Clinical presentation of congenital heart disease is heterogeneous, making identification of the disease-causing genes and their genetic pathways and mechanisms of action challenging. By using in vivo electrocardiography, transthoracic echocardiography and microcomputed tomography imaging to screen 3,894 single-gene-null mouse lines for structural and functional cardiac abnormalities, here we identify 705 lines with cardiac arrhythmia, myocardial hypertrophy and/or ventricular dilation. Among these 705 genes, 486 have not been previously associated with cardiac dysfunction in humans, and some of them represent variants of unknown relevance (VUR). Mice with mutations in Casz1, Dnajc18, Pde4dip, Rnf38 or Tmem161b genes show developmental cardiac structural abnormalities, with their human orthologs being categorized as VUR. Using UK Biobank data, we validate the importance of the DNAJC18 gene for cardiac homeostasis by showing that its loss of function is associated with altered left ventricular systolic function. Our results identify hundreds of previously unappreciated genes with potential function in congenital heart disease and suggest causal function of five VUR in congenital heart disease.
Supplementary Figure 1: Separated visualization of tdTomato and NG2 labeling in the superficial capillary layer in retinal whole mounts at the three TAM induction time points: NG2 labeling of PCs and vSMCs (A-C) as well as tdTomato expression of PCs (arrowheads, A'-C') in the NG2-CreER TM -tdTomato mouse model. In the PDGFRb-P2A-CreER T2 -tdTomato mouse model PCs (representative arrowheads) and vSMCs are labeled with NG2 (D-F), tdTomato expression is detected in PCs (representative arrowheads) and vSMCs and additionally in Müller glial cells (D'-F').
Introduction: Pericytes (PCs) are specialized cells located abluminal of endothelial cells on capillaries, fulfilling numerous important functions. Their potential involvement in wound healing and scar formation is achieving increasing attention since years. Thus, many studies investigated the participation of PCs following brain and spinal cord (SC) injury, however, lacking in-depth analysis of lesioned optic nerve (ON) tissue. Further, due to the lack of a unique PC marker and uniform definition of PCs, contradicting results are published.Methods: In the present study the inducible PDGFRβ-P2A-CreERT2-tdTomato lineage tracing reporter mouse was used to investigate the participation and trans-differentiation of endogenous PC-derived cells in an ON crush (ONC) injury model, analyzing five different post lesion time points up to 8 weeks post lesion.Results: PC-specific labeling of the reporter was evaluated and confirmed in the unlesioned ON of the reporter mouse. After ONC, we detected PC-derived tdTomato+ cells in the lesion, whereof the majority is not associated with vascular structures. The number of PC-derived tdTomato+ cells within the lesion increased over time, accounting for 60–90% of all PDGFRβ+ cells in the lesion. The presence of PDGFRβ+tdTomato- cells in the ON scar suggests the existence of fibrotic cell subpopulations of different origins.Discussion: Our results clearly demonstrate the presence of non-vascular associated tdTomato+ cells in the lesion core, indicating the participation of PC-derived cells in fibrotic scar formation following ONC. Thus, these PC-derived cells represent promising target cells for therapeutic treatment strategies to modulate fibrotic scar formation to improve axonal regeneration.
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