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Main Authors: Shangguan, Jingjing, Yang, Na, Zhang, Litao, Liu, Jianguo, Xia, Xiuluan, Xu, Bingzheng
Format: Artículo científico
Language:en
Published: Bioresource technology 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40139467/
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author Shangguan, Jingjing
Yang, Na
Zhang, Litao
Liu, Jianguo
Xia, Xiuluan
Xu, Bingzheng
author_facet Shangguan, Jingjing
Yang, Na
Zhang, Litao
Liu, Jianguo
Xia, Xiuluan
Xu, Bingzheng
Shangguan, Jingjing
Yang, Na
Zhang, Litao
Liu, Jianguo
Xia, Xiuluan
Xu, Bingzheng
collection PubMed - marine biology
contents Employing Chlorella pyrenoidosa in eco-friendly acetylsalicylic acid degradation: Insights from physiology and transcriptomics. Shangguan, Jingjing Yang, Na Zhang, Litao Liu, Jianguo Xia, Xiuluan Xu, Bingzheng Chlorella Aspirin Biodegradation, Environmental Transcriptome Gene Expression Profiling Photosynthesis Water Pollutants, Chemical Nitrogen Emerging contaminants, often present at low concentrations, are of increasing concern due to their persistence and potential hazards. Chlorella pyrenoidosa has shown significant potential for removing these emerging contaminants from aquatic environments. In this study, C. pyrenoidosa effectively removed and degraded acetylsalicylic acid (ASA) at concentrations ranging from 2.2 to 22.1 mg/L, achieving a removal efficiency of 98.8 %, with 89.0 % of this removal attributed to biodegradation. ASA treatment also significantly promoted cellular growth, enhanced protein and soluble sugar accumulation, and improved both photosynthetic and respiratory activities. At 22.1 mg/L ASA, protein content increased by 51.9 %, and soluble sugar content rose by 34.8 %. Transcriptomic analysis revealed that ASA promoted carbon metabolism and nitrogen metabolism. These results highlight C. pyrenoidosa as a promising, eco-friendly solution for the removal of ASA, offering potential applications in sustainable wastewater treatment and resource recovery.
format Artículo científico
id pubmed_40139467
institution PubMed
language en
publishDate 2025
publisher Bioresource technology
record_format pubmed
spellingShingle Employing Chlorella pyrenoidosa in eco-friendly acetylsalicylic acid degradation: Insights from physiology and transcriptomics.
Shangguan, Jingjing
Yang, Na
Zhang, Litao
Liu, Jianguo
Xia, Xiuluan
Xu, Bingzheng
Chlorella
Aspirin
Biodegradation, Environmental
Transcriptome
Gene Expression Profiling
Photosynthesis
Water Pollutants, Chemical
Nitrogen
Employing Chlorella pyrenoidosa in eco-friendly acetylsalicylic acid degradation: Insights from physiology and transcriptomics. Shangguan, Jingjing Yang, Na Zhang, Litao Liu, Jianguo Xia, Xiuluan Xu, Bingzheng Chlorella Aspirin Biodegradation, Environmental Transcriptome Gene Expression Profiling Photosynthesis Water Pollutants, Chemical Nitrogen Emerging contaminants, often present at low concentrations, are of increasing concern due to their persistence and potential hazards. Chlorella pyrenoidosa has shown significant potential for removing these emerging contaminants from aquatic environments. In this study, C. pyrenoidosa effectively removed and degraded acetylsalicylic acid (ASA) at concentrations ranging from 2.2 to 22.1 mg/L, achieving a removal efficiency of 98.8 %, with 89.0 % of this removal attributed to biodegradation. ASA treatment also significantly promoted cellular growth, enhanced protein and soluble sugar accumulation, and improved both photosynthetic and respiratory activities. At 22.1 mg/L ASA, protein content increased by 51.9 %, and soluble sugar content rose by 34.8 %. Transcriptomic analysis revealed that ASA promoted carbon metabolism and nitrogen metabolism. These results highlight C. pyrenoidosa as a promising, eco-friendly solution for the removal of ASA, offering potential applications in sustainable wastewater treatment and resource recovery.
title Employing Chlorella pyrenoidosa in eco-friendly acetylsalicylic acid degradation: Insights from physiology and transcriptomics.
topic Chlorella
Aspirin
Biodegradation, Environmental
Transcriptome
Gene Expression Profiling
Photosynthesis
Water Pollutants, Chemical
Nitrogen
url https://pubmed.ncbi.nlm.nih.gov/40139467/