Abstract
As a tightly controlled biological process, cardiogenesis requires the specification and migration of a suite of cell types to form a particular three-dimensional configuration of the heart. Many genetic factors are involved in the formation and maturation of the heart, and any genetic mutations may result in severe cardiac failures. The neuron navigator (NAV) family consists of three vertebrate homologs (NAV1, NAV2, and NAV3) of the neural guidance molecule uncoordinated-53 (UNC-53) in Caenorhabditis elegans. Although they are recognized as neural regulators, their expressions are also detected in many organs, including the heart, kidney, and liver. However, the functions of NAVs, regardless of neural guidance, remain largely unexplored. In our study, we found that nav3 gene was expressed in the cardiac region of zebrafish embryos from 24 to 48h post-fertilization (hpf) by means of in situ hybridization (ISH) assay. A CRISPR/Cas9-based genome editing method was utilized to delete the nav3 gene in zebrafish and loss of function of Nav3 resulted in a severe deficiency in its cardiac morphology and structure. The similar phenotypic defects of the knockout mutants could recur by nav3 morpholino injection and be rescued by nav3 mRNA injection. Dual-color fluorescence imaging of ventricle and atrium markers further confirmed the disruption of the heart development in nav3-deleted mutants. Although the heart rate was not affected by the deletion of nav3, the heartbeat intensity was decreased in the mutants. All these findings indicate that Nav3 was required for cardiogenesis in developing zebrafish embryos.
Highlights
Cardiogenesis is an indispensable process in vertebrates during embryogenesis, and the heart plays a vital role in the distribution of nutrients and oxygen in the embryos
We found that nav3 gene was expressed in the cardiac region of zebrafish embryos from 24 to 48 hours post-fertilization by means of in situ hybridization (ISH) assay
All these findings indicate that Nav3 was required for cardiogenesis in developing zebrafish embryos
Summary
Cardiogenesis is an indispensable process in vertebrates during embryogenesis, and the heart plays a vital role in the distribution of nutrients and oxygen in the embryos. Any failures during cardiogenesis will lead to cardiac malformations, further resulting in the death of the embryos. Compared with other mammalian models, such as mice, zebrafish offers several unique advantages for studying cardiac development (Gore et al, 2012; Liu and Stainier, 2012). The zebrafish embryos develop externally after fertilization, allowing direct non-invasive observation of heart development during cardiogenesis. Zebrafish embryos can survive up to 7 days without a functional cardiovascular system to supply the nutrients and oxygen due to their tiny size, offering the possibility to analyze the phenotype of the cardiac defects. Zebrafish is a valuable animal model for exploring the mechanisms underlying cardiac development
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