Effect of Thermal Treatment on the Self-Assembly of Wheat Gluten Polypeptide

Liu, Hao; Wang, Jingxuan; Liu, Mei; Zhang, Xia; Liang, Ying; Wang, Jinshui

doi:10.3390/molecules28020834

Cited by 7 publications

(7 citation statements)

References 33 publications

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“…The results indicated a gradual increase in the proportion of aggregates and β-sheet structures, accompanied by a decrease in the proportion of α-helix and random oil structures in the thermally induced formation of AFs gluten . Aggregation signifies a high density of β-sheet, serving as the predominant structure in AFs . Consistent with these findings, Bruun et al observed that cooking wheat gluten or treating it with transglutaminase led to a transition in protein structure from α-helix to β-sheet.…”

Section: Resultsmentioning

confidence: 74%

“…Aggregation signifies a high density of β-sheet, serving as the predominant structure in AFs. 49 Consistent with these findings, Bruun et al 50 observed that cooking wheat gluten or treating it with transglutaminase led to a transition in protein structure from α-helix to β-sheet. The three β-strand-rich structures in AFs glutenin before and after cooking exhibited increases of 2.50, 4.11, and 3.42% in aggregation, β-sheet, and antiparallel β-sheet, respectively.…”

Section: Average Size and ζ Potential Measurementsmentioning

confidence: 77%

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Amyloid-like Aggregation of Wheat Gluten and Its Components during Cooking: Mechanisms and Structural Characterization

Liang,

Liu,

Jie

et al. 2024

J. Agric. Food Chem.

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Amyloid-like aggregation widely occurs during the processing and production of natural proteins, with evidence indicating its presence following the thermal processing of wheat gluten. However, significant gaps remain in understanding the underlying fibrillation mechanisms and structural polymorphisms. In this study, the amyloid-like aggregation behavior of wheat gluten and its components (glutenin and gliadin) during cooking was systematically analyzed through physicochemical assessment and structural characterization. The presence of amyloid-like fibrils (AFs) was confirmed using X-ray diffraction and Congo red staining, while Thioflavin T fluorescence revealed different patterns and rates of AFs growth among wheat gluten, glutenin, and gliadin. AFs in gliadin exhibited linear growth curves, while those in gluten and glutenin showed S-shaped curves, with the shortest lag phase and fastest growth rate (t 1/2 = 2.11 min) observed in glutenin. Molecular weight analyses revealed AFs primarily in the 10− 15 kDa range, shifting to higher weights over time. Glutenin-derived AFs had the smallest ζ-potential value (−19.5 mV) and the most significant size increase post cooking (approximately 400 nm). AFs in gluten involve interchain reorganization, hydrophobic interactions, and conformational transitions, leading to additional cross β-sheets. Atomic force microscopy depicted varying fibril structures during cooking, notably longer, taller, and stiffer AFs from glutenin.

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Section: Resultsmentioning

confidence: 74%

Section: Average Size and ζ Potential Measurementsmentioning

confidence: 77%

Amyloid-like Aggregation of Wheat Gluten and Its Components during Cooking: Mechanisms and Structural Characterization

Liang,

Liu,

Jie

et al. 2024

J. Agric. Food Chem.

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“…However, CLSM analysis of the gluten network structure at the periphery of the pores revealed that the UT treatment led to a more prominent aggregation of the gluten network and significantly higher ( P < 0.05 ) gluten network junction point than the CMT treatment (Table S1). Increasing drying temperature led to the denaturation and aggregation of higher levels of gluten into larger polymeric proteins, resulting in a more compact and continuous gluten network structure stabilised by hydrogen and disulphide bonds (Liu et al ., 2023). In contrast, the larger pores in the cross section of the UT samples than the CMT samples might be attributed to the UT‐mediated increase in the aggregation of the gluten network.…”

Section: Resultsmentioning

confidence: 99%

High and ultra‐high temperature drying of fermented dried noodles: effect on noodle quality and starch properties

Wang,

He,

Liu

et al. 2023

Int J of Food Sci Tech

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SummaryAlthough dried noodles have been industrialized for many years, some technical bottlenecks, such as dense cross‐section structure, poor rehydration ability, and the lack of nutritional and flavor substances, still need to be addressed. Fermentation has been used to produce dried noodles to impart a porous structure and microbial metabolites, improving their rehydration properties and the nutritional and flavor quality of dried noodles. However, the current commercially fermented dried noodles exhibit some issues, such as high breakage rate, rough surface, and sticky textural, that need to be solved. Drying at high (HT) and ultra‐high temperatures (UT) has been shown to improve the quality of dried pasta or noodles. However, HT and UT drying is not currently used to produce fermented dried noodles. This article investigates the changes in the quality and starch physicochemical properties of fermented dried noodles with high (HM), medium (MM), or low product moisture content (LM) dried at HT or UT. The results showed that the UT‐LM condition most prominently improved the noodle quality, significantly reduced the cooking loss rate (5.19%) and significantly increased the water absorption rate (191.41%) of the noodles, and improved the rehydration of noodles. In addition, the cross‐linking of the gluten network was analyzed using confocal laser scanning microscopy and the AngioTool software. It was found that the UT treatment promoted the cross‐linking of the gluten network, and the highest number of cross‐linking points (976) was achieved under the UT‐LM condition. The tight gluten network reduces the amylose leaching from the noodles, giving the noodles a denser surface structure and lower adhesiveness. In conclusion, UT‐LM drying could be used as an effective drying condition to improve the quality of fermented dried noodles.

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“…As a result, it contributes to narrowing the optical band gap of FCNMs, followed by the emission in the far red or near IR region with high uorescence quantum yield. [69][70][71][72][73][74] Other atoms like selenium, boron, and uorine are also utilized for shiing the wavelength to the red region aer doping at edges on the surface of the organic precursor. The band gap is opened by the incorporation of these heavy atoms into the carbon core.…”

Section: Crucial Aspects For the Synthesis Of Red-emitting Fcnmsmentioning

confidence: 99%

Comprehensive advances in the synthesis, fluorescence mechanism and multifunctional applications of red-emitting carbon nanomaterials

Mandal,

Mishra,

Singh

2023

Nanoscale Adv.

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Effect of Thermal Treatment on the Self-Assembly of Wheat Gluten Polypeptide

Cited by 7 publications

References 33 publications

Amyloid-like Aggregation of Wheat Gluten and Its Components during Cooking: Mechanisms and Structural Characterization

Amyloid-like Aggregation of Wheat Gluten and Its Components during Cooking: Mechanisms and Structural Characterization

High and ultra‐high temperature drying of fermented dried noodles: effect on noodle quality and starch properties

Comprehensive advances in the synthesis, fluorescence mechanism and multifunctional applications of red-emitting carbon nanomaterials

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