蜂蜜诱导小麦-黑麦酸面团中面筋的分子结构和微观结构发生变化。

IF 1.8 4区 农林科学 Q3 CHEMISTRY, APPLIED
Julia Nutter, Amelia Ivone Saiz
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引用次数: 0

摘要

化学氧化剂和氧化还原酶历来被用来提高烘焙食品的质量。然而,消费者现在寻求天然、无污染的配料,避免使用那些听起来像化学名称的配料。蜂蜜是葡萄糖氧化酶(GOX)的天然来源,是烘焙用纯化酶的一种很有前途的替代品。本研究旨在评估蜂蜜对不同乳酸菌(LAB)菌株发酵的酸面团中面筋蛋白的分子结构和微观结构的影响。研究人员制备了四种小麦-黑麦(1:1)酸面团,每种酸面团都添加了蜂蜜,并接种了不同的 LAB 菌株。此外,还在相同条件下制备了两种未接种的面团,一种添加了蜂蜜(蜂蜜面团),另一种未添加(对照面团)。电子顺磁共振光谱显示蜂蜜溶液中存在过氧化氢,表明它是 GOX 的活性来源。拉曼光谱显示,蜂蜜的添加改变了面筋的分子结构,增加了无规线圈的比例,牺牲了 α 螺旋结构。这种变化可能是由于蜂蜜糖和谷蛋白在该体系中竞争水分子所致。此外,与对照面团相比,蜂蜜导致面筋的游离巯基含量下降,这表明二硫交联点增加。在扫描电子显微镜显微照片中可以观察到这些增强的蛋白质间相互作用,表现为由相互连接的链和纤维组成的粗面筋网络。所有酵母菌株都表现出最佳的酸化(pH
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Honey induces changes in the molecular structure and microstructure of gluten in wheat-rye sourdoughs.

Chemical oxidizers and redox enzymes have traditionally been used to enhance the quality of baked goods. However, consumers now seek natural and clean-label ingredients, avoiding those with chemical-sounding names. Honey, a natural source of glucose oxidase (GOX), represents a promising alternative to purified enzymes for baking purposes. This study aimed to evaluate the effect of honey on the molecular structure and microstructure of gluten proteins in sourdough fermented by different lactic acid bacteria (LAB) strains. Four wheat-rye (1:1) sourdoughs were prepared, each supplemented with honey and inoculated with a different LAB strain. Additionally, two uninoculated doughs, one with honey (honey dough) and the other without (control dough), were prepared under identical conditions. Electronic paramagnetic resonance spectroscopy revealed the presence of hydrogen peroxide in honey solutions, indicating its role as an active source of GOX. Raman spectroscopy showed that honey addition altered the molecular structure of gluten by increasing the proportion of random coils at the expense of α-helix structures. This change is likely attributed to the competition between honey sugars and gluten proteins for water molecules in this system. Moreover, honey led to a decrease in the free sulfhydryl content of gluten compared to the control dough, suggesting an increase in disulfide crosslinking points. These enhanced protein-protein interactions were observed in scanning electron microscopy micrographs as a coarse gluten network composed of interconnected strands and fibrils. All LAB strains exhibited optimal acidification (pH < 4.3) in honey-supplemented sourdoughs, promoting the hydrolysis of gluten proteins into smaller fragments. Overall, honey-supplemented sourdoughs showed a gradual increase in the β-sheet content while decreasing the proportion of random coils over time. This trend suggests that the polypeptide fragments interacted through interchain hydrogen bonds, leading to a more ordered structure, which likely contributes to providing dough with good baking aptitude.

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来源期刊
Food Science and Technology International
Food Science and Technology International 工程技术-食品科技
CiteScore
5.80
自引率
4.30%
发文量
63
审稿时长
18-36 weeks
期刊介绍: Food Science and Technology International (FSTI) shares knowledge from leading researchers of food science and technology. Covers food processing and engineering, food safety and preservation, food biotechnology, and physical, chemical and sensory properties of foods. This journal is a member of the Committee on Publication Ethics (COPE).
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