Rapid resting ion fluxes in goldfish hair cells are balanced by (Na+,K+)-ATPase

Mutations in ap1b1 cause mistargeting of the Na(+)/K(+)-ATPase pump in sensory hair cells

The hair cells of the inner ear are polarized epithelial cells with a specialized structure at the apical surface, the mechanosensitive hair bundle. Mechanotransduction occurs within the hair bundle, whereas synaptic transmission takes place at the basolateral membrane. The molecular basis of the development and maintenance of the apical and basal compartments in sensory hair cells is poorly understood. Here we describe auditory/vestibular mutants isolated from forward genetic screens in zebrafish with lesions in the adaptor protein 1 beta subunit 1 (ap1b1) gene. Ap1b1 is a subunit of the adaptor complex AP-1, which has been implicated in the targeting of basolateral membrane proteins. In ap1b1 mutants we observed that although the overall development of the inner ear and lateral-line organ appeared normal, the sensory epithelium showed progressive signs of degeneration. Mechanically-evoked calcium transients were reduced in mutant hair cells, indicating that mechanotransduction was also compromised. To gain insight into the cellular and molecular defects in ap1b1 mutants, we examined the localization of basolateral membrane proteins in hair cells. We observed that the Na(+)/K(+)-ATPase pump (NKA) was less abundant in the basolateral membrane and was mislocalized to apical bundles in ap1b1 mutant hair cells. Accordingly, intracellular Na(+) levels were increased in ap1b1 mutant hair cells. Our results suggest that Ap1b1 is essential for maintaining integrity and ion homeostasis in hair cells.

A biophysical model of an inner hair cell

Whole-cell patch-clamp recordings on isolated inner hair cells (IHCs) of guinea pig cochleae have revealed the presence of voltage-gated potassium channels. A biophysical model of an IHC is presented that indicates activation of slow voltage-gated potassium channels may lead to receptor potentials whose dc component decreases during the stimulus, and membrane potential hyperpolarizes when the stimulus is turned off. Both the decreasing dc and the hyperpolarization are, respectively, consistent with rapid adaptation and suppression of spontaneous rate in the auditory nerve. Receptor potentials recorded in vivo do not show these features, and when a nonspecific leak is included in the model to simulate microelectrode impalement, the model's receptor potentials become similar to those in vivo. The nonspecific leak creates an electrical shunt that masks slow channel activity and allows the cell to depolarize. Both the decreasing dc and the hyperpolarization are sensitive to the resting potential. Because the reported resting potentials in vivo and in vitro differ greatly, the model is used to investigate homeostatic mechanisms responsible for the resting potential. It is found that the voltage-gated potassium channels have the greatest influence on the resting potential, but that the standing transducer current may be sufficient to eliminate the decreasing dc and after-stimulus hyperpolarization.

Estimation of perilymph concentration of agents applied to the round window membrane by microdialysis

OBJECTIVE

The round window membrane (RWM) is known to be permeable to various biological substances. Application of biological substances to the RWM has been shown to affect inner ear fluid composition and damage hair cells, resulting in functional changes RWM instillation of gentamicin, a preferentially vestibulotoxic aminoglycoside, is used as a therapeutic treatment for patients with intractable vertigo and is gaining acceptance as a chemical vestibular ablation agent, despite considerable variations in the incidence and severity of hearing loss associated with gentamicin. Clearly, the susceptibility of vestibular and auditory hair cells to the ototoxic effects of gentamicin is not well understood. The aim of this study was to understand the kinetics of urea and methylene blue instilled into the inner ear space through the RWM and to establish a method for determining the optimal dosage for the treatment of inner ear disorders.

MATERIAL AND METHODS

We used inner ear microdialysis to quantify changes in perilymph concentration of low molecular weight agents applied to the RWM in a chinchilla model.

RESULTS

Preliminary results after placement of a microdialysis probe and application of a low molecular weight marker (urea) to the RWM were extrapolated from a time versus concentration plot from dialysates sampled over a 3-min interval using modifications of standard microdialysis equations for estimation of in vivo recovery. Our data suggest that inner ear microdialysis can be used to measure the pharmacokinetics of a low molecular weight agent within the perilymphatic space without the need for repeated direct sampling.

CONCLUSION

Inner ear microdialysis may be a useful method for establishing a therapeutic dosage for ototoxic agents used in the treatment of inner ear disorders.

