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61,005 resultsShowing papers similar to Microplastic type and concentration affect prokaryotic community structure and species coexistence in deep-sea cold seep sediments
ClearEffects of microplastics on cold seep sediment prokaryotic communities
Researchers studied how polyethylene, polystyrene, and polypropylene microplastics affect microbial communities in cold seep sediments over a 120-day incubation period. The study found that microplastics significantly altered bacterial community structure in a type- and concentration-dependent manner, with some bacteria associated with plastic degradation increasing, while archaeal communities were less affected.
Revealing the response of microbial communities to polyethylene micro(nano)plastics exposure in cold seep sediment
Researchers explored how polyethylene micro- and nanoplastics affect microbial communities in cold seep ocean sediments over a 120-day experiment. While the plastics did not significantly change overall microbial diversity, they did alter the community structure and affected methane-related metabolic processes. The study suggests that plastic pollution could interfere with important deep-sea biogeochemical cycles, including those involved in methane regulation.
Effects of Different Types of Microplastics on Cold Seep Microbial Diversity and Function
Researchers simulated deep-sea cold seep conditions to study how different microplastics affect microbial communities. They found that microplastics made the plastisphere microbial networks more fragile than surrounding environments and disrupted nitrogen cycling and methane metabolism, while potentially concentrating pathogenic species.
Microplastics Affect Anaerobic Oxidation of Methane and Sedimentary Prokaryotic Communities in Cold Seep Areas
Laboratory experiments exposing cold seep seafloor sediments to microplastics for 120 days showed that polyamide and PET microplastics reduced methane oxidation rates to roughly a third of normal and altered the bacterial communities responsible for this process. Cold seep sediments are major global sinks for methane, so microplastic disruption of this microbial activity could have implications for greenhouse gas cycling in deep ocean environments.
Synergetic effects of chlorinated paraffins and microplastics on microbial communities and nitrogen cycling in deep-sea cold seep sediments
Researchers studied the combined effects of chlorinated paraffins and microplastics on microbial communities in deep-sea cold seep sediments. They found that the two pollutants together disrupted nitrogen cycling processes more severely than either one alone, altering the composition of key microbial groups. The study suggests that the co-occurrence of these contaminants in deep-sea environments could have cascading effects on important ocean nutrient cycles.
Interactions of Microplastics and Methane Seepage in the Deep-Sea Environment
Researchers examined the accumulation of microplastics in cold seep sediments characterized by methane fluid seepage and chemosynthetic ecosystems in the deep sea, detecting 16 types of microplastics with high abundances at sediment surfaces. The findings suggest that cold seep environments act as effective sinks for small-scale microplastics under 100 micrometers and represent an important but overlooked reservoir in the marine carbon cycle.
Influence of microplastics on the structure and function of deep-sea communities during long-term enrichment processes
Researchers studied how polystyrene microplastics of different sizes and concentrations affect deep-sea microbial communities over 50 days of incubation. They observed that microorganisms caused visible degradation of the plastic surfaces, while the smallest particles and plastic films significantly inhibited bacterial growth and increased reactive oxygen species production. The study reveals that microplastic pollution can substantially alter deep-sea microbial community structure and function.
Impact of Microplastics on the Gene Abundance of ANME-1 Methane Metabolism
Researchers tested whether microplastics affect methane-metabolizing archaea in cold seep environments and found that microplastic addition did not significantly change gene abundance related to methane production or oxidation, though environmental factors like habitat type had a much stronger influence on these microbial communities.
Microbial colonization of microplastics in the Caribbean Sea
Researchers incubated six common plastic polymers in Caribbean waters for six weeks and found that bacterial biofilm communities were not significantly shaped by plastic type or exposure time, but eukaryotic communities (including distinctive diatom assemblages) were influenced by both factors. This suggests that microplastics act as selective habitats for some microbial groups but not others, with implications for understanding how plastics alter ocean microbial ecology.
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.
