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The Journal of Neuroscience, August 15, 1998, 18(16):6300-6318
Regulation of Free Ca2+ Concentration in Hair-Cell
Stereocilia
Ellen A.
Lumpkin and
A. J.
Hudspeth
Howard Hughes Medical Institute and Laboratory of Sensory
Neuroscience, The Rockefeller University, New York, New York
10021-6399
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ABSTRACT |
By affecting the activity of the adaptation motor,
Ca2+ entering a hair bundle through
mechanoelectrical transduction channels regulates the sensitivity of
the bundle to stimulation. For adaptation to set the position of
mechanosensitivity of the bundle accurately, the free
Ca2+ concentration in stereocilia must be tightly
controlled. To define the roles of Ca2+-regulatory
mechanisms and thus the factors influencing adaptation motor activity,
we used confocal microscopy to detect Ca2+ entry
into and clearance from individual stereocilia of hair cells dialyzed
with the Ca2+ indicator fluo-3. We also developed a
model of stereociliary Ca2+ homeostasis that
incorporates four regulatory mechanisms: Ca2+
clearance from the bundle by free diffusion in one dimension, Ca2+ extrusion by pumps, Ca2+
binding to fixed stereociliary buffers, and Ca2+
binding to mobile buffers. To test the success of the model, we
compared the predicted profiles of fluo-3 fluorescence during the
response to mechanical stimulation with the fluorescence patterns measured in individual stereocilia. The results indicate that all four
of the Ca2+ regulatory mechanisms must be included
in the model to account for the observed rate of clearance of the ion
from the hair bundle. The best fit of the model suggests that a free
Ca2+ concentration of a few micromolar is attained
near the adaptation motor after transduction-channel opening. The free
Ca2+ concentration substantially rises only in the
upper portion of the stereocilium and quickly falls toward the resting
level as adaptation proceeds.
Key words:
auditory system; bullfrog; Ca2+-ATPase; Ca2+ buffer; hair
bundle; mechanoelectrical transduction; vestibular system
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INTRODUCTION |
Vertebrate hair cells activate
neurons in response to mechanical stimuli such as sound and
acceleration. Mechanoelectrical transduction occurs in the hair bundle,
which comprises stepped ranks of actin-filled stereocilia and usually
includes one true cilium, the kinocilium (Lewis et al., 1985 ).
Mechanically gated channels located within 1 µm of the stereociliary
tips (Jaramillo and Hudspeth, 1991; Lumpkin and Hudspeth, 1995) mediate
transduction.
The prevailing model of mechanoelectrical transduction (for review, see
Hudspeth, 1989; Gillespie, 1995) posits that the open probability of
the channels is controlled by elastic gating springs, which are likely
the tip links that connect neighboring stereocilia (Pickles et
al., 1984; Assad et al., 1991). Each tip link is attached to a
few transduction channels (Holton and Hudspeth, 1986; Howard and
Hudspeth, 1988), perhaps just one or two (Denk et al., 1995; Ricci and
Fettiplace, 1997). Positive displacement of a hair bundle, toward its
tall edge, increases tip-link tension and opens these channels. The
influx of cations, mostly K+ but also
Ca2+ and Na+, depolarizes the
plasma membrane of the hair cell, leading to increased synaptic
transmission at the basolateral surface of the cell (for review, see
Howard et al., 1988). Negative bundle displacement reduces tip-link
tension, allowing closure of the transduction channels that are open at
rest (Corey and Hudspeth, 1983a; Crawford et al., 1991; Shepherd and
Corey, 1994).
Like other sensory receptors, hair cells adjust their sensitivity to
stimulation (for review, see Hudspeth and Gillespie, 1994; Gillespie
and Corey, 1997). This adaptive process is mediated by an adaptation
motor that is thought to consist of myosin I molecules (Gillespie et
al., 1993; Metcalf et al., 1994; Solc et al., 1994) and that regulates
tip-link tension and thus transduction- channel open probability by
moving along the actin-filled stereociliary core (Howard and Hudspeth,
1987). The activity of the motor is influenced by the free
Ca2+ concentration (Eatock et al., 1987; Assad et
al., 1989; Crawford et al., 1989, 1991; Hacohen et al., 1989), by
tip-link tension (Assad and Corey, 1992), and perhaps by cAMP (Ricci
and Fettiplace, 1997). Calmodulin molecules, which serve as myosin I
light chains (Reizes et al., 1994), probably confer the
Ca2+ sensitivity of the adaptation motor (Walker and
Hudspeth, 1996). Because of its critical role in adaptation, the free
Ca2+ concentration near the adaptation motor must be
determined if the sensitivity of the bundle to stimulation is to be
understood.
The stereocilium offers an advantageous system in which to examine the
regulation of free Ca2+ concentration in a living
cell. Because of the narrow, cylindrical form of a stereocilium,
diffusion along its length is well approximated by a one-dimensional
model. The transduction channel near the tip of the stereocilium and
the soma at its base serve as a Ca2+ point source
and a sink, respectively. Furthermore, the stereocilium lacks
membrane-bounded organelles that can imbibe Ca2+.
Finally, individual stereocilia can be imaged along their lengths with
high spatial and temporal resolution. To examine
Ca2+ homeostasis in hair bundles, we have used
confocal microscopy to collect images of stereocilia filled with the
Ca2+ indicator fluo-3 and have fit these responses
with a mathematical model of intracellular Ca2+
regulation.
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MATERIALS AND METHODS |
Hair-cell isolation. Experiments were performed at
room temperature on hair cells isolated from saccular maculae of the
bullfrog Rana catesbeiana. Each internal ear was dissected
in oxygenated low-Ca2+ saline solution containing
110 mM Na+, 2 mM
K+, 0.1 mM Ca2+, 110 mM Cl , 3 mM
D-glucose, and 5 mM HEPES at pH 7.25. After
removal of the tissue overlying the saccular nerve, the ear was
incubated for 15 min in the same solution supplemented with 1 mM EGTA and 1 mM MgCl2. Because any
leakage of otoconia prevented cellular dissociation, care was taken to
preserve the integrity of the otoconial sac through this step. After
dissection from the labyrinth, the saccular macula was digested
for 20 min with 50 µg·ml1 subtilisin
Carlsberg (protease type XXIV; Sigma, St. Louis, MO) and then for 5 min
with 50 µg·ml1 deoxyribonuclease I (type II; Sigma).
After a 5 min recuperation period in low-Ca2+ saline
solution, the otolithic membrane was lifted from the hair bundles, and
hair cells were dissociated with an eyelash. After the cells had
settled onto a concanavalin A-coated coverslip, the medium was replaced
with oxygenated standard saline solution containing 110 mM
Na+, 2 mM K+, 4 mM Ca2+, 118 mM
Cl, 3 mM D-glucose, and 5 mM HEPES at pH 7.25.
Loading hair cells with fluo-3 AM. To retain
endogenous mobile Ca2+ buffers in some hair cells,
we loaded these hair cells with membrane-permeant fluo-3 AM (Molecular
Probes, Eugene, OR). Each day of use, we made a fresh stock solution of
0.23% (w/v) fluo-3 AM and 20% (w/v) Pluronic F-127 in
dimethylsulfoxide (DMSO; Molecular Probes). Two fluo-3 AM-loading
solutions, which contained <0.4% (v/v) DMSO, were then prepared from
the stock: 3.33 µM fluo-3 AM in
low-Ca2+ saline solution and 6.67 µM
fluo-3 AM in standard saline solution. Two preparative steps were
critical for adequately loading hair cells. First, all reagents were
brought to room temperature before mixing. Second, the fluo-3 AM stock
solution and all fluo-3 AM aqueous solutions were vortexed vigorously
for at least 1 min and then sonicated in a bath sonicator for 1 min. To
prepare each loading solution, we initially diluted 10 µl of the
fluo-3 AM stock solution into 100 µl of the appropriate saline
solution, then added saline solution to reach the desired concentration of fluo-3 AM.
