Abstract

Werner syndrome (WS) is a rare disease caused by the lack of a functional nuclear WS protein (WRN). WS is characterized by the early onset of premature aging signs and a high incidence of sarcomas. WS diploid fibroblasts have a short life span and extensive genomic instability. Mammalian cells are continuously exposed to reactive oxygen species (ROS), which represent human mutagens and are thought to be a major contributor to the aging process. Hydrogen peroxide (H2O2) is a common ROS intermediate generated by various forms of oxidative stress. In response to H2O2-induced DNA damage, normal human diploid fibroblasts follow a pathway leading to irreversible proliferation arrest and premature senescence. Here we show that in contrast to normal human fibroblasts, WS diploid fibroblasts continue proliferating after extensive H2O2-induced DNA damage and accumulate oxidative DNA lesions. A direct role of WRN in this abnormal cellular response to H2O2 is demonstrated by interfering with WRN expression in normal human fibroblasts. We propose a role for WRN in the detection and/or processing of oxidative DNA lesions and in cellular responses to H2O2 as they relate to some of the phenotypical aspects of WS cells.