An Orthogonal Method to Study the Thermal Stability of Secondary Structure of Protein

doi:10.13560/j.cnki.biotech.bull.1985.2020-0543

Abstract

Abstract:

The study of protein thermal stabilization is a critical step in analyzing the higher structure of proteins,and developing protein function and new drugs,and thus is an important concern in the analysis of its structure. At present,the circular dichroism（CD）temperature ramping is a frequently used method to study the protein thermal stabilization. However,traditional method focuses on a single-wavelength temperature ramping CD curve to fit the Tm values,but the information by it is limited and how to select the single-wavelength point is still a controversial issue. This experiment developed and optimized an orthogonal method for the thermal stability analysis of protein secondary structure. We selected bovine serum protein and hemoglobin as research objects,and investigated the process of protein conformation changing with temperature by the temperature-ramping of full range CD spectrum in the range of 180-260 nm. The resules showed that the protein melting temperature（Tm value）of the thermal denaturation was not affected by the concentration when the absorbance was in the proper range. Also,we repeated the experiment by single-wavelength of 180-260 nm and the results showed that the Tm values measured by single-wavelength method（except the endpoint and intersection）and the full spectrum orthogonal method was consistent,indicating that the two methods on the determination of Tm values were reliable. In conclusion,the full spectrum orthogonal method can not only used to determine the temperature curve of each wavelength of the CD spectrum in the selected range,but also to observe the detailed protein thermal denaturation process by the CD spectrum analysis at every temperature points,while the single-wavelength method does not record the changes of protein conformation under the same experimental time.

Key words: circular dichroism, thermal denaturation, temperature-ramping, protein

CHEN Zhong, LU Xing-yu. An Orthogonal Method to Study the Thermal Stability of Secondary Structure of Protein[J]. Biotechnology Bulletin, 2021, 37(2): 236-245.

Figures/Tables 12

References 18

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蛋白构象	电子跃迁形式	负吸收带/nm	正吸收带/nm
α-螺旋（α-helix）	n→π* π→π*	222-208	192
β-折叠（β-sheet）	n→π* π→π*	217-218	185-200
β-转角（β-turn）	n→π* π→π*	220-230	200-205
P2结构（poly（L-proline）type II）	π→π*	190-205	220
无规卷曲（random coil）	π→π*	200	218

蛋白构象	电子跃迁形式	负吸收带/nm	正吸收带/nm
α-螺旋（α-helix）	n→π* π→π*	222-208	192
β-折叠（β-sheet）	n→π* π→π*	217-218	185-200
β-转角（β-turn）	n→π* π→π*	220-230	200-205
P2结构（poly（L-proline）type II）	π→π*	190-205	220
无规卷曲（random coil）	π→π*	200	218

Wavelength	Fitting Function	Tm（x0,x1）
192 nm （极值点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = 50.036170 +/- 0.175916;At = 14.204700 +/- 0.579455 x0 = 65.962690 +/- 0.370525;w = 9.035970 +/- 0.296864	65.962690 +/- 0.370525
208 nm （极值点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = -29.200821 +/- 0.069834;At = -16.976313 +/- 0.200842 x0 = 66.694838 +/- 0.375953;w = 8.872889 +/- 0.315981	66.694838 +/- 0.375953
222 nm （极值点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = -28.557619 +/- 0.066161;At = -12.848438 +/- 0.197279 x0 = 65.167471 +/- 0.293993;w = 10.044699 +/- 0.247323	65.167471 +/- 0.293993
235 nm （任意点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = -11.088690 +/- 0.012442;At = -6.796280 +/- 0.038061 x0 = 65.810820 +/- 0.203645;w = 8.997813 +/- 0.167840	65.810820 +/- 0.203645
260 nm （端点）	Ab+（（Am-Ab）/（1+exp（（x0-x）/w0）））+（（At-Am）/（1+exp（（x1-x）/w1））） Ab = -2.099029 +/- 0.018708;Am = -2.048087 +/- 0.028690;At = -1.666950 +/- 0.224199 x0 = 54.123624 +/- 1.257872;x1 = 80.424220 +/- 20.694954;w0 = 0.841862 +/- 1.174727 w1 = 17.153602 +/- 7.784341	54.123624 +/- 1.257872 80.424220 +/- 20.694954
203 nm （交叉点）	a.exp（（-（x-x0）^2）/（2.b^2））+ d;a = 1.567304 +/- 0.078462;b = 15.396921 +/- 0.948422 x0 = 52.170676 +/- 0.314500;d = -13.325323 +/- 0.085624	52.170676 +/- 0.314500

Wavelength	Fitting Function	Tm（x0,x1）
192 nm （极值点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = 50.036170 +/- 0.175916;At = 14.204700 +/- 0.579455 x0 = 65.962690 +/- 0.370525;w = 9.035970 +/- 0.296864	65.962690 +/- 0.370525
208 nm （极值点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = -29.200821 +/- 0.069834;At = -16.976313 +/- 0.200842 x0 = 66.694838 +/- 0.375953;w = 8.872889 +/- 0.315981	66.694838 +/- 0.375953
222 nm （极值点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = -28.557619 +/- 0.066161;At = -12.848438 +/- 0.197279 x0 = 65.167471 +/- 0.293993;w = 10.044699 +/- 0.247323	65.167471 +/- 0.293993
235 nm （任意点）	Ab+（（At-Ab）/（1+exp（（x0-x）/w）））;Ab = -11.088690 +/- 0.012442;At = -6.796280 +/- 0.038061 x0 = 65.810820 +/- 0.203645;w = 8.997813 +/- 0.167840	65.810820 +/- 0.203645
260 nm （端点）	Ab+（（Am-Ab）/（1+exp（（x0-x）/w0）））+（（At-Am）/（1+exp（（x1-x）/w1））） Ab = -2.099029 +/- 0.018708;Am = -2.048087 +/- 0.028690;At = -1.666950 +/- 0.224199 x0 = 54.123624 +/- 1.257872;x1 = 80.424220 +/- 20.694954;w0 = 0.841862 +/- 1.174727 w1 = 17.153602 +/- 7.784341	54.123624 +/- 1.257872 80.424220 +/- 20.694954
203 nm （交叉点）	a.exp（（-（x-x0）^2）/（2.b^2））+ d;a = 1.567304 +/- 0.078462;b = 15.396921 +/- 0.948422 x0 = 52.170676 +/- 0.314500;d = -13.325323 +/- 0.085624	52.170676 +/- 0.314500