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61,005 resultsShowing papers similar to Microplastics as drivers of carbon and nitrogen cycling alterations in aquatic ecosystems: A meta-analysis
ClearMicroplastics stimulated nitrous oxide emissions primarily through denitrification: A meta-analysis
Meta-analysis of 60 studies found that microplastic exposure increased soil nitrous oxide (N2O) emissions by 140.6%, primarily by stimulating denitrification rates (up 17.8%) and denitrifier gene abundance (up 10.6%), while nitrification remained unaffected. This resulted in a 38.8% increase in soil nitrite and a 22.4% decrease in nitrate.
Effect of microplastics on carbon, nitrogen and phosphorus cycle in farmland soil: A meta-analysis
This meta-analysis of 102 studies found that microplastics in farmland soil increased soil organic carbon, microbial biomass carbon, and microbial biomass nitrogen, but also elevated CO2, methane, and nitrous oxide emissions through enhanced carbon mineralization and denitrification. Microplastic biodegradability, size, concentration, and soil properties all drove these effects, suggesting agricultural microplastic pollution may worsen greenhouse gas emissions from farmland.
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.
Microplastics alter nitrous oxide production and pathways through affecting microbiome in estuarine sediments
Researchers found that both petroleum-based and biodegradable microplastics increased nitrous oxide production in estuarine sediments, with biodegradable polylactic acid plastics showing greater effects by altering microbial nitrogen cycling pathways.
Microplastics transport and impact on nitrogen cycling and N2O emissions in estuaries
This review synthesized evidence on how microplastics disrupt nitrogen cycling and amplify nitrous oxide emissions in estuarine ecosystems, proposing an integrative conceptual model. Microplastics affect nitrogen transformation through adsorption of nitrogenous compounds, microbial community restructuring, enzymatic inhibition, and promotion of incomplete denitrification within plastisphere biofilms.
Microplastics promote N2O emissions by enhancing nitrification via ammonia-oxidizing bacteria in estuarine and coastal sediments
Incubation experiments with sediments from China's Yangtze River estuary found that polyethylene, polypropylene, and PET microplastics all significantly increased nitrous oxide (N2O) emissions — a potent greenhouse gas — by stimulating ammonia-oxidizing bacteria (AOB) rather than the archaea that normally dominate nitrogen cycling. Genomic analysis revealed that these bacteria carry enzymes capable of degrading plastic, possibly explaining why they thrive in plastic-contaminated sediments. This links microplastic pollution to climate change through an overlooked pathway: disrupting coastal nitrogen cycling and increasing greenhouse gas emissions.
Polyethylene microplastics alter the microbial functional gene abundances and increase nitrous oxide emissions from paddy soils
Researchers found that polyethylene microplastics in paddy soils significantly increased nitrous oxide emissions by altering microbial community structure and functional gene abundances related to nitrogen cycling.
[Advances in the Effects of Microplastics on Soil N2O Emissions and Nitrogen Transformation].
This review synthesizes current research on how microplastics affect soil nitrogen cycling, including N2O emissions, nitrogen transformation processes, functional enzyme activity, and nitrogen-related genes, highlighting inconsistent findings due to variability in microplastic properties, experimental conditions, and spatial-temporal scales.
Effects of microplastics on greenhouse gas emissions and microbial communities in sediment of freshwater systems
Researchers found that PET microplastics of different sizes significantly affected greenhouse gas emissions and microbial communities in freshwater sediments, with smaller particles (5 micrometers) notably increasing methane emissions and altering nutrient cycling over 90 days.
Microplastics promote methane emission in estuarine and coastal wetlands
This study found that microplastics in coastal and estuarine wetlands increase methane emissions by boosting the activity of methane-producing microorganisms while reducing methane-consuming ones. Both conventional and biodegradable plastics had this effect, meaning microplastic pollution is not just a direct health concern but also contributes to climate change by amplifying greenhouse gas release from natural ecosystems.
A Study of the Effects of Microplastics on Microbial Communities in Marine Sediments
This study investigated how the presence of microplastics in marine sediments affects microbial communities and, specifically, the methane cycle, finding that microplastics significantly altered microbial community structure and function. Since marine sediment microbes play a critical role in regulating greenhouse gas emissions, microplastic contamination could have broader climate-relevant effects beyond direct toxicity.
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.
