Two Distinct Ca2+-Dependent Signaling Pathways Regulate the Motor Output of Cochlear Outer Hair Cells

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The Journal of Neuroscience, August 15, 2000, 20(16):5940-5948

Two Distinct Ca²⁺-Dependent Signaling Pathways Regulate the Motor Output of Cochlear Outer Hair Cells
Gregory I. Frolenkov¹, Fabio Mammano², Inna A. Belyantseva¹, Donald Coling¹, and Bechara Kachar¹
¹ Section on Structural Cell Biology, National Institute on Deafness and Other Communication Disorders, National Institutes of Health, Bethesda, Maryland 20892-4163, and ² Laboratory of Biophysics and Istituto Nazionale di Fisica della Materia, International School for Advanced Studies, via Beirut 2-4, 34014, Trieste, Italy

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The outer hair cells (OHCs) of the cochlea have an electromotility mechanism, based on conformational changes of voltage-sensitive"motor" proteins in the lateral plasma membrane. The translocationof electrical charges across the membrane that accompanies electromotilityimparts a voltage dependency to the membrane capacitance. We usedcapacitance measurements to investigate whether electromotilitymay be influenced by different manipulations known to affect intracellularCa²⁺ or Ca²⁺-dependent protein phosphorylation. Application of acetylcholine(ACh) to the synaptic pole of isolated OHCs evoked a Ca²⁺-activated apamin-sensitive outward K⁺ current. It also enhanced electromotility, probably because ofa phosphorylation-dependent decrease of the cell's axial stiffness.However, ACh did not change the voltage-dependent capacitanceeither in conventional whole-cell experiments or under perforated-patchconditions. The effects produced by the Ca²⁺ ionophore ionomycin mimicked those produced by ACh. Hyperpolarizingshifts of the voltage dependence of capacitance and electromotilitywere induced by okadaic acid, a promoter of protein phosphorylation,whereas trifluoperazine and W-7, antagonists of calmodulin, causedopposite depolarizing shifts. Components of the protein phosphorylationcascade $---$ IP₃ receptors and calmodulin-dependent protein kinasetype IV $---$ were immunolocalized to the lateral wall of the OHC. Ourresults suggest that two different Ca²⁺-dependent pathways may control the OHC motor output. The firstpathway modulates cytoskeletal stiffness and can be activatedby ACh. The second pathway shifts the voltage sensitivity of theOHC electromotile mechanism and may be activated by the releaseof Ca²⁺ from intracellular stores located in the proximity of the lateralplasmamembrane.

Key words: sensory transduction; electromotility; voltage-dependent capacitance; cochlea; endoplasmic reticulum; patch clamp; organ of Corti

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Outer hair cells (OHCs) $---$ the sensorimotor receptors of the mammalian cochlea $---$ elongate and shorten at acoustic frequencies whentheir intracellular potential is changed (for review, see Dallos,1992; Frolenkov et al., 1998a). This unique property turns OHCsinto active devices that amplify the sound-evoked mechanical responsesof the organ of Corti. The ability of OHCs to change shape ina voltage-dependent manner is generally referred to as electromotilityand is presumably based on voltage-driven conformational changesof densely packed putative "motor" proteins in the lateral plasmamembrane (Kalinec et al., 1992). These conformational changesentail the translocation of electrical charges across the plasmamembrane, observed as fast transient currents at the onset andoffset of transmembrane voltage steps (Santos-Sacchi, 1991) similarto the "gating" currents recorded from voltage-dependent ion channels.However, the conformational changes of the OHC motor proteinsare not associated with a net ion flow across the membrane (Santos-Sacchiand Dilger, 1988) but produce changes in the surface area of themembrane (Kalinec et al., 1992). The motor's charge movement issensitive to chemicals inhibiting OHC electromotility (Tunstallet al., 1995; Kakehata and Santos-Sacchi, 1996). It commonly saturatesfor membrane voltages below $-$ 120 mV and above +80 mV, which impartsa bell-shaped dependence to the membrane capacitance (Santos-Sacchi,1991).

Clearly, electromotility involves a novel mechanism of force production distinct from conventional ATP-dependent, cytoskeletal-basedcontractile processes (Kachar et al., 1986). Nonetheless, thecylindrical shape of OHCs is maintained by a cortical cytoskeleton(Holley et al., 1992), and the elongation produced in OHCs bythe Ca²⁺ ionophore ionomycin has been attributed to a Ca²⁺/calmodulin-dependent phosphorylation of cytoskeletal proteins(Dulon et al., 1990; Coling et al., 1998).

OHCs are the target of an efferent innervation originating in the brainstem (Warr, 1992). The principal neurotransmitter ofthis efferent system is acetylcholine (ACh) (Eybalin, 1993). Whole-cellrecordings from isolated OHCs have provided evidence of cholinergicreceptors localized around the base of the cell, where the efferentsynapses are located (Housley and Ashmore, 1991). The action ofACh on OHCs requires extracellular Ca²⁺ (Blanchet et al., 1996; Evans, 1996), is accompanied by changesof intracellular free Ca²⁺ concentration ([Ca²⁺]_i) (Doi and Ohmori, 1993), and is mediated by a novel receptor,named the $alpha$ 9 ACh receptor (Elgoyhen et al., 1994). Recently Dalloset al. (1997) showed that ACh increases the electromotile responsesof OHCs and attributed this effect to a decreased axial stiffness,presumably mediated by Ca²⁺-dependent phosphorylation of unspecified cytoskeletal proteins(Szonyi et al., 1999). The molecular targets of these Ca²⁺-mediated intracellular cascades remain difficult to identifybecause the OHC axial stiffness depends also on the transmembranepotential (Frolenkov et al., 1998b; He and Dallos, 1999). Thissuggests that the motor output of OHC can be modulated by regulatorymechanisms that target both the cytoskeleton and the membranemotorproteins.

