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Autores principales: Xu, Yijie, Feng, Jiayin, Hu, YuXuan, Chen, Li, Qin, Wensheng, Chen, Chen, Yan, Maocang, Guo, Haipeng
Formato: Artículo científico
Lenguaje:en
Publicado: Microbial physiology 2025
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Acceso en línea:https://pubmed.ncbi.nlm.nih.gov/39616990/
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author Xu, Yijie
Feng, Jiayin
Hu, YuXuan
Chen, Li
Qin, Wensheng
Chen, Chen
Yan, Maocang
Guo, Haipeng
author_facet Xu, Yijie
Feng, Jiayin
Hu, YuXuan
Chen, Li
Qin, Wensheng
Chen, Chen
Yan, Maocang
Guo, Haipeng
Xu, Yijie
Feng, Jiayin
Hu, YuXuan
Chen, Li
Qin, Wensheng
Chen, Chen
Yan, Maocang
Guo, Haipeng
collection PubMed - marine biology
contents Hub Metabolites Promote the Bioflocculant Production in a Biomass-Degrading Bacterium Pseudomonas boreopolis GO2. Xu, Yijie Feng, Jiayin Hu, YuXuan Chen, Li Qin, Wensheng Chen, Chen Yan, Maocang Guo, Haipeng Pseudomonas Biomass Fermentation Flocculation Zea mays Metabolome Carbon Rhamnose The low yield of bioflocculants has been a bottleneck problem that limits their industrial applications. Understanding the metabolic mechanism of bacteria that produce bioflocculants could provide valuable insights and strategies to directly regulate their yield in future. To investigate the change of metabolites in the process of bioflocculant production by a biomass-degrading bacterium, Pseudomonas boreopolis GO2, an untargeted metabolome analysis was performed. The results showed that metabolites significantly differed during the fermentation process when corn stover was used as the sole carbon source. The differential metabolites were divided into four co-expression modules based on the weighted gene co-expression network analysis. Among them, a module (yellow module) was closely related to the flocculating efficiency, and the metabolites in this module were mainly involved in carbohydrate, lipid, and amino acid metabolism. The top 30 metabolites with the highest degree in the yellow module were identified as hub metabolites for bioflocculant production. Finally, 10 hub metabolites were selected to perform the additional experiments, and the addition of L-rhamnose, tyramine, tryptophan, and glutaric acid alone all could significantly improve the flocculating efficiency of GO2 strain. These results indicated that the hub metabolites were key for bioflocculant production in GO2 strain, and could help guide the improvement of high-efficiency and low-cost bioflocculant production.
format Artículo científico
id pubmed_39616990
institution PubMed
language en
publishDate 2025
publisher Microbial physiology
record_format pubmed
spellingShingle Hub Metabolites Promote the Bioflocculant Production in a Biomass-Degrading Bacterium Pseudomonas boreopolis GO2.
Xu, Yijie
Feng, Jiayin
Hu, YuXuan
Chen, Li
Qin, Wensheng
Chen, Chen
Yan, Maocang
Guo, Haipeng
Pseudomonas
Biomass
Fermentation
Flocculation
Zea mays
Metabolome
Carbon
Rhamnose
Hub Metabolites Promote the Bioflocculant Production in a Biomass-Degrading Bacterium Pseudomonas boreopolis GO2. Xu, Yijie Feng, Jiayin Hu, YuXuan Chen, Li Qin, Wensheng Chen, Chen Yan, Maocang Guo, Haipeng Pseudomonas Biomass Fermentation Flocculation Zea mays Metabolome Carbon Rhamnose The low yield of bioflocculants has been a bottleneck problem that limits their industrial applications. Understanding the metabolic mechanism of bacteria that produce bioflocculants could provide valuable insights and strategies to directly regulate their yield in future. To investigate the change of metabolites in the process of bioflocculant production by a biomass-degrading bacterium, Pseudomonas boreopolis GO2, an untargeted metabolome analysis was performed. The results showed that metabolites significantly differed during the fermentation process when corn stover was used as the sole carbon source. The differential metabolites were divided into four co-expression modules based on the weighted gene co-expression network analysis. Among them, a module (yellow module) was closely related to the flocculating efficiency, and the metabolites in this module were mainly involved in carbohydrate, lipid, and amino acid metabolism. The top 30 metabolites with the highest degree in the yellow module were identified as hub metabolites for bioflocculant production. Finally, 10 hub metabolites were selected to perform the additional experiments, and the addition of L-rhamnose, tyramine, tryptophan, and glutaric acid alone all could significantly improve the flocculating efficiency of GO2 strain. These results indicated that the hub metabolites were key for bioflocculant production in GO2 strain, and could help guide the improvement of high-efficiency and low-cost bioflocculant production.
title Hub Metabolites Promote the Bioflocculant Production in a Biomass-Degrading Bacterium Pseudomonas boreopolis GO2.
topic Pseudomonas
Biomass
Fermentation
Flocculation
Zea mays
Metabolome
Carbon
Rhamnose
url https://pubmed.ncbi.nlm.nih.gov/39616990/