Brain arteriovenous malformations (bAVMs) are complex vascular lesions with significant clinical risks. The Hippo signaling pathway, particularly its downstream effector YAP, plays a crucial role in a Show more
Brain arteriovenous malformations (bAVMs) are complex vascular lesions with significant clinical risks. The Hippo signaling pathway, particularly its downstream effector YAP, plays a crucial role in angiogenesis and vascular remodeling. This study investigates the role of YAP and related molecular markers in bAVMs, focusing on the effects of embolization. Immunohistochemical analysis was conducted on tissue samples from bAVM patients (n = 127), as well as on healthy blood vessels (n = 17). YAP, HIF-1α, FGFR1, CTGF, and CYR61 expression were quantified and correlated with clinical parameters. Results: In healthy vessels, YAP exhibited nuclear localization in (sub)endothelial cells and the tunica media, while CTGF and CYR61 were detected in the cytoplasm and extracellular matrix. The expression of YAP, CTGF, and CYR61 was significantly lower in bAVM tissues. Embolized bAVMs exhibited significantly higher expression of YAP, CTGF, and CYR61 compared to non-embolized tissues, suggesting a link between embolization and pro-angiogenic signaling. Additionally, FGFR1 was upregulated in embolized tissues. These results suggest that upregulation of YAP expression via the Hippo pathway might play a key role in bAVM pathophysiology. Embolization may further promote vascular remodeling. Dysregulation of YAP and related molecules in bAVMs warrants further studies to explore potential therapeutic strategies targeting the Hippo pathway. Show less
Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) in combination with CRISPR/Cas9 genome editing provide unparalleled opportunities to study cardiac biology and disease. However, Show more
Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) in combination with CRISPR/Cas9 genome editing provide unparalleled opportunities to study cardiac biology and disease. However, sarcomeres, the fundamental units of myocyte contraction, are immature and nonlinear in hiPSC-CMs, which technically challenge accurate functional interrogation of contractile parameters in beating cells. Furthermore, existing analysis methods are relatively low-throughput, indirectly assess contractility, or only assess well-aligned sarcomeres found in mature cardiac tissues. We aimed to develop an analysis platform that directly, rapidly, and automatically tracks sarcomeres in beating cardiomyocytes. The platform should assess sarcomere content, contraction and relaxation parameters, and beat rate. We developed SarcTrack, a MatLab software that monitors fluorescently tagged sarcomeres in hiPSC-CMs. The algorithm determines sarcomere content, sarcomere length, and returns rates of sarcomere contraction and relaxation. By rapid measurement of hundreds of sarcomeres in each hiPSC-CM, SarcTrack provides large data sets for robust statistical analyses of multiple contractile parameters. We validated SarcTrack by analyzing drug-treated hiPSC-CMs, confirming the contractility effects of compounds that directly activate (CK-1827452) or inhibit (MYK-461) myosin molecules or indirectly alter contractility (verapamil and propranolol). SarcTrack analysis of hiPSC-CMs carrying a heterozygous truncation variant in the myosin-binding protein C ( MYBPC3) gene, which causes hypertrophic cardiomyopathy, recapitulated seminal disease phenotypes including cardiac hypercontractility and diminished relaxation, abnormalities that normalized with MYK-461 treatment. SarcTrack provides a direct and efficient method to quantitatively assess sarcomere function. By improving existing contractility analysis methods and overcoming technical challenges associated with functional evaluation of hiPSC-CMs, SarcTrack enhances translational prospects for sarcomere-regulating therapeutics and accelerates interrogation of human cardiac genetic variants. Show less