Endogenous gradients of resting potential instructively pattern embryonic neural tissue via Notch signaling and regulation of proliferation

Biophysical forces play important roles throughout embryogenesis, but the roles of spatial differences in cellular resting potentials during large-scale brain morphogenesis remain unknown. Here, we implicate endogenous bioelectricity as an instructive factor during brain patterning in Xenopus laevis...

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Bibliographic Details
Published in:The Journal of neuroscience 2015-03, Vol.35 (10), p.4366-4385
Main Authors: Pai, Vaibhav P, Lemire, Joan M, Paré, Jean-François, Lin, Gufa, Chen, Ying, Levin, Michael
Format: Article
Language:English
Subjects:
Age Factors
Animals
Anura
Body Patterning - genetics
Body Patterning - physiology
Calcium - metabolism
Cell Proliferation - physiology
Embryo, Nonmammalian
Fluorescent Dyes - metabolism
Gap Junctions - drug effects
Gap Junctions - physiology
Gene Expression Regulation, Developmental - drug effects
Gene Expression Regulation, Developmental - physiology
Ion Channels - drug effects
Ion Channels - genetics
Ion Channels - metabolism
Membrane Potentials - genetics
Membrane Potentials - physiology
Microinjections
Nerve Tissue Proteins - genetics
Nerve Tissue Proteins - metabolism
Neural Tube - cytology
Neural Tube - embryology
Neurons - physiology
Receptors, Notch - genetics
Receptors, Notch - metabolism
Signal Transduction - genetics
Signal Transduction - physiology
Transcription Factors - genetics
Transcription Factors - metabolism
Transduction, Genetic
Xenopus laevis
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Summary:Biophysical forces play important roles throughout embryogenesis, but the roles of spatial differences in cellular resting potentials during large-scale brain morphogenesis remain unknown. Here, we implicate endogenous bioelectricity as an instructive factor during brain patterning in Xenopus laevis. Early frog embryos exhibit a characteristic hyperpolarization of cells lining the neural tube; disruption of this spatial gradient of the transmembrane potential (Vmem) diminishes or eliminates the expression of early brain markers, and causes anatomical mispatterning of the brain, including absent or malformed regions. This effect is mediated by voltage-gated calcium signaling and gap-junctional communication. In addition to cell-autonomous effects, we show that hyperpolarization of transmembrane potential (Vmem) in ventral cells outside the brain induces upregulation of neural cell proliferation at long range. Misexpression of the constitutively active form of Notch, a suppressor of neural induction, impairs the normal hyperpolarization pattern and neural patterning; forced hyperpolarization by misexpression of specific ion channels rescues brain defects induced by activated Notch signaling. Strikingly, hyperpolarizing posterior or ventral cells induces the production of ectopic neural tissue considerably outside the neural field. The hyperpolarization signal also synergizes with canonical reprogramming factors (POU and HB4), directing undifferentiated cells toward neural fate in vivo. These data identify a new functional role for bioelectric signaling in brain patterning, reveal interactions between Vmem and key biochemical pathways (Notch and Ca(2+) signaling) as the molecular mechanism by which spatial differences of Vmem regulate organogenesis of the vertebrate brain, and suggest voltage modulation as a tractable strategy for intervention in certain classes of birth defects.
ISSN:0270-6474
1529-2401
DOI:10.1523/JNEUROSCI.1877-14.2015