Differentiation of human keratinocytes requires translational control by the eIF2 kinase GCN2

Abstract

In the human epidermis, differentiation of keratinocytes is essential to form a barrier to protect against a variety of environmental insults. This differentiation process can become dysregulated in many skin diseases, including psoriasis, eczema, and non‐melanoma skin cancer. Although changes in transcriptional networks during keratinocyte differentiation are well characterized, little is known about the role of translational control. A major mechanism of translational control involves phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF2‐P). In response to environmental stresses, induced eIF2‐P represses translation initiation, allowing cells to conserve resources and trigger cytoprotective gene expression. In addition to repression of global protein synthesis, eIF2‐P induces preferential translation of specific mRNAs that promote stress adaptation, including the transcription factors ATF4 and CHOP. Since keratinocytes undergo a massive change in morphology and gene expression during differentiation, we hypothesized that translational control plays a major role. To investigate this hypothesis we measured both genome‐wide and gene‐specific levels of translation. We observed a global reduction in translation initiation as measured by polysome profiling during differentiation in both monolayer and 3D organotypic keratinocyte cultures. Expression of eIF2‐P, ATF4, and CHOP was limited to suprabasal (differentiated) keratinocytes in vivo as visualized histologically in human skin tissue. Keratinocyte differentiation in vitro induced eIF2‐P to levels similar to that seen following endoplasmic reticulum stress, but eIF2‐P alone was not sufficient to induce differentiation. Of interest, the epidermal differentiation transcript involucrin (IVL) was preferentially bound to large polysomes following differentiation, indicative of preferential translation, which was similar to that seen for ATF4 and CHOP. Inhibition of eIF2‐P blocked both general and gene‐specific translational control during differentiation. Loss of either eIF2‐P or the upstream protein kinase GCN2 abrogated both IVL protein and mRNA expression. Strikingly, loss of GCN2 altered epidermal tissue formation in a 3D organotypic model as characterized by disorganized keratinocyte layers and a decreased number of cornified cells. These results provide novel evidence that a whole‐cell repression of protein synthesis alongside gene‐specific translational control occur during normal epidermal differentiation. These findings suggest that translational control through GCN2/eIF2‐P is important for proper epidermal stratification, likely though translational regulation of differentiation genes such as IVL. The GCN2/eIF2‐P pathway in keratinocyte biology provides for novel targets for intervention in dermatological diseases characterized by abnormal differentiation.Support or Funding InformationRuth L. Kirschstein National Research Service Award (1F31ES026517 to AEC)