To load hair cells with fluo-3 AM, we used low-Ca2+
saline solution containing 3.33 µM fluo-3 AM during and
after the deoxyribonuclease treatment of the isolation procedure. After
cellular isolation, the low-Ca2+ solution with
fluo-3 AM was exchanged for standard saline solution containing 6.67 µM fluo-3 AM. After a 15-20 min incubation, this solution was replaced with standard saline solution.
To determine the approximate concentration of de-esterified fluo-3 in
cells loaded with fluo-3 AM, we used the Ca2+
ionophore A23187 at 2.5 µM (Molecular Probes) in standard
saline solution to increase the intracellular Ca2+
concentration at the end of each experiment (Kao, 1994). We compared the maximal hair-bundle fluorescence of hair cells treated in this
manner with that of cells dialyzed through whole-cell recording pipettes with different concentrations of the pentapotassium salt of
fluo-3 (lot number 2641-5; Molecular Probes). Using confocal microscopy, we collected an image of each hair bundle in the focal plane at which the fluorescence was greatest. To quantify the fluorescence, we averaged the intensities of pixels within a region encompassing only the hair bundle. Because images were often acquired at different confocal gain settings, these intensity values were normalized by the gain so that data from multiple cells could be
averaged. To normalize an image, we subtracted the background intensity
in grayscale units from each intensity value. The resultant value was
then divided by the gain of the confocal system expressed on a linear
scale. The maximal hair-bundle fluorescence of fluo-3 AM-loaded cells
(529 ± 31 arbitrary intensity units; mean ± SE; n = 44) was closely matched by that of cells dialyzed
with 0.1 mM fluo-3 (532 ± 72 arbitrary intensity
units; n = 14).
Electrophysiological recording. While the membrane potential
of each hair cell was held at  70 mV with a voltage-clamp amplifier (EPC-7; List Electronics, Darmstadt, Germany), the transmembrane current was measured by either the tight-seal, whole-cell or the perforated-patch recording technique (Marty and Neher, 1995; Walz, 1995). Before seal formation, the resistances of the recording electrodes were 2.5-4 M . To lower its capacitance, we coated the
shank of each recording electrode with beeswax (The Pottery Barn, New
York, NY). Two internal solutions were used for whole-cell recordings.
The first, which included the pentapotassium salt of fluo-3 at either
0.1 or 0.5 mM, contained 106 mM
Cs+, 4 mM Na+, 3 mM Mg2+, 106 mM
Cl, 2 mM ATP, and 5 mM
HEPES at pH 7.26. The second internal solution consisted of 0.2 mM fluo-3, 102 mM Cs+, 4 mM Na+, 1 mM
K+, 2 mM Mg2+, 104 mM Cl, 1 mM ATP, and 5 mM HEPES at pH 7.3. When noted, the second internal solution included 1 mM EGTA, a Ca2+
chelator.
For perforated-patch recordings, we dissolved nystatin (Sigma) in DMSO
at a concentration of 50 mg/ml each day of use. Recording electrodes
were tip-filled for ~1 sec with an internal solution containing 102 mM Cs+, 3 mM
Mg2+, 36 mM Cl, 35 mM SO42, and 5 mM HEPES at pH 7.28 and then back-filled with the same solution containing 200 µg/ml nystatin. The internal solution contained 0.4% (v/v) DMSO. After a tight seal had formed on the soma
of the cell, an access resistance of <20 M was usually achieved in
2-20 min.
To elicit Ca2+ entry through transduction channels,
we deflected a hair bundle using a glass micropipette attached by
gentle suction to the kinociliary bulb. The pipette was displaced using a piezoelectric stimulator (P-835.10 and P-870; Physik Instrumente, Waldbronn, Germany). To prevent excitation of the mechanical resonance of the stimulator, we filtered the driving signal with an eight-pole Bessel filter whose half-power frequency was set at 0.35-0.50 kHz.
The control signals for the voltage-clamp amplifier, piezoelectric
stimulator, and confocal-scanning system were supplied by a computer
programmed in LabVIEW (version 3.1; National Instruments Corporation,
Austin, TX). Signals were low-pass filtered with an eight-pole Bessel
filter set at either 1 or 10 kHz and then were digitized and recorded
with the computer system at a sampling frequency of 5 or 30 kHz,
respectively. Data filtered at 10 kHz were subsequently filtered
digitally at 1 kHz.
Confocal microscopy. As described previously (Lumpkin and
Hudspeth, 1995), fluo-3-loaded hair cells were visualized
simultaneously through epifluorescence and transmitted
differential-interference-contrast optics with a laser-scanning
confocal-imaging system (LSM-410UV; Carl Zeiss, Jena, Germany). Hair
cells dialyzed with 0.1 or 0.5 mM fluo-3 or those loaded
with fluo-3 AM were visualized with a 63×, plan-apochromat,
oil-immersion objective lens of numerical aperture 1.4. One response
(see Fig. 4C) was instead obtained with a 40×,
C-apochromat, water-immersion objective lens of numerical aperture 1.2. Hair cells filled with 0.2 mM fluo-3 were imaged with a
63×, plan-neofluar, oil-immersion objective lens of numerical aperture
1.25. With these lenses, the axial resolution of the confocal system,
measured as the distance between half-maximal points on the intensity
profile of a 100 nm bead, was ~0.8 µm. The lateral resolution was
0.4 µm by the same criterion. These values were determined using a
pinhole aperture of 22.8 µm (setting 13), which was the same as that
used for all experimentation. Given the lateral resolution of the
microscope and the stereociliary spacing, the stereocilia above and
below the plane of focus usually contributed little to the fluorescence
signal of a hair bundle (Lumpkin and Hudspeth, 1995).
The line-scan mode of the confocal microscope was used to follow
fluorescence changes in individual stereocilia. We first collected
frame-scan images of each hair cell to determine the best focal plane
and confocal-system gain setting for imaging. We chose a focal plane in
which a stereocilium containing an active transduction channel could be
imaged along its entire extent. To locate stereocilia containing active
transduction channels, we looked for tip blushes or heightened
fluorescence near stereociliary tips caused by transduction channel
opening at rest (Lumpkin and Hudspeth, 1995). In most cases, fewer than
half of the stereocilia contained active channels. After such a
stereocilium had been identified, a transect along its length and into
the soma was specified by means of the confocal system's software (see
Fig. 1A). For collection of a line-scan image, a
diffraction-limited spot of illumination was repeatedly swept along the
entire length of the transect at 1.4 msec intervals; 2.8 sec of data
were typically collected for each line-scan image. During image
acquisition, the hair bundle was displaced 200 nm for 100 msec to open
transduction channels and to allow Ca2+ influx. When
the transect was properly positioned, the same stereocilium was scanned
before, during, and after the hair-bundle deflection. Unless noted, the
images included in this study represent the first or second line-scan
image acquired from each stereocilium, which was usually collected
100-200 sec after the onset of whole-cell recording.
When recording from fluo-3 AM-loaded hair cells and the associated
control cells, we typically delivered 300 nm, 500 msec hair-bundle
deflections. Instead of imaging single stereocilia along their lengths,
we usually detected transduction in multiple stereocilia simultaneously
by scanning nearly perpendicular to their long axes (see Fig.
6A). To do so, we set the transect of illumination
within 1 µm of the tip of the shortest stereocilium, at an angle of
<12° with respect to the top of the cuticular plate. In such
line-scan images, each stereocilium in the optical slice was scanned at
a slightly different distance from its tip. As a result, the
fluorescence increase during stimulation was first observable in short
stereocilia and then in successively taller ones (Denk et al.,
1995).
