Responses of ciliate community structure to degradation of the Gahai alpine wetland

doi:10.11686/cyxb2017126

Abstract

Abstract: The structural features of ciliate communities can be used to evaluate environmental quality. The aim of this study was to explore the responses of ciliates to environmental change in alpine wetlands and to try to estimate the environmental quality of the Gahai alpine wetlands based on the structural characteristics of the ciliates communities. Species diversity, characteristics of the ciliates community, seasonal distribution of ciliates, and functional-trophic groups were studied and analyzed using the non-flooded Petri dish method, live observations, and a silver staining method from January 2015 to October 2015. In total, 162 species of ciliates were identified, including 30 unnamed species. These 162 species belonged to 66 genera, 46 families, 13 orders, and 3 classes. In this habitat, Kinetofragminophorea was the dominant class with 78 species, accounting for 48.15% of the total number of ciliate species. The next most dominant glass was Polyhymenophorea with 51 species. The number of ciliate species was significantly associated with the temperature and soil moisture content at each site (P<0.05), and more species were detected in summer and autumn than in spring and winter. Analyses of functional-trophic groups of ciliates showed that Bactivores-detritivores was the main group with 118 species, accounting for 72.84% of the total. Some members of this group consumed both algal and debris and others consumed only algal debris. Algivores were the next most dominant group with 51 species, accounting for 31.48% of the total. The main predators were raptors, and nonselective omnivores also fed on ciliates. The results showed that the diet of ciliates in the Gahai alpine wetland is a typical pyramid-type and the community structure of ciliates is stable.

LIU Han-cheng, PU Xiao-jian, LIU Jing, DU Wen-hua. Responses of ciliate community structure to degradation of the Gahai alpine wetland[J]. Acta Prataculturae Sinica, 2018, 27(2): 192-205.

