A Novel VWF Knockout Endothelial Cell Model to Study Von Willebrand Factor Biology and Von Willebrand Disease Mechanisms

Understanding how specific VWF variants disrupt endothelial processing and function is central to elucidating von Willebrand disease (VWD) pathophysiology. However, current in vitro systems lack either the endothelial specificity or the genetic flexibility required for systematic variant characterization. Here, we present a genetically defined VWF-knockout cord-blood-derived endothelial colony-forming cell (VWF-KO cbECFC) model that enables controlled reintroduction of VWF variants in a physiologically relevant endothelial context. Using a patient with type 3 VWD carrying the homozygous pathogenic variant p.M771V and a second homozygous variant of uncertain significance p.R2663P as a reference, we demonstrate that expression of p.M771V in VWF-KO cbECFCs reproduces the patients intracellular processing defect and loss of high-molecular-weight multimers, whereas p.R2663P behaves as a benign allele. These findings establish the models ability to accurately distinguish pathogenic from non-pathogenic variants. Comparative analyses with HEK293 cells show that VWF-KO cbECFCs provide superior subcellular resolution, reliably forming authentic Weibel-Palade bodies (WPBs) and faithfully revealing ER retention phenotypes that remain ambiguous in non-endothelial systems. The proliferative capacity of cbECFCs further enables scalable and reproducible experimentation, overcoming major limitations associated with patient-derived ECFCs. Looking ahead, the VWF-KO cbECFC platform offers broad potential for VWF and VWD research. Its endothelial identity and genetic flexibility make it suitable for investigating VWF biosynthesis and trafficking, secretion dynamics, WPB biology, angiogenic processes, and shear-dependent VWF function. This system therefore provides a versatile foundation for mechanistic studies, systematic variant assessment, and future translational applications.