Abstract
Purpose:
P300 is a lysine acetyltransferase that plays a significant role in regulating transcription and the nuclear acetylome. While P300 has been shown to be required for the transcription of certain early flow responsive genes, relatively little is known about its role in the endothelial response to hemodynamic fluid stress. Here we sought to define the role of P300 in mechanotransduction of fluid shear stress in the vascular endothelium.
Methods:
To characterize cellular mechanotransduction and physical properties after perturbation of P300, we performed bulk RNA sequencing, confocal and Brillouin microscopy, and functional assays on HUVEC.
Results:
Inhibition of P300 in HUVEC triggers a hyper-alignment phenotype, with cells aligning to flow sooner and more uniformly in the presence of the P300 inhibitor A-485 compared to load controls. Bulk transcriptomics revealed differential expression of genes related to the actin cytoskeleton and migration in cells exposed to A-485. Scratch wound and bead sprouting assays demonstrated that treatment with A-485 increased 2D and 3D migration of HUVEC. Closer examination of filamentous actin revealed the presence of a perinuclear actin cap in both P300 knockdown HUVEC and HUVEC treated with A-485. Interrogation of cell mechanical properties via Brillouin microscopy demonstrated that HUVEC treated with A-485 had lower Brillouin shifts in both the cell body and the nucleus, suggesting that P300 inhibition triggers an increase in cellular and nuclear compliance.
Conclusions:
Together, these results point to a novel role of P300 in modulating endothelial cell mechanics and mechanotransduction of hemodynamic shear stress.
Supplementary information:
The online version contains supplementary material available at 10.1007/s12195-024-00805-2.
Keywords:
Cell mechanics; Mechanotransduction; Nuclear mechanotransduction; Vascular biology.