Image processing. Fluorescence and
differential-interference-contrast images were merged into a single
image (see Fig. 1A) with Photoshop (version 3.0;
Adobe Systems, Mountain View, CA). All other image processing and
analysis were accomplished by use of NIH Image (version 1.59; National
Institutes of Health, Bethesda, MD). Before processing, images were
smoothed with a three-by-three filter, which introduced a spread in the
time domain of <0.5 msec. The images (see Figs. 1, 6, 7) were
contrast-enhanced for optimal reproduction during publication.
Fluorescence intensity is plotted on one of three scales in this paper.
For some plots (see Figs. 1, 3-5) and images (see Fig. 6),
fluorescence is displayed on a scale of 256 grayscale units corresponding to the output of the eight-bit detector of the confocal system. Other images (see Figs. 1, 7) are displayed on a color scale
with 128 units ranging from blue to red. Other fluorescence plots (see
Fig. 7C,D) were normalized by the gain setting of
the confocal system so that the fluorescence intensities could be compared directly; a scale of 200 arbitrary intensity units is used.
To constrain the Ca2+-regulation model, we first
determined the length of each stereocilium from the line-scan image.
After plotting average intensity versus distance for the data collected during hair-bundle deflection, we defined the tip of the stereocilium as the distal point at which the maximal fluorescence intensity fell by
one-half. The lengths of the stereocilia used in this investigation
ranged from 4.11 to 6.08 µm and averaged 4.74 µm.
After its length had been quantified, each stereocilium was divided
into compartments for comparison with the
Ca2+-regulation model. The bottom two compartments,
each of which was 0.5 µm in length, represented the taper. The
remainder of the stereocilium was ordinarily divided into seven equal
compartments, each of which was ~0.5 µm in length. For four
compartments, the pixels within each compartment at each time point
were averaged to yield plots of fluorescence intensity versus time.
To quantify the time course of the fluorescence change in an image from
a line scan oriented nearly perpendicular to the long axis of a
stereocilium, we constructed a plot of intensity versus time by
averaging the intensity of all pixels representing the hair bundle
along the transect of illumination. The plot was normalized by the gain
of the confocal system, after which the rise time to half-maximal
fluorescence was determined. This rise time was related to the rate of
fluorescence spread down the individual stereocilia.
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RESULTS |
Detection of Ca2+ influx in
individual stereocilia
To characterize Ca2+ homeostasis in the hair
bundle, we used laser-scanning confocal microscopy to detect changes in
Ca2+ concentration in individual stereocilia of hair
cells dialyzed with fluo-3. After a stereocilium containing an active
transduction channel had been identified (Fig.
1A), the confocal
system repeatedly scanned the length of the stereocilium. During the
acquisition of the line-scan image, the hair bundle was deflected to
elicit Ca2+ entry through transduction channels
(Fig. 1B); the resulting whole-cell current response
was also recorded. This Ca2+ influx was accompanied
by an increase in fluo-3 fluorescence intensity that began near the tip
of the stereocilium (Lumpkin and Hudspeth, 1995) and progressed
approximately halfway down its length. After the 100 msec bundle
deflection ended, the fluorescence quickly approached its baseline
level.
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Figure 1.
Line-scan protocol. A, A merged
differential-interference-contrast and fluorescence image portrays the
undisturbed hair bundle of a hair cell dialyzed with 0.2 mM
fluo-3. The diagonal white line marks the transect of
illumination during line-scan imaging. The stimulus micropipette
attached to the kinociliary bulb (upper right) was used
to deflect the hair bundle. B, In this fluorescence
line-scan image, the ordinate represents distance from
above the stereociliary tip (top) to the cuticular plate
(bottom); time increases to the right
along the abscissa. The colors of individual pixels
depict fluo-3 fluorescence intensity; the 128-color scale ranges from
blue, which corresponds to 3 grayscale units, to
red, which corresponds to 130-234 grayscale units.
During line-scan imaging, a hair-bundle deflection elicited
Ca2+ influx, which was visualized as increased
fluorescence intensity in the top half of the stereocilium. The 200 nm,
100 msec positive displacement pulse, indicated in temporal register
with the 500 msec line-scan image, elicited a peak whole-cell response
of 108 pA (see Fig. 4B). The stereocilium was
divided into nine compartments, four of which are indicated by the
boxes overlying the line-scan image. C,
To compare the fluorescence data with a model of
Ca2+ homeostasis, we generated plots of fluorescence
intensity versus time for compartments 2, 4, 6, and 8 (C2-C8) by averaging for each time point
the intensities of the pixels within the respective compartments.
Fluorescence intensity was measured on a scale of 256 grayscale units.
Five hundred milliseconds of data are plotted; the displacement began
at 100 msec.
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We analyzed the time course of the fluorescence change accompanying
mechanoelectrical transduction by dividing the stereocilium into nine
compartments and plotting the fluorescence intensity versus time for
compartments 2, 4, 6, and 8 (Fig. 1C). In compartment 2, which was near the stereociliary tip, the fluorescence intensity tripled within milliseconds of the onset of the hair-bundle
displacement and then began to fall as adaptation proceeded. By
contrast, both the magnitude and rate of the intensity increase were
lower in compartments located closer to the base of the stereocilium,
confirming that the site of Ca2+ entry was situated
near the stereociliary tip (Hudspeth, 1982; Jaramillo and Hudspeth,
1991; Denk et al., 1995; Lumpkin and Hudspeth, 1995). In all
compartments with detectable fluorescence increases, the intensity
returned to its resting level within 200 msec of the end of the
positive displacement.
A model of stereociliary Ca2+ homeostasis
To represent the cellular mechanisms determining the time course
of Ca2+ influx and efflux in stereocilia, we
constructed a one-dimensional computational model of
Ca2+ homeostasis that included five processes that
might affect the free Ca2+ concentration of the
stereocilium (Fig. 2):
Ca2+ influx through transduction channels, simple
diffusion, extrusion by Ca2+ pumps, buffering by a
fixed Ca2+ buffer F, and buffered diffusion in
conjunction with an indicator I and a mobile Ca2+
buffer B. The components, simplifying assumptions, and implementation of the model are discussed in the ; the parameters of the model
and representative values are listed in Table
1.
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Figure 2.
Model of Ca2+ regulation in a
stereocilium. In the one-dimensional diffusion model of
Ca2+ homeostasis, the shaft of the stereocilium
comprised seven compartments (compartments 1-7), whereas the taper was
represented by two 0.5 µm compartments (compartments 8 and 9). For
the stereocilia included in this study, the first seven compartments
were also ~0.5 µm in length. The soma was represented as a single
compartment in which the concentrations of free Ca2+
and of mobile buffers were held constant. Ca2+
entered through a transduction channel located in compartment 1 or 2. Ca2+ could be removed from the stereocilium by
simple diffusion down its concentration gradient, extrusion by
Ca2+ pumps, or buffered diffusion complexed to
either fluo-3 or EGTA. Alternatively, Ca2+ could
bind to a fixed stereociliary buffer. For each compartment, such as
compartment 2 in the figure, these various processes were represented
by seven differential equations.
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The model describes Ca2+ homeostasis in the
individual stereocilium, which is divided lengthwise into nine
compartments. Ca2+ ions enter the model stereocilium
through one or two transduction channels, which can be located at the
stereociliary tip (compartment 1), ~1 µm from the tip (compartment
2), or both. At its base, the stereocilium is continuous with the soma
of the hair cell, into or from which Ca2+,
indicator, and mobile buffer can diffuse.
