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Papers
61,005 resultsShowing papers similar to The microbial community of rust layer biofilm was driven by seawater microbial community
ClearDynamics and implications of biofilm formation and community succession on floating marine plastic debris
Researchers examined how biofilms form on plastic debris in aquatic environments and how the resulting microbial communities evolve over time, finding that the plastisphere hosts distinct microbial assemblages including potential pathogens. The study has implications for understanding plastic debris as a vector for microbial dispersal.
Marine microbial biofilms on diverse abiotic surfaces
This review provides an overview of how microbial biofilms form on various non-living surfaces in the ocean, including microplastics, seafloor sediments, and submerged structures. Researchers describe how these surface-attached microbial communities have unique compositions and functions that influence ocean ecology and biochemical processes. The study also examines how biofilms contribute to biocorrosion and biofouling, highlighting their broad significance for both natural marine systems and human-built infrastructure.
Seawater copper content controls biofilm bioaccumulation and microbial community on microplastics
Researchers found that seawater copper concentration controls both the microbial community composition of biofilms on microplastics and the amount of copper bioaccumulated in those biofilms, demonstrating that metal pollution levels in seawater influence the ecological and chemical behavior of the 'plastisphere'.
Unique Bacterial Community of the Biofilm on Microplastics in Coastal Water
Researchers compared bacterial communities forming biofilms on steel, silica, and PVC microplastic surfaces in coastal seawater and found that biofilm composition differed by material type. This shows that the type of plastic surface influences which microbial communities colonize it, with implications for how microplastics may spread specific bacteria.
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.
Marine microplastic-associated biofilms – a review
This review synthesizes research on biofilm communities forming on marine microplastics, covering their composition, formation dynamics, and potential consequences for both plastic fate and ocean microbiology. The authors highlight that plastic-associated biofilms can include pathogens and toxin producers, and that the plastisphere community differs meaningfully from the surrounding seawater microbiome.
Microbially influenced corrosion and rust tubercle formation on sheet piles in freshwater systems
This paper is not relevant to microplastics; it investigates the microbial communities and electrochemical processes responsible for corrosion and rust formation on steel sheet piles in a German freshwater river.
Microbial Colonization in Marine Environments: Overview of Current Knowledge and Emerging Research Topics
This review examines how microorganisms colonize submerged surfaces in aquatic environments, with a focus on the factors shaping biofilm communities on microplastics. The authors discuss how the chemical and physical properties of plastic surfaces influence microbial attachment and community development compared to natural substrates.
Marine Plastic Debris: A New Surface for Microbial Colonization
This review examines the "Plastisphere" -- the community of microbes that rapidly colonizes plastic debris in the ocean -- covering biofilm development, potential biodegradation, and the hitchhiking of harmful bacteria. Researchers found that microbial communities on plastics do not dramatically differ from those on other inert surfaces, especially in mature biofilms. The study identifies key knowledge gaps and calls for more environmentally realistic research into how these plastic-associated microbes interact with marine ecosystems.
Analysis of 16S rRNA amplicon data illuminates the major role of environment in determining the marine plastisphere microbial communities
Researchers analysed 16S rRNA amplicon data from marine plastisphere communities, finding that environmental factors play the dominant role in determining the microbial communities that colonise microplastic surfaces in marine ecosystems.
Evidence for selective bacterial community structuring on microplastics
Plastic substrates incubated in Baltic Sea water developed distinct bacterial communities that differed significantly from those on glass surfaces and from the surrounding water, with some plastic-colonizing taxa selected for regardless of polymer type. The study provides experimental evidence that plastic surfaces act as selective filters for microbial community assembly, contributing to the concept of a unique plastisphere.
Relative Influence of Plastic Debris Size and Shape, Chemical Composition and Phytoplankton-Bacteria Interactions in Driving Seawater Plastisphere Abundance, Diversity and Activity
This study evaluated the relative influence of plastic debris size, shape, chemical composition, and environmental conditions on the microbial communities colonizing ocean plastics (the plastisphere). Results showed that multiple plastic properties and environmental factors jointly shape which microorganisms colonize plastic surfaces in the marine environment.
Into the Plastisphere, Where Only the Generalists Thrive: Early Insights in Plastisphere Microbial Community Succession
Researchers tracked prokaryotic and fungal biofilm succession on polyethylene, nylon, and glass panels immersed in a New Zealand harbor for 2, 6, and 12 weeks, finding that microbial communities differed significantly from surrounding seawater regardless of substrate type. No substrate-specific communities were identified, suggesting microorganisms colonize plastics as attachment surfaces rather than for direct metabolic benefit from the plastic polymer.
