Structural chromosome abnormalities, increased DNA strand breaks and DNA strand break repair deficiency in dermal fibroblasts from old female human donors

Faiza Kalfalah,Brigitte Royer-Pokora,Barbara Hildebrandt,Julia Tigges,Sabine Seggewiß,Sebastian Ohse,Hauke Busch,María Moreno-Villanueva,Alexander Bürkle,Regina Walter,Fritz Boege,Melanie Boerries

doi:10.18632/aging.100723

Abstract

Dermal fibroblasts provide a paradigmatic model of cellular adaptation to long-term exogenous stress and ageing processes driven thereby. Here we addressed whether fibroblast ageing analysedex vivo entails genome instability. Dermal fibroblasts from human female donors aged 20-67 years were studied in primary culture at low population doubling. Under these conditions, the incidence of replicative senescence and rates of age-correlated telomere shortening were insignificant. Genome-wide gene expression analysis revealed age-related impairment of mitosis, telomere and chromosome maintenance and induction of genes associated with DNA repair and non-homologous end-joining, most notably XRCC4 and ligase 4. We observed an age-correlated drop in proliferative capacity and age-correlated increases in heterochromatin marks, structural chromosome abnormalities (deletions, translocations and chromatid breaks), DNA strand breaks and histone H2AX-phosphorylation. In a third of the cells from old and middle-aged donors repair of X-ray induced DNA strand breaks was impaired despite up-regulation of DNA repair genes. The distinct phenotype of genome instability, increased heterochromatinisation and (in 30% of the cases futile) up-regulation of DNA repair genes was stably maintained over several cell passages indicating that it represents a feature of geroconversion that is distinct from cellular senescence, as it does not encompass a block of proliferation.

Highlights

Many mechanisms of skin aging converge on the dermis, a skin compartment consisting mainly of dermal fibroblasts and surrounding matrix [1]
The decrease in cell proliferation is www.impactaging.com not likely related to replicative telomere shortening and replicative senescence, because we have previously shown that replicative cell cycle arrest does not occur below 40 population doublings (PD), and that induction of replicative senescence in culture can be avoided by keeping the cells well below that limit [20]
Our data suggest that during ageing in situ dermal fibroblast progressively lose their ability to control base line double strand breaks (DSB) levels, which leads to increased DNA recombination, chromosome breakage and enhanced background noise of DNA damage response (DDR) signalling

Summary

Introduction

Many mechanisms of skin aging converge on the dermis, a skin compartment consisting mainly of dermal fibroblasts and surrounding matrix [1]. Dermal fibroblasts are mostly quiescent cells that are regularly exposed to external noxae such as ultra violet light. These cells provide a paradigmatic model of long-term cellular adaptation to exogenous stress. Features of dermal fibroblast ageing detected by analysis in vivo or ex vivo encompass alterations of the cytoskeleton [3,4,5,6], incipient or manifest cellular senescence [7,8,9,10], epigenetic alterations [10, 11], impaired matrix homeostasis [1217] and mitochondrial dysfunction [18,19,20].

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Results

Conclusion