Daniel J. Jagger

Auditory hair cell precursors immortalized from the mammalian inner ear.

Mammalian auditory hair cells are few in number, experimentally inaccessible, and do not proliferate postnatally or in vitro. Immortal cell lines with the potential to differentiate into auditory hair cells would substantially facilitate auditory research, drug development, and the isolation of critical molecules involved in hair cell biology. We have established two conditionally immortal cell lines that express at least five characteristic hair cell markers. These markers are the transcription factor Brn3.1, the α9 subunit of the acetylcholine receptor, the stereociliary protein fimbrin and the myosins VI and VIIA. These hair cell precursors permit functional studies of cochlear genes and in the longer term they will provide the means to explore therapeutic methods of stimulating auditory hair cell regeneration.

Compartmentalized and Signal-Selective Gap Junctional Coupling in the Hearing Cochlea

Gap junctional intercellular communication (GJIC) plays a major role in cochlear function. Recent evidence suggests that connexin 26 (Cx26) and Cx30 are the major constituent proteins of cochlear gap junction channels, possibly in a unique heteromeric configuration. We investigated the functional and structural properties of native cochlear gap junctions in rats, from birth to the onset of hearing [postnatal day 12 (P12)[. Confocal immunofluorescence revealed increasing Cx26 and Cx30 expression from P0 to P12. Functional GJIC was assessed by coinjection of Lucifer yellow (LY) and Neurobiotin (NBN) during whole-cell recordings in cochlear slices. At P0, there was restricted dye transfer between supporting cells around outer hair cells. Transfer was more extensive between supporting cells around inner hair cells. At P8, there was extensive transfer of both dyes between all supporting cell types. By P12, LY no longer transferred between the supporting cells immediately adjacent to hair cells but still transferred between more peripheral cells. NBN transferred freely, but it did not transfer between inner and outer pillar cells. Freeze fracture further demonstrated decreasing GJIC between inner and outer pillar cells around the onset of hearing. These data are supportive of the appearance of signal-selective gap junctions around the onset of hearing, with specific properties required to support auditory function. Furthermore, they suggest that separate medial and lateral buffering compartments exist in the hearing cochlea, which are individually dedicated to the homeostasis of inner hair cells and outer hair cells.

The Inner Ear Contains Heteromeric Channels Composed of Cx26 and Cx30 and Deafness-Related Mutations in Cx26 Have a Dominant Negative Effect on Cx30

Cx26 and cx30 co-localize in tissues of the mammalian cochlea. Transfected HeLa cells were used to examine interactions between cx26 and cx30 and the effects on cx30 of four point mutations in cx26 that are associated with dominantly inherited hearing loss—W44S, G59A, D66H and R75W. When co-expressed, wtcx26 and wtcx30 trafficked to the same gap junction plaques. Cells transferred neurobiotin but not Lucifer Yellow, which passes freely through cx26 channels, suggesting cx30 affects the properties of cx26. G59A and D66H had a perinuclear localization when expressed alone but trafficked to the membrane when co-expressed with cx30. Co-expression of W44S, G59A or R75W with cx30, significantly reduced neurobiotin transfer in comparison with cells expressing cx30 only. These results indicate that cx26 and cx30 can oligomerize to form heteromeric connexons and demonstrate a dominant negative effect of some cx26 mutants on cx30. Immunogold labeling of thin sections of the cochlea showed both cx26 and cx30 distributed evenly on both sides of individual gap junction profiles. Immunoprecipitation of cochlear membrane proteins, isolated by procedures that preserve connexons, with either cx30 or cx26 antibodies precipitated both cx26 and cx30. Following co-injection of Lucifer Yellow and neurobiotin into individual supporting cells of the organ of Corti in cochlear slices, neurobiotin transferred to many cells, but Lucifer Yellow was retained in the injected cell. These observations are consistent with junctions composed of cx26/cx30 heteromeric connexons in the cochlea. The functional disruption caused by some cx26 mutations upon such heteromeric channels may underlie the non-syndromic nature of their effects on hearing.

Purinergic Regulation of Sound Transduction and Auditory Neurotransmission

In the cochlea, extracellular ATP influences the endocochlear potential, micromechanics, and neurotransmission via P2 receptors. Evidence for this arises from studies demonstrating widespread expression of ATP-gated ion channels (assembled from P2X receptor subunits) and G protein-coupled receptors (P2Y receptors). P2X2 receptor subunits are localized to the luminal membranes of epithelial cells and hair cells lining scala media. These ion channels provide a shunt pathway for K+ ion egress. Thus, when noise exposure elevates ATP levels in this cochlear compartment, the K+ conductance through P2X receptors reduces the endocochlear potential. ATP-mediated K+ efflux from scala media is complemented by a P2Y receptor G protein-coupled pathway that provides coincident reduction of K+ transport into scala media from the stria vascularis when autocrine or paracrine ATP signalling is invoked. This purinergic signalling likely provides a basis for a reactive homoeostatic regulatory mechanism limiting cochlear sensitivity under stressor conditions. Elevation of ATP in the perilymphatic compartment under such conditions is also likely to invoke purinergic receptor-mediated changes in supporting cell micromechanics, mediated by Ca2+ influx and gating of Ca2+ stores. Independent of these humoral actions, ATP can be classified as a putative auditory neurotransmitter based on the localization of P2X receptors at the spiral ganglion neuron-hair cell synapse, and functional verification of ATP-gated currents in spiral ganglion neurons in situ. Expression of P2X receptors by type II spiral ganglion neurons supports a role for ATP as a transmitter encoding the dynamic state of the cochlear amplifier.

