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20 resultsShowing papers similar to Biodegradation of Microplastic Derived from Poly(ethylene terephthalate) with Bacterial Whole-Cell Biocatalysts
ClearImprovement of biodegradation of PET microplastics with whole-cell biocatalyst by interface activation reinforcement
Researchers developed a whole-cell biocatalysis strategy using alkali-resistant bacteria combined with surfactant-mediated interfacial activation to improve the biodegradation of PET microplastics, finding that Tween 20 most effectively enhanced the bio-interfacial activity between bacterial enzymes and the hydrophobic PET surface, leading to improved hydrolysis rates.
Interfacial engineering-based colonization of biofilms on polyethylene terephthalate (PET) surfaces: Implications for whole-cell biodegradation of microplastics
This study applied interfacial engineering to promote biofilm colonization on polyethylene terephthalate (PET) surfaces to facilitate enzymatic depolymerization under mild conditions. The engineered biofilm approach enabled efficient PET biodegradation without requiring harsh alkaline conditions or high temperatures, advancing practical plastic bioremediation.
Enzymatic Degradation of Polyethylene Terephthalate Plastics by Bacterial Curli Display PETase
Researchers engineered bacteria to display a PET-degrading enzyme on their surface, creating a reusable biocatalyst capable of breaking down polyethylene terephthalate plastics. The system worked under various conditions, remained stable for at least 30 days, and could even degrade PET microplastics in wastewater and highly crystalline consumer plastic waste. This biological approach offers a promising environmentally friendly alternative for plastic recycling and waste treatment.
Biodegradation of Poly(Ethylene Terephthalate) Microplastics by Baceterial Communities From Activated Sludge
Scientists isolated bacteria from wastewater treatment sludge that can biodegrade PET plastic, used in plastic bottles and food packaging. The bacteria broke down PET microplastics over a 60-day period, pointing toward a potential biological tool for removing plastic contamination from water treatment systems.
Biodegradation of Poly(Ethylene Terephthalate) Microplastics by Baceterial Communities From Activated Sludge
Scientists isolated bacteria from wastewater treatment sludge that can biodegrade PET plastic, used in plastic bottles and food packaging. The bacteria broke down PET microplastics over a 60-day period, pointing toward a potential biological tool for removing plastic contamination from water treatment systems.
Bioengineering Comamonas testosteroni CNB-1: a robust whole-cell biocatalyst for efficient PET microplastic degradation
This study engineered Comamonas testosteroni CNB-1 as a whole-cell biocatalyst for degrading PET microplastics in biological wastewater treatment, addressing the accumulation of these particles in sewage sludge. The engineered bacterium demonstrated efficient PET degradation, offering a biotechnological solution to a pressing wastewater treatment challenge.
A review on microbial bioremediation of polyethylene terephthalate microplastics
This review focuses on microbial biodegradation of PET microplastics — the plastic used in bottles and synthetic textiles — detailing the specific enzymes (PETase and MHETase) that bacteria use to break the polymer down into its chemical building blocks. Biological degradation offers a lower-energy, more environmentally gentle alternative to chemical recycling or landfill, and understanding the microbial mechanisms involved is key to developing scalable bioremediation solutions for one of the most pervasive microplastic types.
Towards synthetic PETtrophy: Engineering Pseudomonas putida for concurrent polyethylene terephthalate (PET) monomer metabolism and PET hydrolase expression
Researchers engineered a soil bacterium to simultaneously break down PET plastic and use its building-block chemicals as food, identifying key bottlenecks in balancing enzyme production with bacterial fitness that will need to be resolved before such microbes can be used for large-scale plastic biodegradation.
Current Knowledge on Polyethylene Terephthalate Degradation by Genetically Modified Microorganisms
This review covers genetically modified microorganisms engineered to degrade polyethylene terephthalate, examining how bioengineering of enzymes such as PETase and enhanced expression systems can overcome the low biodegradation rates of wild-type microorganisms toward this ubiquitous plastic.
Biodegradation of Poly(ethylene terephthalate) by Bacillus safensis YX8
Researchers isolated a PET-degrading bacterial strain, Bacillus safensis YX8, from the surface of plastic waste and demonstrated its ability to break down PET nanoparticles. The study identified the degradation products as terephthalic acid and related compounds, suggesting this bacterium could contribute to environmentally friendly approaches for managing PET plastic waste.
