Zebrafish arterial valve development occurs through direct differentiation of second heart field progenitors
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Aims
Bicuspid Aortic Valve (BAV) is the most common congenital heart defect, affecting at least 2% of the population. The embryonic origins of BAV remain poorly understood, limiting the identification of assays for validating patient variants and ultimately causative genes for BAV. In both human and mouse, the left and right leaflets of the arterial valves arise from the outflow tract cushions, with interstitial cells originating from neural crest cells and endocardial-to-mesenchymal transition (EndoMT). In contrast, an EndoMT-independent mechanism of direct differentiation by cardiac progenitors from the second heart field (SHF) is responsible for the formation of the anterior and posterior leaflets. Defects in either of these developmental mechanisms can result in BAV. Although zebrafish have been suggested as a model for human variant testing, their naturally bicuspid arterial valve has not been considered suitable for understanding human arterial valve development. Here, we have set out to investigate to what extent the processes involved in arterial valve development are conserved in zebrafish and ultimately, whether functional testing of BAV variants could be carried out in zebrafish.
Methods and Results
Using a combination of live imaging, immunohistochemistry and Cre-mediated lineage tracing, we show that the zebrafish arterial valve primordia develop directly from undifferentiated SHF progenitors with no contribution from EndoMT or neural crest, in keeping with the human and mouse anterior and posterior leaflets. Moreover, once formed, these primordia share common subsequent developmental events with all three mammalian arterial valve leaflets.
Conclusions
Our work highlights a conserved ancestral mechanism of arterial leaflet formation from the SHF and identifies that development of the zebrafish arterial valve is distinct from that of the atrioventricular valve. Crucially, this confirms the utility of zebrafish for understanding the development of specific BAV subtypes and arterial valve dysplasia, offering potential for high-throughput variant testing.
Translational Perspective
Large genomic studies of patients with Bicuspid Aortic Valve (BAV) have identified numerous variants predicted to be causative, yet due to a lack of suitable, in vivo functional assays, advancement of genetic testing, discussion of risk to family members and accurate prognosis is not yet widely possible. Here, we show that zebrafish demonstrate a high level of conservation in arterial valve development with the intercalated leaflets in human, establishing zebrafish as a suitable in vivo model that can begin to overcome the disconnect between clinical genetics and developmental biology.