Fitting fluorescence data with the model
To determine whether our model adequately describes
Ca2+ regulation in a stereocilium, we compared the
predicted fluorescence profiles of the model for a given whole-cell
current response with fluorescence data collected from a stereocilium
during the acquisition of that response. For each stereocilium, the
fits for compartments 2, 4, 6, and 8 were evaluated; to conserve space, we display fewer compartments in most figures. To determine the adequacy of the fit, we compared the output of the model with the
fluorescence data and calculated a squared error for each compartment.
Using the model, we successfully fit eight images collected from seven
cells as described below. Although images were collected from hundreds
of stereocilia, most were not suitable for fitting either because of a
low signal-to-noise ratio in the fluorescence data or the whole-cell
current response or because multiple stereocilia contributed to the
fluorescence signal in the line-scan image.
For a cell dialyzed with 0.2 mM fluo-3 (Fig.
3), reasonable fits to four compartments
were obtained with the parameter values listed in Table 1. By changing
those parameter values that were measured for each cell, as well as the
sensitivity of the confocal system and the somatic
Ca2+ concentration (CaSOMA),
model solutions with a similar goodness of fit for four compartments
could be obtained for stereocilia from three other cells: one filled
with 0.2 mM fluo-3 and 1 mM EGTA (Fig.
4A) and two filled with
0.5 mM fluo-3 (Fig. 4B; data not shown).
A second response from the cell shown in Figure 4B was also well fit by the model.
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Figure 3.
Comparison of experimental fluorescence data and
the predicted fluorescence profiles of the model. In this and
subsequent comparisons, a 200 nm hair-bundle deflection began at 100 msec and ended at 200 msec. Below the fluorescence data are shown the
whole-cell current response recorded during the displacement
(thin trace) and a fit (superimposed
thick line) that includes the estimated transduction and
Ca2+pump currents. The estimated
transduction current was used to specify the transduction-channel
open probability in the model. In a hair cell dialyzed with 0.2 mM fluo-3, the experimental fluo-3 fluorescence
(squares) in compartment 2 doubled within 10 msec of hair-bundle
deflection; the peak intensities and rates of increase in compartments
4-8 were progressively lower. As adaptation proceeded, the
fluorescence in compartments 2 and 4 fell slightly. After the
deflection ended, the fluorescence in all compartments returned to
baseline within 200 msec. For the best fit of the model to these data,
the predicted fluorescence profiles (solid lines) fit
the baseline fluorescence and the rise and fall of fluorescence in four
compartments; the peak fluorescence was slightly underestimated in
compartment 4, however, and overestimated in compartment 8. The squared
error for this fit was 6 square units; the parameter values used are
listed in Table 1. The timescale for compartment 8 applies to all
compartments.
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Figure 4.
Best fits to fluorescence data from stereocilia
under different mobile-buffering conditions. A, In a
cell dialyzed with 0.2 mM fluo-3 and 1 mM EGTA,
the predicted fluorescence traces (solid line) fit well
the experimental fluorescence intensities (squares) in
four compartments; only compartments 2, which contained the
transduction channel in the model, and 6 are shown. The parameter
values used in calculating this fit were L = 4.27 µm, sensitivity = 731, iREST = 6
pA, iMAX = 133 pA,
iADAPT = 10 pA,  POS = 10 msec, NEG = 100 msec, and CaSOMA = 0.085 µM. B, In a cell dialyzed with 0.5 mM fluo-3, the model adequately predicted the baseline,
rise, and fall of the fluorescence signal in four compartments but
slightly underestimated the peak fluorescence in compartment 2, which
contained the transduction channel. The parameter values used in
calculating this fit were L = 4.17 µm,
sensitivity = 497, iREST = 4 pA,
iMAX = 108 pA,
iADAPT = 10 pA, POS = 20 msec, NEG = 30 msec, and CaSOMA = 0.019 µM. C, The model also performed well in
fitting the responses from another cell filled with 0.5 mM
fluo-3 but with single transduction channels situated in both
compartments 1 and 2. The parameter values used in calculating this fit
were L = 4.37 µm, sensitivity = 185, iREST = 4 pA,
iMAX = 160 pA,
iADAPT = 20 pA, POS = 7 msec, NEG = 20 msec, and CaSOMA = 0.079 µM.
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With one exception, all stereocilia were fit with only one transduction
channel, which was situated in compartment 2. In a fifth cell, which
was filled with 0.5 mM fluo-3, a better fit was achieved
with one channel each in compartments 1 and 2 (Fig. 4C).
The summed squared error for the best fits to these five cells, which
were determined with identical extrusion and fixed-buffering conditions, was 83 square units.
Effect of Ca2+ pumps
Because the ionic composition of endolymph, which bathes the hair
bundle in vivo, resembles that of cytoplasm, no obvious ionic gradient is available to drive extrusion of
Ca2+ from the hair bundle through a secondary active
transporter. Extrusion may instead be mediated by plasma membrane
Ca2+-ATPases, or Ca2+ pumps,
which occur in stereocilia (Crouch and Schulte, 1995; Apicella et al.,
1997; Yamoah et al., 1998). In hair cells from the bullfrog's
sacculus, these Ca2+ pumps extrude detectable
amounts of Ca2+, and disruption of their pumping
cycle impedes the ability of a hair cell to clear
Ca2+ that enters stereocilia through transduction
channels (Yamoah et al., 1998).
When Ca2+ pumps were removed from the model, the
best fits to the experimental data consistently peaked in the top
portion of the stereocilium at intensities lower than that observed
experimentally (Fig. 5A). In
the lower half of the stereocilium, however, the model without pumps
overestimated the peak fluorescence. In addition, the decline in
predicted fluorescence after stimulation was slower than that of the
experimental data in all compartments. When the sensitivity was
adjusted so that the peaks in the top compartments were well fit, the
baselines were overestimated in all compartments. The most
straightforward interpretation of these results is that the resting
stereociliary free Ca2+ concentration predicted by
the model in the absence of Ca2+ pumps exceeded that
demonstrated by the experimental data.
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Figure 5.
Effects of removing Ca2+ pumps
or fixed buffers from the model. The experimental data
(squares) are the same as that shown in Figure 3.
A, When Ca2+ pumps were removed from
the model, the best attainable fit (solid line)
underestimated the peak fluorescence in compartment 2, and the time
course of the fall of the predicted fluorescence trace was slower than
that of the experimental data. In the lower half of the stereocilium,
including compartment 6, the peak fluorescence was overestimated. The
squared error for this fit was 24 square units. The parameter values
used in calculating this fit were the same as those listed in Table 1,
except that pump density = 0 µm2 and
sensitivity = 332. B, When the fixed buffer was
removed from the model, the fit overestimated the peak fluorescence in
compartments without the transduction channel, and the rise and fall of
the predicted fluorescence traces were faster than that observed
experimentally. The squared error for this fit was 44 square units. The
parameter values used in calculating this fit were the same as those
listed in Table 1, except that [F]TOTAL = 0 mM and sensitivity = 447.
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|
To determine whether Ca2+ pumps were required to fit
the experimental fluorescence data adequately, we set the density of
Ca2+ pumps to zero and then found the best fits for
the five stereocilia described above. To achieve the best fit, we
varied the concentration and the OFF rate of the fixed buffer F
for all cells simultaneously; the optimal conditions included a fixed
buffer whose concentration was 0.59 mM and whose OFF rate
constant was 277 sec1. In addition, we
independently varied the sensitivity and somatic Ca2+ concentration for each cell. For the five cells
under consideration, the summed squared error without
Ca2+ pumps was 110 square
units.
Effect of fixed buffer
A considerable amount of fixed Ca2+ buffer also
had to be included in the model to fit the experimental fluorescence
profiles adequately. When fixed buffer was removed, the model
substantially overestimated the peak fluorescence values in the lower
half of the stereocilium (Fig. 5B). Furthermore, the time
courses of the rise to peak and return to baseline of the predicted
fluorescence trace were much faster than those of the experimental
data.
