Successional action of Bacteroidota and Firmicutes in decomposing straw polymers in a paddy soil.

IF 6.2 2区 环境科学与生态学 Q1 GENETICS & HEREDITY
Junjie Huang, Kailin Gao, Lu Yang, Yahai Lu
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Abstract

Background: Decomposition of plant biomass is vital for carbon cycling in terrestrial ecosystems. In waterlogged soils including paddy fields and natural wetlands, plant biomass degradation generates the largest natural source of global methane emission. However, the intricate process of plant biomass degradation by diverse soil microorganisms remains poorly characterized. Here we report a chemical and metagenomic investigation into the mechanism of straw decomposition in a paddy soil.

Results: The chemical analysis of 16-day soil microcosm incubation revealed that straw decomposition could be divided into two stages based on the dynamics of methane, short chain fatty acids, dissolved organic carbon and monosaccharides. Metagenomic analysis revealed that the relative abundance of glucoside hydrolase (GH) encoding genes for cellulose decomposition increased rapidly during the initial stage (3-7 days), while genes involved in hemicellulose decomposition increased in the later stage (7-16 days). The increase of cellulose GH genes in initial stage was derived mainly from Firmicutes while Bacteroidota contributed mostly to the later stage increase of hemicellulose GH genes. Flagella assembly genes were prevalent in Firmicutes but scarce in Bacteroidota. Wood-Ljungdahl pathway (WLP) was present in Firmicutes but not detected in Bacteroidota. Overall, Bacteroidota contained the largest proportion of total GHs and the highest number of carbohydrate active enzymes gene clusters in our paddy soil metagenomes. The strong capacity of the Bacteroidota phylum to degrade straw polymers was specifically attributed to Bacteroidales and Chitinophagales orders, the latter has not been previously recognized.

Conclusions: This study revealed a collaborating sequential contribution of microbial taxa and functional genes in the decomposition of straw residues in a paddy soil. Firmicutes with the property of mobility, WLP and cellulose decomposition could be mostly involved in the initial breakdown of straw polymers, while Bacteroidota became abundant and possibly responsible for the decomposition of hemicellulosic polymers during the later stage.

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拟杆菌门和厚壁菌门在水稻土中分解秸秆聚合物的后续作用。
背景:植物生物量的分解对陆地生态系统的碳循环至关重要。在包括稻田和自然湿地在内的积水土壤中,植物生物量退化是全球甲烷排放的最大自然来源。然而,不同土壤微生物降解植物生物量的复杂过程仍然缺乏特征。在这里,我们报道了一项关于稻草在水稻土中分解机制的化学和宏基因组研究。结果:土壤微宇宙培养16天的化学分析表明,秸秆分解可根据甲烷、短链脂肪酸、溶解有机碳和单糖的动态分为两个阶段。宏基因组分析显示,编码纤维素分解基因的葡萄糖苷水解酶(GH)的相对丰度在初始阶段(3-7天)迅速增加,而参与半纤维素分解的基因在后期(7-16天)增加。初期纤维素GH基因的增加主要来源于厚壁菌门,而拟杆菌门对后期半纤维素GH基因增加的贡献很大。Flagella组装基因在厚壁菌门中普遍存在,但在拟杆菌门中很少。Wood-Ljungdahl通路(WLP)存在于厚壁菌门中,但在拟杆菌门中未检测到。总体而言,在我们的水稻土壤宏基因组中,拟杆菌门含有最大比例的总GHs和最高数量的碳水化合物活性酶基因簇。拟杆菌门降解秸秆聚合物的强大能力被专门归因于拟杆菌目和几丁质目,后者以前尚未得到认可。结论:本研究揭示了微生物类群和功能基因在水稻土秸秆残留物分解中的协同序列贡献。具有移动性、WLP和纤维素分解特性的厚壁菌门可能主要参与秸秆聚合物的初始分解,而拟杆菌门变得丰富,并可能负责后期半纤维素聚合物的分解。
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来源期刊
Environmental Microbiome
Environmental Microbiome Immunology and Microbiology-Microbiology
CiteScore
7.40
自引率
2.50%
发文量
55
审稿时长
13 weeks
期刊介绍: Microorganisms, omnipresent across Earth's diverse environments, play a crucial role in adapting to external changes, influencing Earth's systems and cycles, and contributing significantly to agricultural practices. Through applied microbiology, they offer solutions to various everyday needs. Environmental Microbiome recognizes the universal presence and significance of microorganisms, inviting submissions that explore the diverse facets of environmental and applied microbiological research.
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