Abstract

Backgrounds: Congenital heart diseases affect nearly 1% of neonates per year in the United States and are the leading cause of neonatal death. Despite a strong indication of genetic contribution to congenital heart diseases, the developmental processes and genetic components are poorly understood. From the large-scale forward genetic screen using inbred mice chemically mutagenized with ethyl-nitrosourea (ENU), a novel finding of endocytic trafficking gene mutations, including Lrp1, were recovered as causing congenital heart disease phenotypes. Endocytosis plays roles in modulating cell signaling by regulating the trafficking of the internalized endocytic vesicles to different endosomal compartments, some destined for fusion with lysosomes and degradation while others are recycled to the surface by recycling endosomes. Mutations in these genes causes a spectrum of congenital heart disease comprising of outflow tract abnormalities and alignment defects. Methods and Results: The LRP1 [line 1554(MGI 96828)] mutant mouse line recovered from a forward genetic screen results from a missense (C4232R) mutation in the region encoding the epidermal growth factor (EGF) repeat domain of LRP1. The mutants exhibit a spectrum of septation and outflow tract defects including endocardial cushion defects, double outlet of right ventricle with normal related great arteries as well as DORV with D-malposition of great arteries (Taussig-Bing anomalies). Mouse embryonic fibroblasts (MEF) from LRP1 m/m mutants demonstrated decreased cell-surface expression and increased retention in the endosomes. Migration assay of MEF demonstrated decreased migration of LRP1 m/m compared with control with normal Golgi orientation. The decreasing migration LRP1 m/m also observed in the endocardial cushion tissue from E9.5-10.5 embryos. Different cell lineages crucial to cardiac development with tissue-specific genetic manipulations were used to define the roles of the LRP1 pathway in these three fields of cells during outflow tract development and septation. Cardiac neural crest cell (Wnt1-Cre) knockout of LRP1 recapitulate LRP1 m/m cardiac phenotypes as well as Nkx2.5/Tie2-cre double knockout of LRP1. RNA expression profile suggests Notch pathway and integrin pathway are associated with LRP1 during cardiac development. Conclusions: We provide the first evidence of endocytic vesicle trafficking pathway associated with the development of congenital heart diseases with malalignment/septation and outflow tract defects

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