Enzyme engineering improves catalytic efficiency and enantioselectivity of hydroxynitrile lyase for promiscuous retro-nitroaldolase activity

dc.contributor.author Vishnu Priya, Badipatla
dc.contributor.author Sreenivasa Rao, D. H.
dc.contributor.author Gilani, Rubina
dc.contributor.author Lata, Surabhi
dc.contributor.author Rai, Nivedita
dc.contributor.author Akif, Mohd
dc.contributor.author Kumar Padhi, Santosh
dc.date.accessioned 2022-03-27T04:56:20Z
dc.date.available 2022-03-27T04:56:20Z
dc.date.issued 2022-03-01
dc.description.abstract Protein engineering to improve promiscuous catalytic activity is important for biocatalytic application of enzymes in green synthesis. We uncovered the significance of binding site residues in Arabidopsis thaliana hydroxynitrile lyase (AtHNL) for promiscuous retro-nitroaldolase activity. Engineering of AtHNL has improved enantioselective retro-nitroaldolase activity, a synthetically important biotransformation, for the production of enantiopure β-nitroalcohols having absolute configuration opposite to that of the stereopreference of the HNL. The variant F179A has shown ∼ 12 fold increased selectivity towards the retro-nitroaldol reaction over cyanogenesis, the natural activity of the parent enzyme. Screening of the two saturation libraries of Phe179 and Tyr14 revealed several variants with higher kcat, while F179N showed ∼ 2.4-fold kcat/Km than the native enzyme towards retro-nitroaldol reaction. Variants F179N, F179M, F179W, F179V, F179I, Y14L, and Y14M have shown > 99% ee in the preparation of (S)-2-nitro-1-phenylethanol (NPE) from the racemic substrate, while F179N has shown the E value of 138 vs. 81 by the wild type. Our molecular docking and dynamics simulations (MDS) studies results provided insights into the molecular basis of higher enantioselectivity by the F179N toward the retro-nitroaldolase activity than the other mutants. Binding energy calculations also showed the higher negative binding free energy in the case of F179N-(R)-NPE compared to other complexes that support our experimental low Km by the F179N for NPE. A plausible retro-nitroaldol reaction mechanism was proposed based on the MDS study of enzyme-substrate interaction.
dc.identifier.citation Bioorganic Chemistry. v.120
dc.identifier.issn 00452068
dc.identifier.uri 10.1016/j.bioorg.2021.105594
dc.identifier.uri https://www.sciencedirect.com/science/article/abs/pii/S004520682100972X
dc.identifier.uri https://dspace.uohyd.ac.in/handle/1/7511
dc.subject Asymmetric synthesis
dc.subject Catalytic efficiency
dc.subject Catalytic promiscuity
dc.subject Chiral β -nitro alcohol
dc.subject Hydroxynitrile lyase
dc.subject Protein engineering
dc.subject Retro-Henry reaction
dc.title Enzyme engineering improves catalytic efficiency and enantioselectivity of hydroxynitrile lyase for promiscuous retro-nitroaldolase activity
dc.type Journal. Article
dspace.entity.type
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