Selective impairment of p53-mediated cell death in fibroblasts from sporadic Alzheimer's disease patients

In this study, we evaluated the response of different human skin fibroblast cultures obtained from eight probable Alzheimer’s disease patients and eight non-Alzheimer’s disease subjects to an acute oxidative injury elicited by H2O2. This treatment generates reactive oxygen species, which are responsible for DNA damage and apoptosis. To compare the sensitivity of fibroblasts from Alzheimer’s disease or non-Alzheimer’s disease patients to H2O2 exposure, we evaluated different parameters, including cell viability, the extension of DNA damage and the ability of the cells to arrest proliferation and to activate an apoptotic program. We found that fibroblasts from Alzheimer’s disease patients were more resistant that those from control subjects to H2O2 treatment, although the extent of DNA damage induced by the oxidative injury was similar in both experimental groups. The protective mechanism of Alzheimer’s disease fibroblasts was related to an impairment of H2O2-induced cell cycle arrest and characterized by an accelerated re-entry into the cell cycle and a diminished induction of apoptosis. Fibroblasts from Alzheimer’s disease patients also have a profound impairment in the H2O2-activated, p53-dependent pathway, which results in a lack of activation of p53 or p53-target genes, including p21, GADD45 and bax. This study demonstrates a specific alteration of an intracellular pathway involved in sensing and repairing DNA damage in peripheral cells from Alzheimer’s disease patients.