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61,005 resultsShowing papers similar to Antagonistic effects of microplastic biofilms on antibiotic resistance gene horizontal transfer in water environments
ClearMicroplastic biofilms promote the horizontal transfer of antibiotic resistance genes in estuarine environments
Researchers compared how effectively antibiotic resistance genes transfer between bacteria floating freely in water versus bacteria living in biofilms on microplastic surfaces. They found that microplastic biofilms significantly enhanced the transfer of resistance genes compared to free-floating bacteria, with factors like extracellular DNA and cell membrane permeability playing key roles. The study suggests that microplastics in estuaries may act as hotspots for spreading antibiotic resistance in the environment.
Microplastic pollution increases gene exchange in aquatic ecosystems
Researchers found that microplastics in aquatic environments serve as surfaces where bacteria form biofilms and exchange genes at higher rates than free-living bacteria. The study demonstrated increased transfer of antibiotic resistance genes among a wide range of bacterial species growing on microplastic particles. The findings suggest that microplastic pollution could accelerate the spread of antibiotic resistance in waterways, posing a potential hazard to both ecosystems and human health.
Conjugative antibiotic-resistant plasmids promote bacterial colonization of microplastics in water environments
Antibiotic-resistant bacteria carrying conjugative plasmids were shown to more effectively colonize microplastic surfaces in water environments, with plasmid transfer rates on plastic surfaces exceeding those in the surrounding water. The study identifies microplastics as hotspots for the spread of antibiotic resistance genes through horizontal gene transfer in aquatic systems.
Microplastic biofilm as hotspots of antibiotic resistance genes and potential pathogens
This review examined how microplastic biofilms—the plastisphere—serve as hotspots for antibiotic resistance gene (ARG) accumulation and potential pathogen enrichment. The authors described mechanisms by which microplastic surfaces promote horizontal gene transfer and bacterial community shifts that favor ARG-carrying strains, raising concern that microplastics accelerate the spread of antibiotic resistance in aquatic environments.
A review focusing on mechanisms and ecological risks of enrichment and propagation of antibiotic resistance genes and mobile genetic elements by microplastic biofilms
This review examines how microplastics in water serve as surfaces for bacterial biofilms that harbor antibiotic resistance genes. The biofilms that form on microplastic surfaces can spread resistance genes to other bacteria and potentially to organisms that ingest them, including fish and ultimately humans. The authors highlight that microplastic-associated antibiotic resistance is an underappreciated public health risk that needs more research.
Microbubble-microplastic interactions in batch air flotation
Researchers explored the role of microplastics as carriers of antibiotic resistance genes in aquatic environments, finding that plastic surfaces harbor higher densities of resistance genes than surrounding water. Biofilm formation on microplastics appears to facilitate horizontal gene transfer.
Selective enrichment of bacterial pathogens by microplastic biofilm
Researchers incubated biofilms on microplastics and natural substrates in freshwater and found that microplastic surfaces selectively enriched bacterial pathogens and antibiotic resistance genes compared to rock and leaf surfaces. The study suggests that microplastics in waterways may serve as hotspots for harmful bacteria and contribute to the spread of antibiotic resistance in the environment.
The unexpected role of aged microplastics in inhibiting antibiotic resistance gene spread
Aged (weathered) microplastics were unexpectedly found to inhibit antibiotic resistance gene transfer between bacteria compared to virgin plastics. This surprising result suggests that the physical and chemical changes plastics undergo in the environment can alter their role in spreading antibiotic resistance, a key public health concern.
Regulation of ARGs abundance by biofilm colonization on microplastics under selective pressure of antibiotics in river water environment
Researchers investigated how biofilms forming on microplastics in river water affect the spread of antibiotic resistance genes under antibiotic pressure. They found that the presence of antibiotics accelerated biofilm colonization on microplastic surfaces and significantly increased the abundance of resistance genes compared to conditions without antibiotics. The study suggests that microplastics in waterways may serve as hotspots for the development and transfer of antibiotic resistance.
New insight into the effect of microplastics on antibiotic resistance and bacterial community of biofilm
Researchers found that different types of microplastics promote distinct biofilm communities and enhance antibiotic resistance gene proliferation compared to natural substrates, suggesting microplastics serve as unique platforms for the spread of antimicrobial resistance.
[Research progress on the effect of estuary microplastics on antibiotic resistance genes].
This review summarizes research on how microplastics in estuarine environments influence the spread of antibiotic resistance genes (ARGs), focusing on the role of biofilms that form on plastic surfaces. Microplastic biofilms selectively enrich ARG-carrying bacteria and facilitate horizontal gene transfer, increasing the risk of antibiotic resistance dissemination in ecologically and humanly important estuarine zones.