Although this fixed buffer might comprise several endogenous proteins,
we chose for simplicity to represent it as a single Ca2+-binding species. To determine the fixed buffer
concentration and the binding constants that best fit the fluorescence
patterns of five stereocilia, we set the ON rate of the fixed buffer
equal to that of fluo-3 and varied the OFF rate and the concentration. For each cell, we also varied the sensitivity of the confocal system
and the somatic Ca2+ concentration independently. We
found that the best fit for all five cells was achieved with a fixed
buffer concentration of 0.61 mM and an OFF rate of 283 sec1. The same goodness of fit could not be
achieved by setting the OFF rate of the fixed buffer equal to that of
fluo-3 and varying the ON rate and concentration. Furthermore, adequate
fits were not achieved by removing fixed buffers and allowing the
turnover rate of the Ca2+ pumps to vary. The summed
squared error for the best fit without a fixed buffer in five cells was
132 square units.
We noticed that fluo-3 sometimes became immobilized in the cell at the
position of line-scan imaging (Fig. 6),
perhaps because of photocross-linking. Throughout the study, we
attempted to minimize this effect by attenuating the laser to the
lowest irradiance compatible with adequate fluorescence signals.
Furthermore, we did not analyze images in which fluo-3 immobilization
was apparent. We nevertheless found that the first line-scan images
collected were better fit with a lower fixed-buffer concentration than
that required to fit fluorescence data collected after repeated
line-scan imaging (data not shown); local fluo-3 immobilization may
therefore have been a source of fixed buffer.
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Figure 6.
Immobilization of fluo-3 in a hair bundle after
repeated line-scan imaging. A, In a fluorescence image
of the unstimulated hair bundle of a cell dialyzed with 0.5 mM fluo-3, the horizontal white line marks
the transect of illumination during line-scan imaging. Note the tip
blushes in the shortest and second tallest stereocilia in this
optical section. B, After the acquisition of nine
line-scan images, a stripe of increased fluorescence intensity betrayed
the position of line-scan imaging. The enhanced fluorescence persisted
even after cell death, suggesting that fluo-3 had been permanently
immobilized in the stereocilia. The gain of the confocal system for
A was fivefold that for B.
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When the fixed buffer concentration was allowed to vary, a sixth and
seventh cell, both of which had been imaged repeatedly, could be fit; a
cell dialyzed with 0.1 mM fluo-3 was fit with 1.39 mM fixed buffer, whereas a cell filled with 0.2 mM fluo-3 and 1 mM EGTA was fit with 2.2 mM fixed buffer.
Effect of endogenous mobile Ca2+ buffer
Mobile Ca2+ buffers play an important role in
clearing Ca2+ that enters through voltage-gated
Ca2+ channels at the presynaptic active zone of a
hair cell (Roberts, 1993, 1994; Issa and Hudspeth, 1994, 1996; Tucker
and Fettiplace, 1995, 1996; Hall et al., 1997). Because they are washed
out of cells in the whole-cell recording configuration, the mobile
Ca2+ buffers of a hair cell probably had little
effect on the time course of fluorescence changes we observed. To
determine whether endogenous mobile buffers could influence the profile
of fluo-3 fluorescence in the hair bundle, we therefore compared images of cells loaded with membrane-permeant fluo-3 AM with those of cells
loaded with fluo-3 through whole-cell pipettes. During positive bundle
deflections, the spread of increased fluorescence down individual
stereocilia was usually faster in cells loaded with fluo-3 through a
whole-cell pipette (n = 3; Fig.
7A) than in cells loaded with
fluo-3 AM (n = 4; Fig. 7B).
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Figure 7.
Effect of endogenous Ca2+
buffers on experimental fluorescence profiles. A,
B, In line-scan images of individual stereocilia,
increased fluorescence during hair-bundle deflection spread faster in a
cell dialyzed with 0.1 mM fluo-3 through a recording
pipette (A) than in a cell loaded with a
comparable amount of fluo-3 AM (B). The beginning
of a 500 msec hair-bundle deflection is indicated by the white
tick marks at the top of A and
B. The line-scan image in A was the
fourth obtained from one stereocilium, whereas that in B
was the second from another. The 128-color scale extends from
blue, which corresponds to 4 grayscale units, to
red, which corresponds to 60-135 grayscale units. The
scale bar in B also applies to A.
C, D, To quantify the time course of
mechanically stimulated fluorescence increases, we plotted normalized
intensity versus time for hair bundles imaged nearly perpendicular to
the long axes of the stereocilia; fluorescence was expressed in
arbitrary intensity units. C, For a different cell
dialyzed with 0.1 mM fluo-3, the rise time of the plot to
half-maximal fluorescence t1/2 was 25 msec.
D, Although the magnitude of the fluorescence increase
was similar in a fluo-3 AM-loaded hair cell, the
t1/2 of the fluorescence increase was 95 msec. The 500 msec hair-bundle deflections began at 100 msec in
C and D.
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Although the magnitudes of mechanically stimulated fluorescence changes
in hair cells loaded with fluo-3 AM were similar to those in cells
studied by whole-cell recording, tip blushes were not often apparent in
fluo-3 AM-loaded cells. This made the identification of stereocilia
with active transduction channels very difficult. To circumvent the
need to detect tip blushes, we simultaneously imaged changes in the
fluorescence of several stereocilia and determined the rise times to
half-maximal fluorescence (t1/2) during
bundle deflection. For cells loaded with 0.1 mM fluo-3 through recording pipettes, the t1/2 during
positive bundle deflection averaged 22 ± 3 msec (mean ± SE;
n = 4; Fig. 7C). By contrast, the value for
fluo-AM-loaded cells, 82 ± 8 msec (n = 13), was significantly greater (p = 6·106; two-tailed Student's t test;
Fig. 7D).
Because the endogenous mobile buffers dramatically slowed the spread of
fluorescence in these stereocilia, they probably contributed to the
regulation of free Ca2+ concentration. To determine
whether the Ca2+-buffering environment significantly
affected adaptation, we compared the adaptation time constants measured
in perforated-patch and whole-cell recordings. For positive deflections
of 150-250 nm, the mean adaptation time constant measured in the
perforated-patch configuration was 25 ± 5 msec (n = 6). This value was not significantly different from that determined
for cells in the whole-cell configuration (20 ± 3 msec;
n = 8; p = 0.44).
Estimated Ca2+-pump current
A transduction-dependent outward current associated with
Ca2+ extrusion has been measured from bullfrog
saccular hair cells (Yamoah et al., 1998). This current may arise from
the electrogenic exchange of one H+ for one
Ca2+ during each pumping cycle (Hao et al., 1994).
After fitting the experimental data, we used the model to estimate the
amount of Ca2+ extruded from the hair bundle by
Ca2+ pumps. For a cell filled with 0.2 mM fluo-3, hair-bundle Ca2+ pumps were
calculated to produce ~1.3 pA of outward current during stimulation,
which decayed with a time constant of 75 msec at the conclusion of a
positive bundle deflection (Fig. 8). This Ca2+-pump current lies in the range of those
determined from whole-cell recordings (Yamoah et al., 1998). The pump
current estimated to flow during and after the displacement
corresponded to the extrusion of approximately three-quarters of the
Ca2+ that entered through the transduction channel
during the bundle deflection.
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Figure 8.
Estimated Ca2+-pump current in
the hair bundle. A, The experimentally measured
whole-cell current (thin trace) was fit by the
estimated whole-cell current response (thick line).
