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Single Residue Substitution at N-Terminal Affects Temperature Stability and Activity of L2 Lipase

Noramirah Bukhari, Thean Chor Leow, Raja Noor Zaliha Raja Abd Rahman, Fairolniza Mohd Shariff

2020Molecules18 citationsDOIOpen Access PDF

Abstract

Rational design is widely employed in protein engineering to tailor wild-type enzymes for industrial applications. The typical target region for mutation is a functional region like the catalytic site to improve stability and activity. However, few have explored the role of other regions which, in principle, have no evident functionality such as the N-terminal region. In this study, stability prediction software was used to identify the critical point in the non-functional N-terminal region of L2 lipase and the effects of the substitution towards temperature stability and activity were determined. The results showed 3 mutant lipases: A8V, A8P and A8E with 29% better thermostability, 4 h increase in half-life and 6.6 °C higher thermal denaturation point, respectively. A8V showed 1.6-fold enhancement in activity compared to wild-type. To conclude, the improvement in temperature stability upon substitution showed that the N-terminal region plays a role in temperature stability and activity of L2 lipase.

Topics & Concepts

ThermostabilityLipaseProtein engineeringDenaturation (fissile materials)Residue (chemistry)MutantChemistryThermal stabilityWild typeEnzymeRational designPoint mutationBiochemistryBiologyOrganic chemistryGeneticsGeneNuclear chemistryEnzyme Catalysis and ImmobilizationPancreatic function and diabetesMicrobial Metabolic Engineering and Bioproduction
Single Residue Substitution at N-Terminal Affects Temperature Stability and Activity of L2 Lipase | Litcius