Balancing cell numbers during organogenesis: Six1a differentially affects neurons and sensory hair cells in the inner ear

Bricaud, Olivier; Collazo, Andrés

doi:10.1016/j.ydbio.2011.06.035

Cited by 22 publications

(33 citation statements)

References 62 publications

(102 reference statements)

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“…In addition to contributing to early muscle development, six1b (formerly six1a) participates in both inner ear and pituitary development in zebrafish embryos (Bricaud and Collazo, 2011;Pogoda and Hammerschmidt, 2009), with analogous functions for six1a currently not reported. In the inner ear, six1b has divergent roles, as it promotes hair cell fate but inhibits neuronal fate (Bricaud and Collazo, 2011).…”

Section: Discussionmentioning

confidence: 99%

“…In the inner ear, six1b has divergent roles, as it promotes hair cell fate but inhibits neuronal fate (Bricaud and Collazo, 2011). Additional tissues in which SIX1 plays an important embryonic role have been identified in several species, including several embryonic placodes and the kidney, amongst others (Brugmann et al, 2004;Grifone et al, 2005;Ikeda et al, 2007;Laclef et al, 2003b;Sato et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

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MicroRNA-30a regulates zebrafish myogenesis via targeting the transcription factor Six1

O’Brien

Hernandez-Lagunas

Artinger

et al. 2014

Journal of Cell Science

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Precise spatiotemporal regulation of the SIX1 homeoprotein is required to coordinate vital tissue development, including myogenesis. Whereas SIX1 is downregulated in most tissues following embryogenesis, it is re-expressed in numerous cancers, including tumors derived from muscle progenitors. Despite crucial roles in development and disease, the upstream regulation of SIX1 expression has remained elusive. Here, we identify the first direct mechanism for Six1 regulation in embryogenesis, through microRNA30a (miR30a)-mediated repression. In zebrafish somites, we show that miR30a and six1a and six1b (hereafter six1a/b) are expressed in an inverse temporal pattern. Overexpression of miR30a leads to a reduction in six1a/b levels, and results in increased apoptosis and altered somite morphology, which phenocopies six1a/b knockdown. Conversely, miR30a inhibition leads to increased Six1 expression and abnormal somite morphology, revealing a role for endogenous miR30a as a muscle-specific miRNA (myomiR). Importantly, restoration of six1a in miR30a-overexpressing embryos restores proper myogenesis. These data demonstrate a new role for miR30a at a key node in the myogenic regulatory gene network through controlling Six1 expression.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

MicroRNA-30a regulates zebrafish myogenesis via targeting the transcription factor Six1

O’Brien

Hernandez-Lagunas

Artinger

et al. 2014

Journal of Cell Science

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“…Each well of a 6-well plate was transfected with 100 ng of a reporter of Six1/SO transcriptional activity, ARE-luciferase (Silver et al, 2003; Bricaud and Collazo, 2011) and 10 pg of a normalizer plasmid containing Renilla luciferase under the control of a CMV promoter (pRL-CMV). The same assay was performed with a Tfap2α -luciferase reporter that we constructed; 2500 bp of Xenopus laevis genomic sequence upstream of the Tfap2α transcription start site (Karpinka et al, 2015; Vize and Zorn, 2016) was cloned by PCR upstream of the luciferase sequence in the pGl3 plasmid (Promega) using J-Strain Xenopus laevis genomic DNA (National Xenopus Resource; Pearl et al, 2012) and the In-Fusion Kit (Clontech).…”

Section: Methodsmentioning

confidence: 99%

“…Six1 loss-of-function in Xenopus and chick results in reduced expression of several placode genes and defects in otic development (Brugmann et al, 2004; Christophorou et al, 2009; Schlosser et al, 2008). Six1 knock-down in zebrafish results in loss of inner ear hair cells (Bricaud and Collazo, 2006, 2011), and Six1 -null mice show defects in the olfactory placode, inner ear and cranial sensory ganglia (Chen et al, 2009; Ikeda et al, 2007, 2010; Konishi et al, 2006; Laclef et al, 2003; Ozaki et al, 2004; Zheng et al, 2003; Zou et al, 2004). Mutations in SIX1 associated with BOS are not truncations leading to loss-of-function (reviewed in Moody et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Pa2G4 is a novel Six1 co-factor that is required for neural crest and otic development