B, The estimated whole-cell response (thick
line) in turn represented the sum of the calculated
transduction current (thin line) and the estimated
Ca2+-pump current, which is shown on a different
current scale in C. The 200 nm, 100 msec hair-bundle
deflection is indicated below C. The parameter values
used in calculating this fit are listed in Table 1, and the
fluorescence plots for this response are shown in Figure 3.
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Estimated free Ca2+ concentration
The model was also used to estimate the free
Ca2+ concentration in compartments containing
transduction channels. For a cell filled with 0.2 mM fluo-3
(Fig. 9A), the shape of the
calculated change in free Ca2+ concentration in
compartment 2 mimicked that of adaptation, suggesting that
Ca2+ ions are quickly captured by buffers and
Ca2+ pumps in the stereocilium. In a cell loaded
with 0.5 mM fluo-3 (Fig. 9B), the magnitude and
rate of change in the estimated free Ca2+
concentration were lower than that for the cell loaded with 0.2 mM fluo-3, a difference consistent with the distinct
Ca2+-buffering capacities of the cells. Although the
total buffering capacity was higher in a cell filled with 0.2 mM fluo-3 and 1 mM EGTA than in one filled with
0.5 mM fluo-3, the calculated change in fluorescence was
faster in the former (Fig. 9C), presumably because of the
low ON rate of EGTA. In cells for which reasonable fits were achieved,
the peak estimated free Ca2+ concentrations in the
compartments containing transduction channels ranged from 0.44 to 25 µM and averaged 6.5 µM.
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Figure 9.
Estimated free Ca2+
concentration in stereocilia. All panels display the predicted
responses for compartment 2, which contained the transduction channel.
A, For a cell filled with 0.2 mM fluo-3, the
estimated free Ca2+ concentration rose from a
resting level of ~0.31 µM to a peak of 7.4 µM within 25 msec of hair-bundle deflection. The
predicted fluorescence profiles for this solution of the model are
shown in Figure 3. B, In a cell loaded with 0.5 mM fluo-3, the calculated concentration rose from 0.06 to
0.44 µM during mechanical stimulation. The predicted
fluorescence profiles in compartments 2 and 6 for this model solution
are shown in Figure 4B. C, In a
cell loaded with 0.2 mM fluo-3 and 1 mM EGTA,
the free Ca2+ concentration in compartment 2 was
predicted to rise from 0.16 to 1.1 µM during this
positive deflection. The predicted fluorescence profiles in
compartments 2 and 6 for this model solution are shown in Figure
4A.
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Despite the variation in the calculated peak free
Ca2+ concentrations, the positive adaptation time
constants for these cells were similar. For example, the peak estimated
free Ca2+ concentration in compartment 2 was 17 times as high in Figure 9A as in Figure 9B. The
adaptation time constant for both cells, however, was 20 msec.
Although the fluo-3 fluorescence intensity may increase along the
entire stereocilium (Fig.
10A), our model
predicted that, for the hair-bundle displacements used in this study,
the increased free Ca2+ concentration was tightly
restricted to the upper portion of the stereocilium. For a cell filled
with 0.2 mM fluo-3 and bathed in standard saline solution,
the estimated free Ca2+ concentration was elevated
only in the top half of the stereocilium at the peak of the response
(Fig. 10B). At the end of the bundle deflection (Fig.
10, solid lines), the estimated free Ca2+
concentration decreased dramatically, whereas the predicted
fluorescence intensity remained high.
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Figure 10.
Predicted spatial restriction of free
Ca2+. A, For the response shown in
Figure 3 from a cell loaded with 0.2 mM fluo-3, the
predicted fluorescence intensity before bundle deflection
(line with long and short
dashes) was slightly higher at the stereociliary tip
(x = 0 µm) than at the base
(x = 4.11 µm). The predicted fluorescence more
than doubled near the tip 20 msec after deflection (dashed
line). At the end of the 100 msec deflection, the predicted
increase in fluorescence intensity had propagated toward the
stereociliary base (solid line). B, The
free Ca2+ concentration calculated for the response
in A increased significantly only in the top half of the
stereocilium 20 msec after deflection. By the end of the deflection,
the estimated free Ca2+ concentration dropped
precipitously. C, Under endolymph-like ionic conditions,
the free Ca2+ concentration was estimated to
increase from 0.05 to 0.09 µM in the compartment
containing the channel. As in standard saline solution, the change in
free Ca2+ concentration was tightly localized to the
top portion of the stereocilium. Note that the calculated free
Ca2+ concentration in the middle of the stereocilium
was lower than that at the base. The parameter values listed in Table 1
were used in calculating this fit, except that
fCa = 0.03 and
VM = 60 mV. The line
symbols in B and C are described
in A.
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Hair bundles in vivo are bathed in endolymph, which contains
only 260 µM Ca2+ in the bullfrog's
sacculus (Corey and Hudspeth, 1983b), 65 µM in the
turtle's cochlea (Crawford et al., 1991), and 30 µM in the guinea pig's cochlea (Bosher and Warren, 1978). For the
bullfrog's saccular hair cells in the presence of an endolymph-like
solution, the fraction of the total transduction current carried by
Ca2+ is estimated at 0.03 (Lumpkin et al., 1997).
Furthermore, the resting membrane potential of the cells, approximately
60 mV (Hudspeth and Corey, 1977; Corey and Hudspeth, 1983a), is
slightly more positive than is the holding potential used in the
present study. Under these in vivo conditions, the free
Ca2+ concentration in compartment 2 for the response
in Figure 3 was estimated to peak at only 0.09 µM (Fig.
10C).
The magnitude of transduction currents recorded from isolated hair
cells indicates that these cells average fewer than one transduction
channel per stereocilium. In vivo, however, a stereocilium may contain more than one active transduction channel (Holton and
Hudspeth, 1986; Howard and Hudspeth, 1988; Denk et al., 1995). To
ascertain the effect of two active channels on the estimated free
Ca2+ concentration, we ran the model with the
parameter values listed in Table 1, except that one channel was
positioned in compartment 1 and a second was included in compartment 2. For the transduction current response in Figure 3, the estimated peak
free Ca2+ concentrations in compartments 1 and 2 exceeded 130 µM under experimental ionic conditions and
peaked at ~0.15 µM under in vivo conditions.
That a twofold change in Ca2+ influx caused a
16-fold increase in estimated free Ca2+
concentration in vitro suggests that the
Ca2+-regulatory mechanisms near the stereociliary
tip would be saturated by the Ca2+ influx through
two channels. Because doubling the Ca2+ influx under
in vivo conditions increased the estimated free Ca2+ concentration by less than a factor of two, our
results indicate that the Ca2+ regulatory mechanisms
are poised to control the free Ca2+ concentration
in vivo. Consistent with this suggestion, modeling indicated
that, in the presence of only one transduction channel and under
in vivo conditions, approximately one-third of the total fixed buffer was bound to Ca2+ in compartment 2 at
the peak of the response. Furthermore, Ca2+ pumps
were again estimated to extrude three-quarters of the
Ca2+ that entered through the transduction channel
during stimulation.
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DISCUSSION |
This study represents the first attempt to our knowledge at
providing a model of Ca2+ homeostasis in the
stereocilium, the site of sensory transduction in the hair cell.
Because of its structure, a stereocilium provides a relatively simple
system in which to study Ca2+ regulation, which is
far more complicated in most other intracellular contexts. In the
present experimental circumstances, each stereocilium usually has but
one active transduction channel. Moreover, the Ca2+
that enters during mechanical stimulation moves within a femtoliter volume that is devoid of membrane-bounded organelles. By comparing the
output of the Ca2+ regulation model with
high-resolution experimental data, we have found that the control of
free Ca2+ concentration in a stereocilium
nonetheless involves multiple regulatory mechanisms that together
tightly restrict stimulus-induced changes in free
Ca2+ concentration both spatially and temporally.
