Phosphotriesterases (PTEs) represent a class of enzymes capable of efficient neutralization of organophosphates (OPs), a dangerous class of neurotoxic chemicals. PTEs suffer from low catalytic activity, particularly at higher temperatures, due to low thermostability and low solubility. Supercharging, a protein engineering approach via selective mutation of surface residues to charged residues, has been successfully employed to generate proteins with increased solubility and thermostability by promoting charge–charge repulsion between proteins. We set out to overcome the challenges in improving PTE activity against OPs by employing a computational protein supercharging algorithm in Rosetta. Here, we discover two supercharged PTE variants, one negatively supercharged (with −14 net charge) and one positively supercharged (with +12 net charge) and characterize them for their thermodynamic stability and catalytic activity. We find that positively supercharged PTE possesses slight but significant losses in thermostability, which correlates to losses in catalytic efficiency at all temperatures, whereas negatively supercharged PTE possesses increased catalytic activity across 25°C–55°C while offering similar thermostability characteristic to the parent PTE. The impact of supercharging on catalytic efficiency will inform the design of shelf-stable PTE and criteria for enzyme engineering.
This content will become publicly available on March 4, 2025
- PAR ID:
- 10516380
- Publisher / Repository:
- ACS
- Date Published:
- Journal Name:
- ACS Sustainable Chemistry & Engineering
- Volume:
- 12
- Issue:
- 9
- ISSN:
- 2168-0485
- Page Range / eLocation ID:
- 3500 to 3516
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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IfCelS12A from an anaerobic alkaliphile Iocasia fronsfrigidae shows salt tolerance •
IfCelS12A in cocktails with other enzymes efficiently degrades cellulosic biomass •
IfCelS12A used with mobile enzyme sequestration platforms enhances hydrolysis -
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