Time-series incubations in a coastal environment illuminates the importance of early colonizers and the complexity of bacterial biofilm dynamics on marine plastics
Researchers used time-series incubations in a coastal marine environment to track plastisphere biofilm formation on microplastics, finding that early bacterial colonizers play a disproportionate role in shaping community dynamics and that biofilm composition is highly complex, varying with polymer type, incubation time, and surrounding environment.
Structural Diversity in Early-Stage Biofilm Formation on Microplastics Depends on Environmental Medium and Polymer Properties
This study examined the early stages of bacterial biofilm formation on different types of plastic surfaces in different environmental media, finding that both the growth medium and the polymer type influenced which microbial communities colonized the plastic. These plastic-associated biofilms (the plastisphere) can make microplastics more appealing to filter-feeding organisms that mistake them for food.
Novel functional insights into the microbiome inhabiting marine plastic debris: critical considerations to counteract the challenges of thin biofilms using multi-omics and comparative metaproteomics.
Researchers developed a comprehensive metaproteomics approach to study the microbial communities living on the surface of marine plastic debris, known as the plastisphere. The study reveals how microbes on plastic interact with each other and their environment, with implications for understanding how plastic-colonizing bacteria spread through the ocean.
Formation of specific bacterial assemblages on sterile polyethylene microplastic particles added to a marine aquaria system
Researchers characterized bacterial assemblages that formed on sterile polyethylene microplastic particles after 12 weeks of incubation in marine aquaria, comparing the plastisphere communities to those on sterile sandy sediment and in water fractions to determine whether microplastics select for distinct or potentially pathogenic bacterial communities. The study found that microplastics hosted specific bacterial assemblages distinct from surrounding environmental fractions, confirming their role as selective surfaces for microbial colonization.
Spatial and seasonal variation in diversity and structure of microbial biofilms on marine plastics in Northern European waters
Researchers investigated how microbial biofilm communities on marine plastics vary by season, location, and plastic type in Northern European waters. The study found distinct spatial and seasonal patterns in plastisphere microbial communities on polyethylene terephthalate surfaces, providing insights into how plastic debris develops unique biological communities in marine environments.
Plastisphere assemblages differ from the surrounding bacterial communities in transitional coastal environments
Researchers found that bacterial communities colonizing plastic particles (the plastisphere) in Portuguese estuarine and beach environments were significantly different from those in surrounding water and sediments, with plastic type and environmental conditions influencing microbial community composition.
Paint particles are a distinct and variable substrate for marine bacteria
Researchers used 16S rRNA gene sequencing to profile biofilm communities on paint particles from brackish sediment and found that paint-associated microbial communities are distinct from those on water, sediment, and conventional microplastics, with sulfate-reducing bacteria dominating certain paint biofilms.
Plastisphere on microplastics: In situ assays in an estuarine environment
This study examined how microbial biofilm communities (the plastisphere) form on polystyrene and nylon microplastics placed in a polluted estuary over 129 days. Researchers found that the plastisphere influenced metal accumulation and weathering of the microplastic surfaces, with different plastic types supporting distinct microbial communities.
Microplastic biofilm in fresh- and wastewater as a function of microparticle type and size class
Researchers compared the biofilm communities that form on microplastics of different types and sizes in both freshwater and wastewater, finding that biofilm composition was influenced by particle type, size, and water source. These findings advance understanding of the plastisphere — the microbial community unique to plastic surfaces — and its potential role in spreading microorganism-associated risks.
An In Situ Study to Understand Community Structure of Estuarine Microbes on the Plastisphere
Researchers performed 16S rRNA sequencing on biofilms from three microplastic polymer types and glass bead controls deployed in Baltimore Inner Harbor over 28 days, finding that plastisphere communities were taxonomically distinct from free-living microbial communities but that polymer type did not significantly differentiate community composition, with Cyanobacteria, Planctomycetes, and sulfate-reducing bacteria among the notable colonizers.
Plastisphere community assemblage of aquatic environment: plastic-microbe interaction, role in degradation and characterization technologies
This review examines the plastisphere—microbial communities colonizing plastic surfaces in aquatic environments—covering how these biofilms form, their role in plastic biodegradation, and current characterization technologies for studying plastic-microbe interactions.