杉木人工林土壤施用生物炭对细菌群落结构及多样性的影响

doi:10.11707/j.1001-7488.20190820

摘要/Abstract

摘要： [目的]采集杉木人工林土壤，通过室内土壤培养实验，研究添加不同制备原料和制备温度的生物炭对土壤细菌群落结构及多样性的影响，为改善南方酸性红壤及合理应用生物炭提供科学依据。[方法]原土添加3%的300℃杉叶炭（BL300）、600℃杉叶炭（BL600）、300℃木屑炭（BW300）及600℃木屑炭（BW600），与对照土壤进行对比，进行培养实验80天，运用高通量测序技术对PCR所扩增16S rDNA序列的V3+V4区域进行测定。[结果] OTU韦恩图分析表明，添加BL300的土壤细菌较对照丰度提高，其他生物炭处理丰度减小；通过PCoA分析和Beta多样性分析及UPGMA聚类分析得出，添加杉叶炭后土壤细菌群落结构及多样性与对照土壤的差异显著，其中BL600与对照差异最大，添加木屑炭结果与对照较相似；添加生物炭对不同物种水平上的土壤细菌结构和功能产生一定影响，其中杉叶炭处理影响十分显著，使土壤优势菌丰度变化较大，木屑炭处理对优势菌的影响相对较小。[结论]添加BL300生物炭提高了土壤细菌的丰度，而添加其他生物炭降低了细菌丰度；不同制备原料和温度对生物炭存在影响，由于木屑炭可利用氮素不足，杉叶生物炭对土壤细菌结构和多样性的影响比木屑生物炭更显著，高温炭灰分含量较多，因此对细菌多样性的影响大于低温炭；不同的土壤细菌种群生活习性与功能不同，对生物炭组分利用程度也不同，添加生物炭能够改变土壤中优势种群的相对丰度和土壤细菌群落的整体功能。

关键词: 高通量测序, 生物炭, 杉木人工林, 土壤细菌, 多样性

Abstract: [Objective] In this study, soil samples of Chinese fir plantations were collected to study the effects of biochar with different preparation materials and preparation temperatures on soil bacterial community structure and diversity through soil culture experiments in laboratory. The purpose of this study was to provide scientific basis for improving acid red soil in southern China and rational application of biochar.[Method]The V3+V4 region of 16S rDNA sequence of soil bacteria, amplified by PCR, was determined by high-throughput sequencing technique after 80 days of culture in the following different media:original soil with 3% Chinese fir leaf biochar produced at temperature of 300℃ (BL300) and 600℃ (BL600), original soil with 3% Chinese fir wood chip biochar produced at temperature of 300℃(BW300) and at temperature of 600℃ (BW600), and original soil only (served as control).[Result]The OUT-Wayne diagram analysis showed that the soil bacteria abundance with BL300 was higher than that of the control, while the abundance of other biochar treatments was lower. The results of PcoA analysis, Beta diversity analysis and UPGMA cluster analysis showed that the community structure and diversity of soil bacteria of fir leaf biochar treatment were significantly different from those of the control, among which BL600 was the most different from the control. The results of adding wood chip biochar were similar to those of control. The addition of biochar had a certain effect on the structure and function of soil bacteria at different species levels, among which the treatment of fir leaf biochar had very significant effect on the abundance of dominant bacterial species, and the treatment of the wood chip biochar had a relatively small effect on dominant bacteria.[Conclusion]The addition of BL300 biochar increased the abundance of soil bacteria, while other biochar treatments reduced the abundance of bacteria. Different raw materials and temperatures had effects on biochar. Because of the insufficient available nitrogen of fir wood chip biochar, the effect of Chinese fir leaf biochar on soil bacterial structure and diversity was more significant than fir wood chip biochar. The content of high-temperature biochar ash was more, so the influence on bacterial diversity was greater. Different soil bacterial populations have different living habits and functions, and the utilization degree of biochar components is different, so adding biochar can change the relative abundance of dominant populations in soil and the overall function of soil bacterial community.

Key words: high-throughput sequencing, biochar, Cunninghamia lanceolata plantation, soil bacteria, diversity

中图分类号:

S718.83

胡华英, 张虹, 曹升, 殷丹阳, 周垂帆, 何宗明. 杉木人工林土壤施用生物炭对细菌群落结构及多样性的影响[J]. 林业科学, 2019, 55(8): 184-193.

Hu Huaying, Zhang Hong, Cao Sheng, Yin Danyang, Zhou Chuifan, He Zongming. Effects of Biochar Application on Soil Bacterial Community Structure and Diversity in Cunninghamia lanceolata Plantations[J]. Scientia Silvae Sinicae, 2019, 55(8): 184-193.

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