A Critical Period of Ear Development Controlled by Distinct Populations of Ciliated Cells in the Zebrafish

Riley, Bruce B.; Zhu, Changxing; Janetopoulos, Christopher; Aufderheide, Karl J.

doi:10.1006/dbio.1997.8736

Cited by 142 publications

(208 citation statements)

References 49 publications

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“…Hair cell kinocilia, which can be observed in live specimens and stain positively for acetylated tubulin, serve to tether otoliths in place at the onset of vesicle formation. These early hair cells are atypical in several regards and are referred to as tether cells to distinguish them from the more typical hair cells that form later (Riley et al, 1997). Despite the presence of kinocilia, the cell bodies of tether cells do not take on the morphology of mature hair cells until 22 hpf (25-26 somites).…”

Section: Specification Of Hair Cells and Supporting Cells In Sensory mentioning

confidence: 99%

“…This initial seeding process, which lays the foundation for future otolith growth, occurs only during a critical period from 18 to 24 hpf. Soon after 24 hpf, the supply of visible seeding particles becomes depleted, beating cilia are resorbed, and otolith growth slows dramatically (Riley et al, 1997).…”

Section: Development Of Otolithsmentioning

confidence: 99%

“…Embryos carrying the mnl mutation usually produce only a single otolith per vesicle due to a defect in otolith seeding (Riley et al, 1997). Although most aspects of inner ear development appear normal, mnl embryos show a 4-hr delay in the ability of tether cell kinocilia to bind seeding particles.…”

Section: Development Of Otolithsmentioning

confidence: 99%

“…In contrast, formation of utricular otoliths is totally blocked by immobilizing mutant embryos in the opposite orientation. After the close of the critical period, seeding particles are depleted and gravity no longer affects otolith morphogenesis (Riley et al, 1997).…”

Section: Development Of Otolithsmentioning

confidence: 99%

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Development of the zebrafish inner ear

Whitfield

Riley

Chiang

et al. 2002

Developmental Dynamics

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211

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Recent years have seen a renaissance of investigation into the mechanisms of inner ear development. Genetic analysis of zebrafish has contributed significantly to this endeavour, with several dramatic advances reported over the past year or two. Here, we review the major findings from recent work in zebrafish. Several cellular and molecular mechanisms have been elucidated, including the signaling pathways controlling induction of the otic placode, morphogenesis and patterning of the otic vesicle, and elaboration of functional attributes of inner ear.

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Section: Specification Of Hair Cells and Supporting Cells In Sensory mentioning

confidence: 99%

Section: Development Of Otolithsmentioning

confidence: 99%

Section: Development Of Otolithsmentioning

confidence: 99%

Section: Development Of Otolithsmentioning

confidence: 99%

See 2 more Smart Citations

Development of the zebrafish inner ear

Whitfield

Riley

Chiang

et al. 2002

Developmental Dynamics

Self Cite

211

186

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show abstract

“…Otolith formation begins with the aggregation of free-floating protein core particles, identifiable at 18-20 h post-fertilization (hpf). Core particles are directed to either of the two developing sensory maculae through the action of ciliated cells that line the otocyst cavity (Riley et al, 1997) where they adhere to the modified stereocilia on the first hair cells (tether cells) at the anterior and posterior poles of the otocyst. These preotoliths are rapidly mineralized with the aragonitic polymorph of CaCO 3 by 24 hpf.…”

Section: Structure and Development Of The Otoconial And Otolithic Memmentioning

confidence: 99%

Mixing model systems: Using zebrafish and mouse inner ear mutants and other organ systems to unravel the mystery of otoconial development

Hughes

Thalmann

et al. 2006

Brain Research

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Human vestibular dysfunction is an increasing clinical problem. Degeneration or displacement of otoconia is a significant etiology of age-related balance disorders and Benign Positional Vertigo (BPV). In addition, commonly used antibiotics, such as aminoglycoside antibiotics, can lead to disruption of otoconial structure and function. Despite such clinical significance, relatively little information has been compiled about the development and maintenance of otoconia in humans. Recent studies in model organisms and other mammalian organ systems have revealed some of the proteins and processes required for the normal biomineralization of otoconia and otoliths in the inner ear of vertebrates. Orchestration of extracellular biomineralization requires bringing together ionic and proteinaceous components in time and space. Coordination of these events requires the normal formation of the otocyst and sensory maculae, specific secretion and localization of extracellular matrix proteins, as well as tight regulation of the endolymph ionic environment. Disruption of any of these processes can lead to the formation of abnormally shaped, or ectopic, otoconia, or otoconial agenesis. We propose that normal generation of otoconia requires a complex temporal and spatial control of developmental and biochemical events. In this review, we suggest a new hypothetical model for normal otoconial and otolith formation based on matrix vesicle mineralization in bone which we believe to be supported by information from existing mutants, morphants, and biochemical studies.

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