Abstract
ABSTRACTReissner fibre (RF), discovered by the 19th-century German anatomist Ernst Reissner, is a filamentous structure present in cerebrospinal fluid (CSF). RF forms by aggregation of a glycoprotein called SCO-spondin (Sspo), but its function has remained enigmatic. Recent studies have shown that zebrafish sspo mutants develop a curved embryonic body axis. Zebrafish embryos with impaired cilia motility also develop curved bodies, which arises from failure of expression of urotensin related peptide (urp) genes in CSF-contacting neurons (CSF-cNs), impairing downstream signalling in trunk muscles. Here, we show that sspo mutants can survive into adulthood, but display severe curvatures of the vertebral column, resembling the common human spine disorder idiopathic scoliosis (IS). sspo mutants also exhibit significant reduction of urp gene expression from CSF-cNs. Consistent with epinephrine in CSF being bound by RF and required for urp expression, treating sspo mutants with this catecholamine rescued expression of the urp genes and axial defects. More strikingly, providing Urp2, specifically in the CSF-cNs, rescued body curvature of sspo homozygotes during larval stages as well as in the adult. These findings bridge existing gaps in our knowledge between cilia motility, RF, Urp signalling and spine deformities, and suggest that targeting the Urotensin pathway could provide novel therapeutic avenues for IS.
Highlights
Form and function of the vertebrate body is intimately dependent on proper morphogenesis of the spine
We reasoned that the severity of ventral axial curvature could be ameliorated to some degree by releasing the mutant embryos from the confines of the spherical chorion and this could allow them to develop into adults
Recently Reissner fibre (RF) has been shown to be important for proper development of the body axis in the zebrafish embryo, the molecular mechanism involved was completely unexplored (Cantaut-Belarif et al, 2018)
Summary
Form and function of the vertebrate body is intimately dependent on proper morphogenesis of the spine. Using genetic analysis in the zebrafish, we and others have implicated impairment in cilia-driven cerebrospinal fluid (CSF) flow within the brain and spinal canal in the development of spine curvature in the embryo and adult (Grimes et al, 2016; Zhang et al, 2018). Urp proteins, secreted from CSF-cNs, likely function via their receptor, Uts2r3, on slow-twitch muscle fibres of the dorsal somites, and the current hypothesis posits that contractile activity of these muscle fibres brings about proper axial morphogenesis (Zhang et al, 2018)
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