Neilson

Abbruzzesse

Kenyon

et al. 2017

Developmental Biology

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Mutations in SIX1 and in its co-factor, EYA1, underlie Branchiootorenal Spectrum disorder (BOS), which is characterized by variable branchial arch, otic and kidney malformations. However, mutations in these two genes are identified in only half of patients. We screened for other potential co-factors, and herein characterize one of them, Pa2G4 (aka Ebp1/Plfap). In human embryonic kidney cells, Pa2G4 binds to Six1 and interferes with the Six1-Eya1 complex. In Xenopus embryos, knock-down of Pa2G4 leads to down-regulation of neural border zone, neural crest and cranial placode genes, and concomitant expansion of neural plate genes. Gain-of-function leads to a broader neural border zone, expanded neural crest and altered cranial placode domains. In loss-of-function assays, the later developing otocyst is reduced in size, which impacts gene expression. In contrast, the size of the otocyst in gain-of-function assays is not changed but the expression domains of several otocyst genes are reduced. Together these findings establish an interaction between Pa2G4 and Six1, and demonstrate that it has an important role in the development of tissues affected in BOS. Thereby, we suggest that pa2g4 is a potential candidate gene for BOS.

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“…Interestingly, it affects these two processes differently in the two lineages: six1 regulates proliferation in hair cell progenitors and regulates survival of neuroblasts (Bricaud and Collazo, 2006). It does so by having a different mode of transcriptional regulation in each lineage: in the sensory lineage it partners with eya proteins to activate genes involved in cell proliferation, whereas in the neuronal lineage it partners with groucho co-repressors to properly restrict the domain of neurogenesis (Bricaud and Collazo, 2011). Other evidence suggests that transcriptional events occurring very early in zebrafish ear development biases the neuronal-sensory fate decision.…”

Section: : Patterning Neurons and Sensory Cells In The Zebrafish – Smentioning

confidence: 99%

Segregating neural and mechanosensory fates in the developing ear: patterning, signaling, and transcriptional control

Raft

Groves

2014

Cell Tissue Res

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The vertebrate inner ear is composed of multiple sensory receptor epithelia, each of which is specialized for detection of sound, gravity or angular acceleration. Each receptor epithelium contains mechanosensitive hair cells, which are connected to the brainstem by bipolar sensory neurons. Hair cells and their associated neurons are derived from the embryonic rudiment of the inner ear epithelium, but the precise spatial and temporal patterns of their generation, as well as the signals that coordinate these events, have only recently begun to be understood. Gene expression, lineage tracing, and mutant analyses suggest that both neurons and hair cells are generated from a common domain of neural and sensory competence in the embryonic inner ear rudiment. Members of the Shh, Wnt and FGF families, together with retinoic acid signals, regulate transcription factor genes within the inner ear rudiment to establish the axial identity of the ear and regionalize neurogenic activity. Close-range signaling, such as that of the Notch pathway, specifies the fate of sensory regions and individual cell types. We also describe positive and negative interactions between basic helix-loop-helix and SoxB family transcription factors that specify either neuronal or sensory fates in a context-dependent manner. Finally, we review recent work on inner ear development in zebrafish, which demonstrates that the relative timing of neurogenesis and sensory epithelial formation is not phylogenetically constrained.

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Balancing cell numbers during organogenesis: Six1a differentially affects neurons and sensory hair cells in the inner ear

Cited by 22 publications

References 62 publications

MicroRNA-30a regulates zebrafish myogenesis via targeting the transcription factor Six1

MicroRNA-30a regulates zebrafish myogenesis via targeting the transcription factor Six1

Pa2G4 is a novel Six1 co-factor that is required for neural crest and otic development

Segregating neural and mechanosensory fates in the developing ear: patterning, signaling, and transcriptional control

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