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Protein-Glutaminase Engineering Based on Isothermal Compressibility Perturbation for Enhanced Modification of Soy Protein Isolate

Nan Zheng, Mengfei Long, Zehua Zhang, Qijia Zan, Tolbert Osire, Huimin Zhou, Xiaole Xia

2022Journal of Agricultural and Food Chemistry45 citationsDOI

Abstract

Protein-glutaminase plays a significant role in future food (e.g., plant-based meat) processing as a result of its ability to improve the solubility, foaming, emulsifying, and gel properties of plant-based proteins. However, poor stability, activity, high pressure, and high shear processing environments hinder its application. Therefore, we developed an application-oriented method isothermal compressibility perturbation engineering strategy to improve enzyme performance by simulating the high-pressure environment. The best variant with remarkable improvement in specific activity and half-time, N16M/Q21H/T113E, exhibited a 4.28-fold increase compared to the wild type in specific activity (117.18 units/mg) and a 1.23-fold increase in half-time (472 min), as one of the highest comprehensive performances ever reported. The solubility of the soy protein isolate deaminated by the N16M/Q21H/T113E mutant was 55.74% higher than that deaminated by the wild type, with a tinier particle size and coarser texture. Overall, this strategy has the potential to improve the functional performance of enzymes under complex food processing conditions.

Topics & Concepts

Soy proteinCompressibilityProtein engineeringSolubilityChemistryIsothermal processEnzymeChemical engineeringHydrolysisFood scienceBiochemistryThermodynamicsOrganic chemistryEngineeringPhysicsProteins in Food SystemsProbiotics and Fermented FoodsMicrobial Inactivation Methods
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