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Embryological cellular origins and hypoxia-mediated mechanisms in PIK3CA-driven refractory vascular malformations

Sota Torii, Keiki Nagaharu, Nanako Nakanishi, Hidehito Usui, Yumiko Hori, Katsutoshi Hirose, Satoru Toyosawa, Eiichi Morii, Mitsunaga Narushima, Yoshiaki Kubota, Osamu Nakagawa, Kyoko Imanaka-Yoshida, Kazuaki Maruyama

2025EMBO Molecular Medicine9 citationsDOIOpen Access PDF

Abstract

Abstract Congenital vascular malformations, affecting 0.5% of the population, often occur in the head and neck, complicating treatment due to the critical functions in these regions. Our previous research identified distinct developmental origins for blood and lymphatic vessels in these areas, tracing them to the cardiopharyngeal mesoderm (CPM), which contributes to the development of the head, neck, and cardiovascular system in both mouse and human embryos. In this study, we investigated the pathogenesis of these malformations by expressing Pik3ca H1047R in the CPM. Mice expressing Pik3ca H1047R in the CPM developed vascular abnormalities restricted to the head and neck. Single-cell RNA sequencing revealed that Pik3ca H1047R upregulates Vegf-a expression in endothelial cells through HIF-mediated hypoxia signaling. Human samples supported these findings, showing elevated HIF-1α and VEGF-A in malformed vessels. Notably, inhibition of HIF-1α and VEGF-A in the mouse model significantly reduced abnormal vasculature. These results highlight the role of embryonic origins and hypoxia-driven mechanisms in vascular malformations, providing a foundation for the development of therapies targeting these difficult-to-treat conditions.

Topics & Concepts

BiologyHypoxia (environmental)MesodermPathogenesisLymphatic systemPopulationPathologyVascular malformationHead and neckCancer researchEmbryonic stem cellCell biologyMedicineImmunologyGeneticsGeneChemistryOxygenRadiologyEnvironmental healthOrganic chemistrySurgeryVascular Malformations and HemangiomasEar and Head TumorsTracheal and airway disorders
Embryological cellular origins and hypoxia-mediated mechanisms in PIK3CA-driven refractory vascular malformations | Litcius