Characteristics of heavy metals and bacterial community in manure and surrounding soil of cattle farm in Xiji, Ningxia, China

doi:10.13287/j.1001-9332.202009.038

Abstract

Abstract: To understand the contamination status of heavy metals and bacterial community in the manure and surrounding soils of cattle farm in Ningxia, we collected cattle manure at different breeding periods (lactation, calf, growing, pre-fattening and post-fattening periods) and soil samples from the largest beef breeding area in the region by different distances, with the waste land far away as control. We measured heavy metal contents and the composition and diversity of bacterial community in manure and soil samples. The results showed that: 1) The contents of Cu, Zn, Cd, Pb and Hg in cattle manure were 33.8%-95.8% lower than the national average, while As content was 94.7% higher than the national average. During the breeding periods, the change tendencies of seven kinds of heavy metals in cattle manure were different. The contents of Cu, Cd, Hg and Cr of cattle manure in the pre-fattening period were the highest across all periods. The comprehensive pollution index of heavy metals in pre-fattening and post-fattening periods of cattle manure was highest in all periods. 2) The contents of Cu and Zn in the soils with cattle manure application were higher than control, and the content of Zn were significantly higher than surrounding soil samples. All single and comprehensive soil pollution indices of soil were safe. 3) During the breeding periods, Sequence, OTU and Chao1 index of cattle manure had no specific change. Sequence, OTU and Chao1 of soil with cattle manure application were higher than the soil around the farm. 4) The types of dominant phylum were less in the manure. The relative abundance of Firmicutes was the highest, followed by Bacteroidetes and Proteobacteria. The relative abundance of Firmicutes in the growing period was significantly lower than other breeding periods, and that of other phylum had little variation among periods. The cattle farm did not affect bacterial community in the surrounding soil. The cattle manure application didn’t change the relative abundance of bacteria at the phyla level. The abundance of Gp, Gemmatimona, Lysobacte, Subdivision3_genera_incertae_sedis were significantly higher than control and surrounding soil. 5) Organic matter, pH, EC, total nitrogen, total potas-sium, Cd and As significantly affected bacterial diversity and component abundance in cattle manure. Soil pH, total phosphorus and Hg significantly influenced soil bacterial diversity and component abundance. On the whole, the effects of physicochemical properties in cattle manure and soil on bacterial community were more significant than heavy metals. Our results could provide scientific basis for selecting the variety and dosage of feed and veterinary drugs in local cattle farms, as well as the rational application of organic fertilizers.

Key words: cattle manure, soil, heavy metal, bacterial community, physiochemical property

ZHANG Jun-hua, SHANG Tian-hao, LIU Ji-li, SUN Yuan, JIA Ping-ping. Characteristics of heavy metals and bacterial community in manure and surrounding soil of cattle farm in Xiji, Ningxia, China[J]. Chinese Journal of Applied Ecology, 2020, 31(9): 3119-3130.

