Abstract:Trypsin was treated by high pressure technology, and its spatial structure was changed, the relationship between structural changes and trypsin activity was investigated. The secondary structure change of trypsin after pressure treatment was observed by Fourier transform infrared spectroscopy(FTIR). Moreover its tertiary structure change was observed by fluorescence spectroscopy; and its activity was tested using Folin phenol method. The results showed that, compared with the untreated(0.1 MPa), trypsin activity change was significant(p<0.05) under different pressure(100~600 MPa) treatment at 37 ℃ for 20 min. After treated with 300 MPa, its activity was 0.386 times higher than the untreated. Secondary structure of trypsin was analysed using FTIR, and the peak area ratio of α-helix and β-turn in secondary structure was the maximum(2.749);Endogenous fluorescence spectra intensity was the maximum (1 353) at excitation wavelength 295 nm, and was 4 262 at excitation wavelength 280 nm; exogenous fluorescent spectra intensity was 2 022 at excitation wavelength 228 nm, all these change was remarkable(p<0.05)comparing with the untreated. Therefore, ultrahigh pressure processing influence on the spatial structure of trypsin and induce enzyme activity change. Trypsin activity is relate to the peak area ratio of α-helix and β-turn and the exposure degree of Trp and other hydrophobic a mino acid residues and Tyr.
Key words:Ultra high static pressure;Trypsin;Enzyme activity;Infrared spectroscopy;Fluorescence spectroscopy
刘 平,胡志和*,吴子健,薛 璐,王凤玲 . 超高压引发胰蛋白构象变化与酶活性间的关系 [J]. 光谱学与光谱分析, 2015, 35(05): 1335-1339.
LIU Ping, HU Zhi-he*, WU Zi-jian, XUE Lu, WANG Feng-ling . Relationship between the Trypsin Activity and Conformational Change Caused by Ultra High Static Pressure . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2015, 35(05): 1335-1339.
[1] Fuchise T,Kishimura H,Sekizaki H,et al. Food Chemistry(食品化学),2009,116(3):611. [2] ZHANG Zhao-qin,LIU Wei,LIU Jun-ping,et al(张兆琴,刘 伟,刘军平,等). Food Science and Technology(食品工业科技),2013,34(7):102. [3] HUANG Zhuo-lie,CHEN Xiao-li,WU Guang-hong,et al(黄卓烈,陈小丽,巫光宏,等). Chinese Journal of Biochemical Pharmaceutics(中国生化药物杂志),2009,30(4):230. [4] ZHANG Yu(张 瑜). Jiangnan University,2012. [5] Kangcheng R, Reinhard L, Filip M, et al. Eur. J. Biochem., 1999, 265: 79. [6] TAO Min,PAN Jian,ZHANG Wen-cheng,et al(陶 敏, 潘 见, 张文成, 等). Food Science(食品科学),2013,34(15):162. [7] Valerie L P,Balny C. Innovative Food Science and Emerging Technologies,2002,3(3):209. [8] Somkuti J,Smeller L. Biophysical Chemistry,2013,183: 19. [9] Knorr D,Heinz V,Buckow R. Biochimica et Biophysica Acta (BBA)-Proteins and Proteomics,2006,1764(3):619. [10] Hermodson M A, Ericsson L H, Neurath K A. Biochemistry,1973,12:3146. [11] Burstein E A,Vedenkina N S,Ivkova M N. Photochemistry and Photobiology,1973,18(4):263. [12] Lim V I. Journal of Molecular Biology,1974,88: 857. [13] WU Yun-na,SHA Li-na,GE Ri-letu(乌云娜,莎丽娜,格日勒图). Food Science and Technology(食品工业科技),2012, 3:52.