In the present study we used capacitance measurements to investigate whether the voltage-sensitive membrane component of theOHC electromotility mechanism can be directly affected by intracellularCa²⁺ or by Ca²⁺-dependent signaling pathways involving proteinphosphorylation.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell preparation. Adult guinea pigs (200-400 gm) were killed by suffocation with carbon dioxide and decapitated. The temporalbones were removed from the skull and placed in modified Leibovitzcell culture medium (L-15) containing the following inorganicsalts (in mM): NaCl (138), KCl (5.3), CaCl₂ (1.26), MgCl₂ (1.0),Na₂HPO₄ (1.34), KH₂PO₄ (0.44), and MgSO₄ (0.81). For some experiments,a solution designed to block most of the membrane conductancewas used, containing (in mM): NaCl (142), KCl (5.4), CaCl₂ (1.3),MgCl₂ (1.5), HEPES (5), tetraethylammonium chloride (20), CsCl(20), and CoCl₂ (2). The osmolarity of the extracellular solutionswas adjusted to 325 ± 2 mOsm with D-glucose or D-galactose, andthe pH was adjusted to 7.4 with NaOH. To isolate OHCs, we openedthe bulla to expose the cochlea and chipped away the otic capsulawith a surgical blade, starting from the base. Strips of the organof Corti were dissected from the modiolus with a fine needle,transferred with a glass pipette to a 100 µl drop of medium containing1 mg/ml collagenase type IV (Life Technologies, Rockville, MD),and kept there for 15-20 min. In some experiments, the stripswere preincubated (30-60 min at 37°C) with drugs affecting proteinphosphorylation: okadaic acid, trifluoperazine, and W-7 (Calbiochem,San Diego, CA). As controls for these experiments, cells weremaintained in the L-15 medium for the same amount of time. Afterincubation, cells were dissociated by gentle reflux of the tissuethrough the needle of a Hamilton syringe (705; 22 gauge) and allowedto settle on the slide for 5-10 min. During the experiment, cellswere placed in a laminar flow bath (100 µl), with exchange ofsolution (~5 ml/hr) by a pressurized perfusion system (BPS-4;ALA Scientific Instruments, Westbury, NY). OHCs were maintainedat room temperature (22-24°C) throughout theexperiments.

Patch-clamp recordings. As a result of the enzymatic treatment and mechanical dissociation, isolated OHCs showed differentdegrees of cell damage. This required careful selection of thecells before patch clamping. No reports exist in the literaturethat allowed the comparison of differential interference contrastimages of OHCs in situ with isolated ones. Therefore we reliedon the several years of experience of these laboratories to determinecell viability based on the following morphological features:uniform cylindrical shape, basal location of the nucleus, membranebirefringence, and intact stereocilia. Shorter cells (34-52 µm)were used for experiments involving the pressure application ofacetylcholine, and longer cells (40-79 µm) were used for the otherexperiments. Pipettes for conventional or perforated-patch (Hornand Marty, 1988) whole-cell recordings were formed on a programmablepuller (P87; Sutter Instruments, Novato, CA) from 1.0 mm outerdiameter borosilicate glass (#30-30-0; FHC, Bowdoinham, ME). Forconventional patch-clamp recordings, pipettes were filled withan intracellular solution containing (in mM): KCl (144), MgCl₂(2.0), EGTA (0.5), Na₂HPO₄ (8.0), NaH₂PO₄ (2.0), Mg-ATP (2.0),and Na-GTP (0.2), adjusted to pH 7.4 with KOH and brought to 325mOsm with D-glucose. When using ion channel blockers in the extracellularmedium, pipettes were filled with (in mM): CsCl (140), MgCl₂ (2.0),EGTA (5.0), HEPES (5), Mg-ATP (2.0), and Na-GTP (0.2), adjustedto pH 7.4 with CsOH and brought to 325 mOsm with D-glucose.

For perforated-patch recordings the pipette solution contained 150 mM KCl, 10 mM HEPES (buffered with Tris-hydroxymethyl-aminomethaneto pH 7.2), 500 µg/ml nystatin (Calbiochem), and 200 µg/ml fluoresceine(Molecular Probes, Eugene, OR). Both nystatin and fluoresceinewere freshly predissolved in DMSO to make 50 and 20 mg/ml stocksolutions, respectively. Before filling the pipette with the nystatin-containingsolution, its tip was loaded with a small volume of nystatin-and DMSO-free solution to avoid interference with seal formation.After seal formation, the progress of perforation was assayedby monitoring the capacitive current transients evoked by 5 mVsteps. At the end of perforated-patch experiments, we recordedthe image of the OHC under epifluorescent illumination beforeand after breaking the perforated patch with negative pressure.Fluorescent signals were detected from the cell only after breakingthe patch, indicating that the perforated patch had excluded thepassage of substances with a molecular weight comparable with,or larger than, that of the fluorescentprobes.

Patch-clamp recordings were performed using an Axopatch 1D amplifier (Axon Instruments, Foster City, CA). Current and voltagewere sampled at 100 kHz using a standard laboratory interface(Digidata 1200A; Axon Instruments) controlled by pCLAMP 7.0 software(Axon Instruments). The uncompensated pipette resistance was typically3-5 M $Omega$ when measured in the bath. The access resistance did notexceed 15 M $Omega$ under conventional and 25 M $Omega$ under perforated-patchconditions. Potentials were corrected off-line for the error causedby the access resistance. Junction potentials were $-$ 4.2 mV forthe conventional intracellular and extracellular solution combinationand $-$ 5.3 mV for the ion channel-blocking combination, as computedby the pCLAMP 7.0 software on the basis of the given solutioncomposition. These values were very similar and rather small;therefore no correction was applied to the data for liquid junctionpotentials.

Drug delivery. A puff pipette, prepared similarly to the patch pipette, was filled with ACh (Sigma, St. Louis, MO) or ionomycin(Calbiochem) dissolved in the extracellular solution. It was placednear the synaptic pole (ACh; Fig. 1A) or the lateral wall (ionomycin)of the OHC, and 10 kPa of pressure was applied to its back bya pneumatic injection system (PLI-100; Medical Systems Corporation,Greenvale, NY) gated under software control.