References

[1] Herrero M, Henderson B, Havlík P, et al. Greenhouse gas mitigation potentials in the livestock sector. Nature Climate Change, 2016, 6: 452-461
[2] 曲成闯, 陈效民, 张志龙. 施用生物有机肥对黄瓜连作土壤有机碳库和酶活性的持续影响. 应用生态学报, 2019, 30(9): 3145-3154 [Qu C-C, Chen X-M, Zhang Z-L, et al. Long-term effects of bio-organic fertili-zer application on soil organic carbon pool and enzyme activity of cucumber continuous cropping. Chinese Journal of Applied Ecology, 2019, 30(9): 3145-3154]
[3] Xu Y, Li J, Zhang XB, et al. Data integration analysis: Heavy metal pollution in China’s large-scale cattle rearing and reduction potential in manure utilization. Journal of Cleaner Production, 2019, 232: 308-317
[4] Peng H, Chen YL, Weng LP, et al. Comparisons of heavy metal input inventory in agricultural soils in North and South China: A review. Science of the Total Environment, 2019, 660: 776-786
[5] Yang XP, Li Q, Tang Z, et al. Heavy metal concentrations and arsenic speciation in animal manure composts in China. Waste Management, 2017, 64: 333-339
[6] Torres E, Lozano A, Macías F, et al. Passive elimination of sulfate and metals from acid mine drainage using combined limestone and barium carbonate systems. Journal of Cleaner Production, 2018, 182: 114-123
[7] Zhou DM, Hao XZ, Wang YJ, et al. Copper and Zn uptake by radish and pakchoi as affected by application of livestock and poultry manures. Chemosphere, 2005, 59: 167-175
[8] Qian XY, Wang ZQ, Shen GX, et al. Heavy metals accumulation in soil after 4 years of continuous land application of swine manure: A field-scale monitoring and modeling estimation. Chemosphere, 2018, 210: 1029-1034
[9] 王宁, 南宏宇, 冯克云. 化肥减量配施有机肥对棉田土壤微生物生物量、酶活性和棉花产量的影响. 应用生态学报, 2020, 31(1): 173-181 [Wang N, Nan H-Y, Feng K-Y. Effects of chemical fertilizer and organic fertilizer on soil microbial biomass, enzyme activity and cotton yield in cotton field. Chinese Journal of Applied Ecology, 2020, 31(1): 173-181]
[10] Xun WB, Zhao J, Xue C, et al. Significant alteration of soil bacterial communities and organic carbon decomposition by different long-term fertilization management conditions of extremely low-productivity arable soil in South China. Environmental Microbiology, 2016, 18: 1907-1917
[11] Monard C, Jeanneau L, Garrec JL, et al. Short-term effect of pig slurry and its digestate application on biochemical properties of soils and emissions of volatile organic compounds. Applied Soil Ecology, 2019, https://doi.org/10.1016/j.apsoil. 2019.103376
[12] Chodak M, Gołebiewski M, Morawska-Płoskonka J, et al. Diversity of microorganisms from forest soils diffe-rently polluted with heavy metals. Applied Soil Ecology, 2013, 64: 7-14
[13] Kandeler E, Tscherko D, Bruce K, et al. Structure and function of the soil microbial community in microhabitats of a heavy metal polluted soil. Biology and Fertility of Soils, 2000, 32: 390-400
[14] Narendrula-Kotha R, NkongoloKK. Bacterial and fungal community structure and diversity in a mining region under long-term metal exposure revealed by metagenomics sequencing. Ecological Genetics and Genomics, 2017, 2: 13-24
[15] 黄健, 朱旭炎, 陆金, 等. 狮子山矿区不同土地利用类型对土壤微生物群落多样性的影响. 环境科学, 2019, 40(12): 5550-5560 [Huang J, Zhu X-Y, Lu J, et al. Effects of different land use types on microbial community diversity in Shizishan Mining Area. Environmental Science, 2019, 40(12): 5550-5560]
[16] 石宁宁, 丁艳锋, 赵秀峰, 等. 某农药工业园区周边土壤重金属含量与风险评价. 应用生态学报, 2010, 21(7): 1835-1843 [Shi N-N, Ding Y-F, Zhao X-F, et al. Heavy metals content and pollution risk assessment of cropland soils around a pesticide industrial park. Chinese Journal of Applied Ecology, 2010, 21(7): 1835-1843]
[17] 中华人民共和国农业部. 中华人民共和国农业行业标准: 有机肥料(NY525—2012). 北京: 中国标准出版社, 2012 [Ministry of Agriculture of the People’s Republic of China. Agricultural industry standard of the People’s Republic of China: Organic fertilizer (NY525-2012). Beijing: China Standard Press, 2012]
