Litcius/Paper detail

Engineering the Thermostability of a <scp>d-</scp>Carbamoylase Based on Ancestral Sequence Reconstruction for the Efficient Synthesis of <scp>d</scp>-Tryptophan

Jiamin Hu, Xiaoyu Chen, Lu Zhang, Jieyu Zhou, Guochao Xu, Ye Ni

2022Journal of Agricultural and Food Chemistry23 citationsDOI

Abstract

Employing ancestral sequence reconstruction and consensus sequence analysis, the thermostability of a novel d-carbamoylase derived from Nitratireductor indicus (NiHyuC) was engineered through greedy-oriented iterative combinatorial mutagenesis. A mutant S202P/E208D/R277L (M4Th3) was obtained with significantly elevated thermostability. M4Th3 has a half-life of 36.5 h at 40 °C, about 28.5 times of 1.3 h of its parent M4. For the reaction at 40 °C, M4Th3 can catalyze 10 mM N-carbamoyl-d-tryptophan to produce d-tryptophan with a conversion ratio of 96.4% after 12 h, which is significantly higher than 64.1% of M4. MD simulation reveals that new hydrogen bonds emerging from E208D on the surface can increase the hydrophobicity of the protein, leading to improved stability. More importantly, R277L could contribute to enhanced interface stability of homodimeric M4. This study provides a thermostable d-carbamoylase for the “hydantoinase process”, which has potential in the industrial synthesis of optically pure natural and non-natural amino acids.

Topics & Concepts

ThermostabilitySequence (biology)TryptophanChemistryBiochemistryAmino acidEnzymeEnzyme Structure and FunctionAmino Acid Enzymes and MetabolismMetabolomics and Mass Spectrometry Studies
Engineering the Thermostability of a <scp>d-</scp>Carbamoylase Based on Ancestral Sequence Reconstruction for the Efficient Synthesis of <scp>d</scp>-Tryptophan | Litcius