|
|
|
|
|
|
Spectroscopic Method Combined with Molecular Dynamics Simulation to Study the Action Mechanism of Ozone on Myoglobin Structure |
LÜ Fei, ZHANG Jing, CHEN Xin-lu, LIU Jian-hua, DING Yu-ting* |
Ocean College, Zhejiang University of Technology, Hangzhou 310014, China |
|
|
Abstract Ozone (O3) has been widely used for reducing bacteria in fresh meat. However, O3 treatment has a negative impact on the red meat color, and the action mechanism of O3 on red meat color is still lack of research. The existence of myoglobin (Mb) is the basis for determining the key factors of red meat color. Therefore, the spectroscopic characteristics of myoglobin (Mb) under O3 were analyzed by UV-Vis absorption spectroscopy, fluorescence spectroscopy and circular dichroism (CD) spectroscopy. Moreover, the protein oxidation characteristics and molecular dynamics simulation were used to explore the effect and mechanism of O3 on Mb molecule. The results of spectroscopic studies show that the O3 treatment can decrease the intensity peak of the iron porphyrin ring at about 412 nm and the characteristic peak of oxygenated myoglobin (OMb) near 540 and 580 nm in the ultraviolet-visible spectrum of Mb. The characteristic peak of the iron porphyrin ring blue-shifted. It also caused changes in the endogenous fluorescence and synchronous fluorescence spectra of Mb measured at a fixed excitation wavelength of 280 nm, indicating that the fluorescence intensity of Mb was reduced by O3 and the fluorescence peak intensity contributed by the iron porphyrin group was increased and it also caused a blue shift in the characteristic peak of the fluorescence spectrum of the tyrosine residue. The characteristic peak intensity of the three-dimensional fluorescence spectrum decreased and the light scattering intensity increased. It was concluded that O3 would cause the protein oxidation of Mb, the exposure of hydrophobic group of the amino acid residues in Mb and the conformation change of the protein. The CD spectroscopy results show that the longer the contact time between O3 and myoglobin, the more obvious the change of protein secondary structure, resulting in a decrease in the content of α-helix and an increase in random curl. Combined with the chemical detection on the content and characteristics of Mb, it shows that O3 caused the decrease of OMb content, and the increase of MMb, carbonyl and sulfhydryl content, indicating that O3 treatments could lead to the protein oxidation. Moreover, O3 treatments increased the hydrophobicity of protein surface, indicating it resulted in the polarity change of the microenvironment of the protein system. Molecular dynamics simulation results show that O3 can increase the RMSD value of Mb peptide chain, affect the stability of Mb peptide chain, and weaken the interaction between porphyrin ring and Mb peptide chain. The change in RMSF value Mb peptide chain discovered that amino acid residues of Mb near the active pocket changed obviously; Molecular dynamics simulations of protein structural changes were consistent with the results of spectroscopic experiments, namely, the alpha-helix in Mb decreased and the irregular curl increased after O3 treatment. In conclusion, O3 treatment could interact with the residues of Mb, led to the changes in the secondary structure and the hydrophobicity of Mb, and brought on the oxidation of protein and the exposure of iron porphyrin ring, therefore resulting in the change of red meat color. This study can provide theoretical basis for the color protection of red meats.
|
Received: 2018-09-01
Accepted: 2019-02-16
|
|
Corresponding Authors:
DING Yu-ting
E-mail: dingyt@zjut.edu.cn
|
|
[1] Suman S P, Joseph P. Annual Review of Food Science & Technology, 2013, 4(1): 79.
[2] Priyanka B S, Rastogi N K, Tiwari B K. Opportunities and Challenges in the Application of Ozone in Food Processing, 2014.
[3] Ibanoglu S, Ibanoglu E, Uzun H. Journal of Biotechnology, 2016, 231: S64.
[4] Bekhit E D A, Morton J D, Bhat Z F. Meat Color: Factors Affecting Color Stability, 2018.
[5] HAO Shu-xian,HE Jun-yan,LI Lai-hao(郝淑贤,何俊燕,李来好). Food Science(食品科学), 2013, 34(13): 50.
[6] Tang J, Faustman C, Hoagland T A. Journal of Food Science, 2004, 69(9): C717.
[7] Koutina G, Jongberg S, Skibsted L H. Journal of Agricultural & Food Chemistry, 2012, 60(38): 9737.
[8] Chelh I, Gatellier P, Sante Lhoutellier V. Meat Science, 2006, 74(4): 681.
[9] ZHOU Hua-wei,CAO Hong-yu,TANG Qian(周华伟,曹洪玉,唐 乾). Acta Chimica Sinica(化学学报), 2011,(13): 1559.
[10] TANG Qian,ZHANG Yue,CAO Hong-yu(唐 乾,张 越,曹洪玉). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2015,35(7): 1967.
[11] GAO Yuan-yuan,JIN Xing,DING Jun(高园园,金 星,丁 军). Food Science(食品科学), 2012,(21): 11.
[12] Tang L, Li S, Bi H. Food Chemistry, 2016, 196: 550.
[13] MA Jun-yan,MA Jing,ZHENG Xue-fang(马君燕,马 静,郑学仿). Chinese Journal of Analytical Chemistry(分析化学), 2008,(4): 454.
