Understanding the function of water during the gelation of globular proteins by temperature-dependent near infrared spectroscopy

Ma, Li; Cui, Xiaoyu; Cai, Wensheng; Shao, Xueguang

doi:10.1039/c8cp01431k

Cited by 45 publications

(28 citation statements)

References 57 publications

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“…Similarly to perturbation by light, intentional perturbation by temperature is often used in aquaphotomics as it is possible to use temperature dependent NIR spectra to obtain structural and quantitative information of the aqueous systems [42,43,49,50]. For instance, temperature perturbation was employed to study structural changes of ovalbumin as a model protein in aqueous solutions [51]. Two-dimensional correlation NIR spectroscopy and Gaussian fitting were adopted to investigate the variation of different water species and the sequences of the changes in the structure of protein during gelation.…”

Section: Water Spectrum As a Source Of Informationmentioning

confidence: 99%

“…In a study of prion protein isoforms [47], aquaphotomics analysis of Mn and Cu prion isoforms in water solutions revealed that while binding of copper results in increased protein stability in water, the binding of manganese resulted in less stability—which led to fibril formation, responsible of neurodegenerative disease. The fact that the entire process of protein structural changes in aqueous systems can be monitored indirectly through the water absorbance pattern of the protein solution, was demonstrated in a study of amyloid protein—another protein involved in pathogenesis of neurodegenerative diseases [71]—as well as ovalbumin [51].…”

Section: Aquaphotomics—innovative Knowledge Leads To Innovative Apmentioning

confidence: 99%

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Aquaphotomics—From Innovative Knowledge to Integrative Platform in Science and Technology

Munćan

Tsenkova

2019

Molecules

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Aquaphotomics is a young scientific discipline based on innovative knowledge of water molecular network, which as an intrinsic part of every aqueous system is being shaped by all of its components and the properties of the environment. With a high capacity for hydrogen bonding, water molecules are extremely sensitive to any changes the system undergoes. In highly aqueous systems—especially biological—water is the most abundant molecule. Minute changes in system elements or surroundings affect multitude of water molecules, causing rearrangements of water molecular network. Using light of various frequencies as a probe, the specifics of water structure can be extracted from the water spectrum, indirectly providing information about all the internal and external elements influencing the system. The water spectral pattern hence becomes an integrative descriptor of the system state. Aquaphotomics and the new knowledge of water originated from the field of near infrared spectroscopy. This technique resulted in significant findings about water structure-function relationships in various systems contributing to a better understanding of basic life phenomena. From this foundation, aquaphotomics started integration with other disciplines into systematized science from which a variety of applications ensued. This review will present the basics of this emerging science and its technological potential.

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Section: Water Spectrum As a Source Of Informationmentioning

confidence: 99%

Section: Aquaphotomics—innovative Knowledge Leads To Innovative Apmentioning

confidence: 99%

Aquaphotomics—From Innovative Knowledge to Integrative Platform in Science and Technology

Munćan

Tsenkova

2019

Molecules

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“…Structural changes during protein gelation were studied by temperature-dependent NIR spectroscopy using ovalbumin (OVA) aqueous solution. 6 The spectra of OVA solution were recorded at temperatures from 30 to 90 C with a step of 5 C. Using CWT to enhance the spectral resolution of the spectra, the peaks corresponding to a-helix and b-sheet can be identified. The opposite trend of the variation in the spectral intensity gives a clear indication for the transformation from a-helix to b-sheet.…”

Section: Development and Resultsmentioning

confidence: 99%

Temperature-dependent near-infrared spectroscopy for studying the interactions in protein aqueous solutions

et al. 2019

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Temperature-dependent near-infrared spectroscopy has been developed for studying quantitative and structural analysis, as well as the molecular interactions. Taking the advantage of the temperature effect on hydrogen bonding, the technique has shown its potential in analyzing the interactions in aqueous solutions. In our recent studies, the structural changes in homo-oligopeptides K5 (penta-lysine), D5 (penta-aspartic acid), and protein (ovalbumin) aqueous solutions were studied by temperature-dependent near-infrared spectroscopy. The thermodynamics and their interaction with water were analyzed with the help of the chemometric methods including continuous wavelet transform, independent component analysis, two-dimensional (2D) correlation analysis, and Gaussian fitting. The results show that the oligopeptide in aqueous solution improves the thermal stability of the water species, and K5 has stronger interaction with water than D5. In the gelation of ovalbumin, the change of the water species with two hydrogen bonds (S2) follows the same phases as the protein. S2 maintains the stability of the protein in native and molten globule states, and the weakening of the hydrogen bond in S2 by high temperature results in the destruction of the hydration shell and makes the ovalbumin clusters form a gel structure.

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“…Upon heating, native globular molecules in aqueous solution unfold and expose the hydrophobic core facilitating polypeptide-polypeptide and polypeptide-water interactions [29]. This process is initiated by diminishing stability of hydrogen bonds in the hydration shell of the protein, which enables the rearrangement of chain segments to balance a multitude of attractive and repulsive forces [30]. At high enough concentrations, gels are formed upon cooling via disulfide, ionic, hydrophobic and hydrogen bonds [31].…”

Section: Effect Of Heatingmentioning

confidence: 99%

Molecular Functionality of Plant Proteins from Low- to High-Solid Systems with Ligand and Co-Solute

Paramita¹,

Panyoyai

Kasapis

2020

IJMS

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In the food industry, proteins are regarded as multifunctional systems whose bioactive hetero-polymeric properties are affected by physicochemical interactions with the surrounding components in formulations. Due to their nutritional value, plant proteins are increasingly considered by the new product developer to provide three-dimensional assemblies of required structure, texture, solubility and interfacial/bulk stability with physical, chemical or enzymatic treatment. This molecular flexibility allows them to form systems for the preservation of fresh food, retention of good nutrition and interaction with a range of microconstituents. While, animal- and milk-based proteins have been widely discussed in the literature, the role of plant proteins in the development of functional foods with enhanced nutritional profile and targeted physiological effects can be further explored. This review aims to look into the molecular functionality of plant proteins in relation to the transport of bioactive ingredients and interaction with other ligands and proteins. In doing so, it will consider preparations from low- to high-solids and the effect of structural transformation via gelation, phase separation and vitrification on protein functionality as a delivery vehicle or heterologous complex. Applications for the design of novel functional foods and nutraceuticals will also be discussed.

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Understanding the function of water during the gelation of globular proteins by temperature-dependent near infrared spectroscopy

Cited by 45 publications

References 57 publications

Aquaphotomics—From Innovative Knowledge to Integrative Platform in Science and Technology

Aquaphotomics—From Innovative Knowledge to Integrative Platform in Science and Technology

Temperature-dependent near-infrared spectroscopy for studying the interactions in protein aqueous solutions

Molecular Functionality of Plant Proteins from Low- to High-Solid Systems with Ligand and Co-Solute

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