Enzymatic Approaches for Structuring Starch to Improve Functionality.

IF 10.6 1区 农林科学 Q1 FOOD SCIENCE & TECHNOLOGY
Ming Miao, James N BeMiller
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引用次数: 8

Abstract

Starch is one of the most abundant renewable biopolymers in nature and is the main constituent in the human diet and a raw material for the food industry. Native starches are limited in most industrial applications and often tailored by structural modification to enhance desirable attributes, minimize undesirable attributes, or create new attributes. Enzymatic approaches for structuring starch have become of interest to the food industry precisely because the reactions minimize the formation of undesirable by-products and coproducts and are therefore considered environmentally friendly methods for producing clean-label starches with better behavioral characteristics. Starches with improved functionalities for various applications are produced via enzyme hydrolysis and transfer reactions. Use of novel, multifunctional, starch-active enzymes to alter the structures of amylose and/or amylopectin molecules, and thus alter the starch's physiochemical attributes in a predictable and controllable manner, has been explored. This review provides state-of-the-art information on exploiting glycosyl transferases and glycosyl hydrolases for structuring starch to improve its functionalities. The characteristics of starch-active enzymes (including branching enzymes, amylomaltases, GH70 α-transglycosylases, amylosucrases, maltogenic amylases, cyclomaltodextrinases, neopullulanases, and maltooligosaccharide-forming amylases), structure-functionality-driven processing strategies, novel conversion products, and potential industrial applications are discussed.

结构淀粉改善功能的酶促方法。
淀粉是自然界中最丰富的可再生生物聚合物之一,是人类饮食的主要成分和食品工业的原料。原生淀粉在大多数工业应用中是有限的,通常通过结构修改来增强理想属性,最小化不理想属性或创建新属性。用酶来构造淀粉的方法引起了食品工业的兴趣,正是因为这种反应可以最大限度地减少不良副产物和副产物的形成,因此被认为是生产具有更好行为特征的清洁标签淀粉的环保方法。通过酶水解和转移反应生产具有改进功能的淀粉,用于各种应用。利用新型的、多功能的、淀粉活性的酶来改变直链淀粉和/或支链淀粉分子的结构,从而以一种可预测和可控的方式改变淀粉的物理化学属性,已经被探索。本文综述了利用糖基转移酶和糖基水解酶来构建淀粉以提高其功能的最新研究进展。讨论了淀粉活性酶(包括分支酶、淀粉酶、GH70 α-转糖基酶、淀粉蔗糖酶、麦芽原淀粉酶、环麦芽糊精酶、新葡聚糖酶和麦芽糖低聚糖形成淀粉酶)的特性、结构-功能驱动的加工策略、新型转化产品和潜在的工业应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
22.40
自引率
0.80%
发文量
20
审稿时长
>12 weeks
期刊介绍: Since 2010, the Annual Review of Food Science and Technology has been a key source for current developments in the multidisciplinary field. The covered topics span food microbiology, food-borne pathogens, and fermentation; food engineering, chemistry, biochemistry, rheology, and sensory properties; novel ingredients and nutrigenomics; emerging technologies in food processing and preservation; and applications of biotechnology and nanomaterials in food systems.
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