Richard J Helyer scite author profile

Conditionally immortal cell lines were established from the ventral otocyst of the Immortomouse at embryonic day 10.5 and selected to represent precursors of auditory sensory neural and epithelial cells. Selection was based upon dissection, tissue-specific markers, and expression of the transcription factor GATA3. Two cell lines expressed GATA3 but possessed intrinsically different genetic programs under differentiating conditions. US/VOT-E36 represented epithelial progenitors with potential to differentiate into sensory and nonsensory epithelial cells. US/VOT-N33 represented migrating neuroblasts. Under differentiating conditions in vitro the cell lines expressed very different gene expression profiles. Expression of several cell- and tissue-specific markers, including the transcription factors Pax2, GATA3, and NeuroD, differed between the cell lines in a pattern consistent with that observed between their counterparts in vivo. We suggest that these and other conditionally immortal cell lines can be used to study transient events in development against different backgrounds of cell competence.

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E-cadherin and the Differentiation of Mammalian Vestibular Hair Cells

Hackett

Davies

Helyer

et al. 2002

Experimental Cell Research

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Development of Outward Potassium Currents in Inner and Outer Hair Cells from the Embryonic Mouse Cochlea

Helyer

Kennedy²,

Davies³

et al. 2004

Audiol Neurotol

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We recorded K⁺ currents in inner (IHCs) and outer (OHCs) hair cells from mice at embryonic days 16 and 18 and on the day of birth (PO) to characterize their early physiological differentiation. In both cell types, outward currents increased in size during late embryonic development, in cells situated in both the apical and basal coils of the cochlea. Currents increased up to six-fold, with current density increasing four-fold. Currents in basal cells were generally larger than in the apex, and currents in IHCs were larger than in OHCs at any given stage. In OHCs, they were initially non-inactivating but gained the partial inactivation characteristic of the K⁺ current of neonatal mouse cochlear hair cells, I_K,neo, by day 18 in the base and by P0 in the apex. In IHCs, there was little change, other than in amplitude, with partial inactivation already evident in the base by embryonic day 16. These results suggest that changes in the channel complement of OHCs occur within a few days of terminal mitosis, whereas in IHCs any such development would occur earlier. The progressive development of K⁺ currents correlates with a developmental delay of around 2 days from the base to the apex of the cochlea.

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Transplantation of conditionally immortal auditory neuroblasts to the auditory nerve

Sekiya

Holley

Kojima

et al. 2007

Eur J of Neuroscience

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Cell transplantation is a realistic potential therapy for replacement of auditory sensory neurons and could benefit patients with cochlear implants or acoustic neuropathies. The procedure involves many experimental variables, including the nature and conditioning of donor cells, surgical technique and degree of degeneration in the host tissue. It is essential to control these variables in order to develop cell transplantation techniques effectively. We have characterized a conditionally immortal, mouse cell line suitable for transplantation to the auditory nerve. Structural and physiological markers defined the cells as early auditory neuroblasts that lacked neuronal, voltage-gated sodium or calcium currents and had an undifferentiated morphology. When transplanted into the auditory nerves of rats in vivo, the cells migrated peripherally and centrally and aggregated to form coherent, ectopic 'ganglia'. After 7 days they expressed beta 3-tubulin and adopted a similar morphology to native spiral ganglion neurons. They also developed bipolar projections aligned with the host nerves. There was no evidence for uncontrolled proliferation in vivo and cells survived for at least 63 days. If cells were transplanted with the appropriate surgical technique then the auditory brainstem responses were preserved. We have shown that immortal cell lines can potentially be used in the mammalian ear, that it is possible to differentiate significant numbers of cells within the auditory nerve tract and that surgery and cell injection can be achieved with no damage to the cochlea and with minimal degradation of the auditory brainstem response.

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Progress in the utilization of high-fidelity simulation in basic science education

Helyer

Dickens

2016

Advances in Physiology Education

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Richard J Helyer

Ventral otic cell lines as developmental models of auditory epithelial and neural precursors

E-cadherin and the Differentiation of Mammalian Vestibular Hair Cells

Development of Outward Potassium Currents in Inner and Outer Hair Cells from the Embryonic Mouse Cochlea

Transplantation of conditionally immortal auditory neuroblasts to the auditory nerve

Progress in the utilization of high-fidelity simulation in basic science education

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