[14] Bhowmik D, Kumar G S. Journal of Biomolecular Structure & Dynamics, 2016, 35(6): 1260.
[15] Attri P, Jha I, Choi E H. International Journal of Biological Macromolecules, 2014, 69(8): 114.
[16] YUAN Kai,ZHANG Long,GU Dong-chen(袁 凯,张 龙,谷东陈). Food Science(食品科学), 2018, 39(5): 329. |
[1] |
HAN Xue1, 2, LIU Hai1, 2, LIU Jia-wei3, WU Ming-kai1, 2*. Rapid Identification of Inorganic Elements in Understory Soils in
Different Regions of Guizhou Province by X-Ray
Fluorescence Spectrometry[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 225-229. |
[2] |
XU Rong1, AO Dong-mei2*, LI Man-tian1, 2, LIU Sai1, GUO Kun1, HU Ying2, YANG Chun-mei2, XU Chang-qing1. Study on Traditional Chinese Medicine of Lonicera L. Based on Infrared Spectroscopy and Cluster Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3518-3523. |
[3] |
ZHANG Xiao-dan1, 2, LIU Li-li1*, YU Ying1, CHENG Wei-wei1, XU Bao-cheng1, HE Jia-liang1, CHEN Shu-xing1, 2. Activation of Epigallocatechin Gallate on Alcohol Dehydrogenase:
Multispectroscopy and Molecular Docking Methods[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3622-3628. |
[4] |
WANG Peng1, GAO Yong-bao1*, KOU Shao-lei1, MEN Qian-ni1, ZHANG Min1, HE Tao1, YAO Wei2, GAO Rui1, GUO Wen-di1, LIU Chang-rui1. Multi-Objective Optimization of AAS Conditions for Determination of Gold Element Based on Gray Correlation Degree-RSM Model[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(10): 3117-3124. |
[5] |
LIU Pan1, 2, 3, DU Mi-fang1*, LI Bin1, LI Jing-bin1, ZENG Lei1, LIU Guo-yuan1, ZHANG Xin-yao1, 4, ZHA Xiao-qin1, 4. Determination of Trace Tellurium Content in Aluminium Alloy by
Inductively Coupled Plasma-Atomic Emission Spectrometry Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(10): 3125-3131. |
[6] |
LIU Wen-bo, LIU Jin, HAN Tong-shuai*, GE Qing, LIU Rong. Simulation of the Effect of Dermal Thickness on Non-Invasive Blood Glucose Measurement by Near-Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2699-2704. |
[7] |
LI Chen-xi1, SUN Ze-yu1, 2, ZHAO Yu2*, YIN Li-hui2, CHEN Wen-liang1, 3, LIU Rong1, 3, XU Ke-xin1, 3. The Research Progress of Two-Dimensional Correlation Spectroscopy and Its Application in Protein Substances Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 1993-2001. |
[8] |
TANG Yan1, YANG Yun-fan1, HU Jian-bo1, 2, ZHANG Hang2, LIU Yong-gang3*, LIU Qiang-qiang4. Study on the Kinetic Process and Spectral Properties of the Binding of Warfarin to Human Serum Protein[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2099-2104. |
[9] |
WANG Bin1, 2, ZHENG Shao-feng2, GAN Jiu-lin1, LIU Shu3, LI Wei-cai2, YANG Zhong-min1, SONG Wu-yuan4*. Plastic Reference Material (PRM) Combined With Partial Least Square (PLS) in Laser-Induced Breakdown Spectroscopy (LIBS) in the Field of Quantitative Elemental Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2124-2131. |
[10] |
WANG Jie1, 2, 3, LIU Wen-qing1, 2, 4, ZHANG Tian-shu1, XIA Jian-dong5, DENG Wei5, HU Wen-jie5. Collaborative Observation of Vertical Structures of Ozone and Aerosol in a Dust Episode Based on Lidar[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2258-2265. |
[11] |
HOU Qian-yi1, 2, DONG Zhuang-zhuang1, 2, YUAN Hong-xia1, 2*, LI Qing-shan1, 2*. A Study of the Mechanism of Binding Between Quercetin and CAV-1 Based on Molecular Simulation, Bio-Layer Interferometry and
Multi-Spectroscopy Methods[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 890-896. |
[12] |
WU Lei1, LI Ling-yun2, PENG Yong-zhen1*. Rapid Determination of Trace Elements in Water by Total Reflection
X-Ray Fluorescence Spectrometry Using Direct Sampling[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 990-996. |
[13] |
LI Wen, CHEN Yin-yin*, LUO Xue-ke, HE Na. Research on Testing NH3-N and COD in Water Quality Based on
Continuous Spectroscopy Method[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 254-259. |
[14] |
YANG Kun, CHEN Lei*, CHENG Fan-chong, PEI Huan, LIU Gui-ming, WANG Bao-huai, ZENG Wen. Emission Spectroscopy Diagnosis of Air Gliding Arc Plasma Under
Atmospheric Pressure Condition[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(10): 3006-3011. |
[15] |
HU Xuan1, CHENG Zi-hui1*, ZHANG Shu-chao2, SHI Lei2. Matrix Separation-Determination of Rare Earth Oxides in Bauxite by
Inductively Coupled Plasma-Atomic Emission Spectrometry[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(10): 3130-3134. |
|
|
|
|