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Figure 1. A, Video image to indicate how ACh was delivered to isolated OHCs in vitro. The cell was patch-clamped near its nuclear region by a pipette entering from the right. A second pipette was positioned close to the cell's synaptic pole for the focal pressure application of ACh. Scale bar, 10 µm. B, Top left, Brief voltage steps (square wave; amplitude, 5 mV; frequency, 500 Hz) applied by the patch-clamp amplifier, eliciting transient capacitive currents that were not compensated by the amplifier's circuitry. Top right, Scheme of the idealized circuit representing the capacitive cell response. C_m, Membrane capacitance; R_a, pipette access resistance; R_m, cell membrane resistance. Middle, Responses of a model electrical circuit used to test the reliability of the capacitance measurements for various values of R_m, displayed above the recordings, while keeping C_m = 30 pF and R_a = 10 M $Omega$ constant. Approximately at the middle of each step, the voltage was ramped from $-$ 140 to +100 mV, producing practically no changes in the calculated value of C_m(V). Bottom, The mean quadratic difference of three model circuit measurements, taken at C_m = 10, 20, or 30 pF, from their expected capacitance values plotted against the ratio of the membrane resistance R_m to the total resistance R_t = R_a + R_m. Notice the rapid increase of the quadratic error for R_m/R_t < 0.5. C, Sample traces showing the membrane potential ramp (top) that produced the changes of membrane capacitance (middle) and OHC length (bottom). D, Voltage dependence of membrane capacitance (in pF; circles, left y-axis) and motile responses (in percent units of the cell resting length; triangles, right y-axis), obtained from the data in C. The sigmoidal curve through the motility data is a least-square fit obtained from a Boltzmann function with the following parameters: $Delta$ L_max = 1.4%, V_p = $-$ 20.5 mV, and W = 27.9 mV. The bell-shaped curve through the capacitance data is the derivative of the Boltzmann function with the following parameters: C_max = 24.3 pF, C₀ = 18.7 pF, V_p = $-$ 22.3 mV, and W = 24.3 mV. Vertical lines indicate V_p values. E, Specific OHC membrane capacitance versus membrane potential measured with standard intracellular and extracellular media (closed circles) and with ion channel blockers (open circles; see Materials and Methods). Data from two representative cells were fitted by the scaled derivatives of Boltzmann functions with the following parameters: $chi$ _max = 1.6 µF/cm², V_p = $-$ 41.4 mV, and W = 25.5 mV; and $chi$ _max = 1.5 µF/cm², V_p = $-$ 35.3 mV, and W = 25.9 mV, respectively. Inset, Representative I-V curves obtained with the standard intracellular and extracellular media (closed circles) and with ion channel blockers (open circles). The residual voltage-independent leakage conductance was not subtracted.

Capacitance measurement. Measurements of cell capacitance were performed using the "membrane test" feature of the pCLAMP 7.0acquisition software, which continuously delivered a test squarewave of period T = 4 msec to the cell, through the patch-clampamplifier. This produced transient currents that decayed exponentiallywith time constant $tau$ (Fig. 1B, top left). The software was designedfor the simultaneous on-line measurement of $tau$ , the total resistanceR_t seen by the amplifier, and the electrical charge deliveredto the membrane capacitance C_m. Unfortunately the pCLAMP softwareaccurately estimates the parameters cell membrane resistance (R_m),pipette access resistance (R_a), and C_m only if R_m R_a, a conditionthat was not always met. To circumvent this problem, we reversedoff-line the pCLAMP algorithm to recover the original values forthe time integral of the transient current Q and R_t. We then recomputedR_m, R_a, and C_m according to the equations shown below. The simplifiedelectrical circuit used to represent a patch-clamped OHC is shownin Figure 1B, top right. The voltage step V elicited a whole-cellcurrent:

where:

(1)

The charge delivered to the equivalent circuit by the transient current is:

(2)

and the total resistance is:

(3)

Solving simultaneously Equations 1-3 yields:

Because the time constant $tau$ of the patch-clamp amplifier was typically in the range 0.1-0.3 msec at holding potentials from $-$ 50 to $-$ 70 mV, >99.8% of the current had settled within T/2 =2msec.

The patch-clamp parameters were continuously monitored at a resolution of 25 Hz, by averaging the responses to 10 positiveand 10 negative consecutive test steps. The series resistanceand linear capacitance compensation circuitry of the patch-clampamplifier were not used. Instead, to determine the voltage dependenceof C_m, we applied triangular voltage ramps, swinging the cellpotential from V_h $-$ 100 mV to V_h + 160 mV (where V_h is the holdingpotential) in 6 sec (Fig. 1C). Measured values of R_t were correctedfor the slope of the ramp. To test the accuracy of this procedure,we performed measurements of C_m on a model electrical circuit(Fig. 1B, top right), in which we varied R_m from 500 to 5 M $Omega$ keepingR_a = 10 M $Omega$ constant and C_m equal to one of three values: 10, 20,or 30 pF. The values of C_m, calculated according to the aboveprocedure, differed from their nominal values by no > 4 pF, providedthat R_m/R_t > 0.5 (Fig. 1B, bottom). Large errors in the C_m estimateoccurred at high R_m/R_t values because the amplitude of the exponentiallydecaying transient current was less than the steady-state currentresponse to the test step. Under these conditions, the pCLAMPalgorithm was unable to "lock" the exponential decay to calculateits timeconstant.

Generally, we halted data gathering when the ratio R_m/R_t fell < 0.5. In this paper we report only data from cells with voltage-independent(linear) capacitance > 15 pF and R_m/R_t > 0.6. Therefore, the maximumerror in the estimate of C_m was < 16%. The values of C_m, calculatedaccording to the above procedure, did not change significantlywhen the voltage was commanded to follow a ramp (Fig. 1B, middle).Measurements of the cell capacitance during test ramps were correctedfor the voltage drop along the access resistance of the pipetteand then fitted with:

which is the derivative of a Boltzmann function. C₀ is the linear (voltage-independent) capacitance, C_max is the maximumnonlinear capacitance, V_p is the potential at the peak of C_m(V),and W = k_BT/ze is a constant. The latter is a measure of the sensitivityof the nonlinear charge displacement to potential, expressed interms of a charge of valence z moving from the inner to the outeraspect of the plasma membrane. k_B is Boltzmann's constant, T isabsolute temperature, and e is the electroncharge.

The voltage-independent fraction of the cell capacitance scales linearly with the overall surface area of the cell. However,the nonlinear voltage-dependent fraction of the cell capacitanceis proportional to the area of the lateral membrane surface, wherethe putative motor elements are located (Huang and Santos-Sacchi,1993). Therefore, to compare the data obtained from differentcells, the nonlinear voltage-dependent capacitance was dividedby the area of the lateral plasma membrane as follows:

where $chi$ _m(V) is the specific nonlinear voltage-dependent capacitance of the lateral plasma membrane (in µF/cm²). C_ap = 4.38 pF and C_bas = 1.85 pF are the capacitances of theapical and basal parts of OHC devoid of motor proteins (Huangand Santos-Sacchi, 1993). Therefore, C₀ $-$ C_ap $-$ C_bas gives thelinear voltage-independent capacitance of the lateral plasma membrane. $chi$ _lb = 1 µF/cm² is the specific capacitance of a lipidbilayer.

Motility measurements. Motility measurements were performed as described in Frolenkov et al. (1997). Briefly OHC movementswere recorded with a video camera interfacing with an invertedmicroscope equipped with differential interference contrast opticsto an optical disk recorder (Panasonic TQ-3031F). Digitized imageswere analyzed off-line with the image-processing system Image1 (Universal Imaging, West Chester, PA). For movement quantification,a measuring rectangle ranging in length from 5 to 20 µm and composedof 3-15 rows of pixels was positioned across the moving edge ofthe cell. The average intensity profile across the edge of thecell was calculated, and the number of points in the profile wasincreased 10 times by cubic spline interpolation. Movement ofthe cell edge was calculated from the frame-by-frame shift (computedby a least-square procedure) in the interpolated intensity profiles.The sensitivity of the measurement was ~0.02 µm, as determinedpreviously (Frolenkov et al., 1997). Data obtained in this waywere fitted by the scaled Boltzmann function:

Here L₀ is the length of the cell at the holding potential V_h, whereas $Delta$ L_max is the maximum voltage-dependent length change.V_p and W have the same meaning as in the nonlinear capacitanceexpression, and A₀ is a suitable constant, such that $Delta$ L(V_h) =0.

