TY - JOUR
T1 - Epithelial Planar Bipolarity Emerges from Notch-Mediated Asymmetric Inhibition of Emx2
AU - Kozak, Eva L.
AU - Palit, Subarna
AU - Miranda-Rodríguez, Jerónimo R.
AU - Janjic, Aleksandar
AU - Böttcher, Anika
AU - Lickert, Heiko
AU - Enard, Wolfgang
AU - Theis, Fabian J.
AU - López-Schier, Hernán
N1 - Publisher Copyright:
© 2020 Elsevier Ltd
PY - 2020/3/23
Y1 - 2020/3/23
N2 - Most plane-polarized tissues are formed by identically oriented cells [1, 2]. A notable exception occurs in the vertebrate vestibular system and lateral-line neuromasts, where mechanosensory hair cells orient along a single axis but in opposite directions to generate bipolar epithelia [3–5]. In zebrafish neuromasts, pairs of hair cells arise from the division of a non-sensory progenitor [6, 7] and acquire opposing planar polarity via the asymmetric expression of the polarity-determinant transcription factor Emx2 [8–11]. Here, we reveal the initial symmetry-breaking step by decrypting the developmental trajectory of hair cells using single-cell RNA sequencing (scRNA-seq), diffusion pseudotime analysis, lineage tracing, and mutagenesis. We show that Emx2 is absent in non-sensory epithelial cells, begins expression in hair-cell progenitors, and is downregulated in one of the sibling hair cells via signaling through the Notch1a receptor. Analysis of Emx2-deficient specimens, in which every hair cell adopts an identical direction, indicates that Emx2 asymmetry does not result from auto-regulatory feedback. These data reveal a two-tiered mechanism by which the symmetric monodirectional ground state of the epithelium is inverted by deterministic initiation of Emx2 expression in hair-cell progenitors and a subsequent stochastic repression of Emx2 in one of the sibling hair cells breaks directional symmetry to establish planar bipolarity.
AB - Most plane-polarized tissues are formed by identically oriented cells [1, 2]. A notable exception occurs in the vertebrate vestibular system and lateral-line neuromasts, where mechanosensory hair cells orient along a single axis but in opposite directions to generate bipolar epithelia [3–5]. In zebrafish neuromasts, pairs of hair cells arise from the division of a non-sensory progenitor [6, 7] and acquire opposing planar polarity via the asymmetric expression of the polarity-determinant transcription factor Emx2 [8–11]. Here, we reveal the initial symmetry-breaking step by decrypting the developmental trajectory of hair cells using single-cell RNA sequencing (scRNA-seq), diffusion pseudotime analysis, lineage tracing, and mutagenesis. We show that Emx2 is absent in non-sensory epithelial cells, begins expression in hair-cell progenitors, and is downregulated in one of the sibling hair cells via signaling through the Notch1a receptor. Analysis of Emx2-deficient specimens, in which every hair cell adopts an identical direction, indicates that Emx2 asymmetry does not result from auto-regulatory feedback. These data reveal a two-tiered mechanism by which the symmetric monodirectional ground state of the epithelium is inverted by deterministic initiation of Emx2 expression in hair-cell progenitors and a subsequent stochastic repression of Emx2 in one of the sibling hair cells breaks directional symmetry to establish planar bipolarity.
KW - diffusion pseudotime
KW - hair cells
KW - planar polarity
KW - single-cell RNA sequencing
UR - http://www.scopus.com/inward/record.url?scp=85081653735&partnerID=8YFLogxK
U2 - 10.1016/j.cub.2020.01.027
DO - 10.1016/j.cub.2020.01.027
M3 - Article
C2 - 32109392
AN - SCOPUS:85081653735
SN - 0960-9822
VL - 30
SP - 1142-1151.e6
JO - Current Biology
JF - Current Biology
IS - 6
ER -