Soil pore structure changes induced by biochar affect microbial diversity and community structure in an Ultisol

IF 6.8 1区农林科学 Q1 SOIL SCIENCE

Soil & Tillage Research Pub Date : 2022-10-01 DOI:10.1016/j.still.2022.105505

Caidi Yang , Jingjing Liu , Huanchang Ying , Shenggao Lu

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引用次数: 16

Abstract

The chemical mechanisms by which biochar addition affected soil microorganisms have been extensively studied. However, few studies investigated the effect of physical alteration induced by biochar application on microorganisms in soils. The study focused on how the pore structure affected microbial diversity and community structure in an Ultisol amended with straw-derived biochars. The nitrogen adsorption isotherm (NAI) and mercury intrusion porosimetry (MIP) were used to measure the soil pore characteristics. The bacterial and fungal community composition and diversity were analyzed by the sequencing of V4-V5 of 16 S rRNA gene and ITS1 gene, respectively. MIP results showed that biochar increased the total porosity, total pore volume, average pore diameter and the volumes of > 75, 30–75 and 5–30 µm pores in soils. The straw feedstock and pyrolysis temperature of biochar affected the microbial diversity and community structure in soils. The soil amended with RB550 had the highest Shannon diversity of bacteria and fungi, while the soil treated with CB350 had the highest bacterial abundance. The addition of biochar mainly increased the relative abundances of bacterial genera Actinospica, Ellin6067, Streptomyces and Massilia, while decreased the abundance of Pseudomonas, Methylobacterium and Nitrosospira. However, the fungal genera had a greater variation in biochar-amended soils. The > 5 µm pores in soils had positive effects on the microbial diversity and abundance. The bacterial genera that were acidophilic and aerobic had positive correlations with the volumes of > 75, 30–75 and 5–30 µm pores, especially Ellin6067, Flavisolibacter and Haliangium. Inversely, the genera that were facultative anaerobic (Methylobacterium, Pseudomonas and Nitrosospira) and anaerobic (Christensenellaceae_R-7_group) showed a positive correlation with the volume of < 5 µm pores or no obvious regularity. Most fungal genera tended to live in the larger pores of > 5 µm and could extend into smaller pores. Therefore, the pore characteristics largely determined the microbial community structure in the biochar-amended soils.

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生物炭诱导的土壤孔隙结构变化影响了Ultisol中微生物的多样性和群落结构

生物炭添加对土壤微生物影响的化学机制已被广泛研究。然而，很少有研究探讨生物炭施用对土壤微生物的物理变化的影响。研究了秸秆生物炭修饰的Ultisol的孔隙结构对微生物多样性和群落结构的影响。采用氮吸附等温线(NAI)和汞侵入孔隙度法(MIP)测定土壤孔隙特征。通过16s rRNA基因v4 ~ v5序列和ITS1基因v5序列分析细菌和真菌群落组成和多样性。MIP结果表明，生物炭增加了总孔隙率、总孔容、平均孔径和孔隙体积;75、30-75和5-30µm孔隙。秸秆原料和生物炭热解温度对土壤微生物多样性和群落结构有影响。RB550处理土壤的细菌和真菌香农多样性最高，CB350处理土壤的细菌丰度最高。生物炭的添加主要提高了放线菌属、Ellin6067、链霉菌属和Massilia菌属的相对丰度，降低了假单胞菌属、甲基杆菌属和亚硝基螺旋体属的相对丰度。然而，真菌属在生物炭改良的土壤中有较大的变化。比;土壤中5µm孔隙对微生物多样性和丰度有正向影响。嗜酸菌属和好氧菌属与菌体体积呈正相关;以Ellin6067、Flavisolibacter和Haliangium为代表。而兼性厌氧菌属(甲基菌、假单胞菌和亚硝基螺旋菌)和厌氧菌属(Christensenellaceae_R-7_group)与细菌体积呈正相关;5µm孔隙或无明显规律性。大多数真菌属倾向于生活在真菌的较大孔隙中。5µm，可以延伸成更小的孔隙。因此，孔隙特征在很大程度上决定了生物炭改性土壤的微生物群落结构。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Soil & Tillage Research 农林科学-土壤科学

CiteScore

13.00

自引率

6.20%

发文量

266

审稿时长

5 months

期刊介绍： Soil & Tillage Research examines the physical, chemical and biological changes in the soil caused by tillage and field traffic. Manuscripts will be considered on aspects of soil science, physics, technology, mechanization and applied engineering for a sustainable balance among productivity, environmental quality and profitability. The following are examples of suitable topics within the scope of the journal of Soil and Tillage Research: The agricultural and biosystems engineering associated with tillage (including no-tillage, reduced-tillage and direct drilling), irrigation and drainage, crops and crop rotations, fertilization, rehabilitation of mine spoils and processes used to modify soils. Soil change effects on establishment and yield of crops, growth of plants and roots, structure and erosion of soil, cycling of carbon and nutrients, greenhouse gas emissions, leaching, runoff and other processes that affect environmental quality. Characterization or modeling of tillage and field traffic responses, soil, climate, or topographic effects, soil deformation processes, tillage tools, traction devices, energy requirements, economics, surface and subsurface water quality effects, tillage effects on weed, pest and disease control, and their interactions.