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61,005 resultsShowing papers similar to High-throughput metagenomic profiling of functional and resistome features in estuarine microplastic microbiomes
ClearSize effects of microplastics on antibiotic resistome and core microbiome in an urban river
Scientists found that microplastics in an urban river serve as platforms for antibiotic-resistant bacteria and dangerous pathogens including Pseudomonas aeruginosa, Mycobacterium tuberculosis, and Legionella pneumophila. Larger microplastic particles harbored more antibiotic resistance genes, and the concentrations of these genes were much higher on plastic surfaces than in the surrounding water. This research raises concerns that microplastics in waterways could spread drug-resistant infections by providing a surface where dangerous bacteria thrive and share resistance genes.
Comprehensive profiling and risk assessment of antibiotic resistomes in surface water and plastisphere by integrated shotgun metagenomics
Researchers used shotgun metagenomics to compare antibiotic resistance genes in surface water versus the biofilms that form on microplastic surfaces, known as the plastisphere. They found that microplastics harbored distinct microbial communities with different antibiotic resistance profiles compared to surrounding water. The study raises concerns that microplastics may serve as vehicles for spreading antibiotic resistance in aquatic environments.
Microplastics accumulate priority antibiotic-resistant pathogens: Evidence from the riverine plastisphere
Researchers placed microplastics in river water and found they accumulated more antibiotic-resistant bacteria than natural sand particles, including dangerous pathogens like E. coli and Klebsiella. Most of the bacteria isolated from the plastic surfaces were multi-drug resistant and carried virulence traits like biofilm formation. This suggests microplastics in waterways may act as rafts for spreading antibiotic resistance through the environment.
Marine plastisphere selectively enriches microbial assemblages and antibiotic resistance genes during long-term cultivation periods
Researchers placed four types of common microplastics in a marine environment for over 100 days and found that bacterial communities and antibiotic resistance genes accumulated on the plastic surfaces over time. PVC microplastics were particularly effective at concentrating resistance genes, and a key gene-transfer element was found on all plastic types. These results show that microplastics floating in the ocean act as hotspots for antibiotic-resistant bacteria, which could eventually reach humans through seafood or water.
Unraveling the role of microplastics in antibiotic resistance: Insights from long-read metagenomics on ARG mobility and host dynamics
Researchers used long-read metagenomics to investigate how microplastics serve as vectors for antibiotic resistance genes in aquatic environments. They found that plasmid-encoded resistance genes varied significantly between microplastic biofilms and surrounding water, highlighting horizontal gene transfer as a key mechanism for resistance gene enrichment on plastic surfaces. The study identified specific bacterial taxa driving this enrichment and revealed that enhanced cell adhesion and transporter activity on microplastics facilitate the spread of antibiotic resistance.
Antibiotic resistant bacteria colonising microplastics in the aquatic environment: An emerging challenge
Researchers reviewed how microplastics in aquatic environments act as surfaces where antibiotic-resistant bacteria can grow and swap resistance genes with each other, raising concern that contaminated seafood and water could transfer these hard-to-treat bacteria to humans.
Microplastics in fresh- and wastewater are potential contributors to antibiotic resistance - A minireview
Researchers reviewed the link between microplastic pollution and the spread of antibiotic resistance in freshwater environments, finding that microplastic surfaces host unique bacterial communities enriched in antibiotic-resistant bacteria and the resistance genes they can share with other microbes. The close packing of bacteria in these plastic-surface biofilms may accelerate the spread of drug-resistant pathogens through drinking water sources, though the full health implications remain poorly understood.
Antibiotic resistance genes and virulence factors in the plastisphere in wastewater treatment plant effluent: Health risk quantification and driving mechanism interpretation
Researchers found that microplastics in treated wastewater carry significantly more disease-causing bacteria, antibiotic resistance genes, and virulence factors on their surfaces compared to the surrounding water. This means microplastics released from wastewater treatment plants into rivers and lakes could spread antibiotic-resistant infections, posing a direct risk to communities that rely on these water sources.
Metagenomic insights into ecological risk of antibiotic resistome and mobilome in riverine plastisphere under impact of urbanization
This study used advanced genetic sequencing to examine antibiotic resistance genes on microplastics found in an urban river. Microplastics harbored more antibiotic resistance genes and mobile genetic elements than natural materials like rocks and wood, and the problem was worse in more urbanized areas. The findings suggest that microplastics in waterways can act as hotspots for spreading antibiotic resistance, which is a growing public health threat.
Distinct profile of bacterial community and antibiotic resistance genes on microplastics in Ganjiang River at the watershed level
Researchers investigated microplastic pollution and associated bacterial communities, human pathogenic bacteria, and antibiotic resistance genes across the Ganjiang River watershed. They found microplastics were widely distributed with an average of 407 particles per cubic meter, and that microplastic surfaces harbored significantly higher bacterial diversity and more antibiotic resistance genes than surrounding water or sediment.
Dangerous hitchhikers? Evidence for potentially pathogenic Vibrio spp. on microplastic particles
Researchers tested whether marine microplastics carry potentially pathogenic Vibrio bacteria, finding Vibrio species on microplastic surfaces in seawater, raising concerns about plastics as vehicles for transporting harmful bacteria in marine environments.
Effect of selected microplastics on the development and spread of antibiotic resistance in bacteria
Scientists found that tiny plastic particles (microplastics) can help dangerous bacteria become resistant to antibiotics, making infections harder to treat. The smaller plastic pieces were especially good at helping bacteria develop this resistance, and bacteria also formed protective films on the plastic surfaces. This matters because microplastics are everywhere in our environment and food, potentially making antibiotic-resistant "superbugs" more common and threatening our ability to fight bacterial infections.