Biodegradation of polyethylene terephthalate microplastics by bacterial communities from activated sludge
Bacterial communities from activated sludge were shown to grow on PET microplastics as a sole carbon source and achieved measurable biodegradation of heat-pretreated PET fragments in a standardized CO₂ evolution test, identifying activated sludge as a source of PET-degrading microbes.
Engineered Vibrio natriegens as a living biocatalyst for in-situ biodegradation of microplastics in seawater
Researchers engineered the fast-growing marine bacterium Vibrio natriegens to display PETase enzymes on its outer membrane, creating a living biocatalyst that degrades PET microplastics directly in seawater conditions, outperforming comparable E. coli-based systems in both growth rate and hydrolytic activity. This halophilic whole-cell approach addresses a key gap in bioremediation — most PETase studies use freshwater organisms that cannot survive the salinity of marine environments where plastic pollution is most severe.
Development of a yeast whole-cell biocatalyst for MHET conversion into terephthalic acid and ethylene glycol
Researchers engineered baker's yeast to display plastic-degrading enzymes on its cell surface, demonstrating a simpler and potentially cheaper approach to breaking down PET plastic — the material used in bottles — without requiring the costly step of purifying the enzymes first.
Marine hydrocarbon-degrading bacteria breakdown poly(ethylene terephthalate) (PET)
Scientists used microcosm studies to investigate whether marine hydrocarbon-degrading bacteria can break down PET plastic, finding that specific bacterial strains could colonize and degrade PET surfaces, offering insights into natural plastic biodegradation in the ocean.
Degradation of PET plastic with engineered environmental bacteria
Scientists engineered a soil bacterium to break down PET plastic, one of the most common plastics in food packaging and textiles, by giving it the ability to produce and secrete a powerful plastic-degrading enzyme. This is one of the first demonstrations of a living microorganism that can directly consume PET as a food source, which could lead to more sustainable recycling approaches.
Degradation of PET Plastics by Wastewater Bacteria Engineered via Conjugation
Researchers demonstrated a proof-of-concept approach for reducing PET microplastic pollution in wastewater by engineering bacteria in situ via conjugation to express PET-degrading enzymes. The study used a broad-host-range conjugative plasmid to transfer PET hydrolase genes into native wastewater bacterial communities.
Eco-Microbiology: Discovering Biochemical Enhancers of PET Biodegradation by Piscinibacter sakaiensis
This paper reviews biochemical strategies for enhancing PET biodegradation by microorganisms, focusing on the discovery and engineering of plastic-degrading enzymes. The review highlights recent advances and remaining challenges in scaling up enzymatic plastic degradation for industrial applications.
A novel Bacillus subtilis BPM12 with high bis(2 hydroxyethyl)terephthalate hydrolytic activity efficiently interacts with virgin and mechanically recycled polyethylene terephthalate
Researchers discovered a soil bacterium, Bacillus subtilis BPM12, that can break down PET plastic building blocks at impressively high rates and across a wide range of temperatures and pH levels. The study shows that combining mechanical shredding with biological degradation by this microbe could be a practical route to recycling more PET plastic waste, a major source of environmental microplastics, back into useful chemicals.
Development and characterization of a bacterial enzyme cascade reaction system for efficient and stable PET degradation
Scientists engineered a bacterial system that displays plastic-degrading enzymes on the cell surface to efficiently break down PET plastic, achieving a 23% degradation rate of microplastics within 7 days. The system uses E. coli bacteria with specially designed protein fibers that both grip and digest PET fragments. This biotechnology approach could eventually help address the growing problem of microplastic pollution in water and soil environments.
Breakdown of polyethylene therepthalate microplastics under saltwater conditions using engineered Vibrio natriegens
Scientists engineered a marine bacterium, Vibrio natriegens, to break down PET plastic into its basic chemical building blocks in saltwater conditions at moderate temperatures. The engineered bacteria display enzymes on their cell surface that can depolymerize PET without needing any pretreatment of the plastic. This biological approach could eventually help address ocean microplastic pollution, though significant work remains to scale the technology from the laboratory to real-world applications.