Membrane properties of type II spiral ganglion neurones identified in a neonatal rat cochlear slice

Neuro‐anatomical studies in the mammalian cochlea have previously identified a subpopulation of approximately 5% of primary auditory neurones, designated type II spiral ganglion neurones (sgnII). These neurones project to outer hair cells and their supporting cells, within the ‘cochlear amplifier’ region. Physiological characterization of sgnII has proven elusive. Whole‐cell patch clamp of spiral ganglion neurones in P7‐P10 rat cochlear slices provided functional characterization of sgnII, identified by biocytin or Lucifer yellow labelling of their peripheral neurite projections (outer spiral fibres) subsequent to electrophysiological characterisation. SgnII terminal fields comprised multiple outer hair cells and supporting cells, located up to 370 μm basal to their soma. SgnII firing properties were defined by rapidly inactivating A‐type‐like potassium currents that suppress burst firing of action potentials. Type I spiral ganglion neurones (sgnI), had shorter radial projections to single inner hair cells and exhibited larger potassium currents with faster activation and slower inactivation kinetics, compatible with the high temporal firing fidelity seen in auditory nerve coding. Based on these findings, sgnII may be identified in future by the A‐type current. Glutamate‐gated somatic currents in sgnII were more potentiated by cyclothiazide than those in sgnI, suggesting differential AMPA receptor expression. ATP‐activated desensitising inward currents were comparable in sgn II and sgnI. These data support a role for sgnII in providing integrated afferent feedback from the cochlear amplifier.

Defining the Cellular Environment in the Organ of Corti following Extensive Hair Cell Loss: A Basis for Future Sensory Cell Replacement in the Cochlea

Background Following the loss of hair cells from the mammalian cochlea, the sensory epithelium repairs to close the lesions but no new hair cells arise and hearing impairment ensues. For any cell replacement strategy to be successful, the cellular environment of the injured tissue has to be able to nurture new hair cells. This study defines characteristics of the auditory sensory epithelium after hair cell loss. Methodology/Principal Findings Studies were conducted in C57BL/6 and CBA/Ca mice. Treatment with an aminoglycoside-diuretic combination produced loss of all outer hair cells within 48 hours in both strains. The subsequent progressive tissue re-organisation was examined using immunohistochemistry and electron microscopy. There was no evidence of significant de-differentiation of the specialised columnar supporting cells. Kir4.1 was down regulated but KCC4, GLAST, microtubule bundles, connexin expression patterns and pathways of intercellular communication were retained. The columnar supporting cells became covered with non-specialised cells migrating from the outermost region of the organ of Corti. Eventually non-specialised, flat cells replaced the columnar epithelium. Flat epithelium developed in distributed patches interrupting regions of columnar epithelium formed of differentiated supporting cells. Formation of the flat epithelium was initiated within a few weeks post-treatment in C57BL/6 mice but not for several months in CBA/Cas, suggesting genetic background influences the rate of re-organisation. Conclusions/Significance The lack of dedifferentiation amongst supporting cells and their replacement by cells from the outer side of the organ of Corti are factors that may need to be considered in any attempt to promote endogenous hair cell regeneration. The variability of the cellular environment along an individual cochlea arising from patch-like generation of flat epithelium, and the possible variability between individuals resulting from genetic influences on the rate at which remodelling occurs may pose challenges to devising the appropriate regenerative therapy for a deaf patient.

Alström Syndrome protein ALMS1 localizes to basal bodies of cochlear hair cells and regulates cilium-dependent planar cell polarity

Alström Syndrome is a life-threatening disease characterized primarily by numerous metabolic abnormalities, retinal degeneration, cardiomyopathy, kidney and liver disease, and sensorineural hearing loss. The cellular localization of the affected protein, ALMS1, has suggested roles in ciliary function and/or ciliogenesis. We have investigated the role of ALMS1 in the cochlea and the pathogenesis of hearing loss in Alström Syndrome. In neonatal rat organ of Corti, ALMS1 was localized to the basal bodies of hair cells and supporting cells. ALMS1 was also evident at the basal bodies of differentiating fibrocytes and marginal cells in the lateral wall. Centriolar ALMS1 expression was retained into maturity. In Alms1-disrupted mice, which recapitulate the neurosensory deficits of human Alström Syndrome, cochleae displayed several cyto-architectural defects including abnormalities in the shape and orientation of hair cell stereociliary bundles. Developing hair cells were ciliated, suggesting that ciliogenesis was largely normal. In adult mice, in addition to bundle abnormalities, there was an accelerated loss of outer hair cells and the progressive appearance of large lesions in stria vascularis. Although the mice progressively lost distortion product otoacoustic emissions, suggesting defects in outer hair cell amplification, their endocochlear potentials were normal, indicating the strial atrophy did not affect its function. These results identify previously unrecognized cochlear histopathologies associated with this ciliopathy that (i) implicate ALMS1 in planar cell polarity signaling and (ii) suggest that the loss of outer hair cells causes the majority of the hearing loss in Alström Syndrome.

