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61,005 resultsShowing papers similar to Response of microbial communities and biogeochemical cycling functions to sediment physicochemical properties and microplastic pollution under damming and water diversion projects
ClearEffects of microplastics on the structure and function of bacterial communities in sediments of a freshwater lake
Researchers examined how microplastics alter the structure and function of bacterial communities in sediments, finding that plastic exposure shifted community composition and reduced overall diversity compared to plastic-free controls. Functional analysis showed impaired denitrification and organic matter decomposition in microplastic-contaminated sediments, indicating ecosystem-level consequences for nutrient cycling.
Unveiling microplastic's role in nitrogen cycling: Metagenomic insights from estuarine sediment microcosms
Researchers used metagenomic analysis to examine how polyethylene and polystyrene microplastics affect nitrogen cycling in estuarine sediments. They found that microplastics altered the abundance of genes involved in key nitrogen transformation processes like nitrification and denitrification. The study reveals that microplastic pollution in estuaries may disrupt important biogeochemical cycles that support aquatic ecosystem health.
Effects of microplastics on nitrogen and phosphorus cycles and microbial communities in sediments
Researchers found that PVC, PLA, and polypropylene microplastics altered nitrogen and phosphorus cycling in freshwater sediments by shifting microbial community composition, with effects varying by polymer type and biodegradability.
Impact of microplastics on microbial community in sediments of the Huangjinxia Reservoir—water source of a water diversion project in western China
Researchers examined microplastic contamination and its effects on microbial communities in sediments of the Huangjinxia Reservoir in western China, investigating how microplastic presence alters the composition and function of microbial assemblages in this drinking water source.
Seasonal changes in N-cycling functional genes in sediments and their influencing factors in a typical eutrophic shallow lake, China
This study tracked seasonal changes in nitrogen-cycling bacteria in the sediments of a nutrient-rich lake in China, finding that key microbial processes shifted significantly between warmer and colder months. While focused on lake ecology rather than microplastics directly, the research is relevant because microplastics in lake sediments are known to alter microbial communities and nitrogen cycling processes. Understanding these baseline patterns helps scientists assess how microplastic contamination may further disrupt nutrient cycling in freshwater ecosystems.
Microplastics Increase the Risk of Greenhouse Gas Emissions and Water Pollution in a Freshwater Lake by Affecting Microbial Function in Biogenic Element Cycling: A Metagenomic Study
Researchers used metagenomic analysis to examine how microplastics affect microbial community function in a freshwater lake, finding that microplastic contamination disrupts biogenic element cycling processes and increases the risk of greenhouse gas emissions and water quality degradation.
[Response of Relationship Between Microplastic Abundance and Nitrogen Metabolism Function Microorganisms and Genes in Water].
Researchers investigated the relationship between microplastic abundance and nitrogen-metabolizing microorganisms and genes in Lake Ulansuhai using microscopy and metagenomic sequencing, finding that microplastics in freshwater environments significantly influenced the composition and activity of nitrogen metabolism functional bacteria and associated genes.
Undisclosed contribution of microbial assemblages selectively enriched by microplastics to the sulfur cycle in the large deep-water reservoir
Researchers investigated how microbial communities growing on microplastics in a large Chinese reservoir contribute to the sulfur cycle, a key environmental process. They found that plastic-degrading bacteria involved in sulfur cycling were enriched on microplastic surfaces, with specific sulfur-oxidizing species acting as keystone organisms in the microbial network. The study suggests that microplastics create distinct microbial habitats that can influence important nutrient and chemical cycles in freshwater reservoirs.
Microbial Community Dynamics and Biogeochemical Cycling in Microplastic-Contaminated Sediment
This review summarizes current research on how microplastics alter microbial communities and nutrient cycling processes in sediments at the bottom of water bodies. Researchers found that the effects depend on the type of plastic, exposure duration, and the specific sediment environment, with biodegradable plastics causing the most significant changes. The study highlights that microplastics in sediments can reshape the microbial ecosystems that drive essential biogeochemical processes like carbon and nitrogen cycling.
Microplastics increase the microbial functional potential of greenhouse gas emissions and water pollution in a freshwater lake: A metagenomic study
A lab study found that adding common types of microplastics to freshwater lake water changed the microbial community in ways that could increase greenhouse gas production and water pollution. Microplastics, especially polyethylene, boosted genes involved in methane production and nitrogen loss from water. This suggests that microplastic pollution in lakes and reservoirs could have hidden environmental effects beyond direct toxicity, including contributing to climate change and degrading water quality.
Biofilms in plastisphere from freshwater wetlands: Biofilm formation, bacterial community assembly, and biogeochemical cycles
Researchers studied how bacteria form biofilms on microplastic surfaces in freshwater wetlands and found that these plastic-associated communities differ significantly from natural soil bacteria. The microplastic biofilms had lower diversity but higher activity in carbon processing and nitrogen cycling genes. This means microplastics in wetlands can alter natural nutrient cycles, potentially affecting water quality in ecosystems that many communities rely on.
Effects of microplastics on bacterial communities in lake wetland sediments: a comparison between drought and flooded conditions
Researchers established a sediment microcosm system for Poyang Lake wetland and examined the effects of polyethylene and polypropylene microplastics on bacterial community structure, functional genes, and ecological processes over 180 days under both simulated drought and flooded conditions.
