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| Format: | Artículo científico |
| Sprache: | en |
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The ISME journal
2025
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| Online-Zugang: | https://pubmed.ncbi.nlm.nih.gov/41212644/ |
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| author | Acosta, Daniel J Barth, Daryl R Bondy, Julie Appler, Kathryn E De Anda, Valerie Ngo, Phuoc H T Alper, Hal S Baker, Brett J Marcotte, Edward M Ellington, Andrew D |
| author_facet | Acosta, Daniel J Barth, Daryl R Bondy, Julie Appler, Kathryn E De Anda, Valerie Ngo, Phuoc H T Alper, Hal S Baker, Brett J Marcotte, Edward M Ellington, Andrew D Acosta, Daniel J Barth, Daryl R Bondy, Julie Appler, Kathryn E De Anda, Valerie Ngo, Phuoc H T Alper, Hal S Baker, Brett J Marcotte, Edward M Ellington, Andrew D |
| collection | PubMed - marine biology |
| contents | Plastic degradation by enzymes from uncultured deep sea microorganisms. Acosta, Daniel J Barth, Daryl R Bondy, Julie Appler, Kathryn E De Anda, Valerie Ngo, Phuoc H T Alper, Hal S Baker, Brett J Marcotte, Edward M Ellington, Andrew D Polyethylene Terephthalates Phylogeny Bacteria Geologic Sediments Archaea Plastics Seawater Metagenomics Biodegradation, Environmental Metagenome Polyethylene terephthalate (PET)-hydrolyzing enzymes (PETases) are a recently discovered enzyme class capable of plastic degradation. PETases are commonly identified in bacteria; however, pipelines for discovery are often biased to recover highly similar enzymes. Here, we searched metagenomic data from hydrothermally impacted deep sea sediments in the Guaymas Basin (Gulf of California) for PETases. A broad diversity of potential proteins were identified and 22 were selected based on their potential thermal stability and phylogenetic novelty. Heterologous expression and functional analysis of these candidate PETases revealed three candidates capable of depolymerizing PET or its byproducts. One is a PETase from a Bathyarchaeia archaeon (dubbed GuaPA, for Guaymas PETase Archaeal) and two bishydroxyethylene terephthalate-hydrolyzing enzymes (BHETases) from uncultured bacteria, Poribacteria, and Thermotogota. GuaPA is the first archaeal PETase discovered that is able to depolymerize PET films and originates from a specific enzyme class which has endowed it with predicted novel structural features. Within 48 h, GuaPA released ~3-5 mM of terephthalic acid and mono-(2-hydroxyethyl) terephthalate from low crystallinity PET. PET co-hydrolysis containing GuaPA and one of the newly discovered BHETases further improves the hydrolysis of untreated PET film by 68%. Genomic analysis of the PETase- and BHETase-encoding microorganisms reveals that they likely metabolize the products of enzymatic PET depolymerization, suggesting an ecological role in utilizing anthropogenic carbon sources. Our analysis reveals a previously uncharacterized ability of these uncultured microorganisms to catabolize PET, suggesting that the deep ocean is a potential reservoir of biocatalysts for the depolymerization of plastic waste. |
| format | Artículo científico |
| id | pubmed_41212644 |
| institution | PubMed |
| language | en |
| publishDate | 2025 |
| publisher | The ISME journal |
| record_format | pubmed |
| spellingShingle | Plastic degradation by enzymes from uncultured deep sea microorganisms. Acosta, Daniel J Barth, Daryl R Bondy, Julie Appler, Kathryn E De Anda, Valerie Ngo, Phuoc H T Alper, Hal S Baker, Brett J Marcotte, Edward M Ellington, Andrew D Polyethylene Terephthalates Phylogeny Bacteria Geologic Sediments Archaea Plastics Seawater Metagenomics Biodegradation, Environmental Metagenome Plastic degradation by enzymes from uncultured deep sea microorganisms. Acosta, Daniel J Barth, Daryl R Bondy, Julie Appler, Kathryn E De Anda, Valerie Ngo, Phuoc H T Alper, Hal S Baker, Brett J Marcotte, Edward M Ellington, Andrew D Polyethylene Terephthalates Phylogeny Bacteria Geologic Sediments Archaea Plastics Seawater Metagenomics Biodegradation, Environmental Metagenome Polyethylene terephthalate (PET)-hydrolyzing enzymes (PETases) are a recently discovered enzyme class capable of plastic degradation. PETases are commonly identified in bacteria; however, pipelines for discovery are often biased to recover highly similar enzymes. Here, we searched metagenomic data from hydrothermally impacted deep sea sediments in the Guaymas Basin (Gulf of California) for PETases. A broad diversity of potential proteins were identified and 22 were selected based on their potential thermal stability and phylogenetic novelty. Heterologous expression and functional analysis of these candidate PETases revealed three candidates capable of depolymerizing PET or its byproducts. One is a PETase from a Bathyarchaeia archaeon (dubbed GuaPA, for Guaymas PETase Archaeal) and two bishydroxyethylene terephthalate-hydrolyzing enzymes (BHETases) from uncultured bacteria, Poribacteria, and Thermotogota. GuaPA is the first archaeal PETase discovered that is able to depolymerize PET films and originates from a specific enzyme class which has endowed it with predicted novel structural features. Within 48 h, GuaPA released ~3-5 mM of terephthalic acid and mono-(2-hydroxyethyl) terephthalate from low crystallinity PET. PET co-hydrolysis containing GuaPA and one of the newly discovered BHETases further improves the hydrolysis of untreated PET film by 68%. Genomic analysis of the PETase- and BHETase-encoding microorganisms reveals that they likely metabolize the products of enzymatic PET depolymerization, suggesting an ecological role in utilizing anthropogenic carbon sources. Our analysis reveals a previously uncharacterized ability of these uncultured microorganisms to catabolize PET, suggesting that the deep ocean is a potential reservoir of biocatalysts for the depolymerization of plastic waste. |
| title | Plastic degradation by enzymes from uncultured deep sea microorganisms. |
| topic | Polyethylene Terephthalates Phylogeny Bacteria Geologic Sediments Archaea Plastics Seawater Metagenomics Biodegradation, Environmental Metagenome |
| url | https://pubmed.ncbi.nlm.nih.gov/41212644/ |