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Autores principales: Yang, Haiyan, Liu, Jinling, Huangfu, Mingce, Zhao, He, Li, Yushan, Zhou, Yinyin, Wang, Aimin, Chen, Rou-Wen, Li, Xiubao
Formato: Artículo científico
Lenguaje:en
Publicado: Marine environmental research 2025
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Acceso en línea:https://pubmed.ncbi.nlm.nih.gov/40694998/
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author Yang, Haiyan
Liu, Jinling
Huangfu, Mingce
Zhao, He
Li, Yushan
Zhou, Yinyin
Wang, Aimin
Chen, Rou-Wen
Li, Xiubao
author_facet Yang, Haiyan
Liu, Jinling
Huangfu, Mingce
Zhao, He
Li, Yushan
Zhou, Yinyin
Wang, Aimin
Chen, Rou-Wen
Li, Xiubao
Yang, Haiyan
Liu, Jinling
Huangfu, Mingce
Zhao, He
Li, Yushan
Zhou, Yinyin
Wang, Aimin
Chen, Rou-Wen
Li, Xiubao
collection PubMed - marine biology
contents Physiological impairment and metabolic perturbations in Porites cylindrica induced by Hypnea pannosa contact. Yang, Haiyan Liu, Jinling Huangfu, Mingce Zhao, He Li, Yushan Zhou, Yinyin Wang, Aimin Chen, Rou-Wen Li, Xiubao Animals Anthozoa Coral Reefs Seaweed Oxidative Stress Metabolome Rhodophyta Coral reef ecosystems are undergoing accelerated degradation, characterized by phase shifts marked by declining live coral cover and increasing macroalgal proliferation. However, the long-term metabolic adjustments of corals under chronic macroalgal competition remain poorly understood, particularly regarding the integration of physiological changes with metabolic responses resilience mechanisms. This study conducted a 21-day experiment to investigate the physiological and metabolomic response between coral Porites cylindrica and macroalgae Hypnea pannosa. Key findings revealed that direct physical contact with H. pannosa induced severe oxidative stress in P. cylindrica, manifested by a 19.06 % increase in malondialdehyde (MDA) levels, a 12.26 % reduction in Fv/Fm, an 8.65 % decrease in endosymbiotic microalgal density, a 66.73 % diminishment in chlorophyll a content, and depletion of lipid, carbohydrate, and protein reserves by 44.21 %, 7.91 %, and 12.03 %, respectively. Metabolomic profiling identified 81 upregulated and 114 downregulated metabolites. KEGG pathway enrichment analysis demonstrated that these differentially expressed metabolites were predominantly associated with lipid-mediated defense mechanisms, including arachidonic acid metabolism and unsaturated fatty acid biosynthesis pathways. These mechanistic insights advance our understanding of coral-macroalgal competitive dynamics and provide critical theoretical foundations for formulating targeted reef restoration strategies.
format Artículo científico
id pubmed_40694998
institution PubMed
language en
publishDate 2025
publisher Marine environmental research
record_format pubmed
spellingShingle Physiological impairment and metabolic perturbations in Porites cylindrica induced by Hypnea pannosa contact.
Yang, Haiyan
Liu, Jinling
Huangfu, Mingce
Zhao, He
Li, Yushan
Zhou, Yinyin
Wang, Aimin
Chen, Rou-Wen
Li, Xiubao
Animals
Anthozoa
Coral Reefs
Seaweed
Oxidative Stress
Metabolome
Rhodophyta
Physiological impairment and metabolic perturbations in Porites cylindrica induced by Hypnea pannosa contact. Yang, Haiyan Liu, Jinling Huangfu, Mingce Zhao, He Li, Yushan Zhou, Yinyin Wang, Aimin Chen, Rou-Wen Li, Xiubao Animals Anthozoa Coral Reefs Seaweed Oxidative Stress Metabolome Rhodophyta Coral reef ecosystems are undergoing accelerated degradation, characterized by phase shifts marked by declining live coral cover and increasing macroalgal proliferation. However, the long-term metabolic adjustments of corals under chronic macroalgal competition remain poorly understood, particularly regarding the integration of physiological changes with metabolic responses resilience mechanisms. This study conducted a 21-day experiment to investigate the physiological and metabolomic response between coral Porites cylindrica and macroalgae Hypnea pannosa. Key findings revealed that direct physical contact with H. pannosa induced severe oxidative stress in P. cylindrica, manifested by a 19.06 % increase in malondialdehyde (MDA) levels, a 12.26 % reduction in Fv/Fm, an 8.65 % decrease in endosymbiotic microalgal density, a 66.73 % diminishment in chlorophyll a content, and depletion of lipid, carbohydrate, and protein reserves by 44.21 %, 7.91 %, and 12.03 %, respectively. Metabolomic profiling identified 81 upregulated and 114 downregulated metabolites. KEGG pathway enrichment analysis demonstrated that these differentially expressed metabolites were predominantly associated with lipid-mediated defense mechanisms, including arachidonic acid metabolism and unsaturated fatty acid biosynthesis pathways. These mechanistic insights advance our understanding of coral-macroalgal competitive dynamics and provide critical theoretical foundations for formulating targeted reef restoration strategies.
title Physiological impairment and metabolic perturbations in Porites cylindrica induced by Hypnea pannosa contact.
topic Animals
Anthozoa
Coral Reefs
Seaweed
Oxidative Stress
Metabolome
Rhodophyta
url https://pubmed.ncbi.nlm.nih.gov/40694998/