Taxonomic structure and function of the corn stover degradative microbial consortium <scp>GF</scp>‐20 following growth on different sources of nitrogen

Borjigin, Qinggeer; Yu, Xiang; Gao, Julin; Zhang, Bizhou; Wang, Zhigang; Hu, Shuping; Han, Shengcai; Sun, Jiying; Hu, Wanji

doi:10.1111/aab.12729

Cited by 2 publications

(1 citation statement)

References 44 publications

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“…Soils are a rich source of microbes with the metabolic capabilities of biomass deconstruction. Borjigin et al [ 93 ] employed metagenomics methodologies to observe how the microbiome changed with different nitrogen treatments and if the cellulolytic activity changed. The research produced a catalog of microbes and their activities that enabled the conversion of agricultural waste into soil nutrients.…”

Section: Strategies For Advancing and Innovating Metabolic Engineerin...mentioning

confidence: 99%

Engineering the Metabolic Landscape of Microorganisms for Lignocellulosic Conversion

Peña-Castro,

Muñoz-Páez,

Robledo-Narvaez

et al. 2023

Microorganisms

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Bacteria and yeast are being intensively used to produce biofuels and high-added-value products by using plant biomass derivatives as substrates. The number of microorganisms available for industrial processes is increasing thanks to biotechnological improvements to enhance their productivity and yield through microbial metabolic engineering and laboratory evolution. This is allowing the traditional industrial processes for biofuel production, which included multiple steps, to be improved through the consolidation of single-step processes, reducing the time of the global process, and increasing the yield and operational conditions in terms of the desired products. Engineered microorganisms are now capable of using feedstocks that they were unable to process before their modification, opening broader possibilities for establishing new markets in places where biomass is available. This review discusses metabolic engineering approaches that have been used to improve the microbial processing of biomass to convert the plant feedstock into fuels. Metabolically engineered microorganisms (MEMs) such as bacteria, yeasts, and microalgae are described, highlighting their performance and the biotechnological tools that were used to modify them. Finally, some examples of patents related to the MEMs are mentioned in order to contextualize their current industrial use.

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Section: Strategies For Advancing and Innovating Metabolic Engineerin...mentioning

confidence: 99%

Engineering the Metabolic Landscape of Microorganisms for Lignocellulosic Conversion

Peña-Castro,

Muñoz-Páez,

Robledo-Narvaez

et al. 2023

Microorganisms

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Bacillus Intervention: Microbial Ecological Mechanisms for Controlling Root Rot in Coptis chinensis Franch

Liao,

Ke,

Chen

et al. 2024

Preprint

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Background: Coptis root rot (CRR) poses a significant threat to the yield and medicinal quality of Coptis chinensis (Cc), primarily attributed to the presence of Fusarium. This study investigates the potential of four Rhizosphere Bacillus bacteria as biological control agents to combat CRR. These bacteria, namely B. mycoides LB-021, B. pseudomycoides YEM-005, B. velezensis JM-1, and B. subtilis TR-064, were sourced from the rhizosphere of Cc roots. While their antagonistic efficacy has been demonstrated in controlled environments, the translation of their capabilities to field conditions and their impact on the microecological balance within Coptis roots require further exploration. Results: Bacillus introduction significantly reconfigures Cc root microbial communities, simplifying the network. Genera enrichment (Arthrobacter, Sphingobium, Pseudomonas, etc.) and Flavobacterium/Gemmatimonas reduction promote plant growth, disease resistance, and soil health. Bacillus triggers antibiotic synthesis (ansamycin, macrolides, etc.), fortifying plant defence against pathogens. Correlations with transcriptome/metabolome highlight Bacillus's influence on root genetics/chemistry. KEGG analysis reveals Bacillus impact on critical plant metabolic pathways. Conclusions In conclusion, this study delves into the dynamic relationship between plants and microorganisms in their natural environment, specifically focusing on the role of microbial communities in the rhizosphere. The introduction of Bacillus has a profound impact on the composition and behaviour of the root microbial community, enriching beneficial genera and inducing the synthesis of antibiotics and metabolites that enhance the defence ability of plants. The research emphasizes Bacillus's pivotal role in shaping molecular and metabolic responses, suggesting its eco-friendly potential in enhancing plant disease resistance as an alternative to chemical pesticides.

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Taxonomic structure and function of the corn stover degradative microbial consortium GF‐20 following growth on different sources of nitrogen

Cited by 2 publications

References 44 publications

Engineering the Metabolic Landscape of Microorganisms for Lignocellulosic Conversion

Engineering the Metabolic Landscape of Microorganisms for Lignocellulosic Conversion

Bacillus Intervention: Microbial Ecological Mechanisms for Controlling Root Rot in Coptis chinensis Franch

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