Saved in:
Bibliographic Details
Main Authors: Du, Mingyang, Bu, Tian, Wang, Chaogang, Chen, Jincheng, Jiang, Zhuxiang, Wang, Min, Pang, Meiqian, Cong, Rihao, Wang, Wei, Zhang, Guofan, Li, Li
Format: Artículo científico
Language:en
Published: International journal of biological macromolecules 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40623564/
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1868266181660508162
author Du, Mingyang
Bu, Tian
Wang, Chaogang
Chen, Jincheng
Jiang, Zhuxiang
Wang, Min
Pang, Meiqian
Cong, Rihao
Wang, Wei
Zhang, Guofan
Li, Li
author_facet Du, Mingyang
Bu, Tian
Wang, Chaogang
Chen, Jincheng
Jiang, Zhuxiang
Wang, Min
Pang, Meiqian
Cong, Rihao
Wang, Wei
Zhang, Guofan
Li, Li
Du, Mingyang
Bu, Tian
Wang, Chaogang
Chen, Jincheng
Jiang, Zhuxiang
Wang, Min
Pang, Meiqian
Cong, Rihao
Wang, Wei
Zhang, Guofan
Li, Li
collection PubMed - marine biology
contents Unravelling the regulatory network underlying divergent expression of the key lipid metabolism transcription factor SREBP in two congeneric oyster species. Du, Mingyang Bu, Tian Wang, Chaogang Chen, Jincheng Jiang, Zhuxiang Wang, Min Pang, Meiqian Cong, Rihao Wang, Wei Zhang, Guofan Li, Li Animals Lipid Metabolism Gene Regulatory Networks Gene Expression Regulation Promoter Regions, Genetic Sterol Regulatory Element Binding Proteins Crassostrea Ostreidae SREBP serves as the master transcriptional regulator of lipid metabolism, playing a crucial role in temperature adaptation. However, the regulatory mechanisms controlling SREBP expression remain poorly understood in marine organisms. The basic bHLH domain of single-copy SREBP was highly conserved in mollusks, confirming its fundamental role in lipid metabolic regulation. We observed significantly higher SREBP gene expression in the relatively cold-adapted Crassostrea gigas compared to the warm-adapted Crassostrea angulata. The large and stably inherited deletion in the SREBP promoter region of C. gigas prevented binding of repressive transcription factor POU4F3, partially explaining its higher expression levels. Additionally, the eGWAS analysis identified 119 candidate genes potentially associated with SREBP expression regulation. The direct interaction of SREBP with PPP6C and the non-binding PRP4 may activate downstream regulatory pathways of SREBP through phosphorylation mechanisms. The higher expressed activating transcription factor PRRX2 in C. gigas could simultaneously activate the promoter activity in both oyster species, potentially explaining the elevated expression of SREBP in C. gigas. This study provided the first comprehensive characterization the regulatory network of SREBP expression in marine organisms, providing new insights into lipid metabolism for temperature adaptation in the context of global warming.
format Artículo científico
id pubmed_40623564
institution PubMed
language en
publishDate 2025
publisher International journal of biological macromolecules
record_format pubmed
spellingShingle Unravelling the regulatory network underlying divergent expression of the key lipid metabolism transcription factor SREBP in two congeneric oyster species.
Du, Mingyang
Bu, Tian
Wang, Chaogang
Chen, Jincheng
Jiang, Zhuxiang
Wang, Min
Pang, Meiqian
Cong, Rihao
Wang, Wei
Zhang, Guofan
Li, Li
Animals
Lipid Metabolism
Gene Regulatory Networks
Gene Expression Regulation
Promoter Regions, Genetic
Sterol Regulatory Element Binding Proteins
Crassostrea
Ostreidae
Unravelling the regulatory network underlying divergent expression of the key lipid metabolism transcription factor SREBP in two congeneric oyster species. Du, Mingyang Bu, Tian Wang, Chaogang Chen, Jincheng Jiang, Zhuxiang Wang, Min Pang, Meiqian Cong, Rihao Wang, Wei Zhang, Guofan Li, Li Animals Lipid Metabolism Gene Regulatory Networks Gene Expression Regulation Promoter Regions, Genetic Sterol Regulatory Element Binding Proteins Crassostrea Ostreidae SREBP serves as the master transcriptional regulator of lipid metabolism, playing a crucial role in temperature adaptation. However, the regulatory mechanisms controlling SREBP expression remain poorly understood in marine organisms. The basic bHLH domain of single-copy SREBP was highly conserved in mollusks, confirming its fundamental role in lipid metabolic regulation. We observed significantly higher SREBP gene expression in the relatively cold-adapted Crassostrea gigas compared to the warm-adapted Crassostrea angulata. The large and stably inherited deletion in the SREBP promoter region of C. gigas prevented binding of repressive transcription factor POU4F3, partially explaining its higher expression levels. Additionally, the eGWAS analysis identified 119 candidate genes potentially associated with SREBP expression regulation. The direct interaction of SREBP with PPP6C and the non-binding PRP4 may activate downstream regulatory pathways of SREBP through phosphorylation mechanisms. The higher expressed activating transcription factor PRRX2 in C. gigas could simultaneously activate the promoter activity in both oyster species, potentially explaining the elevated expression of SREBP in C. gigas. This study provided the first comprehensive characterization the regulatory network of SREBP expression in marine organisms, providing new insights into lipid metabolism for temperature adaptation in the context of global warming.
title Unravelling the regulatory network underlying divergent expression of the key lipid metabolism transcription factor SREBP in two congeneric oyster species.
topic Animals
Lipid Metabolism
Gene Regulatory Networks
Gene Expression Regulation
Promoter Regions, Genetic
Sterol Regulatory Element Binding Proteins
Crassostrea
Ostreidae
url https://pubmed.ncbi.nlm.nih.gov/40623564/