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Main Authors: Jia, Jia, Liu, Qian, Wang, Tao, Zou, Borui, Xiong, Xiong, Xu, Jun, Wu, Chenxi
Format: Artículo científico
Language:en
Published: Journal of hazardous materials 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40865219/
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author Jia, Jia
Liu, Qian
Wang, Tao
Zou, Borui
Xiong, Xiong
Xu, Jun
Wu, Chenxi
author_facet Jia, Jia
Liu, Qian
Wang, Tao
Zou, Borui
Xiong, Xiong
Xu, Jun
Wu, Chenxi
Jia, Jia
Liu, Qian
Wang, Tao
Zou, Borui
Xiong, Xiong
Xu, Jun
Wu, Chenxi
collection PubMed - marine biology
contents Multiple stressors enhance Microcystis dominance and modulate phycospheric antibiotic resistome in aquatic mesocosm. Jia, Jia Liu, Qian Wang, Tao Zou, Borui Xiong, Xiong Xu, Jun Wu, Chenxi Microcystis Anti-Bacterial Agents Water Pollutants, Chemical Ecosystem Phytoplankton Drug Resistance, Microbial Genes, Bacterial Drug Resistance, Bacterial Assessing the response of phycospheric antibiotic resistance genes (ARGs) to pollutants such as antibiotics and microplastics (MPs) under the background of climate warming is crucial for understanding ARG fate in aquatic ecosystems. In this work, we conducted mesocosm experiments to evaluate how these stressors influence phytoplankton dominance, phycospheric bacteria, and ARG evolution. Results showed that in Microcystis-dominant ecosystem, a single stressor strengthened Microcystis dominance (up to 82.37 % of total abundance), but only warming significantly enhanced phycospheric bacterial metabolic activity and promoted phycospheric ARG proliferation (1.34-fold higher on day 16). The increased propagation of Microcystis symbiotic bacteria (e.g., Roseomonas and Methylobacterium) and microcystin-degraders (e.g., Pseudomonas and Sphingomonas) drove the spread of ARGs. Though the single treatment of antibiotics (0.85- and 0.53-fold for days 16 and 30) or MPs (0.72- and 0.20-fold for days 16 and 30) decreased the abundance of ARGs, co-treatment with warming reversed this suppression (e.g., 1.55- and 1.96-fold for WA and MW groups on day 16). The results underscore the necessity of considering the combined warming-pollutant effects in ARG ecological risk assessment in natural waters, particularly under phytoplankton succession scenarios. Such insights are vital for managing antimicrobial resistance in evolving aquatic environments under global change pressures.
format Artículo científico
id pubmed_40865219
institution PubMed
language en
publishDate 2025
publisher Journal of hazardous materials
record_format pubmed
spellingShingle Multiple stressors enhance Microcystis dominance and modulate phycospheric antibiotic resistome in aquatic mesocosm.
Jia, Jia
Liu, Qian
Wang, Tao
Zou, Borui
Xiong, Xiong
Xu, Jun
Wu, Chenxi
Microcystis
Anti-Bacterial Agents
Water Pollutants, Chemical
Ecosystem
Phytoplankton
Drug Resistance, Microbial
Genes, Bacterial
Drug Resistance, Bacterial
Multiple stressors enhance Microcystis dominance and modulate phycospheric antibiotic resistome in aquatic mesocosm. Jia, Jia Liu, Qian Wang, Tao Zou, Borui Xiong, Xiong Xu, Jun Wu, Chenxi Microcystis Anti-Bacterial Agents Water Pollutants, Chemical Ecosystem Phytoplankton Drug Resistance, Microbial Genes, Bacterial Drug Resistance, Bacterial Assessing the response of phycospheric antibiotic resistance genes (ARGs) to pollutants such as antibiotics and microplastics (MPs) under the background of climate warming is crucial for understanding ARG fate in aquatic ecosystems. In this work, we conducted mesocosm experiments to evaluate how these stressors influence phytoplankton dominance, phycospheric bacteria, and ARG evolution. Results showed that in Microcystis-dominant ecosystem, a single stressor strengthened Microcystis dominance (up to 82.37 % of total abundance), but only warming significantly enhanced phycospheric bacterial metabolic activity and promoted phycospheric ARG proliferation (1.34-fold higher on day 16). The increased propagation of Microcystis symbiotic bacteria (e.g., Roseomonas and Methylobacterium) and microcystin-degraders (e.g., Pseudomonas and Sphingomonas) drove the spread of ARGs. Though the single treatment of antibiotics (0.85- and 0.53-fold for days 16 and 30) or MPs (0.72- and 0.20-fold for days 16 and 30) decreased the abundance of ARGs, co-treatment with warming reversed this suppression (e.g., 1.55- and 1.96-fold for WA and MW groups on day 16). The results underscore the necessity of considering the combined warming-pollutant effects in ARG ecological risk assessment in natural waters, particularly under phytoplankton succession scenarios. Such insights are vital for managing antimicrobial resistance in evolving aquatic environments under global change pressures.
title Multiple stressors enhance Microcystis dominance and modulate phycospheric antibiotic resistome in aquatic mesocosm.
topic Microcystis
Anti-Bacterial Agents
Water Pollutants, Chemical
Ecosystem
Phytoplankton
Drug Resistance, Microbial
Genes, Bacterial
Drug Resistance, Bacterial
url https://pubmed.ncbi.nlm.nih.gov/40865219/