Abstract
Foxc1a is a member of the forkhead transcription factors. It plays an essential role in zebrafish somitogenesis. However, little is known about the molecular mechanisms underlying its controlling somitogenesis. To uncover how foxc1a regulates zebrafish somitogenesis, we generated foxc1a knock-out zebrafish using TALEN (transcription activator-like effector nuclease) technology. The foxc1a null embryos exhibited defective somites at early development. Analyses on the expressions of the key genes that control processes of somitogenesis revealed that foxc1a controlled early somitogenesis by regulating the expression of myod1. In the somites of foxc1a knock-out embryos, expressions of fgf8a and deltaC were abolished, whereas the expression of aldh1a2 (responsible for providing retinoic acid signaling) was significantly increased. Once the increased retinoic acid level in the foxc1a null embryos was reduced by knocking down aldh1a2, the reduced expression of myod1 was partially rescued by resuming expressions of fgf8a and deltaC in the somites of the mutant embryos. Moreover, a chromatin immunoprecipitation assay on zebrafish embryos revealed that Foxc1a bound aldh1a2 promoter directly. On the other hand, neither knocking down fgf8a nor inhibiting Notch signaling affected the expression of aldh1a2, although knocking down fgf8a reduced expression of deltaC in the somites of zebrafish embryos at early somitogenesis and vice versa. Taken together, our results demonstrate that foxc1a plays an essential role in early somitogenesis by controlling Fgf and Notch signaling through restricting the expression of aldh1a2 in paraxial mesoderm directly.
Highlights
The role of foxc1a in zebrafish somitogenesis remains elusive
It was reported that knocking down foxc1a using MO led to a complete loss of somite boundaries, blocked formation of morphological somites, abolished myod1 expression in paraxial mesoderm, and eliminated expression of paraxis implicated in somite epithelialization [14]
We report in this study that foxc1a null zebrafish embryos from two lines of zebrafish mutants exhibit nearly normal somite boundary and show abnormal somitogenesis only with reduced size of the first six somites in the embryos at early somitogenesis (Fig. 2)
Summary
The role of foxc1a in zebrafish somitogenesis remains elusive. Results: Zebrafish foxc1a knock-out embryos exhibit defective somites at early development. foxc1a works on the top of the genetic hierarchy of RA, Fgf, and Notch signaling network to regulate myod expression. Neither knocking down fgf8a nor inhibiting Notch signaling affected the expression of aldh1a2, knocking down fgf8a reduced expression of deltaC in the somites of zebrafish embryos at early somitogenesis and vice versa. Our results demonstrate that foxc1a plays an essential role in early somitogenesis by controlling Fgf and Notch signaling through restricting the expression of aldh1a2 in paraxial mesoderm directly. In the zebrafish smoothened (smu, Shh signaling pathway genes) mutant, the expression of myod is reduced at the adaxial cells, but its expression in the somite mesoderm is unaffected [5, 13]. Further analyses revealed that Foxc1a affected the expression of myod by controlling Fgf and Notch signaling through directly restricting the expression of aldh1a2 in the paraxial mesoderm of embryos at early somitogenesis
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