Cochleovestibular nerve development is integrated with migratory neural crest cells

Sandell, Lisa L.; Tjaden, Naomi E. Butler; Barlow, Amanda; Trainor, Paul A.

doi:10.1016/j.ydbio.2013.11.009

Cited by 62 publications

(68 citation statements)

References 64 publications

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“…However, our data on melanocyte migration toward their target location in the cochlea, which to our knowledge has not been shown before in such clarity, suggests that cochlear melanocytes in humans migrate through the periotic mesenchyme from the opposite side. In agreement, several studies in mice embryos show the presence of neural crest derivatives or melanocytes near this part of the otic vesicle around embryonic day 10.5 (Steel et al, 1992; Freyer et al, 2011; Adameyko et al, 2012; Wakaoka et al, 2013; Sandell et al, 2014). Therefore, although the peripheral glial cells in the cochlea originate from the migratory wave of neural crest cells from rhombomere 4, we now hypothesize that cochlear melanocytes originate from a different wave of neural crest cells, namely those delaminating from the region at rhombomere 6, at the location of the developing glossopharyngeal nerve (cranial nerve IX) and the third pharyngeal arch.…”

Section: Discussionsupporting

confidence: 68%

“…Recently, it has been reported that cranial melanocytes can arise from Schwann cell precursors migrating together with outgrowing nerves (Adameyko et al, 2009; Adameyko et al, 2012). As Schwann cell precursors arrive in the cochlea via the cochlear nerve (Sandell et al, 2014), it is tempting to propose that melanocytes (precursors) may travel along the same path. However, our data on melanocyte migration toward their target location in the cochlea, which to our knowledge has not been shown before in such clarity, suggests that cochlear melanocytes in humans migrate through the periotic mesenchyme from the opposite side.…”

Section: Discussionmentioning

confidence: 99%

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Development of the stria vascularis and potassium regulation in the human fetal cochlea: Insights into hereditary sensorineural hearing loss

Locher

Groot

Iperen

et al. 2015

Developmental Neurobiology

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Sensorineural hearing loss (SNHL) is one of the most common congenital disorders in humans, afflicting one in every thousand newborns. The majority is of heritable origin and can be divided in syndromic and nonsyndromic forms. Knowledge of the expression profile of affected genes in the human fetal cochlea is limited, and as many of the gene mutations causing SNHL likely affect the stria vascularis or cochlear potassium homeostasis (both essential to hearing), a better insight into the embryological development of this organ is needed to understand SNHL etiologies. We present an investigation on the development of the stria vascularis in the human fetal cochlea between 9 and 18 weeks of gestation (W9–W18) and show the cochlear expression dynamics of key potassium‐regulating proteins. At W12, MITF+/SOX10+/KIT+ neural‐crest‐derived melanocytes migrated into the cochlea and penetrated the basement membrane of the lateral wall epithelium, developing into the intermediate cells of the stria vascularis. These melanocytes tightly integrated with Na+/K+‐ATPase‐positive marginal cells, which started to express KCNQ1 in their apical membrane at W16. At W18, KCNJ10 and gap junction proteins GJB2/CX26 and GJB6/CX30 were expressed in the cells in the outer sulcus, but not in the spiral ligament. Finally, we investigated GJA1/CX43 and GJE1/CX23 expression, and suggest that GJE1 presents a potential new SNHL associated locus. Our study helps to better understand human cochlear development, provides more insight into multiple forms of hereditary SNHL, and suggests that human hearing does not commence before the third trimester of pregnancy. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 75: 1219–1240, 2015

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Section: Discussionsupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Development of the stria vascularis and potassium regulation in the human fetal cochlea: Insights into hereditary sensorineural hearing loss

Locher

Groot

Iperen

et al. 2015

Developmental Neurobiology

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“…Concomitant with delamination of neuroblasts, glial cells also migrate from the neural crest [25, 26] and serve as supporting cells for PANs. Myelinating Schwann cells, a glial subtype, surround the peripheral process of type I PANs and non-myelinating Schwann cells surround the peripheral processes of type II PANs.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Expression of Sox2, Gata3, and Prox1 during Primary Auditory Neuron Development in the Mammalian Cochlea