Recording of intracellular [Ca²⁺] changes. Light from a 175 W stabilized xenon arc source (Lambda DG-4; Sutter Instruments)was coupled via a liquid light guide to the epifluorescence sectionof an Axiomat microscope (Carl Zeiss, Jena, Germany), which wasequipped with an Omega Optical XF100 filter block optimized forthe Ca²⁺-selective dye Oregon Green 488 BAPTA-1. The illumination intensitywas attenuated with a neutral density filter to avoid phototoxicityby reducing dye photo-bleaching rates to $<=$ 0.1%/sec. Fluorescenceimages were formed on a scientific grade cooled CCD sensor (Micromax1300Y; Princeton Instruments, Trenton, NJ) using an oil-immersionobjective [100×; numerical aperture (NA) = 1.40; PlanApo; CarlZeiss]. The sensor's output was binned 3 × 3 and digitized at12 bits/pixel to produce images that were recorded to a host personalcomputer controlled by the Axon Imaging Workbench 2.2 software(Axon Instruments) and analyzed off-line. For each image pixel,fluorescence signals were computed as ratios $Delta$ F/F = [F(t) $-$ F(0)]/F(0),where t is time, F(t) is the fluorescence after a stimulus thatcauses Ca²⁺ elevation within the cell, and F(0) is the prestimulus fluorescencecomputed by averaging 10-20images.

Immunofluorescence. For immunofluorescence, guinea pig cochleae (n = 12) were opened and fixed in 4% paraformaldehyde in PBS,pH 7.4, for 1 hr. Samples were permeabilized with 0.5% TritonX-100 in PBS for 30 min, followed by overnight incubation in blockingsolution (5% goat serum plus 2% bovine serum albumin in PBS).Samples were incubated for 1 hr with 2.5 µg/ml affinity-purifiedprimary antibody: the anti-Ca²⁺/calmodulin-dependent protein kinase IV (CaMK-IV) antibody (SantaCruz Biotechnology, Santa Cruz, CA) or the anti-IP₃ receptor antibody(Calbiochem). As a secondary antibody, we used the FITC-conjugateanti-rabbit IgG (Amersham, Piscataway, NJ). Samples were viewedwith a Zeiss laser scanning confocal microscope or a Zeiss Axiophotmicroscope equipped with a 63× objective (NA = 1.4). No signalwas detected using the secondary antibody alone. For the CaMK-IVlabeling, we also performed an additional control, in which theprimary antibody was preadsorbed for 1 hr at room temperaturewith an excess of the immunogenic peptide (50 µg/ml), which suppressedthelabeling.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Validation of the recording procedure

It is a common practice to block at least the most prominent K⁺ membrane conductance to facilitate the investigation of the electromotility-associatedcharge movement and/or voltage-dependent OHC capacitance (seeSantos-Sacchi, 1991; Gale and Ashmore, 1997). Unfortunately, thisapproach cannot be applied to the study of the effects of AChon the OHC voltage-dependent capacitance because the Ca²⁺-activated outward K⁺ current is the main indicator of the successful activation ofOHC ACh receptors. Therefore, it was necessary to develop a procedurefor the simultaneous measurement of C_m and cell motility ( $Delta$ L)under conditions of varying R_m. When the ratio of R_m to R_t (seeMaterials and Methods) was > 0.6, the error affecting our capacitancemeasurements was < 16% (Fig. 1B). This allowed us to determinethe voltage dependence of motility and capacitance from the samevoltage ramp applied to the cell membrane under whole-cell patch-clamprecording conditions (Fig. 1C). The OHC nonlinear capacitancefollowed the derivative of the motile response (Fig. 1D), as describedpreviously (Santos-Sacchi, 1991). The differences between theBoltzmann parameters used to fit motility and capacitance data $---$ themidpoint potential (V_p) and the potential sensitivity (W) (seeMaterials and Methods) $---$ were not statistically significant at thep = 0.05 level for n = 14 controlcells.

As a control, we measured also the voltage dependence of OHC capacitance in a different set of cells using intracellular andextracellular solutions designed to block the majority of ionicmembrane conductances (see Materials and Methods). The valuesof V_p, W, and the maximum specific capacitance $chi$ _max were $-$ 18 ±4 mV, 33 ± 1 mV, and 2.1 ± 0.2 µF/cm² (n = 10) for normal and $-$ 30 ± 9 mV, 36 ± 2 mV, and 2.0 ± 0.1µF/cm² (n = 20) for blocking solutions, respectively. No statisticallysignificant differences between the two groups were found (p >0.05; Fig. 1E, two sample curves shown). These parameter valuesare in agreement with previous reports (see Santos-Sacchi, 1991).Two samples of current-voltage (I-V) relationships, obtained fromeach group by subjecting the membrane potential to a ramp, areplotted in the Figure 1E, inset. With blocking solutions, thewhole-cell current was mainly caused by a voltage-independentleakage conductance that reversed near 0mV.

Our measurements of C_m were robust relative to the changes of R_m not only in a model electrical circuit (Fig. 1B) but alsoin real cells, provided that the value of R_m/R_t was sufficientlyhigh. Figure 2 illustrates an experiment in which the electricallyevoked OHC movements partly destroyed the seal between pipetteand membrane, resulting in the development of a leak. After thevoltage ramps, the apparent R_m fell from ~60 to 6 M $Omega$ , changingthe R_m/R_t ratio from 10 to 0.5. In spite of such dramatic changes,our system satisfactorily tracked the capacitance of the cell.

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Figure 2. Stability test for capacitance measurements. Because of variations of the whole-cell recording conditions, the calculated value of membrane resistance decreased ~10 times after the voltage ramp stimulation. Traces show the simultaneous measurements of the following parameters (from top to bottom): R_a, access resistance; R_m, membrane resistance; I, whole-cell current; and C_m, membrane capacitance.

Nevertheless, we were unable to measure C_m in short OHCs (<30 µm), in which a large inward current was activated at potentialsmore positive than $-$ 20 mV, resulting in a dramatic drop of R_mbelow the value of R_a. Because capacitance could not be reliablymeasured under such unfavorable conditions, these cells have notbeen included in the results. This was an unfortunate limitation,because the largest ACh-evoked currents were found in such shortcells from the high-frequency end of the cochlea (see also Housleyand Ashmore, 1991).

