Ephrin-B2 governs morphogenesis of endolymphatic sac and duct epithelia in the mouse inner ear

Raft, Steven; Andrade, Leonardo R.; Shao, Dongmei; Akiyama, Haruhiko; Henkemeyer, Mark; Wu, Doris K.

doi:10.1016/j.ydbio.2014.02.019

Cited by 24 publications

(28 citation statements)

References 78 publications

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“…Here, both genes are expressed later in development and appear to regulate genes involved in the function of transport epithelium. In the case of zebrafish, foxi3 regulates the development of epidermal ionocytes (Cruz et al, 2013; Esaki et al, 2009; Hsiao et al, 2007; Janicke et al, 2007; Janicke et al, 2010; Thermes et al, 2010), while Foxi1 regulates genes important for production and homeostasis of endolymphatic fluid, such as SLC26A4 which encodes pendrin (Blomqvist et al, 2004; Hulander et al, 2003; Raft et al, 2014; Vidarsson et al, 2009). …”

Section: Discussionmentioning

confidence: 99%

The mouse Foxi3 transcription factor is necessary for the development of posterior placodes

Birol

Ohyama

Edlund

et al. 2016

Developmental Biology

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The inner ear develops from the otic placode, one of the cranial placodes that arise from a region of ectoderm adjacent to the anterior neural plate called the pre-placodal domain. We have identified a Forkhead family transcription factor, Foxi3, that is expressed in the pre-placodal domain and down-regulated when the otic placode is induced. We now show that Foxi3 mutant mice do not form otic placodes as evidenced by expression changes in early molecular markers and the lack of thickened placodal ectoderm, an otic cup or otocyst. Some preplacodal genes downstream of Foxi3 - Gata3, Six1 and Eya1 - are not expressed in the ectoderm of Foxi3 mutant mice, and the ectoderm exhibits signs of increased apoptosis. We also show that Fgf signals from the hindbrain and cranial mesoderm, which are necessary for otic placode induction, are received by pre-placodal ectoderm in Foxi3 mutants, but do not initiate otic induction. Finally, we show that the epibranchial placodes that develop in close proximity to the otic placode and the mandibular division of the trigeminal ganglion are missing in Foxi3 mutants. Our data suggest that Foxi3 is necessary to prime pre-placodal ectoderm for the correct interpretation of inductive signals for the otic and epibranchial placodes.

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Section: Discussionmentioning

confidence: 99%

The mouse Foxi3 transcription factor is necessary for the development of posterior placodes

Birol

Ohyama

Edlund

et al. 2016

Developmental Biology

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“…Although we focused on the potential role of ephrin-B/EphB signaling in axon targeting, we note that ephrin/Eph interactions are also involved in epithelial cell organization [55,56]. In EphB3-rtTA mice, we detected lacZ activity in the mesenchyme adjacent to the epithelium at E13.5–14.5 and, at E17.5, in the apical aspect of the dorsal lingual epithelium as well as just beneath the epithelium (our unpublished observations).…”

Section: Discussionmentioning

confidence: 99%

Ephrin-B/EphB Signaling Is Required for Normal Innervation of Lingual Gustatory Papillae

et al. 2016

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The innervation of taste buds is an excellent model system for studying the guidance of axons during targeting because of their discrete nature and the high fidelity of innervation. The pregustatory epithelium of fungiform papillae is known to secrete diffusible axon guidance cues such as BDNF and Sema3A that attract and repel, respectively, geniculate ganglion axons during targeting, but diffusible factors alone are unlikely to explain how taste axon terminals are restricted to their territories within the taste bud. Nondiffusible cell surface proteins such as Ephs and ephrins can act as receptors and/or ligands for one another and are known to control axon terminal positioning in several parts of the nervous system, but they have not been studied in the gustatory system. We report that ephrin-B2 linked β-galactosidase staining and immunostaining was present along the dorsal epithelium of the mouse tongue as early as embryonic day 15.5 (E15.5), but was not detected at E14.5, when axons first enter the epithelium. Ephrin-B1 immunolabeling was barely detected in the epithelium and found at a somewhat higher concentration in the mesenchyme subjacent to the epithelium. EphB1 and EphB2 were detected in lingual sensory afferents in vivo and geniculate neurites in vitro. Ephrin-B1 and ephrin-B2 were similarly effective in repelling or suppressing outgrowth by geniculate neurites in vitro. These in vitro effects were independent of the neurotrophin used to promote outgrowth, but were reduced by elevated levels of laminin. In vivo, mice null for EphB1 and EphB2 exhibited decreased gustatory innervation of fungiform papillae. These data provide evidence that ephrin-B forward signaling is necessary for normal gustatory innervation of the mammalian tongue.

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“…Wnt signaling orchestrates the proliferative pressure that drives the upward movement of intestinal epithelial cells and also regulates their migratory properties by controlling the expression of Eph/ephrin signaling components (Batlle et al, 2002). Eph/ephrin signaling is associated with several aspects of inner ear development and hair cell innervation (Cowan et al, 2000; Coate et al, 2012; Defourny et al, 2013; Raft et al, 2014), but a specific role in auditory hair cell formation and/or cochlear morphogenesis has yet to be reported, possibly due to functional redundancy between the large number of family members expressed in the ear (Saeger et al, 2011). It will be interesting to determine whether similar mechanisms act to facilitate the migration of Wnt responsive progenitors in the gut and inner ear.…”

Section: Discussionmentioning

confidence: 99%

The cochlear sensory epithelium derives from Wnt responsive cells in the dorsomedial otic cup

Brown

Rakowiecki

et al. 2015

Developmental Biology

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Wnt1 and Wnt3a secreted from the dorsal neural tube were previously shown to regulate a gene expression program in the dorsal otic vesicle that is necessary for vestibular morphogenesis (Riccomagno et al., 2005). Unexpectedly, Wnt1−/−; Wnt3a−/− embryos also displayed a pronounced defect in the outgrowth of the ventrally derived cochlear duct. To determine how Wnt signaling in the dorsal otocyst contributes to cochlear development we performed a series of genetic fate mapping experiments using two independent Wnt responsive driver strains (TopCreER and Gbx2CreER) that when crossed to inducible responder lines (RosalacZ or RosazsGreen) permanently labeled dorsomedial otic progenitors and their derivatives. Tamoxifen time course experiments revealed that most vestibular structures showed some degree of labeling when recombination was induced between E7.75 and E12.5, consistent with continuous Wnt signaling activity in this tissue. Remarkably, a population of Wnt responsive cells in the dorsal otocyst was also found to contribute to the sensory epithelium of the cochlear duct, including auditory hair and support cells. Similar results were observed with both TopCreER and Gbx2CreER strains. The ventral displacement of Wnt responsive cells followed a spatiotemporal sequence that initiated in the anterior otic cup at, or immediately prior to, the 17-somite stage (E9) and then spread progressively to the posterior pole of the otic vesicle by the 25-somite stage (E9.5). These lineage-tracing experiments identify the earliest known origin of auditory sensory progenitors within a population of Wnt responsive cells in the dorsomedial otic cup.

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Ephrin-B2 governs morphogenesis of endolymphatic sac and duct epithelia in the mouse inner ear

Cited by 24 publications

References 78 publications

The mouse Foxi3 transcription factor is necessary for the development of posterior placodes

The mouse Foxi3 transcription factor is necessary for the development of posterior placodes

Ephrin-B/EphB Signaling Is Required for Normal Innervation of Lingual Gustatory Papillae

The cochlear sensory epithelium derives from Wnt responsive cells in the dorsomedial otic cup

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