<i>vHnf1</i> regulates specification of caudal rhombomere identity in the chick hindbrain

Aragón, Ferrán; Vázquez-Echeverría, Citlali; Ulloa, Encarna; Reber, Michaël; Cereghini, Silvia; Alsina, Berta; Giráldez, Fernando; Pujades, Cristina

doi:10.1002/dvdy.20528

Cited by 30 publications

(38 citation statements)

References 60 publications

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“…RA-dependent activation of Mafb depends, at least in part, on the homeodomain protein, variant hepatic nuclear factor 1 (vHnf1/HNF1) (Aragon et al, 2005;Hernandez et al, 2004;Kim et al, 2005;Lecaudey et al, 2004;Maves and Kimmel, 2005;Wiellette and Sive, 2003). At the 0-somite stage, Hnf1b expression, which is induced by RA, extends from the future r4/r5 boundary posteriorly into the posterior hindbrain and spinal cord of mouse, chick and zebrafish embryos (Aragon et al, 2005;Kim et al, 2005;Lecaudey et al, 2004;Maves and Kimmel, 2005). In the mouse, identification of the r5-r6 specific S5 enhancer from Mafb illustrated that vHNF1 is essential, but not sufficient, for driving r5-r6 expression in 0-to 10-somite-stage embryos.…”

Section: Introductionmentioning

confidence: 99%

Cdx1 refines positional identity of the vertebrate hindbrain by directly repressingMafbexpression

et al. 2011

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SUMMARYAn interplay of transcription factors interprets signalling pathways to define anteroposterior positions along the vertebrate axis. In the hindbrain, these transcription factors prompt the position-appropriate appearance of seven to eight segmental structures, known as rhombomeres (r1-r8). The evolutionarily conserved Cdx caudal-type homeodomain transcription factors help specify the vertebrate trunk and tail but have not been shown to directly regulate hindbrain patterning genes. Mafb (Kreisler, Krml1, valentino), a basic domain leucine zipper transcription factor, is required for development of r5 and r6 and is the first gene to show restricted expression within these two segments. The homeodomain protein vHnf1 (Hnf1b) directly activates Mafb expression. vHnf1 and Mafb share an anterior expression limit at the r4/r5 boundary but vHnf1 expression extends beyond the posterior limit of Mafb and, therefore, cannot establish the posterior Mafb expression boundary. Upon identifying regulatory sequences responsible for posterior Mafb repression, we have used in situ hybridization, immunofluorescence and chromatin immunoprecipitation (ChIP) analyses to determine that Cdx1 directly inhibits early Mafb expression in the neural tube posterior of the r6/r7 boundary, which is the anteriormost boundary of Cdx1 expression in the hindbrain. Cdx1 dependent repression of Mafb is transient. After the 10-somite stage, another mechanism acts to restrict Mafb expression in its normal r5 and r6 domain, even in the absence of Cdx1. Our findings identify Mafb as one of the earliest direct targets of Cdx1 and show that Cdx1 plays a direct role in early hindbrain patterning. Thus, just as Cdx2 and Cdx4 govern the trunk-to-tail transition, Cdx1 may regulate the hindbrain-to-spinal cord transition.

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Section: Introductionmentioning

confidence: 99%

Cdx1 refines positional identity of the vertebrate hindbrain by directly repressingMafbexpression

et al. 2011

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“…Restricted Fgf3 expression patterns in the adjacent developing hindbrain confirm this statement in several vertebrate species (zebrafish: Phillips et al 2001, 2003; Kwak et al 2002; Leger and Brand 2002; Maroon et al 2002; Maves et al 2002; Walshe et al 2002; Xenopus : Lombardo et al 1998; chick: Mahmood et al 1995; Aragón et al 2005; Kil et al 2005; Aragón and Pujades 2009; Abello et al 2010; mouse: Mahmood et al 1996; Mckay et al 1996; Pirvola et al 2000; Wright and Mansour 2003; Lin et al 2005; Hatch et al 2007). FGF3 might also participate in the complex network of intrinsic diffusible signals from the otic placode itself.…”

Section: Discussionmentioning

confidence: 78%

“…The incipient acoustic-vestibular ganglion showed a low Fgf3 expression (AVG; Fig 1a, d). In addition, Fgf3 transcripts were recognized with no trouble in the hindbrain alar plate (asterisk in Fig 1a), exclusively in the area separating contiguous rhombomeres, but not in the body of any rhombomere (rh6 in Fig 1d; see Aragón et al, 2005). …”