[18] Verdonck O, Szmidt RAK. Compost Specifications. Acta Horticulture, 1998, 469: 169-177
[19] Wang H, Dong YH, Yang YY, et al. Changes in heavy metal contents in animal feeds and manures in an intensive animal production region of China. Journal of Environmental Sciences, 2013, 25: 2435-2442
[20] 姜海春. 如何做好肉牛的科学育肥. 中国畜禽种业, 2019(9): 112-113 [Jiang H-C. How to fatten beef cattle scientifically. Chinese Livestock and Poultry Breeding, 2019(9): 112-113]
[21] 生态环境部、国家市场监督管理总局. 土壤环境质量:农用地土壤污染风险管控标准(GB 15618—2018). 北京: 中国标准出版社, 2018 [Ministry of Ecology and Environment, State Administration of Market Regulation. Soil Environmental Quality: Risk Control Standard for Soil Contamination of Agricultural Land (GB 15618-2018). Beijing: China Standards Press, 2018]
[22] Griffiths BS, Philippot L. Insights into the resistance and resilience of the soil microbial community. FEMS Microbiology Reviews, 2013, 37: 112-129
[23] Schneider AR, Gommeaux M, Duclercq J, et al. Response of bacterial communities to Pb smelter pollution in contrasting soils. Science of the Total Environment, 2017, 605-606: 436-444
[24] 黄薇, 刘兰英, 吴妙鸿, 等. 养殖废水处理系统中微生物菌群结构及动态变化. 中国环境科学, 2019, 39(2): 839-848 [Huang W, Liu L-Y, Wu M-H, et al. Microbial community structure and dynamics in swine wastewater treatment system. China Environmental Science, 2019, 39(2): 839-848]
[25] 李春红. 三种硬蜱肠道菌群及其部分菌株生物学特性分析. 硕士论文. 长沙: 湖南农业大学, 2012 [Li C-H. Intestinal Flora in Three Hard Ticks and Biological Characteristics Analysis of Some Strains. Master Thesis. Changsha: Hunan Agricultural University, 2012]
[26] Pennanen T. Microbial communities in boreal coniferous forest humus exposed to heavy metals and changes in soil pH: A summary of the use of phospholipids fatty acid, Biolog^© and 3H-thymidine incorporation methods in field studies. Geoderma, 2001, 100: 91-126
[27] 陈熙, 刘以珍, 李金前, 等. 稀土尾矿土壤细菌群落结构对植被修复的响应. 生态学报, 2016, 36(13): 3943-3950 [Chen X, Liu Y-Z, Li J-Q, et al. Response of a rare earth tailing soil bacterial community structure to vegetation restoration. Acta Ecologica Sinica, 2016, 36(13): 3943-3950]
[28] Mounaouer B, Nesrine A, Abdennaceur H. Identification and characterization of heavy metal-resistant bacteria selected from different polluted sources. Desalination and Water Treatment, 2014, 52: 7037-7052
[29] 尹贞. Cr(Ⅵ)污染土壤的微生物多样性分析与Cr(Ⅵ)还原菌的筛选研究. 硕士论文. 长沙: 中南大学, 2012 [Yin Z. Research on the Microbial Diversity of Cr(Ⅵ)-Polluted Soil and the Isolation of Cr(Ⅵ)-Reducing Strains. Master Thesis. Changsha: Central South University, 2012]
[30] 丁苏丽, 张祁炅, 董俊, 等. 深港红树林沉积物微生物群落多样性及其与重金属的关系. 生态学杂志, 2018, 37(10) : 3018-3030 [Ding S-L, Zhang Q-J, Dong J, et al. Microbial community structure and its relationship to heavy metals in Shenzhen and Hong Kong mangrove sediments. Chinese Journal of Ecology, 2018, 37(10): 3018-3030]
[31] Jiang L, Song M, Yang L, et al. Exploring the influence of environmental factors on bacterial communities within the rhizosphere of the Cu-tolerant plant, Elsholtzia splendens. Scientific Reports, 2016, 6: 36302
[32] 刘秉儒. 贺兰山东坡典型植物群落土壤微生物量碳、氮沿海拔梯度的变化特征. 生态环境学报, 2010, 19(4): 883-888 [Liu B-R. Changes in soil microbial biomass carbon and nitrogen under typical plant communities along an altitudinal gradient in east side of Helan Mountain. Ecology and Environmental Sciences, 2010, 19(4): 883-888]
[33] Li XQ, Meng DL, Li J, et al. Response of soil microbial communities and microbial interactions to long-term heavy metal contamination. Environmental Pollution, 2017, 231: 908-917
[34] Du H, Harata N, Li F. Responses of riverbed sediment bacteria to heavy metals: Integrated evaluation based on bacterial density, activity and community structure under well-controlled sequencing batch incubation conditions. Water Research, 2018, 130: 115-126