Water Structure in Proteins in Solid State Studied by Near Infrared Spectroscopy

Siraporn Soonthonhut; Alfred A. Christy

doi:10.4028/www.scientific.net/KEM.735.168

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 735Water Structure in Proteins in Solid State Studied...

Water Structure in Proteins in Solid State Studied by Near Infrared Spectroscopy

Abstract:

Water adsorption in proteins is the crucial process of protein folding and structure stabilizing. Adsorption of water on proteins can be evaluated by near-infrared spectroscopy, a useful technique for observing combination frequency of a water molecule. In this work, albumin, lysozyme, and silk, were used as models for α-helix and β-pleated sheet proteins. Their NIR spectra during water adsorption process were measured by using an NIR spectrometer equipped with a transflectance accessory. Moreover, the quantitative adsorption of water was determined by gravimetric technique. The results indicate that, there are five different NIR absorptions arise from the OH combination frequencies of water adsorbed by albumin in the 5300-5100 cm^-¹ region. But there are only four absorptions for lysozyme and silk. The OH combination frequencies arising from water molecules in albumin indicate that it acquires free water molecules (5280 cm^-¹) and adsorbed water molecules through carbonyl-water interactions (5248 and 5160 cm^-¹) and amino-water interactions (5200 and 5120 cm^-¹). Interestingly, there is no indication for the presence of free water molecules in lysozyme and silk. Furthermore, the gravimetric results indicate that the rate of water adsorbed follows the order R_W_._Alb<R_W_._Lys<R_W_._Sil and total mass of water adsorbed per gram solid follows the order W_Alb<W_Lys=W_Sil.

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Key Engineering Materials (Volume 735)

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168-172

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https://doi.org/10.4028/www.scientific.net/KEM.735.168

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Online since:

May 2017

Authors:

Siraporn Soonthonhut, Alfred A. Christy*

Keywords:

Albumin, Lysozyme, Near Infrared Spectroscopy, Silk, Water Adsorption

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