Neurosensory Development in the Zebrafish Inner Ear

Vemaraju, Shruti

2011 December 1900

The vertebrate inner ear is a complex structure responsible for hearing and balance. The inner ear houses sensory epithelia composed of mechanosensory hair cells and non-sensory support cells. Hair cells synapse with neurons of the VIIIth cranial ganglion, the statoacoustic ganglion (SAG), and transmit sensory information to the hindbrain. This dissertation focuses on the development and regulation of both sensory and neuronal cell populations. The sensory epithelium is established by the basic helixloop- helix transcription factor Atoh1. Misexpression of atoh1a in zebrafish results in induction of ectopic sensory epithelia albeit in limited regions of the inner ear. We show that sensory competence of the inner ear can be enhanced by co-activation of fgf8/3 or sox2, genes that normally act in concert with atoh1a. The developing sensory epithelia express several factors that regulate differentiation and maintenance of hair cells. We show that pax5 is differentially expressed in the anterior utricular macula (sensory epithelium). Knockdown of pax5 function results in utricular hair cell death and subsequent loss of vestibular (balance) but not auditory (hearing) defects. SAG neurons are formed normally in these embryos but show disorganized dendrites in the utricle following loss of hair cells. Lastly, we examine the development of SAG. SAG precursors (neuroblasts) are formed in the floor of the ear by another basic helix-loophelix transcription factor neurogenin1 (neurog1). We show that Fgf emanating from the utricular macula specifies neuroblasts, that later delaminate from the otic floor and undergo a phase of proliferation. Neuroblasts then differentiate into bipolar neurons that extend processes to hair cells and targets in the hindbrain. We show evidence that differentiating neurons express fgf5 and regulate further development of the SAG. As more differentiated neurons accumulate, increasing level of Fgf terminates the phase of neuroblast specification. Later on, elevated Fgf stabilizes the transit-amplifying phase and inhibits terminal differentiation. Thus, Fgf signaling regulates SAG development at various stages to ensure that proper number of neurons is generated.

zebrafish

hair cell

statoacoustic ganglion

fgf5

otic neurogenesis

sox2

Fgf

Applications of organ culture of the mouse inner ear

Berggren, Diana

January 1991

The embryonic mouse inner ear was used as a model with which to study ototoxicity and tissue interactions. The inner ear anlage can be explanted and cultured in vitro from about the 12th gestational day (gd), and will differentiate parallel with the inner ear developing in vivo until a time corresponding to birth (21st gd). During this period the ovoid sac develops into the labyrinth. In the present thesis work, otic anlagen from gd 12, 13, 13.5, 15 and 16 were used. As a rule the explants were kept in culture until a time point equivalent to the 21st gd. Analyses using freeze-fracture technique and transmission electron microscopy showed that in cultured 13th gd otocysts the development of junctional complexes followed the same principal pattern as in vivo. Tight junctions develop into many strands lying parallel to the apical surface of all epithelial cells. Uncoupling of the hair cells occurs with loss of gap junctions. Some tight junctions had an aberrant appearence, with in part very thick strands and strands running at right angles to the apical surface. All aminoglycosides are potentially ototoxic. In the inner ear, outer hair cells of the organ of Corti and vestibular type I hair cells are affected by these antibiotics. The access route to the hair cells and the sites and mechanisms of action of aminoglycosides are not precisely defined. The uptake of tritiated tobramycin in 16th gd inner ears was studied. An initial rapid uptake of the drug, within 10 min, was followed by a slower accumulation, reaching a steady state after 60 min. Most of the tobramycin was bound reversibly, at least after a short period of incubation (2 h). The irreversibly bound fraction was of the same magnitude as the uptake within 10 min. Uptake took place against a concentration gradient. The otocyst can differentiate even without the statoacoustic ganglion. The interaction of the sensory epithelium with the ganglion was investigated by explanting the statoacoustic ganglion without target tissue. Twenty-five percent of the ganglions survived and had outgrowth of neurites but there was no differentiation into either the cochlear or vestibular type of neuron cells. Exposure of cultured otocysts (13 or 13.5 gd) to l-azetidine-2-carboxylic acid, a 1-proline analog that disrupts formation of collagen, resulted in retarded morphogenesis of the labyrinth and a dose- dependent derangement of the basal lamina. The expression of intermediate filaments (IFs) was analysed using monoclonal antibodies. The same IF pattem was found in cultured inner ears as in vivo. Explants were taken on 13th, 15th or 16th gd. Exposure to gentamicin, ethacrynic acid or cisplatin did not alter the IF composition. Cytokeratins (CKs) 8 and 18 were identified in all inner ear epithelia. In addition CKs 7 and 19 were visualized in the epithelia involved in maintaining endolymph homeostasis. The ganglion cells showed coexpression of CK, vimentin and neurofilaments. The elemental composition of the endolymph compartment of 16th gd inner ears cultured for 5 days was studied using energy-dispersive X-ray microanalysis. Na to K ratios characteristic of endolymph were found. / <p>S. 1-34: sammanfattning, s. 37-88: Härtill 6 uppsatser</p> / digitalisering@umu

organ culture

embryonic inner ear

intercellular junctions

aminoglycosides

statoacoustic ganglion

intermediate filaments

collagen

endolymph