Effects of Temperature on DNA Condensation Detected with Temperature-Changed Ultraviolet Spectrum Method
GONG Hong-ling1, LIU Yan-hui2*, TANG Yan-lin2*, HU Lin2
1. College of Life Science, Guizhou University, Guiyang 550025, China
2. Soft Condensed Matter Lab, College of Physics, Guizhou University, Guiyang 550025, China
Abstract:Recent fluorescent single molecule experiment indicated that temperature can facilitate DNA condensation. In the spermine (spermidine)-DNA condensation system, DNA condensation conformation became more compact and orderly with increasing temperature . In order to detect the temperature effects in DNA condensation system further, a temperature-changed ultraviolet spectrum method is developed. By applying the method to the condensation system mentioned by recent fluorescent single molecule experiment and the DNA in DI water, a conclusion is derived from the absorption value at 260 nm of a condensation system will be reduced, when the corresponding system is further condensed and become compact and orderly. Based on this conclusion, effects of temperature on DNA- cobalt amine compounds used in DNA condensation experiments are detected by using temperature-changed ultraviolet Spectrum method. The results indicate that Hexaammine cobalt(Ⅲ) chloride is similar to spermine and spermidine, the UV absorption value at 260 nm of DNA reduces sharply with the temperature increasing, indicating that the DNA conformation tends to be more compact and orderly. However, for the condensation system wherein the DNA is condensed by trans (ethylenediamine) cobalt(Ⅲ) chloride, trans-dichlorobis (ethylenediamine) cobalt(Ⅲ) chloride and pentaamminechloro cobalt(Ⅲ) chloride, respectively, the UV absorption value at 260 nm of the corresponding condensation. System does not change with temperature monotonously, taking an increased-reduced-increased manner.
龚红玲,刘艳辉,唐延林,胡 林. 基于变温紫外分光光度法研究温度对DNA凝聚过程影响[J]. 光谱学与光谱分析, 2017, 37(06): 1831-1837.
GONG Hong-ling, LIU Yan-hui, TANG Yan-lin, HU Lin. Effects of Temperature on DNA Condensation Detected with Temperature-Changed Ultraviolet Spectrum Method. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2017, 37(06): 1831-1837.
[1] Liu Y, Yan J, Santangelo P J, et al. Journal of Controlled Release, 2016, 234: 1.
[2] Samanta K, Jana P, Bcker S, et al. Chemical Communications, 2016, 52(84): 12446.
[3] Katz A M, Tolokh I S, Pabit S A, et al. Biophysical Journal, 2017, 112(1): 22.
[4] Chopra A, Krishnan S, Simmel F C. Nano Letters, 2016, 16(10): 6683.
[5] Li G Y, Guan R L, Ji L N, et al. Coordination Chemistry Reviews, 2014, 281: 100.
[6] Zinchenko A, Tsumoto K, Murata S, et al. The Journal of Physical Chemistry B, 2014, 118(5): 1256.
[7] Ai-Hua C, Shi-Yong R, Dong Z, et al. Chinese Physics B, 2013, 22(9): 098701.
[8] Yang-Wei J, Shi-Yong R, Lin-Li H, et al. Chinese Physics B, 2015, 24(11): 118701.
[9] Yoshihara C, Shew C Y, Ito T, et al. Biophysical Journal, 2010, 98(7): 1257.
[10] Zhang C, Gong Z, Guttula D, et al. The Journal of Physical Chemistry B, 2012, 116(9): 3031.
[11] Krotova M K, Vasilevskaya V V, Makita N, et al. Physical Review Letters, 2010, 105(12): 128302.
[12] Fu Wenbo, Wang Xiaoling, et, al, J. Am. Chem. Soc., 2006, 128: 15040.
[13] Saito T, Iwaki T, Yoshikawa K. Europhysics Letters, 2005, 71(2): 304.
[14] Chen N, Zinchenko A A, Kidoaki S, et al. Langmuir, 2010, 26(5): 2995.
[15] Mao W, Gao Q, Liu Y, et al. Modern Physics Letters B, 2016, 30: 1650298.
[16] Mao W, Liu Y H, Hu L, et al. Communications in Theoretical Physics, 2016, 65: 639.
