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Main Authors: Xu, Huan-Wei, Wang, Xiao-Yan, Wei, Ying, Cao, Yiqi, Wang, Shu-Guang, Xia, Peng-Fei
Format: Artículo científico
Language:en
Published: Applied and environmental microbiology 2025
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Online Access:https://pubmed.ncbi.nlm.nih.gov/40793766/
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author Xu, Huan-Wei
Wang, Xiao-Yan
Wei, Ying
Cao, Yiqi
Wang, Shu-Guang
Xia, Peng-Fei
author_facet Xu, Huan-Wei
Wang, Xiao-Yan
Wei, Ying
Cao, Yiqi
Wang, Shu-Guang
Xia, Peng-Fei
Xu, Huan-Wei
Wang, Xiao-Yan
Wei, Ying
Cao, Yiqi
Wang, Shu-Guang
Xia, Peng-Fei
collection PubMed - marine biology
contents Pathway crosstalk enables degradation of aromatic compounds in marine clade bacteria. Xu, Huan-Wei Wang, Xiao-Yan Wei, Ying Cao, Yiqi Wang, Shu-Guang Xia, Peng-Fei Roseobacter Biodegradation, Environmental Metabolic Networks and Pathways Parabens Hydrocarbons, Aromatic Seawater Aromatic compounds are essential raw materials for almost all sectors of human societies but also persistent environmental pollutants recalcitrant to biodegradation. The ocean serves as a significant sink for these compounds, while their biological conversion routes remain poorly understood, hindering a comprehensive understanding of the marine carbon cycle and advancements in bioremediation and biological carbon upcycling. Here, we report the degradation pathway of aromatic molecules in the marine clade bacteria through multi-omics analysis and CRISPR-Cas-based genome editing. Using and 4-hydroxybenzoate (4HB) as representatives, we identified the transport of 4HB via TRAP, ABC, and MFS transporters. Then, we deciphered the integral β-ketoadipate pathway responsible for aromatic degradation. Next, we discovered a distinct pathway crosstalk at the final thiolation step, which serves as an intersection node of different pathways catalyzed by the 3-oxoadipyl-CoA thiolase from the β-ketoadipate pathway and the acetyl-CoA C-acetyltransferase and acetyl-CoA C-acyltransferase from the β-oxidation pathway. Finally, we proposed as a novel marine platform for systems-level interrogation and bioprospecting. Our study provides a foundation for leveraging clade bacteria as novel chassis for environmental and industrial innovations.IMPORTANCEAromatic compounds lie in an essential node of carbon cycling in both natural and engineered systems. Marine bacteria orchestrate the cycling of aromatic compounds in the ocean and, as emerging chassis, have shown unusual potentials in the degradation and valorization of aromatics. However, the corresponding metabolic pathway in marine bacteria remains poorly interpreted over decades, hindering further scientific interrogation and engineering practices. Here, we deciphered the complete degradation pathway of aromatic compounds in the marine clade bacteria and established a marine platform for systems and synthetic biology. Our study provides a paradigm for biological interrogation with combined multi-omics and the cutting-edge CRISPR-Cas approaches, laying a foundation for biological innovations with marine bacteria.
format Artículo científico
id pubmed_40793766
institution PubMed
language en
publishDate 2025
publisher Applied and environmental microbiology
record_format pubmed
spellingShingle Pathway crosstalk enables degradation of aromatic compounds in marine clade bacteria.
Xu, Huan-Wei
Wang, Xiao-Yan
Wei, Ying
Cao, Yiqi
Wang, Shu-Guang
Xia, Peng-Fei
Roseobacter
Biodegradation, Environmental
Metabolic Networks and Pathways
Parabens
Hydrocarbons, Aromatic
Seawater
Pathway crosstalk enables degradation of aromatic compounds in marine clade bacteria. Xu, Huan-Wei Wang, Xiao-Yan Wei, Ying Cao, Yiqi Wang, Shu-Guang Xia, Peng-Fei Roseobacter Biodegradation, Environmental Metabolic Networks and Pathways Parabens Hydrocarbons, Aromatic Seawater Aromatic compounds are essential raw materials for almost all sectors of human societies but also persistent environmental pollutants recalcitrant to biodegradation. The ocean serves as a significant sink for these compounds, while their biological conversion routes remain poorly understood, hindering a comprehensive understanding of the marine carbon cycle and advancements in bioremediation and biological carbon upcycling. Here, we report the degradation pathway of aromatic molecules in the marine clade bacteria through multi-omics analysis and CRISPR-Cas-based genome editing. Using and 4-hydroxybenzoate (4HB) as representatives, we identified the transport of 4HB via TRAP, ABC, and MFS transporters. Then, we deciphered the integral β-ketoadipate pathway responsible for aromatic degradation. Next, we discovered a distinct pathway crosstalk at the final thiolation step, which serves as an intersection node of different pathways catalyzed by the 3-oxoadipyl-CoA thiolase from the β-ketoadipate pathway and the acetyl-CoA C-acetyltransferase and acetyl-CoA C-acyltransferase from the β-oxidation pathway. Finally, we proposed as a novel marine platform for systems-level interrogation and bioprospecting. Our study provides a foundation for leveraging clade bacteria as novel chassis for environmental and industrial innovations.IMPORTANCEAromatic compounds lie in an essential node of carbon cycling in both natural and engineered systems. Marine bacteria orchestrate the cycling of aromatic compounds in the ocean and, as emerging chassis, have shown unusual potentials in the degradation and valorization of aromatics. However, the corresponding metabolic pathway in marine bacteria remains poorly interpreted over decades, hindering further scientific interrogation and engineering practices. Here, we deciphered the complete degradation pathway of aromatic compounds in the marine clade bacteria and established a marine platform for systems and synthetic biology. Our study provides a paradigm for biological interrogation with combined multi-omics and the cutting-edge CRISPR-Cas approaches, laying a foundation for biological innovations with marine bacteria.
title Pathway crosstalk enables degradation of aromatic compounds in marine clade bacteria.
topic Roseobacter
Biodegradation, Environmental
Metabolic Networks and Pathways
Parabens
Hydrocarbons, Aromatic
Seawater
url https://pubmed.ncbi.nlm.nih.gov/40793766/