Werner syndrome, caused by mutations of the WRN gene, mimics many changes of normal aging. Although roles for WRN protein in DNA replication, recombination, and telomere maintenance have been suggested, the pathology of rapidly dividing cells is not a feature of Werner syndrome. To identify cellular events that are specifically vulnerable to WRN deficiency, we used RNA interference (RNAi) to knockdown WRN or BLM (the RecQ helicase mutated in Bloom syndrome) expression in primary human fibroblasts. Withdrawal of WRN or BLM produced accelerated cellular senescence phenotype and DNA damage response in normal fibroblasts, as evidenced by induction of ␥H2AX and 53BP1 nuclear foci. After WRN depletion, the induction of these foci was seen most prominently in nondividing cells. Growth in physiological (3%) oxygen or in the presence of an antioxidant prevented the development of the DNA damage foci in WRN-depleted cells, whereas acute oxidative stress led to inefficient repair of the lesions. Furthermore, WRN RNAi-induced DNA damage was suppressed by overexpression of the telomere-binding protein TRF2. These conditions, however, did not prevent the DNA damage response in BLM-ablated cells, suggesting a distinct role for WRN in DNA homeostasis in vivo. Thus, manifestations of Werner syndrome may reflect an impaired ability of slowly dividing cells to limit oxidative DNA damage.Among the simple Mendelian disorders of humans, Werner syndrome most closely resembles an acceleration of normal aging (20,32). Although the distribution of lesions is somewhat atypical for normal aging, Werner patients show osteoporosis, atherosclerosis, thinning of skin, graying of hair, cataracts and diabetes (33). Peripheral insulin resistance appears to precede the diabetes, as it does in maturity onset type II diabetes in the general population. Werner syndrome has attracted the interest of a number of investigators because of the hope that understanding its pathogenesis could shed light on the molecular weak links in normal aging.The gene mutated in Werner syndrome encodes the WRN protein, a 3Ј-5Ј DNA helicase of the RecQ family that also exhibits exonuclease activity (for a review, see references 25, 35, and 37). WRN has been suggested to function in DNA replication and repair. The helicase is capable of unwinding various DNA structures such as D-loops and G-quartets, and various structures potentially associated with progressing replication forks, as well as promoting migration of Holliday junctions such as might be formed as intermediates in DNA recombination. WRN can directly interact with a variety of proteins involved in these processes, including the major DNA polymerase, polymerase delta; polymerase beta, a DNA polymerase used in base excision repair; the Ku complex; the FEN1 nuclease that removes single-stranded branch structures in DNA; and the p53 DNA checkpoint gene. Previous studies reported slow progression of S phase in cells from Werner patients and proposed that fewer origins of replication are used and/or that the replicati...
