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61,005 resultsShowing papers similar to Novel bacterial lineages assembled from wastewater-impacted river metagenomes unveil ecosystem functions and risk of antibiotic resistance spread in the community
ClearLongitudinal patterns of microplastic concentration and bacterial assemblages in surface and benthic habitats of an urban river
This study measured microplastic concentrations and microbial communities in a river from source to mouth, finding that both plastic levels and unique plastisphere bacterial communities increased downstream of wastewater treatment plant outflows. The results identify wastewater discharge as a key driver of both microplastic loading and microbial community shifts in rivers.
Metagenomic insights into environmental risk of field microplastics in an urban river
Metagenomic analysis of microplastics sampled along an urban river watershed revealed that MP-associated microbial communities carried antibiotic resistance genes and virulence factors at higher levels than surrounding water, with composition shifting along the river gradient. The findings confirm microplastics as environmental vectors for spreading antimicrobial resistance.
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.
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.
Increased inheritance of structure and function of bacterial communities and pathogen propagation in plastisphere along a river with increasing antibiotics pollution gradient.
This study examined how bacterial communities colonizing plastic debris in a river — the Plastisphere — change along a gradient of increasing antibiotic pollution. Plastic debris hosted distinct microbial communities compared to surrounding water, and areas with higher antibiotic levels showed greater inheritance of resistant bacterial structures on plastic surfaces, suggesting plastics facilitate the spread of antibiotic resistance.
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.
Potential routes of plastics biotransformation involving novel plastizymes revealed by global multi-omic analysis of plastic associated microbes
Researchers analyzed all publicly available genetic data from microbes living on plastic debris worldwide and found that while plastic-eating bacteria are rare in most environments, rivers appear to be hotspots for novel plastic-degrading organisms. They also created a freely accessible database of these plastic-associated microbes, which could accelerate efforts to develop biological solutions for plastic pollution.
Plastisphere showing unique microbiome and resistome different from activated sludge
Researchers used metagenomics to compare the microbiome and resistome of PVC plastisphere biofilms with activated sludge, finding that microplastic surfaces enriched distinct pathogenic bacteria and antibiotic resistance genes that differ from the surrounding sludge community.
Impact of Urbanization on Antibiotic Resistome in Different Microplastics: Evidence from a Large-Scale Whole River Analysis
Researchers conducted a large-scale river survey across urbanization gradients and characterized antibiotic resistance genes on microplastics from each zone, finding that urbanization level strongly predicted the diversity and abundance of resistance genes on plastic surfaces.
Metagenomics reveals combined effects of microplastics and antibiotics on microbial community structure and function in coastal sediments
A metagenomic study of coastal sediments exposed to combined microplastic and antibiotic pollution found that co-exposure altered microbial community composition and significantly elevated the abundance and diversity of antibiotic resistance genes compared to either pollutant alone.
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.
Impact of sulfamethoxazole on a riverine microbiome
Scientists studied how the antibiotic sulfamethoxazole affects the microbial community in a river, finding that even low concentrations shifted the balance of bacteria and promoted antibiotic resistance genes. This is relevant to the microplastic field because both antibiotics and microplastics promote antibiotic resistance when they co-occur in aquatic environments.
Untargeted metabolomic insights into plastisphere communities in European rivers
Researchers used untargeted metabolomics to characterize plastisphere microbial communities colonizing polyethylene-based plastic pellets in European rivers, simulating microplastic transport between freshwater and marine ecosystems to understand how the plastisphere microbiome and its metabolic outputs shift across environmental transitions.
Evaluating the role of microplastics and wastewater in shaping Vibrio spp. and antibiotic resistance gene abundance in urban freshwaters
Researchers sampled water and microplastic biofilms from urban South African rivers and found that microplastics disproportionately enriched Vibrio spp. and tetracycline resistance genes relative to the surrounding water, suggesting microplastics selectively concentrate pathogens and antibiotic resistance genes.
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.
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.
Deciphering the mechanisms shaping the plastisphere antibiotic resistome on riverine microplastics
Researchers found that microplastics in China's Huangpu River selectively enrich antibiotic resistance genes for Rifamycin and Vancomycin, creating unique bacterial niches that favor horizontal gene transfer and dissemination of resistance through stochastic assembly processes.
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.
Ecological Rolesand Shared Microbes Differentiatethe Plastisphere from Natural Particle-Associated Microbiomes in UrbanRivers
Researchers compared the microbiomes on microplastics (the 'plastisphere') versus natural particles in ten urban rivers using metagenomics, finding similar overall taxonomic and functional compositions between the two. However, the plastisphere harbored distinct specialist taxa with enhanced capacity for complex carbohydrate metabolism and unique ecological strategies.
Disentangling abiotic and biotic effects of treated wastewater on stream biofilm resistomes enables the discovery of a new planctomycete beta-lactamase
This paper is not about microplastics — it investigates how wastewater discharge shapes antibiotic resistance gene (ARG) communities in stream biofilms, finding that biological (microbial community) factors dominate over chemical factors, and reports the discovery of a novel functional beta-lactamase enzyme from a rarely studied bacterial phylum.
Identification of microplastic-associated microbial communities from various stages of wastewater treatment and recipient surface waters using MALDI-TOF mass spectrometry
Researchers deployed six polymer types at different stages of wastewater treatment across three Hungarian plants and used MALDI-TOF mass spectrometry to identify the bacteria colonizing microplastic surfaces, finding distinct microbial communities that may act as vectors for antibiotic resistance.
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 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.
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.