物完整性指数(B-IBI)的永定河水系生态健康评价. 生态环境学报, 2018, 27(3): 550-555
[16] 慕林青, 张海萍, 赵树旗, 等. 永定河底栖动物生物完整性指数构建与健康评价. 环境科学研究, 2018, 31(4): 697-707
[17] 《中国河湖大典》编纂委员会. 中国河湖大典: 海河卷. 北京: 中国水利水电出版社, 2013: 62-91
[18] Throp JH, Covich AP. Ecology and classification of North American freshwater invertebrates. New York: Academic Press, 2009
[19] Merritt RW, Cummins KW. An Introduction to the Aquatic Insects of North America. Dubuque, Canada: Kendall Hunt, 1996
[20] 周长发. 中国大陆蜉蝣目分类研究. 天津: 南开大学出版社, 2002
[21] 国家环保总局. 水和废水监测分析方法(第四版). 北京: 中国环境科学出版社, 2002
[22] Yoshimura C, Tockner K, Omura T, et al. Species diversity and functional assessment of macroinvertebrate communities in Austrian rivers. Limnology, 2006, 7: 63-74
[23] 朱晨曦, 莫康乐, 唐磊, 等. 漓江大型底栖动物功能摄食类群时空分布及生态效应. 生态学报, 2020, 40(1): 60-69
[24] 孙小玲, 蔡庆华, 李凤清, 等. 春季昌江大型底栖无脊椎动物群落结构及功能摄食类群的空间分布. 应用与环境生物学报, 2012, 18(2): 163-169
[25] 蒋万祥, 蔡庆华, 唐涛, 等. 香溪河水系大型底栖动物功能摄食类群生态学. 生态学报, 2009, 29(10): 5207-5218
[26] Mérigoux S, Dolédec S. Hydraulic requirements of stream communities: A case study on invertebrates. Freshwater Biology, 2004, 49: 600-613
[27] Vannote RL, Wayne MG, Cummins KW, et al. The River Continuum Concept. Canadian Journal of Fisheries and Aquatic Sciences, 1980, 37: 130-137
[28] 渠晓东, 蔡庆华, 谢志才, 等. 香溪河附石性大型底栖动物功能摄食类群研究. 长江流域资源与环境, 2007, 16(6): 738-743
[29] 魏艳秀, 武佳. 妫水河两侧重要地表水源区生态建设工程设计. 河北水利水电技术, 2014(3): 60-62
[30] 赵茜, 高欣, 张远, 等. 广西红水河大型底栖动物群落结构时空分布特征. 环境科学研究, 2014, 27(10): 1150-1156
[31] 任海庆, 袁兴中, 刘红, 等. 环境因子对河流底栖无脊椎动物群落结构的影响. 生态学报, 2015, 35(10): 3148-3156
[32] 殷旭旺, 韩洁, 王博涵, 等. 太子河流域底栖动物群落结构及其与环境因子的关系. 水产学杂志, 2017, 30(3): 40-44
[33] 寿鹿, 曾江宁, 廖一波, 等. 瓯江口海域大型底栖动物分布及其与环境的关系. 应用生态学报, 2009, 20(8): 1958-1964
[34] 杨柏贺, 马思琦, 王汨, 等. 北运河水系大型底栖动物摄食功能群多样性及时空分布特征. 河南师范大学学报: 自然科学版, 2019, 47(1): 105-111
[35] 王银东, 熊邦喜, 陈才保, 等. 环境因子对底栖动物生命活动的影响. 浙江海洋学院学报: 自然科学版, 2005, 24(3): 253-257
[36] 王博涵, 吴丹, 张吉, 等. 济南河流大型底栖动物摄食功能群多样性及时空动态. 生态学报, 2017, 37(21): 7128-7139