Abstract
Hereditary Hemorrhagic Telangiectasia (HHT) is an autosomal dominant vascular disorder with presentations including severe nose bleeding and microhemorrhage in brains. Despite being the second most common inherited bleeding disorder, the pathophysiological mechanism underlying HHT-associated hemorrhage is poorly understood. Mutations in activin receptor-like kinase 1 (ALK1) gene cause HHT type 2. HHT pathogenesis is thought to follow a Knudsonian two-hit model, requiring a second somatic mutation for lesion formation. We hypothesize that somatic mutation of Alk1 in arterial endothelial cells (AECs) leads to arterial defects and hemorrhage. Here, we investigate the effects of Alk1 mutation in AECs in mice, using Bmx(PAC)-CreERT2-mediated postnatal somatic mutation. We mutated Alk1 in primarily AECs and found that somatic arterial endothelial mutation of Alk1 is sufficient to induce spontaneous epistaxis and multifocal cerebral microhemorrhage. Interestingly, this bleeding occurred in the presence of tortuous and enlarged blood vessels, loss of arterial molecular marker Efnb2, disorganization of vascular smooth muscle, and impaired vasoregulation. Our data suggest that arterial endothelial mutation of Alk1 causing reduced arterial identity and disruption of vascular smooth muscle cell coverage is a plausible molecular mechanism for HHT-associated severe epistaxis. This work provides the first evidence that somatic ALK1 loss in AECs can cause hemorrhagic vascular lesions, offering a novel preclinical model critically needed for studying HHT-associated epistaxis, and delineating an arterial mechanism to HHT pathophysiology.
Competing Interest Statement
The authors have declared no competing interest.