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Main Authors: Wang, Xinjie, Xi, Yimei, Fang, Kuo, Li, Cheng, Li, Yongbin, Wang, Shaofeng, Bi, Ran, Chi, Zhanyou, Tian, Jiashen, Zeng, Xiangfeng
Format: Artículo científico
Language:en
Published: Marine environmental research 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/42033968/
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author Wang, Xinjie
Xi, Yimei
Fang, Kuo
Li, Cheng
Li, Yongbin
Wang, Shaofeng
Bi, Ran
Chi, Zhanyou
Tian, Jiashen
Zeng, Xiangfeng
author_facet Wang, Xinjie
Xi, Yimei
Fang, Kuo
Li, Cheng
Li, Yongbin
Wang, Shaofeng
Bi, Ran
Chi, Zhanyou
Tian, Jiashen
Zeng, Xiangfeng
Wang, Xinjie
Xi, Yimei
Fang, Kuo
Li, Cheng
Li, Yongbin
Wang, Shaofeng
Bi, Ran
Chi, Zhanyou
Tian, Jiashen
Zeng, Xiangfeng
collection PubMed - marine biology
contents Influence of suspended particulate matter input on phytoplankton community structure in estuarine environments. Wang, Xinjie Xi, Yimei Fang, Kuo Li, Cheng Li, Yongbin Wang, Shaofeng Bi, Ran Chi, Zhanyou Tian, Jiashen Zeng, Xiangfeng Phytoplankton Particulate Matter Estuaries Environmental Monitoring Particle Size Ecosystem Biomass Seawater Riverine suspended particulate matter (SPM) inputs play a crucial role in regulating phytoplankton sedimentation and stability in estuarine ecosystems, thereby mediating organic matter cycling. However, our understanding of how the physicochemical properties of SPM influence the short-term response mechanisms of phytoplankton remains insufficient. This study focuses on the sedimentation phase following SPM input and employs a controlled microcosm experimental system. Through short-term sedimentation experiments, it thoroughly investigates the effects of SPM particle size and surface charge on the sedimentation behavior and community composition of marine phytoplankton. The results show that SPM sedimentation substantially decreased phytoplankton biomass in seawater, with sedimentation rates increasing significantly as SPM particle size decreased. Surface charge also strongly enhanced phytoplankton sedimentation. In terms of community composition, SPM markedly altered phytoplankton structure by significantly reducing the relative abundance of Bacillariophyta and Dinophyta while increasing that of Heterokontophyta. Among the examined factors, SPM particle size emerged as a primary driver of these changes. Additionally, SPM inputs increased the relative abundance of microalgae-associated symbiotic bacteria, and combined with the changes in community composition and the results of co-occurrence network analysis, it is hypothesized that the enriched microalgae-associated bacteria may form potential ecological associations with phytoplankton under SPM disturbance conditions. Overall, this study provides new insights into the short-term responses of marine phytoplankton to riverine SPM input during the initial sedimentation phase, and offers preliminary mechanistic references for understanding particulate matter-driven plankton dynamics in estuarine systems.
format Artículo científico
id pubmed_42033968
institution PubMed
language en
publishDate 2026
publisher Marine environmental research
record_format pubmed
spellingShingle Influence of suspended particulate matter input on phytoplankton community structure in estuarine environments.
Wang, Xinjie
Xi, Yimei
Fang, Kuo
Li, Cheng
Li, Yongbin
Wang, Shaofeng
Bi, Ran
Chi, Zhanyou
Tian, Jiashen
Zeng, Xiangfeng
Phytoplankton
Particulate Matter
Estuaries
Environmental Monitoring
Particle Size
Ecosystem
Biomass
Seawater
Influence of suspended particulate matter input on phytoplankton community structure in estuarine environments. Wang, Xinjie Xi, Yimei Fang, Kuo Li, Cheng Li, Yongbin Wang, Shaofeng Bi, Ran Chi, Zhanyou Tian, Jiashen Zeng, Xiangfeng Phytoplankton Particulate Matter Estuaries Environmental Monitoring Particle Size Ecosystem Biomass Seawater Riverine suspended particulate matter (SPM) inputs play a crucial role in regulating phytoplankton sedimentation and stability in estuarine ecosystems, thereby mediating organic matter cycling. However, our understanding of how the physicochemical properties of SPM influence the short-term response mechanisms of phytoplankton remains insufficient. This study focuses on the sedimentation phase following SPM input and employs a controlled microcosm experimental system. Through short-term sedimentation experiments, it thoroughly investigates the effects of SPM particle size and surface charge on the sedimentation behavior and community composition of marine phytoplankton. The results show that SPM sedimentation substantially decreased phytoplankton biomass in seawater, with sedimentation rates increasing significantly as SPM particle size decreased. Surface charge also strongly enhanced phytoplankton sedimentation. In terms of community composition, SPM markedly altered phytoplankton structure by significantly reducing the relative abundance of Bacillariophyta and Dinophyta while increasing that of Heterokontophyta. Among the examined factors, SPM particle size emerged as a primary driver of these changes. Additionally, SPM inputs increased the relative abundance of microalgae-associated symbiotic bacteria, and combined with the changes in community composition and the results of co-occurrence network analysis, it is hypothesized that the enriched microalgae-associated bacteria may form potential ecological associations with phytoplankton under SPM disturbance conditions. Overall, this study provides new insights into the short-term responses of marine phytoplankton to riverine SPM input during the initial sedimentation phase, and offers preliminary mechanistic references for understanding particulate matter-driven plankton dynamics in estuarine systems.
title Influence of suspended particulate matter input on phytoplankton community structure in estuarine environments.
topic Phytoplankton
Particulate Matter
Estuaries
Environmental Monitoring
Particle Size
Ecosystem
Biomass
Seawater
url https://pubmed.ncbi.nlm.nih.gov/42033968/