Center for Computational Quantum Chemistry, University of Georgia, Athens, GA 30602, USA.
Chemistry. 2010 Oct 18;16(39):11848-58. doi: 10.1002/chem.201001236.
In order to address problems such as aging, cell death, and cancer, it is important to understand the mechanisms behind reactions causing DNA damage. One specific reaction implicated in DNA oxidative damage is hydroxyl free-radical attack on adenine (A) and other nucleic acid bases. The adenine reaction has been studied experimentally, but there are few theoretical results. In the present study, adenine dehydrogenation at various sites, and the potential-energy surfaces for these reactions, are investigated theoretically. Four reactant complexes [A···OH]* have been found, with binding energies relative to A+OH* of 32.8, 11.4, 10.7, and 10.1 kcal mol(-1). These four reactant complexes lead to six transition states, which in turn lie +4.3, -5.4, (-3.7 and +0.8), and (-2.3 and +0.8) kcal mol(-1) below A+OH*, respectively. Thus the lowest lying [A···OH]* complex faces the highest local barrier to formation of the product (A-H)+H(2)O. Between the transition states and the products lie six product complexes. Adopting the same order as the reactant complexes, the product complexes [(A-H)···H(2)O] lie at -10.9, -22.4, (-24.2 and -18.7), and (-20.5 and -17.5) kcal mol(-1), respectively, again relative to separated A+OH*. All six A+OH* → (A-H)+H(2)O pathways are exothermic, by -0.3, -14.7, (-17.4 and -7.8), and (-13.7 and -7.8) kcal mol(-1), respectively. The transition state for dehydrogenation at N(6) lies at the lowest energy (-5.4 kcal mol(-1) relative to A+OH), and thus reaction is likely to occur at this site. This theoretical prediction dovetails with the observed high reactivity of OH radicals with the NH(2) group of aromatic amines. However, the high barrier (37.1 kcal mol(-1)) for reaction at the C(8) site makes C(8) dehydrogenation unlikely. This last result is consistent with experimental observation of the imidazole ring opening upon OH radical addition to C(8). In addition, TD-DFT computed electronic transitions of the N(6) product around 420 nm confirm that this is the most likely site for hydrogen abstraction by hydroxyl radical.
为了解决衰老、细胞死亡和癌症等问题,了解导致 DNA 损伤的反应机制非常重要。一种与 DNA 氧化损伤有关的特定反应是羟基自由基攻击腺嘌呤(A)和其他核酸碱基。腺嘌呤反应已在实验中进行了研究,但理论结果却很少。在本研究中,我们从理论上研究了腺嘌呤在不同部位的脱氢作用以及这些反应的势能面。发现了四个反应物络合物[A···OH],其结合能相对于 A+OH为 32.8、11.4、10.7 和 10.1 kcal mol(-1)。这四个反应物络合物导致六个过渡态,分别位于 A+OH以下+4.3、-5.4、(-3.7 和 +0.8)和(-2.3 和 +0.8)kcal mol(-1)。因此,最低能的[A···OH]络合物在形成产物(A-H)+H(2)O 时面临最高的局部形成势垒。在过渡态和产物之间存在六个产物络合物。按照与反应物络合物相同的顺序,产物络合物[(A-H)···H(2)O]位于-10.9、-22.4、(-24.2 和 -18.7)和(-20.5 和 -17.5)kcal mol(-1),相对于分离的 A+OH。所有六个 A+OH→(A-H)+H(2)O 途径都是放热的,分别为-0.3、-14.7、(-17.4 和 -7.8)和(-13.7 和-7.8)kcal mol(-1)。N(6)脱氢的过渡态能量最低(-5.4 kcal mol(-1)相对于 A+OH),因此反应很可能在此处发生。这一理论预测与 OH 自由基与芳香胺的 NH(2)基团高反应性的观察结果相符。然而,C(8)位点反应的高势垒(37.1 kcal mol(-1))使得 C(8)脱氢不太可能发生。这一最后结果与 OH 自由基加成到 C(8)时咪唑环打开的实验观察结果一致。此外,TD-DFT 计算的 N(6)产物的电子跃迁在 420nm 左右,证实这是羟基自由基夺取氢的最可能位点。