Effect of ACh on the OHC voltage-dependent capacitance and electromotility

Focal applications of ACh (100 µM) to the synaptic pole of the OHC, held at approximately V_h = $-$ 60 mV (n = 10), elicited outwardcurrents of 50-200 pA and simultaneous 5-40% drops in R_m (Fig.3A). The latency of this outward current was in the range of 150-250msec (Fig. 3B), i.e., much longer than the drug delivery timethat was estimated on the order of 20 msec, on the basis of similarexperiments in which salicylate was applied to elicit a rapiddecrease in the OHC nonlinear capacitance (Tunstall et al., 1995)(G. I. Frolenkov, unpublished results). In two experiments, asmall inward current preceded the ACh-evoked outward current (Fig.3B). The voltage dependence of the latter (Fig. 3D) had a characteristicN shape (Blanchet et al., 1996; Evans, 1996). These data agreewith the view that ACh activates a small inward current, partlycarried by Ca²⁺, which in turn triggers a large Ca²⁺-activated outward K⁺ current (Evans, 1996). Application of apamin (1 µM) to the bathsuppressed the ACh-evoked outward current (data not shown), indicatingthat it was carried through small-conductance Ca²⁺-activated K⁺ channels (Blatz and Magleby, 1986; Yamamoto et al., 1997).

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Figure 3. Acetylcholine does not affect OHC capacitance. A, Monitoring cell parameters before, during, and after two consecutive applications of ACh (100 µM; 20 sec; open horizontal bars). From top to bottom, the following parameters were measured: I, whole-cell current; R_a, access resistance; R_m, membrane resistance; and C_m, membrane capacitance. Trace deflections are caused by the delivery of triangular voltage ramps to the cell (see Fig. 1C; ramps are numbered 1-7). B, Sample of the current response to ACh (100 µM; 1 sec) from a different cell, shown on a faster time scale to reveal a barely noticeable inward current preceding the large outward current. C, Current-voltage I-V relationship without ACh (control; closed squares; average of the data from ramps 1, 3, 4, 6, and 7) and during the first (ACh1; open circles) and the second (ACh2; open triangles) application of ACh in A. D, ACh-sensitive fraction of the I-V curve, obtained by subtraction of the whole-cell current during ACh application from the mean of the whole-cell currents before and after ACh (data from C). E, F, Insensitivity of the capacitance-voltage C_m(V) relationship to ACh, measured before (control; closed squares), during (open circles), and after (washout; closed triangles) the first (E) and the second (F) application of ACh (ACh1, ACh2 in A). C_m(V) relationships were obtained from ramps 1-6 (indicated in parentheses). Data were fitted by the scaled derivatives of Boltzmann functions. All data points were obtained at R_m/R_t < 0.7; therefore the estimated error of C_m measurements was < 2 pF.

In spite of the prominent ACh-induced current responses, we observed virtually no ACh-induced changes in the OHC voltage-dependentmembrane capacitance (Fig. 3A,E,F). However, simultaneous measurementsof the length changes of the same cell showed a significant ACh-inducedincrease of the electromotile responses (Fig. 4). In a group ofcells showing a well preserved cylindrical cell body (n = 4),which we took as an indication of normal turgor condition, theelectromotile responses increased by 2-26% after ACh, withoutstatistically significant changes (at p = 0.05 level) in the peakvalue of C_m(V). After ACh, the midpoint of the voltage sensitivityof the membrane capacitance shifted slightly toward more hyperpolarizedvalues ( $Delta$ V_p = $-$ 3.9 ± 0.8 mV; p < 0.05). The ACh-induced stationaryelongation of the cells of this group ( $Delta$ L = 2.4 ± 3.0%) was notstatistically significant (p = 0.48).

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Figure 4. Functional decoupling of electromotility and nonlinear capacitance after ACh application. Capacitance-voltage relationships C_m(V) (top) and the voltage dependence of electromotile responses $Delta$ L(V) (bottom), measured before (control; closed squares), during (ACh; open circles), and after (washout; closed triangles) ACh application. Data are from the same experiment shown in Figure 3, A and C-F. Capacitance data were fitted by the scaled derivative of Boltzmann functions with the following parameters: C_max = 15 pF, C₀ = 16 pF, V_p = $-$ 55 mV, and W = 21 mV (control); C_max = 15 pF, C₀ = 16 pF, V_p = $-$ 50 mV, and W = 21 mV (ACh); and C_max = 16 pF, C₀ = 15 pF, V_p = $-$ 57 mV, and W = 22 mV (washout). Motility data were fitted by the Boltzmann functions with the following parameters: $Delta$ L_max = 4.5%, V_p = $-$ 56 mV, and W = 25 mV (control); $Delta$ L_max = 5.6%, V_p = $-$ 52 mV, and W = 23 mV (ACh); and $Delta$ L_max = 4.9%, V_p = $-$ 58 mV, and W = 24 mV (washout).

Cell turgor (intracellular pressure) is an important factor in the control of OHC electromotility (Shehata et al., 1991; Chertoffand Brownell, 1994) and nonlinear capacitance (Iwasa, 1993; Kakehataand Santos-Sacchi, 1995). Therefore, it was possible that theincrease of electromotility after ACh depended on turgor increase,with turgor and ACh effects canceling each other at the levelof the nonlinear capacitance. To exclude this possibility, wetested the effect of ACh on OHCs (n = 4) whose natural turgorhad been removed by applying negative pressure to the patch pipette(see Kakehata and Santos-Sacchi, 1996; Santos-Sacchi and Huang,1998). ACh did not change the maximal voltage-dependent capacitanceof these collapsed OHCs but shifted slightly the peak of C_m(V)( $Delta$ V_p = $-$ 3.3 ± 1.2 mV; p < 0.05).

Effect of ionomycin

To determine whether the elevation of [Ca²⁺]_i affects the OHC nonlinear capacitance, we applied the Ca²⁺ ionophore ionomycin. This drug is known to induce a generalized,transient increase of [Ca²⁺]_i by making the plasma membrane, as well as the membranes ofintracellular Ca²⁺ stores, permeable to Ca²⁺ (Liu and Hermann, 1978; Smith et al., 1989).