References

[1] Guo H.Discussion on the technology and development of artificial wetland wastewater treatment. Products and Quality, 2016, (32): 108-109.
郭昊. 浅谈人工湿地污水处理技术及其发展. 商品与质量, 2016, (32): 108-109.
[2] Qu M, Hu Y H.The utilization status and sustainable development strategy of wetland resources in Guangdong. Central South Forest Inventory and Planning, 2015, 34(4): 18-21.
屈明, 胡喻华. 广东省湿地资源利用现状与可持续发展对策探讨. 中南林业调查规划, 2015, 34(4): 18-21.
[3] Yang Y X.Main characteristics, progress and prospect of international wetland science research. Progress in Geography, 2002, 21(2): 111-120.
杨永兴. 国际湿地科学研究的主要特点、进展与展望. 地理科学进展, 2002, 21(2): 111-120.
[4] Cheng X, Liu H C, Du H F, et al. Species diversity of sarcodinids and flagellates in the provincial nature reserve of wetland of first meander of Yellow River. Journal of Northwest Normal University (Natural Science), 2009, 45(6): 92-97.
程晓, 刘汉成, 杜海峰, 等. 甘肃黄河首曲湿地省级自然保护区肉鞭虫物种多样性研究. 西北师范大学学报(自然科学版), 2009, 45(6): 92-97.
[5] Zhou Y F.An analysis of the causes of wetland ecological function degradation and its restoration and protection——a case study of Lianhua Lake Wetland in Tieling. Science and Technology Achievements, 2012, (3): 54-55.
周雅芳. 浅析城市湿地生态功能退化的原因及其恢复与保护——以铁岭市莲花湖湿地为例. 科技成果纵横, 2012, (3): 54-55.
[6] Shang H Y, Yin Z D.An analysis on the Tarim River Basin ecological water conveyance. Water Conservancy Science and Technology and Economy, 2014, (2): 17-20.
尚河英, 尹忠东. 塔里木河流域生态输水效益分析. 水利科技与经济, 2014, (2): 17-20.
[7] Sun Z Q, Shi X L, Xu L L, et al. The protozoan community structure and its response to the change of water quality in a typical wetland landscape in summer. Acta Hydrobiologica Sinica, 2013, 37(2): 290-299.
孙志强, 施心路, 徐琳琳, 等. 景观湿地夏季原生动物群落结构与水质关系. 水生生物学报, 2013, 37(2): 290-299.
[8] Compilation Group of “Soil Animal Research Methods Manual”. Soil Animal Research Methods Manual. Beijing: China Forestry Publishing House, 1998: 63-67.
土壤动物研究方法手册编写组. 土壤动物研究方法手册. 北京: 中国林业出版社, 1998: 63-67.
[9] Li G W, Wang Y J, Luo J M, et al. Research on the soil moisture content of Zhalong wetland during thawing period. Journal of Science of Teachers’ College and University, 2009, 29(6): 71-74.
李广文, 王永洁, 罗金明, 等. 融冻时期扎龙湿地土壤含水量变化研究. 高师理科学刊, 2009, 29(6): 71-74.
[10] Foissner W.Estimating the species richness of soil protozoa using the “non-flooded Petri dish method”//Lee J J, Soldo A T. Protocols in Protozoology. Lawrence: Allen Press, 1992.
[11] Song W B. Progress Protozoology.Qingdao: Qingdao Ocean University Press, 1999.
宋微波. 原生动物学专论. 青岛: 青岛海洋大学出版社, 1999.
[12] Lee J J, Leedale G F, Bradbury P.An Illustrated Guide to the Protozoa. 2nd edition. Volume I, Volume II. Lawrence: Allen Press Inc, 2000.
[13] Page F C.An Illustrated Key to Freshwater and Soil Amoebae with Notes on Cultivation and Ecology. Ambleside: Freshwater Biological Association, 1976.
[14] Patterson D J, Hedley S.Free-living Freshwater Protozoa,A Color Guide. London: Wolfe Publishing, 1992.
[15] Patterson D J, Larsen J.The Biology of Free-living Heterotrophic Flagellates. Oxford: Oxford University Press, 1991.
[16] Feng W S, Yang J, Ye Z H, et al. Soil protozoa in wetland treatment system of Pb-Zn mine in Fankou. Chinese Journal of Zoology, 2004, 39(1): 2-11.
冯伟松, 杨军, 叶志鸿, 等. 凡口铅锌矿湿地处理系统的土壤原生动物. 动物学杂志, 2004, 39(1): 2-11.
[17] Hu H J, Li Y Y, Wei Y X, et al.The Algae China. Shanghai: Shanghai Science Technology Press, 1980.
胡鸿钧, 李尧英, 魏印心, 等. 中国淡水藻类. 上海: 上海科学技术出版社, 1980.
[18] Ning Y Z, Shen Y F.New records of protozoa (Sarcomastigophora) in China. Chinese Journal of Zoology, 1999, 34(4): 2-5.
宁应之, 沈韫芬. 中国土壤原生动物新记录种(肉鞭虫门). 动物学杂志, 1999, 34(4): 2-5.
[19] Shen Y F, Zhang Z S, Gong X J, et al.Modern Biomonitoring Techniques Using Freshwater Microbiota. Beijing: Chinese Architecture and Building Press, 1990: 231-524.
沈韫芬, 章宗涉, 龚循矩, 等.微型生物监测新技术. 北京: 中国建筑工业出版社, 1990: 231-524.
[20] Jiang X Z, Shen Y F, Gong X J.Aquatic Invertebrates of the Tibetan Plateau. Beijing: Science Press, 1983.
蒋燮治, 沈韫芬, 龚循矩.西藏水生无脊椎动物. 北京: 科学出版社, 1983.
[21] Angeler D G, Alvarez-Cobelas M, Rojo C, et al. The significance of water inputs to plankton biomass and trophic relationships in a semi-arid freshwater wetland (central Spain). Journal of Plankton Research, 2000, 22(11): 2075-2093.
