Qianhuan D
Sci Sin. 1980 Apr;23(4):453-70.
In this paper, we prove by perturbational molecular orbital (PMO) theory that with polycyclic aromatic hydrocarbons (PAH) there exist two regions having electrophilic activity, which are the necessary and sufficient condition for its carcinogenic activity. We are the first to obtain a quantitative equation for the carcinogenic activity of PAH, using the carbonium ion delocalization energies as parameters. By using the equation, the calculated carcinogenic activity is in fair accord with the experiment, and the consistent ratio comes up to 98%. Further study shows that the optimum distance for carcinogenic activity approximates to 2.80 A. This is just the distance between the negative centers in DNA double helix. Therefore, the key step of the carcinogenesis for PAH in vivo is the interstrand cross linkage between the DNA complementary base pair. In terms of this deduction, we suggest that the possible mechanism of chemical carcinogenesis should be a complementary frameshift mutation between the DNA double helix. We name such an idea "di-region theory", which probably might be of general significance for other chemical carcinogenesis.
在本文中,我们通过微扰分子轨道(PMO)理论证明,多环芳烃(PAH)存在两个具有亲电活性的区域,这是其致癌活性的充要条件。我们首次以碳正离子离域能为参数,得到了PAH致癌活性的定量方程。利用该方程计算得到的致癌活性与实验结果相当吻合,符合率高达98%。进一步研究表明,致癌活性的最佳距离约为2.80埃。这恰好是DNA双螺旋中负电荷中心之间的距离。因此,PAH在体内致癌的关键步骤是DNA互补碱基对之间的链间交联。基于这一推断,我们认为化学致癌的可能机制应该是DNA双螺旋之间的互补移码突变。我们将这一观点命名为“双区域理论”,它可能对其他化学致癌作用具有普遍意义。