O16 Understanding the pleiotropic effects of the Rho-kinase inhibitor Y-27632 on human keratinocytes

Abstract

Abstract Introduction and aims Successful epidermal transplant generation depends on sufficiently high numbers of self-renewing stem cells that give rise to clonal colonies termed ‘holoclones’. Treatment with Y-27632, a nonspecific Rho-kinase 1/2 inhibitor, conditionally immortalizes epidermal keratinocyte cultures. However, the pleiotropic signalling mechanisms downstream of Y-27632 remain largely unexplored. We have therefore characterized the effects of continuous long-term Y-27632 treatment on chromatin regulation, and investigated whether Y-27632 reprogrammes a holoclone-like state. Methods Neonatal foreskin-derived human epidermal keratinocytes were cultured from passage p5 to p30, with or without Y treatment. Samples were collected for RNA sequencing analysis from progenitor-enriched middle passage cells (p5, MPK), progenitor-depleted late-passage cells (p8, LPK) and Y-treated cells at p8 (LPK-Y). Samples were also collected for assay for transposase-accessible chromatin (ATAC)-Seq analysis to assess open and closed chromatin regions. Results Untreated cultures became depleted of proliferating cells by p11, whereas Y maintained a highly proliferative culture up to p30 and beyond. Y withdrawal at p11 resulted in rapid loss of proliferative capacity within a single passage. ATAC-Seq identified 196 differentially regulated chromatin sites in MPK vs. LPK. Y treatment maintained accessibility in approximately 40% of these MPK-enriched chromatin regions. Approximately 3000 differentially expressed genes (DEGs) were identified in MPK vs. LPK, while Y treatment induced approximately 11 000 DEGs. Activated genes in LPK-Y were enriched for a holoclone signature, with no evidence for activation of a precancerous transcriptome. Y treatment altered the expression of various genes associated with amino acid metabolism, enabling cells to overcome serine/glycine autotrophy. Conclusions Y acts by preserving accessibility of progenitor-enriched chromatin sites and further reprogrammes the keratinocyte transcriptome towards a more holoclone-like state. However, keratinocytes retain a ‘memory’ of their doubling number, which is conditionally suppressed by Y. The observed global transcriptomic changes are indicative of the highly pleiotropic nature of the Y-induced signalling changes, warranting further deconvolution.