Manufacturing of the highly active thermophile PETases PHL7 and PHL7mut3 using Escherichia coli

The global plastic waste crisis requires combined recycling strategies. One approach, enzymatic degradation of PET waste into monomers, followed by re-polymerization, offers a circular economy solution. However, challenges remain in producing sufficient amounts of highly active PET-degrading enzymes...

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Bibliographic Details
Published in:Microbial cell factories 2024-10, Vol.23 (1), p.272-15, Article 272
Main Authors: Fohler, Lisa, Leibetseder, Lukas, Cserjan-Puschmann, Monika, Striedner, Gerald
Format: Article
Language:English
Subjects:
Bacteria, Thermophilic
Bacterial Proteins - genetics
Bacterial Proteins - metabolism
Chemical engineering
Chemical engineering research
Chemical properties
Costs (Law)
Decomposition (Chemistry)
E. coli
Enzyme engineering
Enzyme production
Enzyme Stability
Enzymes
Escherichia coli
Escherichia coli - genetics
Escherichia coli - metabolism
Fermentation
Hydrogen-Ion Concentration
Methods
Microbiological synthesis
PET degradation
PETase
PHL7
Physiological aspects
Polyethylene terephthalate
Polyethylene Terephthalates - metabolism
Polymerization
Recycling
Recycling (Waste, etc.)
Temperature
Waste management
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Summary:The global plastic waste crisis requires combined recycling strategies. One approach, enzymatic degradation of PET waste into monomers, followed by re-polymerization, offers a circular economy solution. However, challenges remain in producing sufficient amounts of highly active PET-degrading enzymes without costly downstream processes. Using the growth-decoupled enGenes e -press V2 E. coli strain, pH, induction strength and feed rate were varied in a factorial-based optimization approach, to find the best-suited production conditions for the PHL7 enzyme. This led to a 40% increase in activity of the fermentation supernatant. Optimization of the expression construct resulted in a further 4-fold activity gain. Finally, the identified improvements were applied to the production of the more active and temperature stable enzyme variant, PHL7mut3. The unpurified fermentation supernatant of the PHL7mut3 fermentation was able to completely degrade our PET film sample after 16 h of incubation at 70 °C at an enzyme loading of only 0.32 mg enzyme per g of PET. In this research, we present an optimized process for the extracellular production of thermophile and highly active PETases PHL7 and PHL7mut3, eliminating the need for costly purification steps. These advancements support large-scale enzymatic recycling, contributing to solving the global plastic waste crisis.
ISSN:1475-2859
1475-2859
DOI:10.1186/s12934-024-02551-6