Microplastics affect organic nitrogen in sediment: The response of organic nitrogen mineralization to microbes and benthic animals
Researchers investigated how different types of microplastics affect organic nitrogen cycling in sediments, measuring the responses of key nitrogen-transforming microorganisms. They found microplastics alter the composition of organic nitrogen and suppress certain nitrogen cycling processes.
Microplastics AmplifyGreenhouse Gas Emissions fromFreshwater Sediments through Synergistic Interactions
Researchers found that increasing microplastic chemodiversity — measured by polymer type number and chemical composition — amplified greenhouse gas emissions from freshwater sediments by up to 4.69-fold in aquatic microcosms, with synergistic interactions prevailing when three or more polymer types were combined. This amplification effect was further intensified under warming conditions and was mediated by shifts in microbial community composition and dissolved organic matter.
Impacts and mechanism of biodegradable microplastics on lake sediment properties, bacterial dynamics, and greenhouse gasses emissions
Researchers found that biodegradable PBAT microplastics in lake sediments increased greenhouse gas emissions more than conventional polyethylene microplastics, altering sediment properties and microbial communities in ways that enhanced carbon dioxide and methane production.
Microplastic diversity stimulates N2O emission during NO3−-N transformation by altering microbial interaction and electron consumption in eutrophic water
Researchers examined how mixtures of different microplastic types in eutrophic water bodies affect nitrous oxide emissions during nitrogen transformation. They found that greater microplastic diversity significantly increased N2O emissions by altering microbial community interactions and electron transfer processes. The study suggests that the combined presence of multiple microplastic types may amplify their environmental impact on greenhouse gas emissions from water systems.
Differential impacts of microplastics on carbon and nitrogen cycling in plant-soil systems: A meta-analysis
A meta-analysis of 3,338 observations found that microplastics increased soil CO2 emissions by 25.7% but also boosted soil carbon storage through increases in total carbon (53.3%), soil organic carbon (25.4%), and microbial biomass carbon (19.6%). However, microplastics decreased plant aboveground biomass and reduced nitrate and ammonia volatilization, suggesting that while soil carbon sink capacity may increase, agricultural productivity could suffer.
Microplastics Reshape the Fate of Aqueous Carbon by Inducing Dynamic Changes in Biodiversity and Chemodiversity
Researchers found that microplastics reshape aqueous carbon cycling by releasing chemical additives that inhibit autotrophic bacteria, promoting CO2 emissions, and stimulating microbial metabolic pathways that transform dissolved organic matter into more stable, less bioavailable forms.
Effects of microplastics on denitrification and associated N2O emission in estuarine and coastal sediments: insights from interactions between sulfate reducers and denitrifiers
This study investigated how microplastics affect nitrogen cycling and greenhouse gas emissions in estuary sediments by altering the interactions between two key types of bacteria. Microplastics disrupted the balance between sulfate-reducing and nitrogen-removing bacteria, with different effects depending on location in the estuary. These changes could worsen water quality in coastal zones where microplastic pollution is severe, potentially affecting fisheries and water resources that communities depend on.
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.
Microplastics and their mechanisms in influencing methane oxidation: A physiological and ecological perspective
This review examines the physiological and ecological mechanisms by which microplastics influence methane oxidation processes in the environment, synthesising current understanding of how ubiquitous plastic contamination may disrupt microbial communities responsible for mitigating methane — a greenhouse gas 20-30 times more potent than CO2.
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.
Microplastic composition-dependent effects on N2O emissions driven by changes in soil N process and microbial communities
This study found that biodegradable and conventional microplastics both reduced nitrous oxide emissions from plant-soil systems by 17-32%, but through different mechanisms: polyethylene promoted complete denitrification, PLA suppressed a key denitrification gene, and PBAT inhibited both nitrification and denitrification. A companion meta-analysis of 14 plant-soil studies confirmed that microplastics reduce N2O emissions by an average of 22% in vegetated systems.
Effect of microplastics on soil greenhouse gas emissions: A global meta-analysis study
This global meta-analysis found that microplastic exposure in soil decreased nitrous oxide emissions by 28.5% and increased methane emissions by 28.6%, though neither change was statistically significant overall. Effects varied dramatically depending on microplastic shape, concentration, soil type, and pH, with fiber-shaped microplastics reducing CO2 emissions by 40% while microplastics in sandy soils increased CO2 by 21%.