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Main Authors: Wang, Yan, Wang, Zhen, Zhao, Wen-Xiao, Yuan, Xiao-Jie, Yu, Yang, Wang, Peng, Wang, Min, McMinn, Andrew, Zhang, Yu-Zhong, Peng, Ming, Fu, Hui-Hui, Chen, Xiu-Lan
Format: Artículo científico
Language:en
Published: Marine life science & technology 2025
Online Access:https://pubmed.ncbi.nlm.nih.gov/40027322/
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author Wang, Yan
Wang, Zhen
Zhao, Wen-Xiao
Yuan, Xiao-Jie
Yu, Yang
Wang, Peng
Wang, Min
McMinn, Andrew
Zhang, Yu-Zhong
Peng, Ming
Fu, Hui-Hui
Chen, Xiu-Lan
author_facet Wang, Yan
Wang, Zhen
Zhao, Wen-Xiao
Yuan, Xiao-Jie
Yu, Yang
Wang, Peng
Wang, Min
McMinn, Andrew
Zhang, Yu-Zhong
Peng, Ming
Fu, Hui-Hui
Chen, Xiu-Lan
Wang, Yan
Wang, Zhen
Zhao, Wen-Xiao
Yuan, Xiao-Jie
Yu, Yang
Wang, Peng
Wang, Min
McMinn, Andrew
Zhang, Yu-Zhong
Peng, Ming
Fu, Hui-Hui
Chen, Xiu-Lan
collection PubMed - marine biology
contents -4-hydroxy-L-proline catabolism by in the ocean. Wang, Yan Wang, Zhen Zhao, Wen-Xiao Yuan, Xiao-Jie Yu, Yang Wang, Peng Wang, Min McMinn, Andrew Zhang, Yu-Zhong Peng, Ming Fu, Hui-Hui Chen, Xiu-Lan Free -4-hydroxy-L-proline (T4LHyp), a non-proteinogenic amino acid, is mainly released from the degradation of collagen, hydroxyproline-rich glycoproteins, and some peptide antibiotics in nature. Although it has been known that some terrestrial bacteria utilize T4LHyp as carbon and nitrogen source via a T4LHyp gene cluster, which and how marine microorganisms catabolize T4LHyp still remains unclear. Here, five T4LHyp-utilizing marine bacterial strains, sp. 5021, sp. 4072, sp. 6022, sp. 5112 and sp. 30521, were isolated from hydrothermal vent sediment samples collected from the southwest Indian Ocean. While sp. 5021 can utilize T4LHyp as both a nitrogen and carbon source, the other four strains can utilize T4LHyp as only a nitrogen source. Then, the T4LHyp catabolic mechanisms of sp. 5021 and sp. 4072, as a representative of the four strains, were further investigated by genomic, transcriptional, and biochemical analyses. sp. 5021 adopts an intact T4LHyp gene cluster containing four enzymes to catabolize T4LHyp into NH and α-ketoglutarate to provide nitrogen and carbon sources for its growth. Compared to sp. 5021, sp. 4072 lacks an α-KGSA dehydrogenase gene in the T4LHyp gene cluster and can only catabolize T4LHyp into NH and α-ketoglutarate semialdehyde to provide a nitrogen source for its growth. Bioinformatic investigation showed that the 5021-like and 4072-like T4LHyp gene clusters are predominantly found in bacteria from , which are widely distributed in multiple marine habitats. Thus, bacteria are likely the dominant group to drive the recycling and mineralization of T4LHyp in the ocean. The online version contains supplementary material available at 10.1007/s42995-024-00272-8.
format Artículo científico
id pubmed_40027322
institution PubMed
language en
publishDate 2025
publisher Marine life science & technology
record_format pubmed
spellingShingle -4-hydroxy-L-proline catabolism by in the ocean.
Wang, Yan
Wang, Zhen
Zhao, Wen-Xiao
Yuan, Xiao-Jie
Yu, Yang
Wang, Peng
Wang, Min
McMinn, Andrew
Zhang, Yu-Zhong
Peng, Ming
Fu, Hui-Hui
Chen, Xiu-Lan
-4-hydroxy-L-proline catabolism by in the ocean. Wang, Yan Wang, Zhen Zhao, Wen-Xiao Yuan, Xiao-Jie Yu, Yang Wang, Peng Wang, Min McMinn, Andrew Zhang, Yu-Zhong Peng, Ming Fu, Hui-Hui Chen, Xiu-Lan Free -4-hydroxy-L-proline (T4LHyp), a non-proteinogenic amino acid, is mainly released from the degradation of collagen, hydroxyproline-rich glycoproteins, and some peptide antibiotics in nature. Although it has been known that some terrestrial bacteria utilize T4LHyp as carbon and nitrogen source via a T4LHyp gene cluster, which and how marine microorganisms catabolize T4LHyp still remains unclear. Here, five T4LHyp-utilizing marine bacterial strains, sp. 5021, sp. 4072, sp. 6022, sp. 5112 and sp. 30521, were isolated from hydrothermal vent sediment samples collected from the southwest Indian Ocean. While sp. 5021 can utilize T4LHyp as both a nitrogen and carbon source, the other four strains can utilize T4LHyp as only a nitrogen source. Then, the T4LHyp catabolic mechanisms of sp. 5021 and sp. 4072, as a representative of the four strains, were further investigated by genomic, transcriptional, and biochemical analyses. sp. 5021 adopts an intact T4LHyp gene cluster containing four enzymes to catabolize T4LHyp into NH and α-ketoglutarate to provide nitrogen and carbon sources for its growth. Compared to sp. 5021, sp. 4072 lacks an α-KGSA dehydrogenase gene in the T4LHyp gene cluster and can only catabolize T4LHyp into NH and α-ketoglutarate semialdehyde to provide a nitrogen source for its growth. Bioinformatic investigation showed that the 5021-like and 4072-like T4LHyp gene clusters are predominantly found in bacteria from , which are widely distributed in multiple marine habitats. Thus, bacteria are likely the dominant group to drive the recycling and mineralization of T4LHyp in the ocean. The online version contains supplementary material available at 10.1007/s42995-024-00272-8.
title -4-hydroxy-L-proline catabolism by in the ocean.
url https://pubmed.ncbi.nlm.nih.gov/40027322/