Section: Resultsmentioning

confidence: 99%

Fgf3 and Fgf16 expression patterns define spatial and temporal domains in the developing chick inner ear

et al. 2016

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The inner ear is a complex sensorial structure with auditory and vestibular functions. The developing otic epithelium gives rise to neurosensory and non-sensory elements of the adult membranous labyrinth. Extrinsic and intrinsic signals manage the patterning and cell specification of the developing otic epithelium by the establishment of lineage-restricted compartments defined in turn by differential expressions of regulatory genes. FGF3 and FGF16 are excellent candidates to govern these developmental events. In the chick, we showed that Fgf3 expression was present in the borders of all developing cristae. Strong Fgf16 expressions were detected in a portion of the developing vertical and horizontal pouches, whereas the cristae showed weaker or undetected Fgf16 expressions at different developmental stages. Concerning the rest of the vestibular sensory elements, both the utricular and saccular maculae were Fgf3 positive. Interestingly, a strong Fgf16 expression delimited these Fgf16-negative sensory patches. The Fgf3-negative macula neglecta and Fgf3-positive macula lagena were included within weakly Fgf16-expressing areas. Therefore, different FGF-mediated mechanisms might regulate the specification of the anterior (utricular and saccular) and posterior (neglecta and lagena) maculae. In the developing cochlear duct, the dynamic Fgf3 and Fgf16 expressions suggest their co-operation in the early specification and later cell differentiation in the hearing system. The requirement of Fgf3 and Fgf16 genes in endolymphatic apparatus development and neurogenesis are discussed. Based on these observations, FGF3 and FGF16 appear to be key signaling pathways to control the inner ear plan by means of defining epithelial identities within the developing otic epithelium.

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Section: Caudal Hindbrain Patterningmentioning

confidence: 99%

“…Thus, by secreting FGF signals, r4 forms a signaling centre involved in caudal hindbrain patterning, in particular in val and krox20 activation. Although Fgf gene expression patterns in the hindbrain of amniotes differ from that of zebrafish (see below), FGF signaling in chick embryos has also been involved in hindbrain patterning, particularly in the regulation of MafB and Krox20 expression (Marin and Charnay, 2000;Aragon et al, 2005).The functional data obtained in different vertebrates can be combined into a regulatory hierarchy involved in caudal hindbrain formation (Figure 4). However, it should be mentioned that several data have been obtained in only one vertebrate species.…”

mentioning

confidence: 99%

Hindbrain signals in otic regionalization: walk on the wild side

Schneider‐Maunoury¹,

Pujades²

2007

Int. J. Dev. Biol.

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The inner ear, the sensory organ responsible for hearing and balance, contains specialized sensory and non-sensory epithelia arranged in a highly complex three-dimensional structure. To achieve this level of complexity, a tight coordination between morphogenesis and cell fate specification is essential during otic development. Tissues surrounding the otic primordium and more particularly the adjacent segmented hindbrain, have been implicated in conferring signals required for inner ear development. In this review, we present the current view on the role of hindbrain signals in axial specification of the inner ear. The functional analysis of mutants of hindbrain segmentation genes, as well as the investigation of signaling pathways potentially involved, all point to an essential role of FGF, Wnt and Hh signaling in otic regionalization. However, these data provide conflicting evidence regarding the involvement of hindbrain signals in otic regionalization in fish and in amniotes. We discuss the possible origin of these differences. KEY WORDS: hindbrain, patterning, otic regionalization, FGF signaling Basic structure of the adult inner earThe vertebrate inner ear is a sensory organ responsible for the senses of hearing, balance and detection of acceleration. It consists of a closed epithelial structure, the membranous labyrinth, composed of several sensory and non-sensory structures and surrounded by a bony capsule. The mechanosensory function of the inner ear is provided by the hair cells, which, along with supporting and secretory cells, are contained in the sensory epithelia. Hair cells are innervated by sensory neurons of the vestibular and acoustic ganglia that project to the vestibular and auditory nuclei in the brainstem.The membranous labyrinth is subdivided into vestibular and auditory regions. The vestibule forms the dorsal part of the labyrinth and is responsible for the senses of motion and position. It comprises the three cristae, the sensory organs located at the basis of three orthogonally arranged semi-circular canals and the utricle and saccule, which contain two additional sensory organs, the maculae. The ventral auditory part is more diverse. In mammals it is composed of the cochlea, a coiled structure whose sensory epithelium is called the organ of Corti. In birds, the auditory region is composed of the basilar papilla, while in fish the saccule and lagena are both involved in hearing (Figure 1). In jawed vertebrates, the adult inner ear is highly regionalised along its three axes. In addition to the dorso-ventral (DV) subdivision Int. J. Dev. Biol. 51: 495-506 (2007) doi: 10.1387/ijdb.072345ss into vestibular and auditory regions, an asymmetry along the medio-lateral (ML) axis is also obvious with, for instance, the endolymphatic sac and duct located in the medial part, close to the brain. The whole structure also shows pronounced anteroposterior (AP) asymmetry (Figure 1).How are these asymmetries established during ear development? What are the signals involved in establishing thes...

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vHnf1 regulates specification of caudal rhombomere identity in the chick hindbrain

Cited by 30 publications

References 60 publications

Cdx1 refines positional identity of the vertebrate hindbrain by directly repressingMafbexpression

Cdx1 refines positional identity of the vertebrate hindbrain by directly repressingMafbexpression

Fgf3 and Fgf16 expression patterns define spatial and temporal domains in the developing chick inner ear

Hindbrain signals in otic regionalization: walk on the wild side

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