Electromagnetic Fields Effects on the Secondary Structure of Lysozyme and Bioprotective Effectiveness of Trehalose

Advances in Physical Chemistry Pub Date : 2012-08-09 DOI:10.1155/2012/970369

E. Calabrò, S. Magazù

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引用次数: 31

Abstract

FTIR spectroscopy was used to investigate the effects of extremely low frequency (50 Hz) electromagnetic field and of microwaves at 900 MHz on the secondary structure of a typical protein, the lysozyme, evaluating the bioprotective effectiveness of trehalose. Lysozyme in D2O solution (60 mg/ml) was exposed to 50 Hz frequency electromagnetic field at 180 μT. The FTIR spectra indicated an increase of CH2 group at 1921 and 1853 cm−1 after 3 h of exposure. Such effect was not observed after the addition of trehalose (150 mg/mL) at the same exposure conditions. Lysozyme dissolved in D2O at the concentration of 100 mg/mL was exposed up to 4 h to 900 MHz mobile phone microwaves at 25 mA/m. A significant increase in intensity of the amide I vibration band in the secondary structure of the protein was observed after 4 h exposure to microwaves. This effect was inhibited by the presence of trehalose at the concentration of 150 mg/mL. Fourier self-deconvolution spectral analysis of lysozyme in D2O solution after exposure to microwaves revealed an increase in intensity of the conformational components of amide I mode, particularly of β-sheet and turn that can be attributed to disorder and unfolding processes of the protein.

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电磁场对溶菌酶二级结构及海藻糖生物保护效果的影响

利用FTIR光谱研究了极低频(50 Hz)电磁场和900 MHz微波对典型蛋白质溶菌酶二级结构的影响，评价了海藻糖的生物保护效果。将溶菌酶溶液(60 mg/ml)暴露于180 μT的50 Hz频率电磁场中。FTIR光谱显示，暴露3h后CH2基团在1921和1853 cm−1处增加。在相同的暴露条件下，添加海藻糖(150 mg/mL)后，没有观察到这种影响。将溶解在浓度为100 mg/mL的D2O中的溶菌酶在25 mA/m的900 MHz手机微波下暴露4 h。在微波作用4小时后，蛋白质二级结构中酰胺I振动带的强度显著增加。当海藻糖浓度为150 mg/mL时，这种作用被抑制。暴露于微波后的D2O溶液中的溶菌酶的傅里叶自反卷积光谱分析显示，酰胺I模式构象成分的强度增加，特别是β-sheet和turn，这可归因于蛋白质的无序和展开过程。

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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Advances in Physical Chemistry

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