Exploiting microplastics and the plastisphere for the surveillance of human pathogenic bacteria discharged into surface waters in wastewater effluent
Researchers placed small plastic particles in rivers upstream and downstream of a wastewater treatment plant and found that disease-causing bacteria, including E. coli and Klebsiella, quickly formed biofilms on them within 24 hours. These biofilms carried antibiotic resistance genes and virulence factors, showing that microplastics in waterways can serve as floating platforms for dangerous bacteria that pose risks to human health.
Contribution of microplastic particles to the spread of resistances and pathogenic bacteria in treated wastewaters
Researchers studied microplastic particles collected from treated wastewater effluents and found that MPs harbored significantly higher loads of antibiotic resistance genes and pathogenic bacteria compared to surrounding water, suggesting MPs facilitate their environmental spread.
Microplastics as hubs enriching antibiotic-resistant bacteria and pathogens in municipal activated sludge
Researchers demonstrated that microplastics in municipal wastewater treatment plants act as "hubs," selectively concentrating antibiotic-resistant bacteria and pathogens in their surface biofilms, with antibiotic-resistance genes enriched up to 4.5-fold compared to sand particles — raising concerns about microplastics spreading drug-resistant microbes into the environment.
Assessment of Emerging Pathogens and Antibiotic Resistance Genes in the Biofilm of Microplastics Incubated Under a Wastewater Discharge Simulation
Researchers incubated common plastic types in flowing water that simulated wastewater discharge conditions for 10 weeks and studied the bacteria that colonized the plastic surfaces. They found that microplastics exposed to treated wastewater developed distinct bacterial communities compared to those in clean river water, including emerging pathogens and antibiotic resistance genes. The study suggests that microplastics in waterways receiving wastewater may serve as mobile platforms for spreading harmful bacteria and antibiotic resistance in the environment.
Marine microplastics enrich antibiotic resistance genes (ARGs), especially extracellular ARGs: An investigation in the East China Sea
Researchers found that microplastics floating in the East China Sea carried 5 to 140 times more antibiotic resistance genes than the surrounding seawater, with genes on the outside of cells being especially enriched. The microplastic surfaces also hosted a more diverse bacterial community, including disease-causing species. This means microplastics in the ocean act as rafts that concentrate and spread antibiotic-resistant bacteria, which could eventually reach humans through seafood and water.
Decoding the microplastic Micro-interface: a complex Web of gene transfer and pathogenic threats in wastewater
Researchers used metagenomics to study how microplastic surfaces in wastewater treatment systems serve as hotspots for antibiotic resistance genes and pathogenic bacteria. They found that microplastic micro-interfaces supported more robust microbial networks and facilitated horizontal gene transfer of resistance and virulence genes more actively than surrounding environments. The study suggests that microplastics in wastewater may accelerate the spread of antibiotic resistance and increase pathogenicity risks.
Wastewater discharges and polymer type modulate the riverine plastisphere and set the role of microplastics as vectors of pathogens and antibiotic resistance
Researchers investigated how wastewater treatment plant discharges and polymer type shape microbial communities on microplastics in a river environment. They found that microplastics harbored significantly higher microbial diversity than surrounding water, and that wastewater discharges led to a 2.3-fold increase in antibiotic resistance gene abundance on the plastic surfaces. Different polymer types, including polyethylene, polypropylene, and PET, each attracted distinct microbial communities with varying levels of pathogens and resistance genes.
Microbial diversity and potential pathogens associated with the plastisphere on beaches of Rio de Janeiro, Brazil
Researchers analyzed the microbes living on plastic debris collected from beaches in Rio de Janeiro, finding that both polypropylene and polyethylene plastics harbored communities containing potential human and marine pathogens as well as bacteria carrying antibiotic resistance genes. The study confirms that ocean plastics can transport dangerous microorganisms across long distances, posing risks to human health and marine biodiversity.
The Travelling Particles: Investigating microplastics as possible transport vectors for multidrug resistant E. coli in the Weser estuary (Germany)
Scientists tested whether microplastics in the Weser estuary in Germany carry multidrug-resistant ESBL-producing E. coli, finding resistant bacteria on plastic surfaces at concentrations above surrounding water, confirming that microplastics can serve as vectors for antibiotic-resistant pathogens.
Quantifying health risks of plastisphere antibiotic resistome and deciphering driving mechanisms in an urbanizing watershed
This study measured the health risks posed by antibiotic resistance genes found on microplastic surfaces in a watershed affected by urbanization. Polyethylene microplastics carried the highest risk, and urban development increased the danger by promoting the spread of resistance genes among bacteria living on plastic surfaces. The findings show that microplastics in waterways act as vehicles for antibiotic resistance, which could make infections harder to treat in communities downstream.
Exploring the dynamics of antibiotic resistome on plastic debris traveling from the river to the sea along a representative estuary based on field sequential transfer incubations
Researchers tracked how antibiotic resistance genes change on plastic debris as it travels from a river through an estuary into the sea. They found that over 80 percent of resistance genes persisted on the plastic throughout the journey, and some genes found on the plastic were absent from the surrounding seawater. The study suggests that floating plastic waste could act as a vehicle for spreading antibiotic resistance from inland waterways into marine environments.
Evidence of selective enrichment of bacterial assemblages and antibiotic resistant genes by microplastics in urban rivers
Researchers sampled microplastics from two urban rivers in China and found that the bacterial communities colonizing plastic particles were distinctly different from those in the surrounding water. The microplastic-associated bacteria had lower diversity but higher proportions of biofilm-forming species and functions linked to human disease. Notably, the study found that microplastics selectively enriched antibiotic resistance genes, raising concerns about plastics serving as reservoirs for drug-resistant bacteria.