O08 Exploring the effect of skin ageing-related basement membrane collagen loss on nuclear mechanics

Abstract

Abstract Introduction and aims Skin ageing is a universal process that can increase susceptibility to inflammation and disease. Basement membrane collagens (BMCs) are reduced during ageing and the consequences are poorly understood. BMC sensing of mechanical stress, vital for skin homeostasis, elicits signalling sensed via cytoskeletal actin filaments to the linker of nucleoskeleton and cytoskeleton (LINC) complex (composed of nesprin and sun proteins), nuclear lamina and lamina-associated chromatin. Our hypothesis is that BMC loss during ageing leads to a deformation of the nucleocytoskeleton and disrupts chromatin organization in keratinocytes, leading to impairment of epidermal differentiation and inability to withstand mechanical stress. Methods To explore the role of BMC in mechanical stress response, stable lentiviral short hairpin (sh)RNA knockdowns of Col7 (shCol7) and Col17 (shCol17) were generated in immortalized N/TERT keratinocytes. Western blot (WB) validated knockdowns were compared with shC nontargeting control. IncuCyte assays showed shCol17 had a hyperproliferative phenotype compared with shC. Sun2 was reduced in shCol17 (P < 0.001) compared with shC (n = 5 experimental replicates). The mechanical stretch effect on cells on a flexible membrane was studied using immunofluorescence and WB analysis. Images taken from the IN Cell Analyzer confocal microscope were analysed to detect changes in protein expression and localization. Nuclear and cytoplasmic fractions made before and after stretch were analysed by WB. Results We observed collagen-specific responses to stretch-induced stress with changes to actin, components of the nuclear membrane, and LINC complex proteins. Additionally, work on investigating chromatin changes with BMC knockdown using Cleavage Under Targets & Tagmentation and Cleavage Under Targeted Accessible Chromatin assays is ongoing. Conclusions Our data show an altered nucleocytoskeleton in the context of BMC loss and mechanotransduction in skin. These data could provide novel insights into epidermal regulation by BMC in ageing.