Puff applications of ionomycin (25 µM; 20 sec) produced dramatic increases of [Ca²⁺]_i in OHCs ( $Delta$ F/F = 84 ± 28%; n = 10), widespread along the whole-cellbody (Fig. 5A-C). The [Ca²⁺]_i increase was accompanied by a voltage-independent elongationof the cell (Fig. 5C, middle) amounting, on average, to $Delta$ L/L₀= 4.6 ± 0.9% (n = 10; p < 0.001). In 70% of the cells this elongationwas terminated by the loss of cell turgor, either temporary orpermanent. Usually, the [Ca²⁺]_i initially elevated by ionomycin showed a very slow decline,and it did not return to the baseline within 10-20 min. Furtherapplications of ionomycin to the same cell produced additionalstep-like increases of [Ca²⁺]_i, up to the saturating level of the fluorescent indicator. Saturationwas commonly reached after the second or third application. Onlydata from the first applications are reported here.

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Figure 5. Ionophore-mediated elevation of intracellular free Ca²⁺ concentration increases the OHC resting length, enhances electromotile responses, but does not affect nonlinear capacitance. A, Fluorescent image of an OHC filled with Oregon Green 488 BAPTA-1 (50 µM) through the patch pipette. B, The same cell shown in A 1 min after the application of 25 µM ionomycin. Scale bar, 10 µm. C, Time course of fluorescence changes (top), resting length (middle), and whole-cell current (bottom) after application of ionomycin to the cell shown in A and B. Fluorescence intensity was computed by averaging pixel values throughout the cell body. Deflections on the current and length records are caused by the delivery of triangular voltage ramps (numbered 1-4) to the cell. A closed horizontal bar at the bottom of the panel indicates the timing of the drug application. D, Membrane capacitance-voltage C_m(V) relationships before (control; ramp 1; closed squares) and after (ramps 2, 3, 4; open symbols) application of ionomycin, obtained during the correspondingly numbered voltage ramps in C. Data were fitted by the scaled derivatives of the Boltzmann function. E, Electromotility responses of a different OHC before application of ionomycin (Control; closed squares) and after recovery from ionomycin-induced turgor loss (Ionomycin, open circles; 2 min after drug application). Data were fitted by Boltzmann functions. Inset, A sample of the current-voltage relationship of the ionomycin-sensitive fraction of the whole-cell current.

Similar to ACh, ionomycin was able to evoke a transient outward current in 50% of the cells (range, 15-320 pA; n = 6) at V_h= $-$ 50 mV (Fig. 5C, bottom). The voltage dependence of this currenthad an N shape (Fig. 5E, inset) similar to that of the ACh-inducedoutward current (compare Fig. 3D). The simplest explanation isthat ionomycin evoked Ca²⁺-activated K⁺ current. At the concentration of 10 µM, ionomycin evoked onlyan outward current in three out of seven cells tested. In theremainder of the cells, no current response was detected, althoughan increase of [Ca²⁺]_i was always observed. At the higher concentration (25 µM), infour out of nine cells the outward current was followed by aninward current with a reversal potential close to zero (data notshown). Such inward current was generally found in cells witha high basal level of [Ca²⁺]_i, as judged by the resting fluorescence level of the cell andby the relatively small difference between resting and saturatingfluorescence. Ca²⁺-activated nonselective cation channels, possibly underlying theobserved inward currents, have been described in OHCs (Van denAbbeele et al., 1996). The nature of this second current was notinvestigatedfurther.

Usually, we did not observe any substantial changes of OHC voltage-dependent capacitance after ionomycin application, exceptat a relatively high drug concentration (50 µM) or with repeatedapplications of the drug to cells whose resting [Ca²⁺]_i level was initially already high (data not shown). In cellswith low resting [Ca²⁺]_i, ionomycin produced virtually no changes of the cell nonlinearcapacitance, even at a concentration of 25 µM (Fig. 5D).

Three cells were observed in bright field to investigate electromotile responses before and after the application of ionomycin(25 µM). In all three cases the maximum voltage-activated motileresponses of the OHCs increased (Fig. 5E) by 0.73, 0.63, and 1.24%of the cell length [0.87 ± 0.19% (mean ± SE); p < 0.05].

Effect of ACh and ionomycin on OHCs under perforated-patch conditions

Metabotropic effects of ACh may be significantly compromised under conventional whole-cell patch-clamp recording conditionsbecause of washout of intracellular constituents during the firstminutes after breaching the membrane patch (Horn and Marty, 1988).Therefore, we investigated the effects of ACh and ionomycin onthe cell's membrane capacitance under perforated-patch conditions,i.e., when the membrane patch at the pipette tip was not physicallybroken but was made permeable to small ions with nystatin (Hornand Marty, 1988). Under these conditions, we managed to measurereliably the OHC capacitance only in the two experiments shownin Figure 6. Neither ACh (Fig. 6A; 100 µM; 20 sec) nor ionomycin(Fig. 6B; 25 µM; 20 sec) produced measurable changes of C_m inthese experiments.

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Figure 6. ACh (A) and ionomycin (B) do not affect the OHC capacitance even under perforated-patch conditions. From top to bottom, the following parameters were measured: I, whole-cell current, R_m, membrane resistance; and C_m, membrane capacitance. The closed horizontal bars at the top of A and B indicate the timing of drug application.

Modulation of the operating range of OHC electromotility by protein phosphorylation

It has been suggested that the effect of ACh on OHC electromotility is mediated by a Ca²⁺-dependent phosphorylation of cytoskeletal proteins (Dallos etal., 1997). We tested whether phosphorylation affects also thevoltage sensor of the OHC motor by investigating the effects ofinhibitors and promoters of protein phosphorylation on $chi$ _m(V).Cells were preincubated at 37°C in okadaic acid, a powerful inhibitorof protein phosphatase-1 and -2A that promote phosphorylationof a wide range of proteins in vivo (Haystead et al., 1989), andthe specific calmodulin inhibitors trifluoperazine and W-7. Afterincubation, the cytoplasmic morphology of the cells in the dishdid not change visibly. A significant number of OHCs remainedviable according to our selection criteria (see Materials andMethods). After incubation in okadaic acid (1 µm; 30-60 min), $chi$ _m(V) shifted in the hyperpolarized direction (Fig. 7, top). Incubationfor 30-60 min with trifluoperazine (30 µM) and W-7 (150 µM) shifted $chi$ _m(V) in the opposite direction (Fig. 7, top). The voltage dependenceof the electromotile responses, $Delta$ L(V), was affected similarly(Fig. 7, middle). The effects of these reagents on $chi$ _m(V) did notdepend on intracellular pressure because they were reproducibleboth in artificially collapsed cells and in cells with apparentlynormal turgor. In artificially collapsed OHCs we observed thefollowing values of the potential at the peak of $chi$ _m(V): $-$ 37.7± 3.1 mV (control; n = 9), $-$ 56.8 ± 5.2 mV (okadaic acid; n = 4), $-$ 2.2 ± 1.9 mV (trifluoperazine; n = 3), and 0.9 ± 1.2 mV (W-7;n = 3). Parameters of $chi$ _m(V) and $Delta$ L(V) relationships for OHCs withapparently normal turgor are shown in Table 1. Comparing theeffects of these reagents (Fig. 7) with those produced by ACh(Fig. 3) indicates that the shift of $chi$ _m(V) induced by ACh is only~5-6% of the maximal range covered by phosphorylation.