Because Ca2+ provides a signal that controls
adaptation of the mechanoelectrical transduction process, this
regulation is critical for the operation of the hair cell. In addition,
rapid removal of free Ca2+ may be required to
reprime the capacity of the hair bundle for mechanical amplification
powered by the transmembrane Ca2+ gradient (for
review, see Hudspeth, 1997).
Ca2+ extrusion from stereocilia
Plasma membrane Ca2+-ATPase molecules, which
are found at high density in the stereociliary membrane (Crouch and
Schulte, 1995; Apicella et al., 1997; Yamoah et al., 1998), provide the
only known Ca2+-extrusion mechanism in the hair
bundle. Our results indicate that these pumps play a critical role in
setting both the resting and the peak free Ca2+
concentrations in the stereocilium. In fact, our model suggests that
pumps in vivo reduce the resting free
Ca2+ concentration in a stereocilium below that in
the soma (Fig. 10C). The extrusion of
Ca2+ by this means should result in a constant
translocation of the ion from the soma into the endolymphatic space
(Yamoah et al., 1998).
Fixed Ca2+ buffers in stereocilia
This study indicates that fixed Ca2+ buffers
play an important role in spatially restricting the spread of free
Ca2+ during mechanoelectrical transduction. In doing
so, fixed buffers increase the period during which the total
Ca2+ concentration is elevated in the stereocilium
after transduction-channel opening. By increasing the chance that a
Ca2+ ion entering through a transduction channel
would be extruded across the apical rather than the basolateral surface
of the hair cell, this effect could augment an extracellular
Ca2+ gradient near the hair bundle resulting from
Ca2+-pump activity (Yamoah et al., 1998).
Some of the fixed buffer we observed was likely to have been
immobilized fluo-3. Because substantial fixed buffer was required to
fit the first line-scan image collected from each stereocilium, however, we believe that endogenous molecules also contributed. The
stereociliary cytoskeleton includes such potential fixed
Ca2+ buffers as actin (DeRosier et al., 1980) and
fimbrin (Flock et al., 1982; de Arruda et al., 1990); the divalent
cation-binding site of the former may, however, be predominantly
occupied in vivo by Mg2+ (for review, see
Estes et al., 1992). Calmodulin, half of which is immobilized in the
hair bundle (Walker et al., 1993), also may contribute to the
fixed-buffering capacity of the stereocilium.
Mobile Ca2+ buffers in stereocilia
In cells loaded with fluo-3 AM, the spread of fluorescence within
stereocilia was slowed compared with that in cells dialyzed through
recording pipettes with an equivalent concentration of fluo-3. This
difference indicates that mobile Ca2+ buffers are
normally present in stereocilia but diffuse from hair cells in the
whole-cell recording configuration. Furthermore, because these buffers
significantly competed with 0.1 mM fluo-3 for the binding
of free Ca2+, the endogenous mobile-buffering
capacity of stereocilia may be substantial. Preliminary evidence
suggests oncomodulin, or -parvalbumin, as a candidate mobile
Ca2+ buffer in some hair cells (Henzl et al., 1997;
S. Heller and A. J. Hudspeth, unpublished observations). This
cytoplasmic protein contains two Ca2+-binding sites
with dissociation constants of ~0.01 and 1 µM (for review, see Pauls et al., 1996).
In hair cells from the frog's sacculus and the turtle's cochlea, the
capacity of the somatic mobile Ca2+ buffer is
similar to that of 1 mM BAPTA (Roberts, 1993; Tucker and
Fettiplace, 1996). The abolition of adaptation in hair cells filled
with 1 mM BAPTA and bathed in an endolymph-like solution led to the suggestion that, to promote adaptation in vivo,
stereocilia maintain a low Ca2+-buffering capacity
(Ricci and Fettiplace, 1997). By contrast, the time lag between a
change in extracellular Ca2+ concentration and a
corresponding alteration in adaptation kinetics suggests that
Ca2+ buffers are present in the chicken's
stereocilia (Kimitsuki and Ohmori, 1992). Although our results do not
exclude the possibility that the buffering capacity of the soma and
that of the stereocilia are distinct, they do indicate that hair
bundles from the bullfrog's sacculus contain significant amounts of
both fixed and mobile buffers. This conclusion is buttressed by the
immunohistochemical detection of mobile Ca2+ buffers
in the stereocilia of hair cells from the bullfrog's sacculus and
utriculus (Baird et al., 1997).
Free Ca2+ concentration at the
adaptation motor
Like most other experiments on isolated hair cells, the present
investigation was conducted in a medium containing an elevated Ca2+ concentration. Because the influx of
Ca2+ through an open transduction channel is reduced
in the low-Ca2+ environment of endolymph, the
Ca2+ concentrations achieved in stereociliary tips
must be lower in vivo than are those estimated here. Despite
the substantial Ca2+-buffering capacity of bullfrog
saccular hair bundles, adaptation has nonetheless been observed both
in vivo (Eatock et al., 1987) and in vitro in an
ionic environment similar to endolymph (Corey and Hudspeth, 1983a).
This result implies that the Ca2+ sensor of the
adaptation motor can respond to small changes in free
Ca2+ concentration.
The present results provide an estimate under experimental conditions
of the free Ca2+ concentration near stereociliary
tips, where transduction channels and adaptation motors reside. To
appreciate the effect of Ca2+ on the adaptation
motor in vivo, however, one must consider two additional
factors that lie beyond the temporal and spatial resolution achieved in
this study. The first is the stochastic nature of channel opening. We
have modeled the flow of Ca2+ through a transduction
channel as a continuous process whose magnitude varies with the channel
open probability. In reality, however, each transduction channel
continually clatters between its open and closed states. With a resting
open probability of 0.2, for example, the average open time is ~500
µsec and the closed time is 2000 µsec (Corey and Hudspeth, 1983b;
Holton and Hudspeth, 1986; Crawford et al., 1991). It follows that the
adaptation motor is subjected not to a smoothly changing concentration
of Ca2+ but rather to a staccato rhythm of
Ca2+ pulses that reflect channel flickering.
The other consideration is that, as evidenced by the latency of
adaptation (Assad et al., 1989) and the effect of exogenous Ca2+ buffers (Crawford et al., 1989), the
Ca2+ sensor of the adaptation motor is located only
tens of nanometers from the transduction channel (for review, see Lenzi
and Roberts, 1994). Within that distance of a channel, our assumption
that the free Ca2+ concentration is identical
throughout a stereociliary compartment fails on three grounds. First,
very near a point-like source, diffusion produces a much steeper
concentration gradient than that modeled here. Next, the influx of
Ca2+ results in a concentration close to the channel
that exceeds the local buffering capacity. Finally, the finite rate of
binding implies that the free Ca2+ near a channel is
not at an equilibrium with the buffers. If we assume that the mobile-
and fixed-buffering capacities are 1 and 0.6 mM,
respectively, and that the ON rates of these buffers are
diffusion-limited, then the mean time to capture for an entering Ca2+ ion (Roberts, 1993) is ~0.5 µsec, and the
mean distance to capture is 50 nm. If the Ca2+
sensor of the adaptation motor is situated within that distance of the
transduction channel, as now seems likely (for review, see Hudspeth and
Gillespie, 1994; Gillespie and Corey, 1997), Ca2+
buffers can play only a limited role in attenuating the free Ca2+ concentration there. The contribution to the
free Ca2+ concentration at the adaptation motor from
transduction-channel opening can therefore be estimated from the
time-dependent solution of Fick's second law for diffusion from a
point source into a hemi-infinite space [Berg (1993), his
Equation 2.12]:
![[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]=<FR><NU><UP>−</UP>f<SUB><UP>Ca</UP></SUB>&ggr;(V<SUB>M</SUB>−E<SUB>R</SUB>)</NU><DE>2&pgr;zℱD<SUB><UP>Ca</UP></SUB>r</DE></FR><UP>erfc</UP><FENCE><FR><NU>r</NU><DE>(4D<SUB><UP>Ca</UP></SUB>t)<SUP>1/2</SUP></DE></FR></FENCE>.](/content/vol18/issue16/fulltext/6300/img001.gif)
|
(1)
|
Here fCa is the fraction of the total
transduction current carried by Ca2+,  is the
single-channel conductance, VM is the
holding potential of the cell, ER is the
reversal potential for the transduction current, z is the
valence of Ca2+, F is the Faraday
constant, DCa is the diffusion coefficient of
Ca2+, and r is the distance from the
channel to the motor; erfc denotes the complement of the error
function.
