Abstract
The miR-183 family consists of 3 related microRNAs (miR-183, miR-96, miR-182) that are required to complete maturation of primary sensory cells in the mammalian inner ear. Because the level of these microRNAs is not uniform across hair cell subtypes in the murine cochlea, the question arises as to whether hair cell phenotypes are influenced by microRNA expression levels. To address this, we used the chicken embryo to study expression and misexpression of this gene family. By in situ hybridization, expression of all 3 microRNAs is robust in immature hair cells of both auditory and vestibular organs and is present in the statoacoustic ganglion. The auditory organ, called the basilar papilla, shows a weak radial gradient (highest on the neural side) in prosensory cells near the base on embryonic day 7. About nine days later, the basilar papilla also displays a longitudinal gradient (highest in apical hair cells) for the 3 microRNAs. Tol2-mediated gene delivery was used to ask whether cell phenotypes are malleable when the prosensory epithelium was forced to overexpress the miR-183 family. The expression plasmid included EGFP as a reporter located upstream of an intron carrying the microRNA genes. The vectors were electroporated into the otic cup/vesicle, resulting in strong co-expression of EGFP and the miR-183 family that persisted for at least 2 weeks. This manipulation did not generate ectopic hair cells in non-sensory territories of the cochlear duct, although within the basilar papilla, hair cells were over-represented relative to supporting cells. There was no evidence for a change in hair cell phenotypes, such as short-to-tall, or basal-to-apical hair cell features. Therefore, while increasing expression of the miR-183 family was sufficient to influence cell lineage decisions, it did not redirect the differentiation of hair cells towards alternative radial or longitudinal phenotypes.
Highlights
The avian basilar papilla (BP) exhibits several similarities to the mammalian hearing organ, the organ of Corti
Both avian tall HCs (THCs) and mammalian inner HCs (IHCs) are predominantly innervated by afferents [6, 7], while both avian short HCs (SHCs) and mammalian outer HCs (OHCs) receive most of their innervation from efferents and share a functional role in amplifying cochlear vibrations in response to sound [8, 9]
In situ hybridization was used to detect the expression of mature miR-183, miR-96 and miR182 on sections through the embryonic chicken inner ear at stages when nascent hair cells (HCs) are present in vestibular and auditory sensory organs (E5/S28 and E7/S31, respectively)
Summary
The avian basilar papilla (BP) exhibits several similarities to the mammalian hearing organ, the organ of Corti. In situ hybridization was used to detect the expression of mature miR-183, miR-96 and miR182 on sections through the embryonic chicken inner ear at stages when nascent HCs are present in vestibular and auditory sensory organs (E5/S28 and E7/S31, respectively).
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