[22] Berger H, Foissner W.Morphology and biomentry of some soil hypotrichs (Protozoa: Ciliophora). Zoologische Jahrbücher Systematik, 1987, 114: 193-239.
[23] Berger H.Monograph of the Oxytrichidae (Ciliophora, Hypotrichia). London: Kluwer Academic Publishers, 1999.
[24] Berger H, Foissner W.Morphology and biometry of some soil hypotrichs (Protozoa, Ciliophora) from Europe and Japan. Bulletin of the British Museum of Natural History, 1989, 55(1): 19-46.
[25] Wickham S, Nagel S, Hillebrand H.Control of epibenthic ciliate communities by grazers and nutrients. Aquatic Microbial Ecology, 2004, 35: 153-162.
[26] Ye X, Liao Q Y, Xu R L.Ecological research of protozoan communities on five different habitats of arbor barks in Sun Yat-sen University Campus. Acta Scientiarum Naturalium Universitatis Sunyatseni, 2008, 47(S1): 77-84.
叶欣, 廖庆玉, 徐润林. 中山大学校园5种乔木树皮上原生动物群落的生态学研究. 中山大学学报(自然科学版), 2008, 47(S1): 77-84.
[27] Foissner W.Tropical protozoan diversity: 80 ciliate species (Protozoa, Ciliophora) in a soil sample from a tropical dry forest of Costa Rica, with descriptions of four new genera and seven new species. Archiv für Protistenkunde, 1995, 145: 37-79.
[28] Hardoim E L, Heckman C W.The seasonal succession of biotic communities in wetlands of the tropical wet-and-dry climatic zone: IV. The free-living sarcodines and ciliates of the Pantanal of Mato Grosso, Brazil. Internationale Revue der Gesamten Hydrobiologie und Hydrographie, 2007, 81(3): 367-384.
[29] John M D, Ward A K.Influence of phagotrophic protistan bacterivory in determining the fate of dissolved organic matter (DOM) in a wetland microbial food web. Microbial Ecology, 1997, 33(2): 149-162.
[30] Wickham S, Gieseke A, BerNinger U G. Benthic ciliate identification and enumeration: an improved methodology and its application. Aquatic Microbial Ecology, 2000, 22: 79-91.
[31] Jaccard P.Nouvelles recherches sur la distribution florale. Bulletin de la Société vaudoise des Sciences Naturelles, 1908, 44: 223-270.
[32] Ning Y Z, Shen Y F.Soil protozoa in typical zones of China: I. Faunal characteristics and distribution of species. Acta Zoologica Sinica, 1998, 44(1): 5-9.
宁应之, 沈韫芬. 中国典型地带土壤原生动物: Ⅰ. 区系特征和物种分布. 动物学报, 1998, 44(1): 5-9.
[33] Ning Y Z, Su C, Wang H J, et al. Community characteristics of ciliates in Plateau Swamp wetland of Gannan, Gansu province in summer. Journal of Northwest Normal University (Natural Science), 2013, 49(3): 81-86.
宁应之, 苏苌, 王红军, 等. 甘肃甘南高原沼泽湿地夏季纤毛虫群落特征. 西北师范大学学报(自然科学版), 2013, 49(3): 81-86.
[34] Ning Y Z, Wang F G, Du H F, et al. Ciliate species diversity and its relationships with environmental factors in Plateau Swamp wetlands of southern Gansu Province, Northwest China in autumn. Chinese Journal of Ecology, 2013, 32(3): 634-640.
宁应之, 王芳国, 杜海峰, 等. 甘南高原沼泽湿地秋季纤毛虫物种多样性及其与环境因子的关系. 生态学杂志, 2013, 32(3): 634-640.
[35] Ning Y Z, Liu G L, Dang H, et al. Community characteristics of Ciliates in Plateau Swamp Wetland of Gannan, Gansu in winter. Journal of Anhui Agriculture Science, 2014, 42(4): 1059-1062.
宁应之, 刘光龙, 党怀, 等. 甘肃省甘南高原沼泽湿地冬季纤毛虫群落特征. 安徽农业科学, 2014, 42(4): 1059-1062.
[36] Ning Y Z, Wu W N, Liu H C, et al. Community characteristics of ciliates in Plateau Swamp wetland of Gannan in spring. Journal of Northwest Normal University (Natural Science), 2014, 50(2): 87-92.
宁应之, 武维宁, 刘汉成, 等. 甘南高原沼泽湿地春季纤毛虫群落结构特征. 西北师范大学学报(自然科学版), 2014, 50(2): 87-92.
[37] Ba S.Study on the Characteristics of Community Structure of Protozoa, Lhasa Lhalu Wetland National Nature Reserve, Tibet. Lanzhou: Northwest Normal University, 2013.
巴桑. 西藏拉鲁湿地国家级自然保护区原生动物群落结构特征. 兰州: 西北师范大学, 2013.
[38] Tian J Y.Impact factor of growth and distribution of Protozoa. Natural Science Journal of Harbin Normal University, 2012, 28(4): 61-63.
田佳玉. 原生动物生长和分布的影响因子. 哈尔滨师范大学自然科学学报, 2012, 28(4): 61-63.
[39] Liao C H, Li J X, Yang Y P, et al. The community of soil animal in tropical rain forest in Jianfeng Mountain, Hainan Island, China: Relationship between seasonal change of community structure and climatic factors. Acta Ecologica Sinica, 2003, 23(1): 139-147.
廖崇惠, 李健雄, 杨悦屏, 等. 海南尖峰岭热带林土壤动物群落—群落结构的季节变化及其气候因素. 生态学报, 2003, 23(1): 139-147.
[40] Ning Y Z, Shen Y F.Observation of feeding habits of soil protozoa in Chinese six typical zones. Zoological Research, 1998, 19(5): 397-400.
宁应之, 沈韫芬. 中国典型地带土壤原生动物食性的观察. 动物学研究, 1998, 19(5): 397-400.