Inwardly rectifying currents in hair cells and supporting cells in the goldfish sacculus

1. Inwardly rectifying ionic currents were studied using patch-clamp recording methods in oscillatory-type and spike-type hair cells and supporting cells dissociated from the goldfish sacculus. These cells had different types of inwardly rectifying currents. The biophysical properties of these currents were investigated. 2. A unique potassium current (Isc) was the sole ionic current recognized in supporting cells. Isc was active throughout the membrane potential range between +30 and -170 mV, but showed weak inward rectification and no inactivation. 3. In spike-type hair cells, inwardly rectifying current (Ik1) was selectively permeable to K+ (K+:Na+ permeability ratio, 1:0.0021). Ik1 could underlie the high negative resting potential of these hair cells because it is partially active at this potential. The strong inward rectification of Ik1 contributed to the low negative plateau potential seen in spike-type hair cells. 4. In oscillatory-type hair cells, hyperpolarization-activated potassium-sodium current (Ih), which had properties similar to that in photoreceptor and other neurons, was present instead of inwardly rectifying K+ current. 5. In the cell-attached and inside-out modes with 125 microM external K+ ([K+]o), IK1 channel had a unitary conductance of 27 pS and showed inactivation with increasing hyperpolarization. Putative Ih and Iso single channels had unitary conductances of 7 and 61 pS, respectively, in the cell-attached mode with 125 microM Ko+.

Calcium and magnesium transport by isolated goldfish hair cells

We used electron-probe analysis (EPA) to investigate the transport of the divalent cations calcium and magnesium across the plasma membranes of hair cells. Unlike ion-sensitive fluorescent dyes, EPA detects these ions regardless of the state of chemical combination inside the cell; changes in these cell ions determined by EPA indicate net transport across the cell membrane. Raising or lowering either extracellular divalent cation within 1 mM of its control level raised or lowered its cell contents, but further increases in extracellular concentration of either ion had little additional effect on the cell content of that ion. New steady-state contents could be obtained within minutes, but the net divalent cation currents required to account for the observed changes would have been smaller than most currents recorded electrophysiologically, less than 1 pA. The effects of replacing extracellular Na+ with other ions were consistent with the presence in hair cells of exchangers for divalent cations thought to occur in other tissues: electrically neutral sodium/magnesium exchange (2 Na+ per Mg2+) and electrogenic sodium/calcium exchange (at least 3 Na+ per Ca2+). The increase in cell Ca after 1 minute of potassium-depolarization was similar to that expected from electrophysiological studies of voltage-sensitive calcium currents in goldfish hair cells. After that time in elevated potassium, however, either calcium-entry pathways were inhibited or calcium-export mechanisms were enhanced.

Extracellular N-methyl-D-glucamine leads to loss of hair-cell sodium, potassium, and chloride

The organic cation N-methyl-D-glucamine (NMDG) is often used to replace extracellular sodium in experimental studies. Replacing 100 mM of Na+ with NMDG+ in the fluid bathing isolated goldfish hair cells led to a rapid loss not only of cell sodium, but also of cell potassium and chloride. The loss of inorganic cell solutes was accompanied by acidification of the cells. Cell volume did not change significantly. These results are consistent with passage of the cationic form of NMDG, a titratable amine with a pKa of 9.6, across the hair-cell membrane. These results should have bearing in interpreting results of experiments in which this cation is used to replace extracellular sodium, particularly for periods of time longer than 3 min.

Electron-probe analysis of isolated goldfish hair cells: implications for preparing healthy cells

Electron-probe analysis provides an objective criterion for the physiological status of cells: whether they show the high potassium and low sodium that are expected of healthy animal cells. Preparing isolated goldfish hair cells that were healthy by this criterion required several precautions, including: limited exposure to enzymes and to simple salt solutions, a rest period between enzyme treatment and mechanical disruption of the tissue, and presence of bovine albumin in the medium both during the rest period and during mechanical dispersion and plating. Cells prepared with these precautions from the saccule and lagena and kept in an enriched medium had the following elemental composition (mole percentages with respect to phosphorus): K, 103; Na, 18; Cl, 23; S, 13; Mg, 8; Ca, 1.5. These mole percentages were close to these elements' total millimolar concentrations in the cells. If the precautions were not taken, cells with intact surface membranes (as assessed by exclusion and retention of dyes) could be obtained, but the cells had elevated cell sodium and low cell potassium.