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Figure 7. Modulation of the electromotility operating range by protein phosphorylation. Top, The voltage-dependent nonlinear capacitance shifts to hyperpolarizing potentials after preincubation of OHCs with okadaic acid (1 µM), a nonspecific inhibitor of native phosphatases. Preincubation with agents inhibiting Ca²⁺/calmodulin-dependent phosphorylation (trifluoperazine, 30 µM; W-7, 150 µM) shifts the curve in the opposite direction. Each curve is the average of measurements from several cells (n > 5) fitted by the derivative of Boltzmann functions, with the SE for both voltage and capacitance plotted at the maximum of each curve. Middle, Corresponding shifts of the motile responses. To highlight the shift of the midpoint of the curves, the maximal motile responses were normalized to 1. The parameter $Delta$ L_max varied substantially between the groups of cells, but the differences were not statistically significant. Boltzmann parameters for the curves are given in Table 1. Bottom, Effects of these reagents on the zero-current potentials measured from the corresponding I-V curves.


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Table 1. Parameters of $chi$ _m(V) and $Delta$ L(V) relationships for the control group of OHCs and the cells preincubated with okadaic acid (1 µM), trifluoperazine (30 µM), and W-7 (150 µM)

The reagents tested did not change significantly the maximal nonlinear capacitance $chi$ _max, the maximal motile response $Delta$ L_max,or the voltage sensitivity W of capacitance and electromotility,with the exception of okadaic acid that changed the voltage sensitivityW of $chi$ _m(V) (Table 1). However, they increased the zero-currentvoltage (Fig. 7, bottom), probably because of the disruption ofmechanisms responsible for maintaining the intracellular potential(Hasin and Barry, 1984).

It is well known that isolated OHCs are depolarized (Ashmore, 1987). Immediately after achieving the whole-cell configuration,the zero-current potential V_z is rarely more negative than $-$ 30mV and gradually shifts to more hyperpolarized values over 3-5min as potassium in the patch pipette equilibrates with the cellinterior. This explains the difference in the values of V_z inFigures 3C and 7, bottom. The latter were obtained within 60 secafter breaching the patch of membrane under the recording pipetteto minimize the dialysis of the intracellular constituents withthe pipette solution. The $-$ 6 mV shift in V_z reported for longOHCs in the presence of okadaic acid (Jagger and Ashmore, 1999)is not compatible with data in Figure 7 simply because the latterwere not obtained in steady-stateconditions.

Immunohistochemical localization of Ca²⁺ release channels and CaMK-IV

Ca²⁺/calmodulin-dependent protein phosphorylation often involves the release of Ca²⁺ from IP₃-gated intracellular stores (Berridge, 1993). To determinewhether the key elements of this pathway colocalize with the electromotileapparatus, we immunolabeled whole-mount preparations of the organof Corti with fluo-rescent antibodies raised against IP₃ receptors(Fig. 8, left) and CaMK-IV (Fig. 8, right). Labeling for boththe IP₃ receptors and CaMK-IV was found to be concentrated atthe cell cortex, along the OHC lateral wall between the nucleusand the cuticular plate. The lateral plasma membrane of the OHCcontains the putative molecular motors (Dallos et al., 1991; Kalinecet al., 1992) and is underlined by a cortical cytoskeleton adjacentto layers of endoplasmic reticulum named lateral cisternae (Holleyet al., 1992). The thicker pattern of labeling was observed forthe IP₃ receptor localization (Fig. 8, left), suggesting thatit is associated with the lateral cisternae. The thinner labelingobserved for the CaMK-IV (Fig. 8, right) suggests associationwith the cortical cytoskeleton or the plasma membrane. Some punctuatedlabeling was also observed below the cuticular plate and at thesynaptic pole of the OHC, for both the IP₃ receptor and the CaMK-IV.

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Figure 8. Colocalization of IP₃ receptors (IP₃R; left) and CaMK-IV (right) to the lateral wall of OHCs by confocal immunofluorescence microscopy. Optical cross sections (0.4 µm) were taken at 20 µm intervals, below the cuticular plate (top), halfway down the length of the cells (middle), and in the nuclei region (bottom). In both cases, the antibodies distinctly labeled the lateral wall of the OHC visualized as annular fluorescence patterns. Scale bar, 10 µm.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our results show, for the first time, that the voltage sensitivity of the OHC electromotile mechanism can be modulated byreagents affecting Ca²⁺/calmodulin-dependent phosphorylation. Inhibition of protein phosphorylationproduces a depolarizing shift of voltage sensitivity, whereasactivation leads to a hyperpolarizing shift (Fig. 7). The invarianceof the capacitance measurement in the presence and in the absenceof ion channel blockers (Fig. 1E) argues against the possibilitythat the effects of phosphorylation are indirect effects on ionchannels that in turn affect the motors. Calcium currents in OHCsare extremely small, and none of the several Ca²⁺ channel blockers we tested (Frolenkov et al., 1998a) had anyeffect on OHC electromotility. Therefore, it seems unlikely thatthe observed effects may be caused by modification of calciuminflux produced by the phosphorylation/dephosphorylation of calciumchannels. These effects are also not related to the changes ofcell turgor, because they were present in artificially collapsedcells as well as in cells with apparently normalturgor.

We have measured the voltage dependence of the nonlinear membrane capacitance C_m(V) and length change $Delta$ L(V) in isolated OHCswithout blocking ion channels. In these cells, most ion channelsare localized to a fraction of the plasma membrane near the synapticpole (Santos-Sacchi et al., 1997), where their density is severalfold lower than the density of the putative motor proteins inthe basolateral membrane [up to 6000/µm² (Frolenkov et al., 1998a)]. On the basis of our own measurementof the total motor's charge density movement:

we estimate the number of gating charges per protein to be ~2. This is well outside the range of 10-15 gating charges perpotassium channel estimated by Aidley and Stanfield (1996). Becausevoltage-dependent potassium currents provide by far the dominantcontribution to the OHC ionic conductance (Mammano and Ashmore,1996), we conclude that the charge movement underlying the voltagedependence of C_m(V) does not include a significant contributionfrom ion channel gating. In support of this conclusion we didnot find any significant differences measuring C_m(V) with andwithout ionic channel blockers (Fig. 1E).

