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Papers
20 resultsShowing papers similar to Characterization and engineering of a plastic-degrading aromatic polyesterase
ClearAn Overview into Polyethylene Terephthalate (PET) Hydrolases and Efforts in Tailoring Enzymes for Improved Plastic Degradation
This review examines the discovery and engineering of PET-degrading enzymes including PETase and cutinase variants, discussing protein engineering strategies to improve catalytic efficiency and thermostability for practical biodegradation of polyethylene terephthalate plastic waste.
Recent trends in microbial and enzymatic plastic degradation: a solution for plastic pollution predicaments
This review covers recent advances in using microorganisms and their enzymes to break down plastics including polyethylene, PVC, polystyrene, and PET, with techniques like protein engineering being used to boost enzyme efficiency. Microbial degradation offers a sustainable approach to reducing the persistent plastic pollution that generates the microplastics found throughout the environment and human body.
Characterization and engineering of plastic-degrading polyesterases jmPE13 and jmPE14 from Pseudomonas bacterium
Two new plastic-degrading polyesterases, jmPE13 and jmPE14, were characterized and engineered from Pseudomonas strains to improve their efficiency in hydrolyzing polyester plastics. The study aimed to develop higher-performance biocatalysts for the enzymatic upcycling of plastic waste.
Recent advances in enzyme engineering for improved deconstruction of poly(ethylene terephthalate) (PET) plastics
This review covers recent progress in engineering enzymes that can break down PET plastic, the material used in water bottles and food containers. While natural enzymes that digest PET have been discovered, they are not yet fast or durable enough for industrial-scale recycling. Advances in protein engineering, directed evolution, and computational design are steadily improving these enzymes, which could eventually provide a sustainable way to recycle PET and reduce microplastic pollution at its source.
Computational redesign of a PETase for plastic biodegradation by the GRAPE strategy
Researchers engineered a more stable version of the enzyme PETase, which breaks down PET plastic, using a computational protein design strategy. The improved enzyme could enable more efficient industrial biodegradation of PET plastic waste, including microplastics.
Discovery and Biochemical Characterization of a Novel Polyesterase for the Degradation of Synthetic Plastics
Researchers used bioinformatics to discover a new enzyme from soil bacteria capable of breaking down synthetic plastics like PET and polyurethane. The enzyme was successfully expressed and characterized in the lab, offering a promising lead for developing biological plastic recycling approaches.
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.
An efficient strategy to tailor PET hydrolase: Simple preparation with high yield and enhanced hydrolysis to micro-nano plastics
This study developed a simplified, high-yield preparation method for PET-degrading hydrolase enzymes to improve their ability to break down PET nano- and microplastics. The engineered enzyme showed enhanced hydrolysis activity against PET microplastics, offering a more practical route to enzymatic plastic waste treatment.
A sequence- and structure-based characterization of microbial enzymes identifies P. stutzeri as a plastic-degrading species
Researchers characterized microbial enzymes with potential plastic-degrading capabilities, focusing on PETase and MHETase enzyme systems. The study identified Pseudomonas stutzeri as a species with notable plastic degradation potential, contributing to the growing understanding of biological approaches for addressing plastic pollution through enzymatic bioremediation.
Enzymatic Remediation of Polyethylene Terephthalate (PET)–Based Polymers for Effective Management of Plastic Wastes: An Overview
Enzymatic approaches for remediating PET-based plastic waste were reviewed, covering PETase and related enzymes that can break PET into reusable monomers. Enzyme engineering strategies to improve thermostability and catalytic efficiency are discussed as a pathway to scalable biological PET recycling.
Marine PET Hydrolase (PET2): Assessment of Terephthalate- and Indole-Based Polyesters Depolymerization
Researchers characterized a marine enzyme (PET2) capable of breaking down PET plastic and related polyester materials under relatively mild conditions. Discovering and engineering enzymes that can degrade PET could help address the massive accumulation of PET microplastics in ocean environments.
Genetic Enhancement of Plastic Degrading Bacteria: The Way to a Sustainable and Healthy Environment
Researchers review how genetic engineering of plastic-degrading bacteria could accelerate the biological breakdown of plastic waste, highlighting promising enzymes and metabolic pathways. Engineering microbes with enhanced plastic-digesting capabilities could become an important tool for reducing the global accumulation of microplastics in the environment.
Engineering Plastic Eating Enzymes Using Structural Biology
This review examines how structural biology approaches are being used to engineer plastic-degrading enzymes with improved efficiency and industrial scalability. Understanding the molecular interactions between enzymes and plastic substrates at an atomic level is guiding the design of more effective biocatalysts for plastic biodegradation.
Harnessing extremophilic carboxylesterases for applications in polyester depolymerisation and plastic waste recycling
This paper is not about microplastics; it reviews the use of microbial carboxylesterases (polyesterases) to enzymatically break down synthetic polyesters like PET for plastic recycling, focusing on enzyme engineering for industrial applications.
Enzymes to make plastics disappear
This review article discusses the problem of plastic waste accumulating in the environment, including the formation of microplastics, and explores the potential of engineered enzymes to break down synthetic polymers as a biological solution to plastic pollution.
Switched reaction specificity in polyesterases towards amide bond hydrolysis by enzyme engineering
Researchers engineered enzymes that can break down polyamide plastics like nylon, which are normally very resistant to degradation. This could open new pathways for enzymatic recycling of synthetic fabrics and help address nylon microplastic pollution.
A high‐throughput expression and screening platform for applications‐driven PETase engineering
Researchers developed a high-throughput platform for engineering PETase enzymes — which break down plastic polyester — by using secretory expression to eliminate purification steps, enabling faster screening of enzyme variants for industrial plastic biodegradation applications.
Microbial plastic degradation: enzymes, pathways, challenges, and perspectives.
This review synthesizes current knowledge on microbial plastic degradation, covering the enzymes and metabolic pathways involved in breaking down major synthetic polymers, the challenges limiting efficient biodegradation, and perspectives for engineering improved microbial solutions to plastic waste.
Plastic biodegradation: Frontline microbes and their enzymes
Researchers reviewed microbial biodegradation of synthetic plastics — including PE, PP, PS, and PET — cataloguing the insects, bacteria, and fungi capable of breaking down these polymers along with the enzymatic mechanisms involved, and outlining paths forward including metabolic pathway engineering and molecular cloning to improve degradation rates.
Application of PETase in Plastic Biodegradation and Its Synthesis
This review examines how PETase enzymes can be used to biodegrade plastic waste, particularly polyethylene terephthalate, which is one of the most widely used plastics globally. Researchers discuss recent advances in modifying PETase enzymes for improved efficiency and establishing sustainable synthesis platforms. The study suggests that enzymatic biodegradation offers a promising biological solution to the growing plastic pollution crisis.