Jerónimo R. Miranda-Rodríguez scite author profile

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][4][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][9][10][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.

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RhoA/ROCK pathway activity is essential for the correct localization of the germ plasm mRNAs in zebrafish embryos

Miranda-Rodríguez

Salas‐Vidal

Lomelı́

et al. 2017

Developmental Biology

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Zebrafish germ plasm is composed of mRNAs such as vasa and nanos and of proteins such as Bucky ball, all of which localize symmetrically in four aggregates at the distal region of the first two cleavage furrows. The coordination of actin microfilaments, microtubules and kinesin is essential for the correct localization of the germ plasm. Rho-GTPases, through their effectors, coordinate cytoskeletal dynamics. We address the participation of RhoA and its effector ROCK in germ plasm localization during the transition from two- to eight-cell embryos. We found that active RhoA is enriched along the cleavage furrow during the first two division cycles, whereas ROCK localizes at the distal region of the cleavage furrows in a similar pattern as the germ plasm mRNAs. Specific inhibition of RhoA and ROCK affected microtubules organization at the cleavage furrow; these caused the incorrect localization of the germ plasm mRNAs. The incorrect localization of the germ plasm led to a dramatic change in the number of germ cells during the blastula and 24hpf embryo stages without affecting any other developmental processes. We demonstrate that the Rho/ROCK pathway is intimately related to the determination of germ cells in zebrafish embryos.

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Quantitative videomicroscopy reveals latent control of cell-pair rotations in vivo

Kozak

Miranda-Rodríguez

Borges

et al. 2023

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Collective cell rotations are widely used during animal organogenesis. Theoretical and in vitro studies have conceptualized rotating cells as identical rigid-point objects that stochastically break symmetry to move monotonously and perpetually within an inert environment. However, it is unclear if this notion can be extrapolated to a natural context, where rotations are ephemeral and heterogeneous cellular cohorts interact with an active epithelium. In zebrafish neuromasts nascent sibling hair cells invert positions by rotating≤180° around their geometric center after acquiring different identities via Notch1a-mediated asymmetric repression of Emx2. Here we show that this multicellular rotation is a three-phasic movement that progresses via coherent homotypic coupling and heterotypic junction remodeling. We found no correlation between rotations and epithelium-wide cellular flow or anisotropic resistive forces. Moreover, the Notch/Emx2 status of the cell dyad does not determine asymmetric interactions with the surrounding epithelium. Aided by computer modeling, we suggest that initial stochastic inhomogeneities generate a metastable state that poises cells to move, spontaneous intercellular coordination of the resulting instabilities enables persistently directional rotations, whereas Notch1a-determined symmetry breaking buffers rotational noise.

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Incoherent collective cell chemotaxis underlies organ dysmorphia in a model of branchio-oto-renal syndrome

Miranda-Rodríguez

Borges

Pinto-Teixeira

et al. 2021

Preprint

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SUMMARYTissue remodeling presents an enormous challenge to the stability of intercellular signaling domains. Here we investigate this issue during the development of the posterior lateral line in zebrafish. We find that the transcriptional co-activator and phosphatase Eya1, mutated in the branchio-oto-renal syndrome in humans, is essential for the homeostasis of the Wnt/β-catenin and FGF morphogenetic domains during the collective migration of lateral-line primordial cells. Loss of Eya1 strongly diminishes the expression of Dkk1, expanding Wnt/β-catenin activity in the primordium, which in turn abrogates FGFR1 expression. Deficits in Eya1 also abolishes the expression of the chemokine receptor CXCR7b, disrupting primordium migration. These results reinforce the concept that morphogenetic domains in dynamically remodeling tissues are formed by cellular states maintained by continuous signaling.

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Incoherent Collective Cell Chemotaxis in a Zebrafish Model of Branchio-Oto-Renal Syndrome

Miranda-Rodríguez¹,

Borges²,

Pinto-Teixeira³

et al. 2022

SSRN Journal

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