RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN >> 2023, Vol. 32 >> Issue (3): 498-506.doi: 10.11870/cjlyzyyhj202303005

Previous Articles     Next Articles

Spatial Distribution Pattern and Driving Factors of Nematode-trapping Fungi in Jinsha River Basin

ZHANG Xin1,2, QI Yu-kun1,2, ZAHNG Fa1,2, DENG Wei1,2, YANG Xiao-yan1,2,3, XIAO Wen1,2,3,4,5,6   

  1. (1. Institute of Eastern-Himalaya Biodiversity Research, Dali 671003, China; 2. The “Key Laboratory of Yunnan State Education Department on Er’hai Lake Basin Protection and the Sustainable Development Research”, Dali 671003, China; 3. The provincial innovation team of biodiversity conservation and utility of the three parallel rivers region from Dali University, Dali 671003, China; 4. Collaborative Innovation Center for Biodiversity and Conservation in the Three Parallel Rivers Region of China, Dali 671003, China; 5. Yunling black-and-white snub-nosed monkey observation and research station of Yunnan province, Dali, Yunnan 671003, China; 6.Center for Cultural Ecology in Northwest Yunnan, Dali, Yunnan 671003, China)
  • Online:2023-03-20 Published:2023-04-19

PDF (PC)

39

Abstract: To examine the spatial distribution patterns of nematode-trapping fungi (NTF) and driving factors in the Jinsha River Basin in North China, 54 sampling sites were set up along the river, and 5 samples of aquatic sediment and 5 samples of terrestrial soil were taken from each sampling site. The NTF strains were isolated, purified, and identified using conventional pure culture techniques along with morphological and molecular biology techniques. 540 samples were collected and a total of 567 strains, classified into 29 species and 3 genera, were isolated. The upstream stream included 79 strains, which were classified into 16 species from 2 genera; the middle stream contained 205 strains, which were classified into 18 species from 2 genera; and the downstream contained 283 strains, which were classified into 21 species from 3 genera. From upstream to lower, NTF detection rates and species richness increased. Terrestrial soil had 354 strains classified into 23 species from 3 taxa, and aquatic silt included 213 strains classified into 22 species from 2 genera. In comparison to aquatic sediment, terrestrial soil had greater detection rates and species richness of NTF. (1) Among the geographical environmental factors, both longitude, latitude and altitude had significant effects on the species richness and detection rate of NTF (P<0.05).(2) Under phenological conditions, the average annual temperature had significant effects on species richness and detection rate of NTF (P<0.05), while average annual rainfall had no significant effects on species richness and detection rate of NTF (P>0.05).(3) In terms of soil physical and chemical properties, soil pH, total potassium and total phosphorus had extremely significant effects on species richness (P<0.01), soil total phosphorus, total potassium and organic matter had significant effects on species detection rate (P<0.05), while soil total nitrogen had no significant effects on species distribution of NTF (P>0.05).Geographical factors, phenological conditions and soil physicochemical factors all jointly drive the formation of this pattern to different degrees.

No related articles found!
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] ZHUANG Rulong, MI Kena, LIANG Longwu. China’s Industrial Wastewater Discharge Pattern and Its Driving Factors[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2018, 27(08): 1765 .
[2] . Characteristics of Mercury in Surface Sediments of Lakes from Parks in Shanghai City and its Environmental Pollution Assessment[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, , (): 0 .
[3] TANG En-bin, ZHANG Mei-qing.  

Urban Rail Accessibility and Interurban Spatial Effects on the Background of High-Speed rail in Jiangxi Province [J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2018, 27(10): 2241 -2249 .
[4] GU Zheng-ming, JIN Xiao-bin, SHEN Chun-zhu, JIN Zhi-feng, ZHOU Yin-kang. Variation and Influence Factors of Water Conservation Service Function in Jiangsu Province from 2000 to 2015[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2018, 27(11): 2453 -2462 .
[5] GAO Jie-zhi , ZHENG Hua-wei, LIU You-zhao. Diagnosis of the Multi-functionality of Land Use Based on an  Entropy Weight TOPSIS Model[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2018, 27(11): 2496 -2504 .
[6] QIU Yu , CHEN Ying-zi , RAO Qing-hua , LIN Xiu-zhu , CHEN Wen-hua. Trans-regional Eco-Compensation Research of Minjiang River Basin Based on Pollution Rights[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2018, 27(12): 2839 -2847 .
[7] WANG Bing, CHENG Ting. Space-time Evolution of Environmental Total FactorProductivity of Cities in the Central Region of China:Based on Malmquist-Luenberger Productivity Index Method[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2019, 28(01): 48 -59 .
[8] WANG Gang-yi, LIU Jie. Coordinating Evaluation of Water Resources Environment and Economic Development Based on Improved Water Ecological Footprint:A Case Study of Central Plains Urban Agglomeration[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2019, 28(01): 80 -90 .
[9] HUANG Xiao-hui, WANG Li-li, LU Qian. Capital Endowment Influencing on Farmers Value Perception of Soil and Water Conservation Technology——Take the Loess Plateau as An Example[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2019, 28(01): 222 -230 .
[10] GUO Guan-cheng, PENG Zi-xin, ZHOU Zhi-wei. Impact of Industrial Enterprise Type of Macro Perspective on Industrial Land Use Efficiency[J]. RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, 2019, 28(02): 241 -249 .
Copyright © RESOURCES AND ENVIRONMENT IN THE YANGTZE BASIN, All Rights Reserved.
Powered by Beijing Magtech Co. Ltd