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Autores principales: Wu, Shan, She, Yiting, Chen, Xitao, Huang, Xingwei, Xu, Tao, Miao, Congcong, Wu, Qianyi, Li, Zheng, Li, Chengcheng, Cheng, Yuhui, Xin, Yi
Formato: Artículo científico
Lenguaje:en
Publicado: Plant cell reports 2025
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Acceso en línea:https://pubmed.ncbi.nlm.nih.gov/40455335/
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author Wu, Shan
She, Yiting
Chen, Xitao
Huang, Xingwei
Xu, Tao
Miao, Congcong
Wu, Qianyi
Li, Zheng
Li, Chengcheng
Cheng, Yuhui
Xin, Yi
author_facet Wu, Shan
She, Yiting
Chen, Xitao
Huang, Xingwei
Xu, Tao
Miao, Congcong
Wu, Qianyi
Li, Zheng
Li, Chengcheng
Cheng, Yuhui
Xin, Yi
Wu, Shan
She, Yiting
Chen, Xitao
Huang, Xingwei
Xu, Tao
Miao, Congcong
Wu, Qianyi
Li, Zheng
Li, Chengcheng
Cheng, Yuhui
Xin, Yi
collection PubMed - marine biology
contents Enhanced thermotolerance via overexpression of a stromal ascorbate peroxidase in Nannochloropsis oceanica. Wu, Shan She, Yiting Chen, Xitao Huang, Xingwei Xu, Tao Miao, Congcong Wu, Qianyi Li, Zheng Li, Chengcheng Cheng, Yuhui Xin, Yi Ascorbate Peroxidases Thermotolerance Microalgae Stramenopiles Reactive Oxygen Species Photosynthesis Chloroplasts Overexpression of the heat-responsive ascorbate peroxidase gene NoAPX2430 improves thermotolerance and growth of Nannochloropsis oceanica, offering potential strategies for enhanced resilience in plant cells. Microalgae are promising for industrial lipid production but face challenges from high-temperature (HT) stress. This study focused on improving thermotolerance in Nannochloropsis oceanica by studying and modifying the heat-responsive ascorbate peroxidase gene, NoAPX2430. Functional and localization analyses confirmed NoAPX2430 as an active enzyme in the chloroplast stroma. Knockdown of NoAPX2430 resulted in reduced growth, photosynthetic efficiency, and reactive oxygen species (ROS) scavenging under HT (35 °C). In contrast, overexpression of NoAPX2430 significantly improved photosynthetic performance, lowered ROS levels, and boosted growth rates. Additionally, lipid and triacylglycerol contents increased significantly under combined nitrogen depletion and HT, with polyunsaturated fatty acids rising by up to 194.4%. These results highlight NoAPX2430's critical role in enhancing thermotolerance and lipid biosynthesis. This provides a foundation for genetic and environmental strategies to boost microalgal resilience and productivity for sustainable biofuel and nutraceutical development.
format Artículo científico
id pubmed_40455335
institution PubMed
language en
publishDate 2025
publisher Plant cell reports
record_format pubmed
spellingShingle Enhanced thermotolerance via overexpression of a stromal ascorbate peroxidase in Nannochloropsis oceanica.
Wu, Shan
She, Yiting
Chen, Xitao
Huang, Xingwei
Xu, Tao
Miao, Congcong
Wu, Qianyi
Li, Zheng
Li, Chengcheng
Cheng, Yuhui
Xin, Yi
Ascorbate Peroxidases
Thermotolerance
Microalgae
Stramenopiles
Reactive Oxygen Species
Photosynthesis
Chloroplasts
Enhanced thermotolerance via overexpression of a stromal ascorbate peroxidase in Nannochloropsis oceanica. Wu, Shan She, Yiting Chen, Xitao Huang, Xingwei Xu, Tao Miao, Congcong Wu, Qianyi Li, Zheng Li, Chengcheng Cheng, Yuhui Xin, Yi Ascorbate Peroxidases Thermotolerance Microalgae Stramenopiles Reactive Oxygen Species Photosynthesis Chloroplasts Overexpression of the heat-responsive ascorbate peroxidase gene NoAPX2430 improves thermotolerance and growth of Nannochloropsis oceanica, offering potential strategies for enhanced resilience in plant cells. Microalgae are promising for industrial lipid production but face challenges from high-temperature (HT) stress. This study focused on improving thermotolerance in Nannochloropsis oceanica by studying and modifying the heat-responsive ascorbate peroxidase gene, NoAPX2430. Functional and localization analyses confirmed NoAPX2430 as an active enzyme in the chloroplast stroma. Knockdown of NoAPX2430 resulted in reduced growth, photosynthetic efficiency, and reactive oxygen species (ROS) scavenging under HT (35 °C). In contrast, overexpression of NoAPX2430 significantly improved photosynthetic performance, lowered ROS levels, and boosted growth rates. Additionally, lipid and triacylglycerol contents increased significantly under combined nitrogen depletion and HT, with polyunsaturated fatty acids rising by up to 194.4%. These results highlight NoAPX2430's critical role in enhancing thermotolerance and lipid biosynthesis. This provides a foundation for genetic and environmental strategies to boost microalgal resilience and productivity for sustainable biofuel and nutraceutical development.
title Enhanced thermotolerance via overexpression of a stromal ascorbate peroxidase in Nannochloropsis oceanica.
topic Ascorbate Peroxidases
Thermotolerance
Microalgae
Stramenopiles
Reactive Oxygen Species
Photosynthesis
Chloroplasts
url https://pubmed.ncbi.nlm.nih.gov/40455335/