Cellular apoptosis and cytotoxicity of phenolic compounds: A quantitative structure-activity relationship study

In this comprehensive study on the caspase-mediated apoptosis-inducing effect of 51 substituted phenols in a murine leukemia cell line (L1210), we determined the concentrations needed to induce caspase activity by 50% (I-50) and utilized these data to develop the following quantitative structure-activity relationship (QSAR) model: log (1)/I-50 = 1.06 B5(2) + 0.33 B5(3) - 0.18 pi(2,4) - 0.92. B5(3) and B5(2) represent steric terms, while pi(2,4) represents the hydrophobic character of the substituents on the ring. The strong dependence of caspase-mediated apoptosis on mostly steric parameters suggests that the process is a receptor-mediated interaction with caspases or mitochondrial proteins being the likely targets. Conversely, cytotoxicity studies of 65 electron-releasing phenols in the L1210 cell line led to the development of the following equation: log (1)/ ID50 = - 1.39 sigma(+) - 0.28 B5(2,6) + 0.16 log P - 0.58I(2) - 1.04I(1) + 3.90. The low coefficient with log P may pertain to cellular transport that may be enhanced by a modest increase in overall hydrophobicity, while - the presence of e is consistent with the suggestion that radical stabilization is of prime importance in the case of electron-releasing substituents. On the other hand, the QSAR for the interactions of 27 electron-attracting phenols in L1210 cells, log (1)/ID50 = 0.56 log P - 0.30 B5(2) + 2.79, suggests that hydrophobicity, as represented by log P is of critical importance. Similar cytotoxicity patterns are observed in other mammalian cell lines such as HL-60, MCF-7, CCRF-CEM, and CEM/VLB. The significant differences between the cytotoxicity and apoptosis QSAR for electron-releasing phenols suggest that cytotoxicity involves minimal apoptosis in most of these substituted monophenols.