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DNA寡核苷酸中能量转移的序列依赖性。

Sequence dependence of energy transfer in DNA oligonucleotides.

作者信息

Xu D G, Nordlund T M

机构信息

Department of Physics, University of Alabama at Birmingham, Birmingham, Alabama 35294-1170, USA.

出版信息

Biophys J. 2000 Feb;78(2):1042-58. doi: 10.1016/S0006-3495(00)76663-X.

DOI:10.1016/S0006-3495(00)76663-X
PMID:10653818
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1300708/
Abstract

The sequence, temperature, concentration, and solvent dependence of singlet energy transfer from normal DNA bases to the 2-aminopurine base in synthesized DNA oligomers were investigated by optical spectroscopy. Transfer was shown directly by a variable fluorescence excitation band at 260-280 nm. Adenine (A) is the most efficient energy donor by an order of magnitude. Stacks of A adjacent to 2AP act as an antenna for 2AP excitation. An interposed G, C, or T base between A and 2AP effectively blocks transfer from A to 2AP. Base stacking facilitates transfer, while base pairing reduces energy transfer slightly. The efficiency is differentially temperature dependent in single- and double-stranded oligomers and is highest below 0 degrees C in samples measured. An efficiency transition occurs well below the melting transition of a double-stranded decamer. The transfer efficiency in the duplex decamer d(CTGA[2AP]TTCAG)(2) is moderately dependent on the sample and salt concentration and is solvent dependent. Transfer at physiological temperature over more than a few bases is improbable, except along consecutive A's, indicating that singlet energy transfer is not a major factor in the localization of UV damage in DNA. These results have features in common with recently observed electron transfer from 2AP to G in oligonucleotides.

摘要

通过光谱学研究了合成DNA寡聚物中从正常DNA碱基到2-氨基嘌呤碱基的单线态能量转移的序列、温度、浓度和溶剂依赖性。在260 - 280nm处的可变荧光激发带直接显示了能量转移。腺嘌呤(A)作为能量供体的效率最高,比其他碱基高一个数量级。与2-氨基嘌呤(2AP)相邻的腺嘌呤(A)堆叠可作为2AP激发的天线。在A和2AP之间插入一个鸟嘌呤(G)、胞嘧啶(C)或胸腺嘧啶(T)碱基会有效地阻止从A到2AP的能量转移。碱基堆叠促进能量转移,而碱基配对会使能量转移略有减少。在单链和双链寡聚物中,效率对温度的依赖性不同,在所测样品中,在0摄氏度以下效率最高。在双链十聚体的解链转变温度以下很远就会发生效率转变。双链十聚体d(CTGA[2AP]TTCAG)(2)中的能量转移效率适度依赖于样品和盐浓度,并且依赖于溶剂。除了沿着连续的A之外,在生理温度下超过几个碱基的能量转移是不太可能的,这表明单线态能量转移不是DNA中紫外线损伤定位的主要因素。这些结果与最近在寡核苷酸中观察到的从2AP到G的电子转移有共同特征。

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