Abstract

BackgroundHydrocephalus, the pathological expansion of the cerebrospinal fluid (CSF)-filled cerebral ventricles, is a common, deadly disease. In the adult, cardiac and respiratory forces are the main drivers of CSF flow within the brain ventricular system to remove waste and deliver nutrients. In contrast, the mechanics and functions of CSF circulation in the embryonic brain are poorly understood. This is primarily due to the lack of model systems and imaging technology to study these early time points. Here, we studied embryos of the vertebrate Xenopus with optical coherence tomography (OCT) imaging to investigate in vivo ventricular and neural development during the onset of CSF circulation.MethodsOptical coherence tomography (OCT), a cross-sectional imaging modality, was used to study developing Xenopus tadpole brains and to dynamically detect in vivo ventricular morphology and CSF circulation in real-time, at micrometer resolution. The effects of immobilizing cilia and cardiac ablation were investigated.ResultsIn Xenopus, using OCT imaging, we demonstrated that ventriculogenesis can be tracked throughout development until the beginning of metamorphosis. We found that during Xenopus embryogenesis, initially, CSF fills the primitive ventricular space and remains static, followed by the initiation of the cilia driven CSF circulation where ependymal cilia create a polarized CSF flow. No pulsatile flow was detected throughout these tailbud and early tadpole stages. As development progressed, despite the emergence of the choroid plexus in Xenopus, cardiac forces did not contribute to the CSF circulation, and ciliary flow remained the driver of the intercompartmental bidirectional flow as well as the near-wall flow. We finally showed that cilia driven flow is crucial for proper rostral development and regulated the spatial neural cell organization.ConclusionsOur data support a paradigm in which Xenopus embryonic ventriculogenesis and rostral brain development are critically dependent on ependymal cilia-driven CSF flow currents that are generated independently of cardiac pulsatile forces. Our work suggests that the Xenopus ventricular system forms a complex cilia-driven CSF flow network which regulates neural cell organization. This work will redirect efforts to understand the molecular regulators of embryonic CSF flow by focusing attention on motile cilia rather than other forces relevant only to the adult.

Highlights

  • Hydrocephalus, the pathological expansion of the cerebrospinal fluid (CSF)-filled cerebral ventricles, is a common, deadly disease

  • The bulk of the CSF flows from the choroid plexuses, with the pulsatile arterial flow acting as a pump to drive CSF movement through the ventricles [3, 4], in conjunction with respiratory movements [5]

  • optical coherence tomography (OCT) imaging in Xenopus enables in vivo temporal examination of ventriculogenesis as well as CSF flow initiation and maturation without manipulation We have previously shown that using a Xenopus Optical Coherence Tomography platform, in a non-destructive fashion, we can detect global CSF flow mapped to central nervous system (CNS) structures in the Xenopus tadpole [34]

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Summary

Introduction

Hydrocephalus, the pathological expansion of the cerebrospinal fluid (CSF)-filled cerebral ventricles, is a common, deadly disease. The bulk of the CSF flows from the choroid plexuses, with the pulsatile arterial flow acting as a pump to drive CSF movement through the ventricles [3, 4], in conjunction with respiratory movements [5] Besides these properties, emerging data underscore the critical role CSF plays in early embryonic neurogenesis, where CSF maintains appropriate neuroprogenitor identity, proliferation, and differentiation [6,7,8,9,10]. Mutations in genes expressed predominantly by the neuroprogenitor cells have been shown to lead to congenital hydrocephalus [11] These findings implicate a new embryonic perspective in hydrocephalus pathogenesis, suggesting that neuroprogenitors may contribute to a hydrocephalus outcome. It is essential to understand what constitutes early CSF dynamics

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