A Deafness Associated Mutant Human Connexin 26 Improves The Epithelial Barrier In Vitro

A large proportion of recessive nonsyndromic hearing loss is due to mutations in the GJB2 gene encoding connexin 26 (Cx26), a component of a gap junction. Within different ethnic groups there are specific common recessive mutations, each with a relatively high carrier frequency, suggesting the possibility of heterozygous advantage. Carriers of the R143W GJB2 allele, the most prevalent in the African population, present with a thicker epidermis than noncarriers. In this study, we show that (R143W)Cx26-expressing keratinocytes form a significantly thicker epidermis in an organotypic coculture skin model. In addition, we show increased migration of cells expressing (R143W)Cx26 compared to (WT)Cx26-overexpressing cells. We also demonstrate that cells expressing (R143W)Cx26 are significantly less susceptible to cellular invasion by the enteric pathogen Shigella flexneri than (WT)Cx26-expressing cells. These in vitro studies suggest an advantageous effect of (R143W)Cx26 in epithelial cells.

Calcium signalling mediated by the α9 acetylcholine receptor in a cochlear cell line from the Immortomouse

1 We have investigated the characteristics of the α9 acetylcholine receptor (α9AChR) expressed in hair cell precursors in an immortalized cell line UB/OC‐2 developed from the organ of Corti of the transgenic H‐2Kb‐tsA58 mouse (the Immortomouse) using both calcium imaging and whole‐cell recording. 2 Ratiometric measurements of fura‐2 fluorescence revealed an increase of intracellular calcium concentration in cells when challenged with 10 μM ACh. The calcium increase was seen in 66 % of the cells grown at 39 °C in differentiated conditions. A smaller fraction (34 %) of cells grown at 33 °C in proliferative conditions responded. 3 Caffeine (10 mM) elevated cell calcium. In the absence of caffeine, the majority of imaged cells responded only once to ACh. A small proportion (< 2 % of the total) responded with an increase in intracellular calcium to multiple ACh presentations. Pretreatment with caffeine inhibited all calcium responses to ACh. 4 In whole‐cell tight‐seal recordings 10 μM ACh activated an inward, non‐selective cation current. The reversal potential of the ACh‐activated inward current was dependent on the extracellular calcium concentration with an estimated PCa/PNa of 80 for the α9 receptor at physiological calcium levels. 5 The data indicate that ACh activates a calcium‐permeable channel α9AChR in UB/OC‐2 cells and that the channel has a significantly higher calcium permeability than other AChRs. The results indicate that the α9AChR may be able to elevate intracellular calcium levels in hair cells both directly and via store release.

The Alström Syndrome Protein, ALMS1, Interacts with α-Actinin and Components of the Endosome Recycling Pathway

Alström syndrome (ALMS) is a progressive multi-systemic disorder characterized by cone-rod dystrophy, sensorineural hearing loss, childhood obesity, insulin resistance and cardiac, renal, and hepatic dysfunction. The gene responsible for Alström syndrome, ALMS1, is ubiquitously expressed and has multiple splice variants. The protein encoded by this gene has been implicated in ciliary function, cell cycle control, and intracellular transport. To gain better insight into the pathways through which ALMS1 functions, we carried out a yeast two hybrid (Y2H) screen in several mouse tissue libraries to identify ALMS1 interacting partners. The majority of proteins found to interact with the murine carboxy-terminal end (19/32) of ALMS1 were α-actinin isoforms. Interestingly, several of the identified ALMS1 interacting partners (α-actinin 1, α-actinin 4, myosin Vb, rad50 interacting 1 and huntingtin associated protein1A) have been previously associated with endosome recycling and/or centrosome function. We examined dermal fibroblasts from human subjects bearing a disruption in ALMS1 for defects in the endocytic pathway. Fibroblasts from these patients had a lower uptake of transferrin and reduced clearance of transferrin compared to controls. Antibodies directed against ALMS1 N- and C-terminal epitopes label centrosomes and endosomal structures at the cleavage furrow of dividing MDCK cells, respectively, suggesting isoform-specific cellular functions. Our results suggest a role for ALMS1 variants in the recycling endosome pathway and give us new insights into the pathogenesis of a subset of clinical phenotypes associated with ALMS.