Although we were able to detect a small shift of the voltage sensitivity of C_m(V) in the hyperpolarizing direction after ACh,this was at least 10 times smaller than the maximum shift inducedby protein phosphorylation. We observed a similar small effecton the OHC nonlinear capacitance after the application of ATP,a second natural ligand capable of promoting an [Ca²⁺]_i increase in OHCs (Mammano et al., 1999). The application ofACh to isolated OHCs evokes both a fast ionotropic response anda slow metabotropic response. The fast response is a BAPTA-sensitiveoutward current, attributed to K⁺ efflux through Ca²⁺-activated K⁺ channels (Blanchet et al., 1996; Evans, 1996). The slow responseis an increase in OHC motile responses, with a delay of ~10 sec,attributed to the activation of a Ca²⁺-dependent phosphorylation of cytoskeletal proteins and the subsequentdecrease in the global axial stiffness of the cell (Dallos etal., 1997). Our results confirm and extend these findings. Afterthe focal application of ACh to the synaptic pole of OHCs, weobserved a fast apamin-sensitive outward current (Fig. 3) as wellas an increase of the OHC electromotile responses (Fig. 4), independentof any appreciable change in the nonlinear capacitance (Fig. 3).

Changes in intracellular pressure (turgor) are known to shift the midpoint of the voltage sensitivity V_p of C_m(V) by as muchas 40 mV (Kakehata and Santos-Sacchi, 1995). In contrast, V_p isrelatively insensitive to the variations of intracellular pressurewhen OHCs are artificially deflated below the point of collapse(Kakehata and Santos-Sacchi, 1995). Under these conditions AChdid not alter C_m(V). Likewise, in cells with apparently normalturgor, the increase in the $Delta$ L(V) induced by ACh caused no significantchange in the concurrently measured C_m(V), both under whole-cell(Fig. 3) and under perforated-patch (Fig. 6) conditions. Thereforewe conclude that (1) the effects of ACh on OHC electromotilityare not mediated by turgor changes and (2) they do not involvea modulation of the operating range of the motor's voltagesensor.

It has been shown in unclamped OHCs that the increase in the concentration of intracellular Ca²⁺ induced by the selective Ca²⁺ ionophore ionomycin is followed by cell elongation promoted bya Ca²⁺/calmodulin-dependent pathway (Dulon et al., 1990; Coling et al.,1998). In our experiments both ACh and ionomycin evoked outwardcurrents (Figs. 3A, 5C), most probably because of the openingof Ca²⁺-activated K⁺ channels. Similar to ACh (Fig. 4), ionomycin was able to increasethe OHC motile responses without a significant effect on the cellvoltage-dependent capacitance (Figs. 4, 5E). Thus the effect ofACh on the electromotility is not unique; in both cases the crucialsteps seem to involve the elevation of [Ca²⁺]_i.

In unclamped OHC an outward current would produce hyperpolarization and consequently an electrically evoked elongation ofthe cell. In our experiments, OHCs were voltage-clamped, and theirelongation after ionomycin should be attributed to some mechanismchanging the mechanical properties of the cell. We conclude thatthe ionomycin-induced elongation of the OHC (Fig. 5C) is likelyto be a passive reaction of a turgid cell to a decrease of itsaxial stiffness, resulting from a Ca²⁺-dependent modification of cytoskeletal proteins. This mechanismwas proposed by Dallos et al. (1997) to explain the increase ofthe electromotile responses induced byACh.

Using immunofluorescence, we determined, in agreement with others (Koyama et al., 1999), that some key elements required toactivate a Ca²⁺-dependent protein phosphorylation cascade, i.e., IP₃ receptorsand CaMK-IV, are present along the OHC lateral wall (Fig. 8) wherethe putative molecular motors of the OHC are localized (Dalloset al., 1991; Kalinec et al., 1992). Like the cortical latticein erythrocytes, the filamentous network of OHC cytoskeletal proteinsseems to be anchored to the plasma membrane by periodic proteinpillars ~25 nm long (Raphael and Wroblewski, 1986). Normally,the relatively stiff circumferential filaments may restrain largechanges in cell diameter, whereas the elastic cross-links offerless resistance. The cortical lattice is a highly orthotropicstructure because its resultant circumferential stiffness modulusis approximately one order of magnitude larger than the axialone (Tolomeo et al., 1996). Consequently, a major function ofthe cytoskeleton would be to direct electrically driven shapechanges along the longitudinal axis of the cell (Tolomeo et al.,1996). A system of flattened, membrane-bound intracellular compartments,the subsurface cisternae (Engstrom, 1958), is found near the cytoskeletallattice. Closely related is the synaptic cisterna, located atthe basal (synaptic) pole of the cell. Together with the cytoskeletallattice and plasma membrane, they form a complex structure, thecell cortex (Holley et al., 1992). The preferential distributionof Ca²⁺-ATPase near the innermost layer of the cisternae, in strict appositionto linearly arranged mitochondria, supports a role for these structuresas intracellular Ca²⁺ stores (Schulte, 1993), a conclusion compatible with our presentimmunofluorescence data. Release of Ca²⁺ from these putative stores may activate biochemical cascadesthat modulate the cell's axial stiffness and the voltage sensitivityof the plasma membranemotors.

In conclusion, our data suggest that the OHC motor output may be affected by two Ca²⁺-dependent pathways. One pathway targets the proteins of the corticalcytoskeleton, altering the global axial stiffness of the cell.The other pathway targets the putative membrane motors, shiftingits operating range. Our results show that the natural ligandsACh (Figs. 3, 4, 6) and ATP (Mammano et al., 1999) do not causechanges in the voltage sensitivity of the membrane motors in isolatedOHCs maintained at room temperature and under whole-cell patch-clamprecording conditions. However, there are strong indications forthe existence of functional intracellular Ca²⁺ stores in close proximity to the OHC electromotile machinery.Release of Ca²⁺ from such stores may potentially modulate the function of theOHC motors very effectively. It remains to be determined whatsort of physiological stimuli may be responsible for the activationof these putative Ca²⁺ release-dependentcascades.

  FOOTNOTES

Received Dec. 6, 1999; revised May 24, 2000; accepted May 25, 2000.

This work was supported in part by a grant to F.M. from Istituto Nazionale di Fisica della Materia (Progetto di Ricerca AvanzataCADY). We thank Robert Fettiplace and Kuni Iwasa for criticalcomments and helpfulsuggestions.
Correspondence should be addressed to Dr. Bechara Kachar, Section on Structural Cell Biology, National Institute on Deafnessand Other Communication Disorders, National Institutes of Health,Building 36, Room 5D15, Bethesda, MD 20892-4163. E-mail: kacharb{at}nidcd.nih.gov.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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