A rice variety with a high straw biomass retained nitrogen and phosphorus without affecting soil bacterial species

被引:0
|
作者
Xinqiang Liang
Fayong Li
Sheng Wang
Guifen Hua
Miaomiao He
Guangming Tian
Sangar Khan
Ravin Poudel
Karen A. Garrett
机构
[1] Zhejiang University,College of Environmental and Resource Sciences
[2] Hangzhou Dianzi University,College of Life Information Science and Instrument Engineering
[3] Hangzhou Normal University,Department of Life and Environmental Science
[4] University of Florida,Plant Pathology Department, Institute for Sustainable Food Systems, and Emerging Pathogens Institute
来源
Soil Ecology Letters | 2020年 / 2卷
关键词
Agricultural wetland; Network analysis; Nutrient; Rice variety; Soil bacterial communities;
D O I
暂无
中图分类号
学科分类号
摘要
It is well documented that rice paddy fields act as agricultural wetlands that remove or retain nutrients; however, their associated effects on soil microbial communities are rarely reported. The present study evaluates the impact of rice variety on nutrient removal via plant uptake, nutrient retention in the soil, and bacterial associations in rice paddy fields, using a network analysis that compares the soil bacterial communities of two rice varieties. We found that the high-straw rice variety (YD-1) allows uptake of a high amount of nitrogen (N) and phosphorus (P) from paddy rice fields via harvesting, but causes less residual total N and P to remain in the soil. However, both rice varieties (YD-1 and XS-134 (Xiushui-134)) had non-significant effects on the dominant bacterial taxa. The short-term response of bacterial community diversity to rice variety is found to be mainly due to less frequently recovered species. A network analysis that incorporates soil nutrients as nodes, along with bacterial taxa, found that only one node representing the total P related to the non-dominant species had an indirect association with the rice straw biomass. The observed short-term impact of the two rice varieties (XS-134 and YD-1) on soil bacterial diversity and nutrient surplus in these agricultural wetlands is limited under a high level of fertilization.
引用
收藏
页码:131 / 144
页数:13
相关论文
共 41 条
  • [31] Five years nitrogen reduction management shifted soil bacterial community structure and function in high-yielding 'super' rice cultivation
    Wang, Juanjuan
    Xie, Ruqing
    He, Nanan
    Wang, Wanlu
    Wang, Guiliang
    Yang, Yanju
    Hu, Qing
    Zhao, Haitao
    Qian, Xiaoqing
    AGRICULTURE ECOSYSTEMS & ENVIRONMENT, 2024, 360
  • [32] Nitrogen transformations in vertical flow systems with and without rice (Oryza sativa) studied with a high-resolution soil-water profiler
    Zhou, Sheng
    Nakashimada, Yutaka
    Hosomi, Masaaki
    ECOLOGICAL ENGINEERING, 2009, 35 (02) : 213 - 220
  • [33] Long-term biochar-based fertilizer substitution promotes carbon, nitrogen, and phosphorus acquisition enzymes in dryland soils by affecting soil properties and regulating bacterial community
    Wang, Jun
    Sun, Lijuan
    Sun, Yafei
    Yang, Shiyan
    Qin, Qin
    Xue, Yong
    APPLIED SOIL ECOLOGY, 2025, 206
  • [34] Rice-fish coculture without phosphorus addition improves paddy soil nitrogen availability by shaping ammonia-oxidizing archaea and bacteria in subtropical regions of South China
    Liu, Xing
    Sun, Daolin
    Huang, Huaqiao
    Zhang, Jiaen
    Zheng, Hongjun
    Jia, Qi
    Zhao, Min
    SCIENCE OF THE TOTAL ENVIRONMENT, 2024, 927
  • [35] Silicon in soil and its interaction with nitrogen, phosphorus, and potassium nutrients on rice yield: A case study of paddy fields in the Taihu Lake region, China, without a history of silicon fertilization
    Huang, Sihua
    Pu, Lijie
    He, Gaili
    Wang, Xiaoqing
    Chen, Dejing
    Xie, Xuefeng
    Qie, Lu
    Dan, Yang
    Zhang, Rui
    Gong, Zhongshun
    Lu, Yumeng
    SOIL & TILLAGE RESEARCH, 2024, 238
  • [36] Effects of Straw Returning and Biochar Addition on Greenhouse Gas Emissions from High Nitrate Nitrogen Soil After Flooding in Rice-vegetable Rotation System in Tropical China
    Hu T.-Y.
    Che J.-Y.
    Hu Y.-J.
    Chen Q.-Q.
    Zhang D.-M.
    Lei F.
    Zeng J.-H.
    Tang S.-R.
    Wu Y.
    Meng L.
    Huanjing Kexue/Environmental Science, 2024, 45 (03): : 1692 - 1701
  • [37] Temporal dynamics of total and free-living nitrogen-fixing bacterial community abundance and structure in soil with and without history of arsenic contamination during a rice growing season
    Arindam Chakraborty
    Ekramul Islam
    Environmental Science and Pollution Research, 2018, 25 : 4951 - 4962
  • [39] An Opportunity for Regenerative Rice Production: Combining Plastic Film Cover and Plant Biomass Mulch with No-Till Soil Management to Build Soil Carbon, Curb Nitrogen Pollution, and Maintain High-Stable Yield
    Lv, Shi Hua
    Dong, Yu Jiao
    Jiang, Yuan
    Padilla, Hilario
    Li, Joanne
    Uphoff, Norman
    AGRONOMY-BASEL, 2019, 9 (10):
  • [40] Silicon in soil and its interaction with nitrogen, phosphorus, and potassium nutrients on rice yield: A case study of paddy fields in the Taihu Lake region, China, without a history of silicon fertilization (vol 238, 106027, 2024)
    Huang, Sihua
    Pu, Lijie
    He, Gaili
    Wang, Xiaoqing
    Chen, Dejing
    Xie, Xuefeng
    Qie, Lu
    Dan, Yang
    Zhang, Rui
    Gong, Zhongshun
    Lu, Yumeng
    SOIL & TILLAGE RESEARCH, 2024, 239