Tmic-80. perk contributes to glioblastoma progression by regulating glioblastoma stem cell adaptation to extra cellular matrix stiffening through f-actin remodeling and focal adhesion complex regulation

Abstract The association between a stiffening extracellular matrix (ECM) and increased aggressiveness of gliomas is well established. Originally recognized as a protective mechanism against endoplasmic reticulum (ER) stress, the unfolded protein response (UPR) is primarily responsible for maintaining cellular protein homeostasis and triggering cell death under severe stress conditions. However, emerging evidence indicates that the ER transmembrane UPR sensors, IRE1 and PERK, possess additional functions beyond proteostasis, such as modulating cancer stem cell differentiation, cell adhesion, and migration, which also involve more recently identified protein scaffold functions. In this study, we uncover a novel role of PERK in cellular adaptation to matrix stiffening. Glioblastoma stem cells (GSCs), when cultured on human blood plasma/alginate hydrogels with tuneable stiffness, exhibited stiffness-dependent cellular responses, including cell flattening, differentiation, and enhanced migration. Through genetic depletion and pharmacological inhibition strategies combined with immunofluorescence microscopy, we identified the involvement of a previously found PERK/FLNA signaling mechanism in the adaptive response to matrix stiffness, where F-actin polymerization emerged as a key mechanism. To explore the possible involvement of PERK in sensing ECM stiffness, the expression of various proteins that constitute the focal adhesion complex were studied. Remarkably, PERK also influenced the maturation of focal adhesion complexes components know to be involved in sensing ECM stiffness. Finally, comparative transcriptional profiling of PERK proficient and deficient GSCs uncovered significant alterations in the expression of genes associated with cell adhesion and extracellular matrix (ECM)-related processes. These findings reveal a novel function of PERK in stiffness-dependent cellular adaptations, with ongoing investigations exploring the underlying molecular mechanisms and therapeutic implications for glioblastoma progression