2017

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Primary auditory neurons (PANs) connect cochlear sensory hair cells in the mammalian inner ear to cochlear nucleus neurons in the brainstem. PANs develop from neuroblasts delaminated from the proneurosensory domain of the otocyst and keep maturing until the onset of hearing after birth. There are two types of PANs: type I, which innervate the inner hair cells (IHCs), and type II, which innervate the outer hair cells (OHCs). Glial cells surrounding these neurons originate from neural crest cells and migrate to the spiral ganglion. Several transcription factors are known to regulate the development and differentiation of PANs. Here we systematically examined the spatiotemporal expression of five transcription factors: Sox2, Sox10, Gata3, Mafb, and Prox1 from early delamination at embryonic day (E) 10.5 to adult. We found that Sox2 and Sox10 were initially expressed in the proneurosensory cells in the otocyst (E10.5). By E12.75 both Sox2 and Sox10 were downregulated in the developing PANs; however, Sox2 expression transiently increased in the neurons around birth. Furthermore, both Sox2 and Sox10 continued to be expressed in spiral ganglion glial cells. We also show that Gata3 and Prox1 were first expressed in all developing neurons, followed by a decrease in expression of Gata3 and Mafb in type I PANs and Prox1 in type II PANs as they matured. Moreover, we describe two subtypes of type II neurons based on Peripherin expression. These results suggest that Sox2, Gata3 and Prox1 play a role during neurogenesis as well as maturation of the PANs.

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“…A similar intermingling of placode and neural crest-derived neurons has been suggested for the lateral line and the inner ear [Freyer et al 2011], with a report of variable numbers of neurons from the spiral ganglion and vestibular neurons as well as hair cells being derived from Pax3-expressing neural crest precursors [Freyer et al 2011]. However, in a different transgenic mouse line expressing Pax3-cre, transgene expression labeled only Schwann cell precursors that tightly interacted with the developing vestibular and cochlear ganglion neurons [Sandell et al 2014]. Thus, the neural crest contribution to the inner ear and lateral line systems does not appear to include the neuronal lineage [Mao et al 2014].…”

Section: Evolution and Development Of Peripheral Sensory Structures Amentioning

confidence: 99%

Sensing External and Self-Motion with Hair Cells: A Comparison of the Lateral Line and Vestibular Systems from a Developmental and Evolutionary Perspective

Chagnaud

Engelmann²,

Fritzsch³

et al. 2017

Brain Behav Evol

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Detection of motion is a feature essential to any living animal. In vertebrates, mechanosensory hair cells organized into the lateral line and vestibular systems are used to detect external water or head/body motion, respectively. While the neuronal components to detect these physical attributes are similar between the two sensory systems, the organizational pattern of the receptors in the periphery and the distribution of hindbrain afferent and efferent projections are adapted to the specific functions of the respective system. Here we provide a concise review comparing the functional organization of the vestibular and lateral line systems from the development of the organs to the wiring from the periphery and the first processing stages. The goal of this review is to highlight the similarities and differences to demonstrate how evolution caused a common neuronal substrate to adapt to different functions, one for the detection of external water stimuli and the generation of sensory maps and the other for the detection of self-motion and the generation of motor commands for immediate behavioral reactions.

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Cochleovestibular nerve development is integrated with migratory neural crest cells

Cited by 62 publications

References 64 publications

Development of the stria vascularis and potassium regulation in the human fetal cochlea: Insights into hereditary sensorineural hearing loss

Development of the stria vascularis and potassium regulation in the human fetal cochlea: Insights into hereditary sensorineural hearing loss

Dynamic Expression of Sox2, Gata3, and Prox1 during Primary Auditory Neuron Development in the Mammalian Cochlea

Sensing External and Self-Motion with Hair Cells: A Comparison of the Lateral Line and Vestibular Systems from a Developmental and Evolutionary Perspective

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