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20 resultsShowing papers similar to Bacterial community are more susceptible to nanoplastics than algae community in aquatic ecosystems dominated by submerged macrophytes
ClearNano- and microplastics affect the composition of freshwater benthic communities in the long term
Researchers conducted a 15-month mesocosm experiment exposing freshwater communities to five concentrations of nano- and microplastics, assessing long-term effects on community composition under ecologically realistic conditions. The study found that chronic exposure at environmentally relevant concentrations affected the composition of freshwater microalgal assemblages.
Effect of different size microplastic particles on the construction of algal-bacterial biofilms and microbial communities
Researchers tested how microplastic particles of different sizes affect algal-bacterial biofilms used for sewage treatment. Smaller nanoplastics caused more damage to the biofilm community, reducing algal growth and shifting microbial diversity, while larger microplastics had milder effects. This matters because algal-bacterial systems are a green technology for water treatment, and microplastic contamination could undermine their effectiveness.
Shifting enzyme activity and microbial composition in sediment coregulate the structure of an aquatic plant community under polyethylene microplastic exposure
Researchers investigated how polyethylene microplastics affect underwater plant communities and found that the impact varies significantly by species. Canopy-forming plants actually grew more under microplastic exposure, while rosette-forming species declined sharply, shifting the overall community structure. The study suggests that microplastics in freshwater sediments can reshape aquatic ecosystems by altering enzyme activity and microbial composition in ways that favor some plant species over others.
A critical review of interactions between microplastics, microalgae and aquatic ecosystem function
This review of microplastic-microalgae interactions found that microplastics form distinct epiplastic algal communities that differ from surrounding water communities, and that the interactions are bidirectional — MP properties affect algal physiology while algal surface coatings alter MP behavior and fate.
Deciphering the pathogenic risks of microplastics as emerging particulate organic matter in aquatic ecosystem
Researchers compared how microplastics and natural organic matter like leaves and algae affect bacterial communities in aquatic environments. The study found that microplastics uniquely promoted pathogenic bacteria as keystone species and amplified their capacity to host antibiotic resistance genes, suggesting that microplastic pollution may pose distinct pathogenic risks beyond those of natural particles.
Effects of nanoplastics and microplastics on the growth of sediment-rooted macrophytes
Both nano- and microplastic particles negatively affected the growth of freshwater macrophytes in sediment-rooted experiments, with nanoplastics causing more pronounced effects at lower concentrations. The findings highlight that aquatic plants, which form the base of many freshwater food webs, are vulnerable to plastic particle pollution.
Microplastics alter the functioning of marine microbial ecosystems
Researchers used experimental mesocosms to investigate how microplastics affect the structure and functioning of marine microbial ecosystems. They found that microplastics indirectly altered marine productivity by shifting the composition of bacterial and phytoplankton communities. The study provides evidence that microplastic pollution can disrupt fundamental ecological processes in ocean ecosystems beyond effects on individual organisms.
Distribution of Microplastics and Nanoplastics in Aquatic Ecosystems and Their Impacts on Aquatic Organisms, with Emphasis on Microalgae
This review covers the distribution of microplastics and nanoplastics in aquatic ecosystems and their impacts on aquatic organisms from bacteria to fish, with a focus on effects on microalgae as primary producers. The authors highlight that nanoplastics may be more biologically active than microplastics due to their size and surface reactivity, warranting greater research attention.
Contrasting the effects of microplastic types, concentrations and nutrient enrichment on freshwater communities and ecosystem functioning
Researchers tested two types of microplastics, conventional polyethylene and biodegradable polylactic acid, in outdoor freshwater mesocosms and found that neither type significantly affected community composition or ecosystem functions like algae growth and leaf decomposition. Even at concentrations known to cause harm in lab settings, the microplastics had minimal impact when tested in more realistic ecological conditions. The study suggests that real-world microplastic effects on freshwater communities may differ from laboratory predictions.
Effects 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.
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.