Interaction between microplastic biofilm formation and antibiotics: Effect of microplastic biofilm and its driving mechanisms on antibiotic resistance gene
This review explores how microplastics in water environments develop biofilms that interact with antibiotics in concerning ways. Researchers found that biofilm-coated microplastics can enhance the adsorption of antibiotics and serve as hotspots for antibiotic resistance genes. The study highlights the risk that microplastic biofilms could accelerate the spread of antibiotic resistance through aquatic ecosystems.
Enhanced propagation of intracellular and extracellular antibiotic resistance genes in municipal wastewater by microplastics
Researchers investigated how microplastics in municipal wastewater can carry and promote the spread of antibiotic resistance genes, including those found both inside and outside bacterial cells. They found that microplastics adsorbed both types of resistance genes and enhanced their transfer between bacteria through horizontal gene transfer. The study reveals that microplastics in wastewater systems may act as an underappreciated accelerator of antibiotic resistance spread.
Microplastic-Mediated Dissemination of Antibiotic Resistance Genes in Marine Environments: Mechanisms, Environmental Modulators, and Emerging Risks
This review examines how microplastics serve as vectors for spreading antibiotic resistance genes in marine environments through biofilm formation and horizontal gene transfer. Researchers found that plastic surfaces promote colonization by resistant bacteria, and environmental factors like salinity, UV exposure, and co-occurring heavy metals further accelerate the spread of resistance genes, posing significant ecological and public health risks.
Slower antibiotics degradation and higher resistance genes enrichment in plastisphere
Researchers compared how antibiotics break down on microplastic surfaces versus natural mineral surfaces in urban water environments. Tetracycline degraded significantly more slowly on microplastic biofilms than on quartzite biofilms, and the plastic surfaces harbored higher levels of antibiotic resistance genes. The findings suggest that microplastics in waterways may slow antibiotic breakdown while promoting the spread of antibiotic resistance.
From Interface to Cell: The Complex Interaction and Transfer Process Coupling Mechanism between Microplastics and Antibiotic Resistance Genes
Researchers examined how microplastic surfaces act as vectors for spreading antibiotic resistance genes in wastewater treatment systems. The study found that aged microplastics of PET, PE, and PP promoted bacterial adhesion, enhanced horizontal gene transfer, and triggered overproduction of reactive oxygen species, ultimately amplifying the spread of antimicrobial resistance through multiple molecular mechanisms.
Horizontal Gene Transfer of Antibiotic Resistance Genes in Biofilms
This review explains how bacteria living in biofilms -- sticky communities attached to surfaces -- can rapidly share antibiotic resistance genes with each other through horizontal gene transfer, spreading resistance faster than free-floating bacteria. This is relevant to microplastic pollution because microplastics provide ideal surfaces for biofilm formation, potentially acting as hotspots for the spread of antibiotic resistance in the environment.
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.
Underestimated Risks of Microplastics on the Environmental Spread of Antibiotic Resistance Genes
Researchers highlight how microplastics in aquatic environments can accelerate the spread of antibiotic resistance genes, a risk that current assessment methods may significantly underestimate. Biofilms that form on microplastic surfaces create conditions where bacteria are in close contact, facilitating the transfer of resistance genes between species. The study argues that standard microplastic detection methods miss many small particles, meaning the true scope of this resistance-spreading pathway is likely much larger than reported.
Biofilm formation on microplastics and interactions with antibiotics, antibiotic resistance genes and pathogens in aquatic environment
This review explains how microplastics in waterways develop bacterial biofilms on their surfaces that can harbor antibiotic-resistant bacteria and help spread antibiotic resistance genes to new environments. This is concerning for human health because these resistant microbes could eventually reach people through drinking water or seafood consumption.
Unraveling the effect of micro/nanoplastics on the occurrence and horizontal transfer of environmental antibiotic resistance genes: Advances, mechanisms and future prospects
This review examines how micro- and nanoplastics promote the spread of antibiotic resistance genes in the environment. The tiny plastic particles create conditions that help bacteria exchange resistance genes more easily by generating oxidative stress, making cell membranes more permeable, and providing surfaces where resistant bacteria can form communities. This is a growing public health concern because antibiotic-resistant infections are increasingly difficult to treat.
Selective enrichment of antibiotic resistome and bacterial pathogens by aquatic microplastics
This review found that microplastics in aquatic environments selectively enrich antibiotic-resistant bacteria, resistance genes, and bacterial pathogens in their biofilms, making plastic debris a potential vector for spreading antimicrobial resistance.
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.
Prevalence of microplastics, antibiotic resistant genes and microplastic associated biofilms in estuary - A review
This review examined evidence for microplastics, antibiotic resistance genes, and microplastic-associated biofilms in estuarine ecosystems. Microplastics in estuaries serve as substrates for diverse microbial biofilms including pathogens and antibiotic-resistant bacteria, and estuaries are identified as important reservoirs for microplastic-facilitated horizontal gene transfer.