AI Article Synopsis
- - Werner's syndrome (WS) is a genetic disorder that leads to premature aging, primarily studied through WS fibroblasts, which exhibit faster aging due to specific cellular issues like telomere shortening and halted DNA replication.
- - Unlike WS fibroblasts, human dermal keratinocytes (skin cells) from WS patients can proliferate extensively (over 100 population doublings) while still maintaining mechanisms that regulate growth, indicating they don't show signs of premature senescence.
- - The study suggests that certain tissues, like the epidermis, remain unaffected by WS-related aging symptoms, supporting the idea that Werner's syndrome is a form of segmental progeroid syndrome, affecting some cell types differently than others.
Article Abstract
Werner's syndrome (WS) is an autosomal recessive genetic disorder caused by loss of function mutation in wrn and is a useful model of premature in vivo ageing. Cellular senescence is a plausible causal mechanism of mammalian ageing and, at the cellular level, WS fibroblasts show premature senescence resulting from a combination of telomeric attrition and replication fork stalling. Over 90% of WS fibroblast cultures achieve <20 population doublings (PD) in vitro compared to wild type human fibroblast cultures. It has been proposed that some cell types, capable of proliferation, will fail to show a premature senescence phenotype in response to wrn mutations. To test this hypothesis, human dermal keratinocytes (derived from both WS and wild type patients) were cultured long term. WS Keratinocytes showed a replicative lifespan in excess of 100 population doublings but maintained functional growth arrest mechanisms based on p16 and p53. The karyotype of the cells was superficially normal and the cultures retained markers characteristic of keratinocyte holoclones (stem cells) including p63 expression and telomerase activity. Accordingly we conclude that, in contrast to WS fibroblasts, WS keratinocytes do not demonstrate slow growth rates or features of premature senescence. These findings suggest that the epidermis is among the tissue types that do not display symptoms of premature ageing caused by loss of function of wrn. This is in support that Werner's syndrome is a segmental progeroid syndrome.
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| http://dx.doi.org/10.1016/j.exger.2016.07.017 | DOI Listing |
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