Weak effects of conventional and biodegradable microplastics on marine microbial communities
Researchers conducted a mesocosm experiment to compare the effects of biodegradable and conventional microplastics on marine microbial communities in the Baltic Sea. Using epifluorescence microscopy and other techniques, they found that both types of microplastics had relatively weak effects on planktonic bacterial activity and abundance. The study suggests that the direct impact of microplastics on marine microbial communities may be less pronounced than previously assumed.
Responses of submerged plant Vallisneria natans growth and leaf biofilms to water contaminated with microplastics
Researchers exposed the submerged aquatic plant Vallisneria natans to environmentally relevant concentrations of microplastics and observed increased antioxidant enzyme activity and cellular organelle damage. The microplastics also altered the microbial community composition on leaf biofilms. The findings indicate that even moderate microplastic concentrations can disrupt plant defense mechanisms and shift the microbial ecology of aquatic environments.
Biodegradability of microplastics reshapes surface biofilm microbial community structure and nitrogen cycling functions in aquatic environments
Researchers compared how biodegradable (PLA) and non-biodegradable (polyethylene and PVC) microplastics affect the microbial communities that form on their surfaces in aquatic environments, finding substantial differences in which bacteria colonized each plastic type and how they processed nitrogen. PLA supported communities rich in nitrogen-cycling bacteria, while PVC and polyethylene enriched different microbial groups associated with pollutant degradation. The study suggests that the push toward biodegradable plastics will change — not just reduce — the ecological effects of microplastics in rivers and lakes.
Response strategies of stem/leaves endophyte communities to nano-plastics regulate growth performance of submerged macrophytes.
Nano-polystyrene exposure changed the composition and activity of endophytic bacterial communities in the stems and leaves of aquatic macrophytes, with some endophyte shifts helping plants maintain growth by modulating stress responses, revealing a microbiome-mediated tolerance mechanism.
Responses of submerged macrophytes to different particle size microplastics and tetracycline co-pollutants at the community and population level
Researchers set up outdoor experimental ponds to study how microplastics of different sizes combined with the antibiotic tetracycline affect communities of underwater aquatic plants. Smaller microplastics caused more harm to plant diversity and growth, and the combined exposure with antibiotics created worse effects than either pollutant alone. The study suggests that microplastic pollution could amplify the damage antibiotics cause to freshwater plant ecosystems.
Effects of polypropylene micro(nano)plastics on soil bacterial and fungal community assembly in saline-alkaline wetlands
Scientists found that polypropylene nano-sized plastics disrupted soil bacterial communities more severely than micro-sized particles in saline wetland soil, reducing network complexity and altering how communities form. Bacteria were more sensitive to the plastic stress than fungi, and nanoplastics disrupted important interactions between soil microbes and plants. This suggests that as plastics break down into ever-smaller pieces in the environment, their impact on soil health may actually increase.
Microplastics drive community dynamics of periphytic protozoan fauna in marine environments
Researchers exposed marine protozoan communities to varying concentrations of microplastics and tracked how the communities changed over time. They found that higher microplastic concentrations reduced species diversity and shifted community composition toward more pollution-tolerant species. The study demonstrates that microplastic pollution can reshape the structure of microscopic marine communities, with potential cascading effects up the food web.
Microplastics can alter phytoplankton community composition
Researchers tested how microplastic fibers affect natural communities of tiny aquatic organisms called phytoplankton, which form the base of aquatic food webs. At higher concentrations, microplastics significantly shifted the community makeup, boosting certain cyanobacteria while reducing other species. The study suggests that growing microplastic pollution could reshape the foundation of aquatic ecosystems in heavily polluted waterways.
Microplastics in freshwaters: Comparing effects of particle properties and an invertebrate consumer on microbial communities and ecosystem functions
Researchers tested how different microplastic properties, including concentration, shape, and polymer type, affect microbial communities and ecosystem functions in freshwater environments. They found that the presence of an invertebrate consumer had a stronger influence on microbial activity than the microplastics themselves, though high concentrations of certain particle shapes did alter community composition. The study suggests that the ecological effects of microplastics in freshwater depend heavily on the broader biological context.