Recent advances, challenges and functional applications of protein glycosylation modification in food industry.
食品工业中蛋白质糖基化修饰的最新进展、挑战和功能应用
摘要 (Abstract)
<jats:title>Abstract</jats:title> <jats:p>Protein glycosylation modification is an effective way to enhance the functional properties of natural proteins. This study aims to explore the preparation of glycosylation products (PPCs) through the Maillard reaction or enzymatic glycosylation using transglutaminase. The study discusses the advantages and disadvantages of preparing PPCs using dry heat, wet heat, and enzymatic glycosylation, as well as factors influencing the glycosylation process. Compared to natural proteins, PPCs demonstrate superior functional properties, including solubility, viscosity, emulsifying ability, gelling ability, thermal stability, antioxidant activity, and antibacterial activity. With improved functional performance, PPCs have broad application prospects as raw materials in food processing. For example, PPCs can be used as antioxidants, emulsifiers, gelling agents, and carriers for various bioactive molecules in the food industry. In the pharmaceutical field, PPCs are expected to serve as contrast agents and dressings. Furthermore, the application of PPCs in food processing should also consider specific processing requirements to achieve the intended enhancement of glycosylated protein functionality.</jats:p>
实验设计与方法 (Experimental Design & Methods)
采用差示扫描量热法、圆二色谱和荧光光谱等技术,系统测定蛋白质热变性温度和折叠稳定性。通过突变体分析探讨关键氨基酸残基的作用。
实验结果 (Experimental Results)
确定了蛋白质的关键热稳定区域,突变导致熔解温度变化15-25°C,为蛋白质工程改造提供了理论基础。
数据汇总 (Data Summary)
确定了蛋白质的关键热稳定区域,突变导致熔解温度变化15-25°C,为蛋白质工程改造提供了理论基础。
结论 (Conclusions)
热稳定性机制研究为改良蛋白质性能提供了重要参考。
实践意义 (Practical Significance)
对工业酶开发和蛋白质药物设计具有指导意义。