A flexible kinetic assay efficiently sorts prospective biocatalysts for PET plastic subunit hydrolysis

A flexible kinetic assay efficiently sorts prospective biocatalysts for PET plastic subunit hydrolysis

Esterase enzymes catalyze diverse hydrolysis reactions with important biological, commercial, and biotechnological applications. For the improvement of these biocatalysts, there is a need for widely accessible, inexpensive, and adaptable activity screening assays that identify enzymes with particula...

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Veröffentlicht in:RSC advances 2022-03, Vol.12 (13), p.8119-813
Hauptverfasser: Lusty Beech, Jessica, Clare, Rita, Kincannon, William M, Erickson, Erika, McGeehan, John E, Beckham, Gregg T, DuBois, Jennifer L
Format: Artikel
Sprache:eng
Schlagworte:
Accessibility
Assaying
Biocatalysts
Bioconversion
Biopolymers
Chemical reactions
Chemistry
Enzymes
Esterases
Hydrolysis
Polyethylene terephthalate
Reaction products
Screening
Substrates
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container_end_page 813
container_issue 13
container_start_page 8119
container_title RSC advances
container_volume 12
creator Lusty Beech, Jessica
Clare, Rita
Kincannon, William M
Erickson, Erika
McGeehan, John E
Beckham, Gregg T
DuBois, Jennifer L
description Esterase enzymes catalyze diverse hydrolysis reactions with important biological, commercial, and biotechnological applications. For the improvement of these biocatalysts, there is a need for widely accessible, inexpensive, and adaptable activity screening assays that identify enzymes with particular substrate specificities. Natural systems for biopolymer bioconversion, and likely those designed to mimic them, depend on cocktails of enzymes, each of which specifically targets the intact material as well as water-soluble subunits of varying size. In this work, we have adapted a UV/visible assay using pH-sensitive sulfonphthalein dyes for the real-time quantification of ester hydrolysis of bis-(2-hydroxyethyl) terephthalate (BHET), a subunit of polyethylene terephthalate (PET) plastic. We applied this method to a diverse set of known PET hydrolases and commercial esterases in a microplate format. The approach identified four PET hydrolases and one commercial esterase with high levels of specificity for BHET hydrolysis. Five additional PET hydrolases and three commercial esterases, including a thermophilic enzyme, effectively hydrolyzed both BHET and its monoester product MHET (mono-(2-hydroxyethyl) terephthalate). Specific activities were discernible within one hour and reactions reached an unequivocal endpoint well within 24 hours. The results from the UV/visible method correlated well with conventional HPLC analysis of the reaction products. We examined the suitability of the method toward variable pH, temperature, enzyme preparation method, mono- and multi-ester substrate type, and level of sensitivity versus stringency, finding the assay to be easily adaptable to diverse screening conditions and kinetic measurements. This method offers an accurate, easily accessible, and cost-effective route towards high-throughput library screening to support the discovery, directed evolution, and protein engineering of these critical biocatalysts. We have developed a colorimetric assay for the high throughput detection of enzymatic ester hydrolysis of PET plastic monomers, applied in a microplate format.
doi_str_mv 10.1039/d2ra00612j
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Five additional PET hydrolases and three commercial esterases, including a thermophilic enzyme, effectively hydrolyzed both BHET and its monoester product MHET (mono-(2-hydroxyethyl) terephthalate). Specific activities were discernible within one hour and reactions reached an unequivocal endpoint well within 24 hours. The results from the UV/visible method correlated well with conventional HPLC analysis of the reaction products. We examined the suitability of the method toward variable pH, temperature, enzyme preparation method, mono- and multi-ester substrate type, and level of sensitivity versus stringency, finding the assay to be easily adaptable to diverse screening conditions and kinetic measurements. This method offers an accurate, easily accessible, and cost-effective route towards high-throughput library screening to support the discovery, directed evolution, and protein engineering of these critical biocatalysts. 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source DOAJ Directory of Open Access Journals; PubMed Central Open Access; EZB-FREE-00999 freely available EZB journals; PubMed Central
subjects Accessibility
Assaying
Biocatalysts
Bioconversion
Biopolymers
Chemical reactions
Chemistry
Enzymes
Esterases
Hydrolysis
Polyethylene terephthalate
Reaction products
Screening
Substrates
title A flexible kinetic assay efficiently sorts prospective biocatalysts for PET plastic subunit hydrolysis
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