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20 resultsShowing papers similar to Distinctive patterns of bacterial community succession in the riverine micro-plastisphere in view of biofilm development and ecological niches
ClearThe Effect of Microplastics on Microbial Succession at Impaired and Unimpaired Sites in a Riverine System
Researchers compared microbial biofilm diversity on microplastic polymers and natural substrates at impaired and unimpaired riverine sites, examining how environmental nutrient loads, seasonality, and geography influence microbiome succession on plastic surfaces in freshwater ecosystems.
Biofilms on plastic litter in an urban river: Community composition and activity vary by substrate type
Researchers examined biofilms colonizing plastic litter versus natural surfaces in an urban river, finding that community composition and metabolic activity vary by substrate type, with plastic surfaces hosting distinct microbial communities that may influence plastic degradation rates.
Microplastic is an Abundant and Distinct Microbial Habitat in an Urban River
Researchers demonstrated that microplastic surfaces in an urban river host a microbial community that is distinct from surrounding water and sediment communities, establishing microplastic as an abundant and ecologically distinct habitat for river microorganisms.
Ecological Roles and Shared Microbes Differentiate the Plastisphere from Natural Particle-Associated Microbiomes in Urban Rivers
Researchers compared the microbial communities living on microplastics versus natural particles in ten urban river systems. While the two communities shared many similarities, the microplastic-associated community, known as the plastisphere, harbored distinct bacteria with specialized abilities to break down complex carbon compounds. The study suggests that microplastics in rivers create unique microbial habitats that may influence nutrient cycling and pollutant degradation differently than natural particles.
Plastic substrate and residual time of microplastics in the urban river shape the composition and structure of bacterial communities in plastisphere
Researchers conducted an in-site incubation experiment in an urban river using microplastics from three plastic product types (garbage bags, shopping bags, and plastic bottles), finding that both plastic substrate type and incubation time shaped the bacterial communities colonizing the plastisphere. Different plastic products harbored distinct microbial communities, with potential implications for the spread of plastic-associated microorganisms in urban freshwater.
Deciphering the distinct successional patterns and potential roles of abundant and rare microbial taxa of urban riverine plastisphere
Researchers examined how microbial communities colonize microplastics in urban river environments, distinguishing between abundant and rare bacterial species. The study found that rare taxa played critical roles in maintaining community stability on plastic surfaces, while abundant taxa drove community succession, and both groups contributed to nutrient cycling functions.
Diversity, abundance and distribution characteristics of potential polyethylene and polypropylene microplastic degradation bacterial communities in the urban river
Researchers conducted a 1,150-day experiment in an urban river to identify bacteria capable of degrading polyethylene and polypropylene microplastics. The study found two distinct groups of plastic-degrading bacteria, with many rare or low-abundance species in natural river biofilms that may serve as potential degraders, helping explain the slow breakdown rate of these common microplastics in waterways.
In situ Prokaryotic and Eukaryotic Communities on Microplastic Particles in a Small Headwater Stream in Germany
Researchers characterized prokaryotic and eukaryotic communities colonizing microplastic particles in a German headwater stream, finding distinct plastisphere biofilms enriched in specific bacterial taxa compared to surrounding water and natural substrates.
Microbial community niches on microplastics and prioritized environmental factors under various urban riverine conditions
Researchers manipulated organic content, salinity, and dissolved oxygen in bioreactors to assess which environmental factors most strongly shaped microbial communities colonizing microplastics in urban rivers. Dissolved oxygen and organic carbon content were identified as priority drivers of plastisphere community composition, with implications for predicting pathogen enrichment on MPs across river conditions.
Bacterial and fungal assemblages and functions associated with biofilms differ between diverse types of plastic debris in a freshwater system
Researchers characterised bacterial and fungal assemblages on three types of plastic debris in a freshwater urban river system, finding that microbial communities on plastics differ from those in surrounding water. High-throughput sequencing revealed that alpha diversity of bacterial communities was higher on polyethylene microplastics than on other plastic types, with intraspecies interactions between bacteria and fungi differing across diverse plastic substrates.
Environmental Factors Support the Formation of Specific Bacterial Assemblages on Microplastics
Researchers incubated polystyrene, polyethylene, and wooden pellets across marine and freshwater environments and found that environmental conditions — more than plastic type — drove the formation of specific bacterial communities on microplastics, with plastic-specific assemblages only emerging under certain conditions.
Microplastic selects for convergent microbiomes from distinct riverine sources
Laboratory experiments showed that microplastic particles from different freshwater sources recruited very similar bacterial communities regardless of their original environment, suggesting that microplastics selectively favor specific bacterial taxa. This convergent microbiome formation on microplastics could facilitate the spread of particular bacteria — including potential pathogens — across diverse water systems.
Distinct community structure and microbial functions of biofilms colonizing microplastics
Biofilm communities were established on polyethylene, polypropylene, cobblestone, and wood substrates over 21 days under controlled conditions and compared by 16S rRNA sequencing, finding that plastic substrates harbored distinct microbial communities and functional profiles compared to natural materials. The study demonstrates that microplastics in freshwater environments provide a selective niche that enriches for distinct microbial taxa and metabolic functions.
Lacustrine plastisphere: Distinct succession and assembly processes of prokaryotic and eukaryotic communities and role of site, time, and polymer types
Researchers investigated how microbial communities colonize different types of microplastic polymers in freshwater lakes. The study found that bacteria and single-celled organisms follow distinct assembly patterns on microplastic surfaces, with colonization time, location, and polymer type all influencing community composition. These findings suggest microplastics serve as carriers that can promote microbial spread in aquatic environments.
Nascently generated microplastics in freshwater stream are colonized by bacterial communities from stream and riparian sources
Researchers examined bacterial colonization of different types of nascently generated microplastics through time in a freshwater stream ecosystem, finding that colonizing taxa and their degradative abilities varied based on microplastic polymer type and time of exposure.
Impact de la pollution plastique sur les communautés microbiennes de rivière
This study investigates how plastic pollution affects microbial communities in rivers, focusing on the 'plastisphere' — the distinct biofilm communities that form on plastic surfaces in aquatic environments. Plastics not only carry unique microbial assemblages but may also harbor potentially harmful microorganisms, raising concerns for aquatic ecosystem health.
Investigating the roles of microbes in biodegrading or colonizing microplastic surfaces
Researchers investigated the roles of microbes in biodegrading or colonizing microplastic surfaces, examining how microbial communities interact with plastic polymers in environmental settings. The study characterized the 'plastisphere' — the community of microorganisms that colonize microplastic surfaces — and assessed the extent to which microbial activity contributes to plastic degradation in natural environments.
The structure and assembly mechanisms of plastisphere microbial community in natural marine environment
Researchers investigated how microbial communities colonize different types of microplastic surfaces in natural marine environments over an eight-week period. They found that the composition of these plastic-associated microbial communities, known as the plastisphere, was shaped more by environmental conditions and time than by the specific type of plastic. The study provides new understanding of the ecological processes governing how microorganisms assemble on ocean plastic debris.
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.
Riverine microplastic and microbial community compositions: A field study in the Netherlands
Researchers collected microplastic samples from the Dutch section of the Rhine River and analyzed the microbial communities living on them. The study found an average of over 213,000 microplastic particles per cubic meter of water, with polyamide and PVC being the most common types. Larger microplastics hosted distinctly different bacterial communities compared to the surrounding water, including biofilm-forming species and potential pathogens, raising concerns about microplastics as vehicles for harmful microorganisms.