Microplastics alter the microbiota-mediated phosphorus profiles at sediment-water interface: Distinct microbial effects between sediment and plastisphere
This study found that microplastics in lake sediments change how bacteria process phosphorus, a key nutrient in freshwater ecosystems. Both petroleum-based and biodegradable microplastics altered bacterial communities and phosphorus cycling, but in different ways depending on whether bacteria were in the sediment or on the plastic surfaces. These changes could contribute to water quality problems like algal blooms that affect both ecosystems and the drinking water supply.
Microplastic biofilms as potential hotspots for plastic biodegradation and nitrogen cycling: a metagenomic perspective
Researchers used genetic analysis to study the microbial communities that form biofilms on different types of microplastics in an estuarine environment. They found that these plastic-associated communities contained genes for both plastic degradation and nitrogen cycling, suggesting the biofilms may play dual roles in the ecosystem. The study indicates that microplastic surfaces in waterways create unique microbial habitats that could influence both pollution breakdown and nutrient processing.
Non-synergistic effects of microplastics and submerged macrophytes on sediment microorganisms involved in carbon and nitrogen cycling
This study used genomic analysis to look at how polystyrene microplastics and aquatic plants (submerged macrophytes) together influence the microbial communities in lake sediments that control nutrient cycling. Rather than amplifying each other's effects, the two factors acted independently — microplastics increased microbial diversity while the plants shaped which metabolic functions dominated. The finding suggests that the ecological impact of microplastics in lakes cannot be predicted by looking at microplastics alone, without accounting for the vegetation already present.
Can Microplastic Pollution Change Important Aquatic Bacterial Communities?
Microplastics in coastal sediments can change the composition of important bacterial communities that cycle nutrients and maintain ecosystem health. Microplastic-associated bacteria differ significantly from natural sediment bacteria, with potential consequences for the chemical processes these communities perform.
Discrepancy strategies of sediment abundant and rare microbial communities in response to floating microplastic disturbances: Study using a microcosmic experiment
Using microcosm experiments with fluvial sediment exposed to four plastic types, researchers found that floating microplastics altered sediment microbial diversity and reduced bacteria involved in carbon and nitrogen cycling. Abundant microbial taxa were more sensitive to microplastic disturbance than rare taxa, and microplastics decreased network complexity and increased negative species interactions in microbial communities.
Effects of microplastic particles on carbon source metabolism and bacterial community in freshwater lake sediments
A microcosm experiment tested how four common plastic types affect carbon metabolism and bacterial communities in freshwater lake sediments, finding that microplastics disrupted microbial carbon cycling and altered community composition.
Effect of microplastics on ecosystem functioning: Microbial nitrogen removal mediated by benthic invertebrates
Researchers investigated how polyethylene microplastics affect nitrogen removal in freshwater sediments where chironomid larvae and microorganisms coexist. They found that while microplastics and larvae each individually promoted nitrogen removal by boosting denitrifying bacteria, combining them together produced less benefit than expected. The study suggests that rising microplastic concentrations may disrupt the natural nitrogen cycling that benthic invertebrates help maintain in freshwater ecosystems.
Uniqueness and Dependence of Bacterial Communities on Microplastics: Comparison with Water, Sediment, and Soil
Researchers compared bacterial communities on microplastics with those in water, sediment, and soil in the Three Gorges Reservoir area, finding that microplastic-associated communities are unique in composition and ecological function compared to surrounding environments.
Unveiling the hidden world of microorganisms and their impact on the Earth's ecosystems
This paper is not directly about microplastics; it is a broad review of microbial ecology covering microorganism roles in biogeochemical cycling of carbon, nitrogen, phosphorus, sulfur, and metals, and how advances in genomics have transformed our understanding of microbial community diversity and function.
Varied influence of aged microplastics and related leachates on phosphorus transformation and release from the sediments
Researchers investigated how aged microplastics and their chemical leachates affect phosphorus cycling in freshwater sediments, a process linked to harmful algal blooms. They found that different types of weathered plastics and their leachates altered microbial communities and shifted the forms of phosphorus present in sediments. The study suggests that microplastic pollution in lake and river sediments may contribute to nutrient imbalances that worsen water quality problems.
Damming has changed the migration process of microplastics and increased the pollution risk in the reservoirs in the Shaying River Basin
Researchers investigated how dam construction in the Shaying River Basin affects microplastic pollution in water, sediment, and biological tissues near ten dams. The study found that dams alter the transport and deposition of microplastics, intercepting large amounts in reservoirs and changing how microplastics accumulate in freshwater organisms through shifts in food web structure.
Multi-omics-based approach reveals the effects of microplastics on microbial abundance and function of sediments in Shenzhen coastal waters
Researchers used a multi-omics approach combining metagenomics and metatranscriptomics to investigate how microplastic contamination affects microbial community abundance and functional gene expression in coastal sediments from eastern and western Shenzhen, China. They found microplastic concentrations of 119 items per kilogram in eastern sediments and 664 items per kilogram in western sediments, with higher contamination sites showing significant shifts in microbial community composition and altered expression of genes involved in carbon, nitrogen, and sulfur cycling.