Response of sedimentary microbial community and antibiotic resistance genes to aged Micro(Nano)plastics exposure under high hydrostatic pressure
Researchers investigated how aged microplastics and nanoplastics affect sedimentary microbial communities and antibiotic resistance genes under high pressure conditions simulating the deep sea. They found that nanoplastics significantly reduced bacterial diversity and simplified microbial network complexity, while both micro- and nanoplastics increased the importance of random processes in shaping microbial communities. Short-term exposure decreased antibiotic resistance gene abundance, but longer four-month exposure increased it, suggesting that prolonged plastic pollution in deep-sea sediments could promote the spread of antibiotic resistance.
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.
Tracing the Century‐Long Evolution of Microplastics Deposition in a Cold Seep
Researchers traced a century of microplastic deposition in a deep-sea cold seep, finding that burial rates increased significantly since the 1930s in non-seepage areas, while methane seepage zones showed lower microplastic levels, suggesting potential microbial degradation of plastics.
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.
Microbial Communities on Plastic Polymers in the Mediterranean Sea
Researchers collected floating microplastics from a bay in the Mediterranean and analyzed their bacterial biofilm communities using 16S rRNA sequencing, finding that microbial communities on plastics were distinct from surrounding seawater and differed between polymer types.
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.
Are bacterial communities associated with microplastics influenced by marine habitats?
A three-month field exposure experiment on a Chinese island compared bacterial communities on polyethylene and PET microplastics in three marine habitats (intertidal, supralittoral, seawater), finding that habitat significantly shaped community structure but polymer type had a weaker influence.
Environmental exposure more than plastic composition shapes marine microplastic‐associated bacterial communities in Pacific versus Caribbean field incubations
Researchers incubated six types of household plastic polymers in Pacific and Caribbean coastal waters to study the bacterial communities that form on microplastics. They found that geographic location and exposure time were far more important than plastic type in shaping these microbial communities. The study identified a core plastisphere of 57 bacterial variants common across all conditions, suggesting environmental context plays a bigger role than plastic composition in microplastic colonization.
Microplastic bacterial communities in the Bay of Brest: Influence of polymer type and size
Researchers analyzed bacterial communities growing on microplastics collected from a coastal bay in France and found that the type of polymer influenced which bacteria colonized the surface. Different plastics like polyethylene, polypropylene, and polystyrene each hosted distinct microbial communities, though particle size had less influence. The study reveals that microplastics in the ocean serve as unique habitats for bacteria, which could have implications for how pollutants and pathogens are transported through marine environments.
Microplastic Contamination of a Benthic Ecosystem in a Hydrothermal Vent
Researchers documented microplastic contamination in a deep-sea hydrothermal vent at the Central Indian Ridge for the first time. The study found microplastics in seawater, sediments, and all six major benthic species examined, with polypropylene, PET, and polystyrene fragments being the most common types, demonstrating that plastic pollution has reached even extreme deep-sea environments.
Microplastic Contamination of a Benthic Ecosystem in a Deep-Sea Hydrothermal Vent
Researchers documented, for the first time, microplastic contamination at a deep-sea hydrothermal vent on the Central Indian Ridge, finding MPs in seawater (2.08 MPs/L), surface sediments (0.57 MP/g), and all six major benthic species sampled, with polypropylene, PET, and polystyrene fragments under 100 micrometers dominating.
Short‐term plastisphere colonization dynamics across six plastic types
Researchers studied the short-term colonization dynamics of microbial communities (plastisphere) forming on six plastic polymer types submerged in marine waters in South Australia, finding polymer-type-specific differences in prokaryotic community composition over four weeks.
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.
Plastisphere colonization in Antarctica: a microcosmos approach
Researchers conducted a 33-day microcosm experiment incubating polypropylene, polyester, polystyrene, and quartz fragments in Antarctic seawater and used SEM, flow cytometry, qPCR, and metagenomics to characterize bacterial plastisphere colonization, finding that microbial community composition was driven primarily by incubation time rather than polymer type, with Oleispira potentially involved in hydrocarbon degradation.