Earthworm modifies microbial community and functional genes for lignocellulosic waste valorization: Isolating plant-growth-promoting bacteria via next generation sequencing

IF 4.1 2区 环境科学与生态学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Ratan Chowdhury , Soma Barman , Moharana Choudhury , Ki-Hyun Kim , Satya Sundar Bhattacharya
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引用次数: 0

Abstract

The primary motivation of this study is the lack of knowledge regarding the shift in microbial community and functional compositions in lignocellulosic waste-based composting and vermicomposting systems. To date, the next-generation sequencing approaches have scantily been made for the isolation of plant-growth-promoting microorganisms from vermicomposting systems. Therefore, two types of lignocellulosic waste (paddy straw and food waste) are mixed with and without cow dung in different ratios and vermicomposted with Eisenia fetida, while using a series of aerobic composting as a control. Significant decreases in pH, organic C (∼3 fold), and XRD-derived crystallinity are seen most evidently in the paddy straw-food waste (1:1) mixtures upon vermicomposting (compared to composting) along with a concurrent increment of nutrients (NPK) (∼2–3.5 fold). Significant augmentation (P < 0.01) in microbial activity (biomass and respiration) and growth (bacteria and fungus) is observed under vermicomposting. A considerable shift in taxonomic diversity, accompanied by differential functional diversity of the microbial communities, is detected between paddy straw-food waste (1:1) vermicompost and compost after 60 days of incubation. The overall gene volume is greater in the vermibed than in the compost, and genes of a few well-known microbial communities with good plant growth promoting traits (e.g., Beijerinckiaceae and Propionibacteriaceae) are exclusive to the vermicompost. Additionally, genes associated with beneficial microbial activities, such as amino acid transport, nuclear structure development, and lipid transport, are found to be more abundant in vermicompost than in compost. These data are helpful in identifying suitable feedstock for isolating scalable microbial species with beneficial traits. Subsequently, six multi-dimensional plant-growth-promoting endophytic bacterial species are isolated from both the vermibed and earthworm guts. Interestingly, close genetic resemblances are found for a few of these isolates with the metagenomically detected genes. In conclusion, this is the first study to identify the practical utility of next-generation sequencing-based metagenomic analyses for the meaningful isolation of economically viable microbial species from vermicomposting systems that might replace a sizeable portion of the chemical fertilizers used in agriculture.

Abstract Image

蚯蚓改变微生物群落和功能基因,实现木质纤维素废物的价值化:通过新一代测序分离促进植物生长的细菌
这项研究的主要动机是对木质纤维素废物堆肥和蚯蚓堆肥系统中微生物群落和功能组成的变化缺乏了解。迄今为止,从蚯蚓堆肥系统中分离促进植物生长微生物的新一代测序方法还很少见。因此,我们将两种木质纤维素废物(稻草和食物垃圾)按不同比例与牛粪或不与牛粪混合,并用埃森藻进行蚯蚓堆肥,同时使用一系列好氧堆肥作为对照。与堆肥相比,水稻秸秆-食物垃圾(1:1)混合物在蚯蚓堆肥后,pH 值、有机碳(3 倍)和 XRD 衍射结晶度明显下降,养分(氮磷钾)也同时增加(2-3.5 倍)。在蚯蚓堆肥过程中,微生物活动(生物量和呼吸作用)和生长(细菌和真菌)显著增加(P < 0.01)。培养 60 天后,稻草-食物垃圾(1:1)蚯蚓堆肥和堆肥之间的分类多样性发生了很大变化,同时微生物群落的功能多样性也有所不同。蛭石堆肥的总体基因量大于堆肥,一些具有良好植物生长促进特性的知名微生物群落(如贝氏菌科和丙酸杆菌科)的基因是蛭石堆肥所独有的。此外,与氨基酸运输、核结构发育和脂质运输等有益微生物活动相关的基因在蛭肥中的含量也高于堆肥。这些数据有助于确定合适的原料,以分离出具有有益性状的可扩展微生物物种。随后,从蛭石和蚯蚓内脏中分离出六种多维植物生长促进内生细菌。有趣的是,这些分离物中有几个与元基因组检测到的基因非常相似。总之,这是首次发现基于下一代测序的元基因组分析在从蚯蚓堆肥系统中分离出经济上可行的微生物物种方面的实际用途的研究。
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来源期刊
CiteScore
9.60
自引率
10.40%
发文量
107
审稿时长
21 days
期刊介绍: International Biodeterioration and Biodegradation publishes original research papers and reviews on the biological causes of deterioration or degradation.
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