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Main Authors: Han, Jia-Rui, Li, Shuai, Lian, Wen-Hui, Xu, Lu, Duan, Li, Li, Jia-Ling, Shi, Guo-Yuan, Wei, Qi-Chuang, Ali, Mukhtiar, Li, Wen-Jun, Dong, Lei
Format: Artículo científico
Language:en
Published: Applied and environmental microbiology 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/41586531/
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author Han, Jia-Rui
Li, Shuai
Lian, Wen-Hui
Xu, Lu
Duan, Li
Li, Jia-Ling
Shi, Guo-Yuan
Wei, Qi-Chuang
Ali, Mukhtiar
Li, Wen-Jun
Dong, Lei
author_facet Han, Jia-Rui
Li, Shuai
Lian, Wen-Hui
Xu, Lu
Duan, Li
Li, Jia-Ling
Shi, Guo-Yuan
Wei, Qi-Chuang
Ali, Mukhtiar
Li, Wen-Jun
Dong, Lei
Han, Jia-Rui
Li, Shuai
Lian, Wen-Hui
Xu, Lu
Duan, Li
Li, Jia-Ling
Shi, Guo-Yuan
Wei, Qi-Chuang
Ali, Mukhtiar
Li, Wen-Jun
Dong, Lei
collection PubMed - marine biology
contents Fermentation conditions outweigh phylogeny in shaping the metabolome of novel strains: an integrated genomics-metabolomics analysis. Han, Jia-Rui Li, Shuai Lian, Wen-Hui Xu, Lu Duan, Li Li, Jia-Ling Shi, Guo-Yuan Wei, Qi-Chuang Ali, Mukhtiar Li, Wen-Jun Dong, Lei Micromonospora Phylogeny Metabolome Genomics Metabolomics Fermentation Multiomics Genome, Bacterial Geologic Sediments Soil Microbiology Terpenes Polyketides The genus , a key member of the actinomycetes, has demonstrated considerable potential for natural product biosynthesis. In this study, we isolated 15 spp. strains from desert soil and marine sediment samples, eight of which represent four novel species. To explore the biosynthetic capacity of this genus, we performed an integrated analysis of reference genomes. Pan-genomic analysis further unveiled the core biosynthetic characteristics of the genus responsible for producing terpenes and polyketides. Further multi-omics investigation, combining genomic and metabolomic data, uncovered a positive correlation between phylogenetic relationships and biosynthetic potential, alongside a decoupling of metabolic profiles. Notably, metabolomic findings emphasized the dominant influence of culture conditions on the expression of biosynthetic capabilities. Overall, our study provides a comprehensive elucidation of the biosynthetic potential of the genus and highlights the value of investigating novel strains and applying diverse cultivation strategies in natural product discovery.IMPORTANCEOur study provides a comprehensive genomic and metabolomic elucidation of the significant biosynthetic potential within the genus . It reveals a core biosynthetic capacity for terpenes and polyketides that is phylogenetically linked, whereas the resulting natural product repertoire is subject to strong modulation by cultivation conditions. These findings underscore the critical importance of exploring novel species and employing diverse cultivation strategies to unlock the full potential of microbial resources for natural product discovery.
format Artículo científico
id pubmed_41586531
institution PubMed
language en
publishDate 2026
publisher Applied and environmental microbiology
record_format pubmed
spellingShingle Fermentation conditions outweigh phylogeny in shaping the metabolome of novel strains: an integrated genomics-metabolomics analysis.
Han, Jia-Rui
Li, Shuai
Lian, Wen-Hui
Xu, Lu
Duan, Li
Li, Jia-Ling
Shi, Guo-Yuan
Wei, Qi-Chuang
Ali, Mukhtiar
Li, Wen-Jun
Dong, Lei
Micromonospora
Phylogeny
Metabolome
Genomics
Metabolomics
Fermentation
Multiomics
Genome, Bacterial
Geologic Sediments
Soil Microbiology
Terpenes
Polyketides
Fermentation conditions outweigh phylogeny in shaping the metabolome of novel strains: an integrated genomics-metabolomics analysis. Han, Jia-Rui Li, Shuai Lian, Wen-Hui Xu, Lu Duan, Li Li, Jia-Ling Shi, Guo-Yuan Wei, Qi-Chuang Ali, Mukhtiar Li, Wen-Jun Dong, Lei Micromonospora Phylogeny Metabolome Genomics Metabolomics Fermentation Multiomics Genome, Bacterial Geologic Sediments Soil Microbiology Terpenes Polyketides The genus , a key member of the actinomycetes, has demonstrated considerable potential for natural product biosynthesis. In this study, we isolated 15 spp. strains from desert soil and marine sediment samples, eight of which represent four novel species. To explore the biosynthetic capacity of this genus, we performed an integrated analysis of reference genomes. Pan-genomic analysis further unveiled the core biosynthetic characteristics of the genus responsible for producing terpenes and polyketides. Further multi-omics investigation, combining genomic and metabolomic data, uncovered a positive correlation between phylogenetic relationships and biosynthetic potential, alongside a decoupling of metabolic profiles. Notably, metabolomic findings emphasized the dominant influence of culture conditions on the expression of biosynthetic capabilities. Overall, our study provides a comprehensive elucidation of the biosynthetic potential of the genus and highlights the value of investigating novel strains and applying diverse cultivation strategies in natural product discovery.IMPORTANCEOur study provides a comprehensive genomic and metabolomic elucidation of the significant biosynthetic potential within the genus . It reveals a core biosynthetic capacity for terpenes and polyketides that is phylogenetically linked, whereas the resulting natural product repertoire is subject to strong modulation by cultivation conditions. These findings underscore the critical importance of exploring novel species and employing diverse cultivation strategies to unlock the full potential of microbial resources for natural product discovery.
title Fermentation conditions outweigh phylogeny in shaping the metabolome of novel strains: an integrated genomics-metabolomics analysis.
topic Micromonospora
Phylogeny
Metabolome
Genomics
Metabolomics
Fermentation
Multiomics
Genome, Bacterial
Geologic Sediments
Soil Microbiology
Terpenes
Polyketides
url https://pubmed.ncbi.nlm.nih.gov/41586531/