The consequence of these factors is that the Ca2+
concentration experienced by the adaptation motor has two components.
When a transduction channel is open for tens of microseconds, the free Ca2+ concentration at the motor is dominated by the
local Ca2+ influx. For a cell bathed in standard
saline solution and with the parameter values of Table 1, the
Ca2+ concentration calculated with Equation 1
requires <30 µsec after channel opening to attain 80% of the
calculated steady-state level of 33 µM. In the presence
of endolymph, the corresponding estimated concentration is 4 µM. The adaptation motor is also exposed to Ca2+ from past channel activity, however, as
reflected in the smaller but longer-lasting elevations in concentration
throughout the upper stereociliary compartments (Figs. 9, 10). To
increase the responsiveness of hair cells tuned to high frequencies,
these smaller rises in Ca2+ concentration could be
abbreviated by increasing the number or turnover rate of the
Ca2+ pumps or the concentration of mobile
Ca2+ buffer in the stereocilium.
The free Ca2+ concentrations estimated above lie in
the range in which the binding of calmodulin is sensitive (for review,
see Cox et al., 1988) and in which the myosin-ATPase activity of the hair bundle is modulated (Burlacu et al., 1997). The
Ca2+ concentration at the adaptation motor is
presumably time-averaged by the binding of the ion to and the unbinding
of the ion from the calmodulin light chains associated with each myosin
molecule; the mechanical response of each myosin molecule in turn
reflects the binding status of these calmodulin molecules. Finally, the adaptive response of a hair cell is smoothed by the participation of
dozens of myosin molecules at each adaptation motor and by the presence
of dozens of motors in a hair bundle.
| |
FOOTNOTES |
Received Jan. 30, 1998; revised May 27, 1998; accepted May 28, 1998.
This investigation was supported by National Institutes of Health Grant
DC00241 and by a Howard Hughes Medical Institute predoctoral fellowship
to E.A.L. A.J.H. is an Investigator of Howard Hughes Medical
Institute. We thank Mr. Y. Choe for assistance with Mathematica programming, Dr. J. Phelps and Mr. C. McKinney for LabVIEW programming, Drs. J. Albanesi, K. Luby-Phelps, and V. Markin for discussions, and
Dr. C. Chabbert for a fluo-3 AM-loading protocol. Drs. J. Howard, F. Jaramillo, and S. Simon and the members of our research group provided
valuable comments on this manuscript.
Correspondence should be addressed to Dr. A. J. Hudspeth, Howard
Hughes Medical Institute and Laboratory of Sensory Neuroscience, Box
314, The Rockefeller University, 1230 York Avenue, New York, NY
10021-6399.
Dr. Lumpkin's present address: Department of Physiology and
Biophysics, Box 357290, University of Washington School of Medicine, Seattle, WA 98195-7290.
| |
APPENDIX |
This section details the model of stereociliary
Ca2+ regulation.
Components of the model
Geometrical considerations
A stereocilium was modeled as a right circular cylinder, oriented
with the stereociliary tip at x = 0 and the soma at
x = L, the measured length of the
stereocilium (Fig. 2). The stereociliary shaft was divided into
n 2 discrete compartments of equal length; two
additional compartments represented the taper at the stereociliary insertion. In most simulations, a value of n = 9 was
used; the length of each compartment was therefore ~0.5 µm, or
slightly more than the stereociliary diameter of 0.45 µm (Jacobs and
Hudspeth, 1990).
The effect of the stereociliary taper was accommodated by adding two
compartments, each 0.5 µm long, consisting of a pair of cylinders of
successively smaller diameters than those used for the remainder of the
stereocilium. These diameters were adjusted so that the volume of each
compartment equaled that of the frustum corresponding to that segment
of the stereociliary taper. We examined transmission electron
micrographs of bullfrog saccular hair bundles, and on the assumption
that the stereociliary insertion shrinks in diameter during electron
microscopic preparation to the same extent that the stereociliary shaft
shrinks, we estimated the diameter of the insertion in vivo
to be 0.18 ± 0.03 µm (mean ± SE; n = 11).
The diameters of the two taper compartments were accordingly 0.38 and
0.25 µm. In the calculation of fluxes between compartments, the
surface areas between adjoining compartments of differing diameter were
approximated by the geometrical means of the two relevant areas.
Although large, protracted stimuli can demonstrably increase the
Ca2+ concentration in the soma of a hair cell
(Ohmori, 1988; Lumpkin and Hudspeth, 1995), the brief stimuli used in
the present experiments had a negligible effect there. We accordingly
modeled the soma as a single, homogeneous compartment adjacent to the
nth compartment and assumed that the somatic
Ca2+ concentration CaSOMA remained
constant at a specified level. We also fixed the total concentrations
of indicator and mobile buffer in the soma at their concentrations in
the recording pipette and assumed that both species were at equilibrium
in their binding to the specified somatic Ca2+
concentration.
Ca2+ influx
The mechanoelectrical transduction channels generally carried a
significant transduction current, iREST,
before the onset of a stimulus. In response to a positive stimulus
pulse, the whole-cell current response peaked rapidly and then adapted
almost exponentially to a plateau level; at the end of such a stimulus,
the receptor current fell to zero (Eatock et al., 1987). To represent
the response of a cell during a deflection beginning at
t = 0, we fit the channel open probability
pO with the relation:
|
(A1)
|
in which iADAPT is the asymptotic
transduction current after adaptation, iMAX is
the peak transduction current, and POS is the time
constant of adaptation. The recovery of the resting open probability
after a stimulus of duration tSTIM was fit with a second exponential relation characterized by the time constant NEG:
![p<SUB>o</SUB>=<FR><NU>i<SUB><UP>REST</UP></SUB>[1−e<SUP><UP>−</UP>(t<UP>−</UP>t<SUB><UP>STIM</UP></SUB>)/&tgr;<SUB><UP>NEG</UP></SUB></SUP>]</NU><DE>i<SUB><UP>MAX</UP></SUB></DE></FR>.](/content/vol18/issue16/fulltext/6300/img003.gif)
|
(A2)
|
For the one cell whose transduction current after
positive stimulation was not well fit by a single-exponential function (Fig. 4C), we set pO = 1 for 0 msec  t 5 msec and then used Equation A1 with
a time lag of 5 msec and Equation A2 to calculate pO for the remainder of the response.
In the intact sensory epithelium of the bullfrog's sacculus, a hair
cell with ~60 stereocilia possesses 40-90 active transduction channels (Holton and Hudspeth, 1986; Howard and Hudspeth, 1988; Denk et
al., 1995); as a result of damage during isolation, solitary hair cells
such as those used in the present work have fewer. Because we wished to
consider Ca2+ homeostasis in individual stereocilia,
we estimated the influx of the ion through individual transduction
channels. Because these channels are located within 1 µm of the
stereociliary tip (Jaramillo and Hudspeth, 1991; Denk et al., 1995;
Lumpkin and Hudspeth, 1995), we included in the model the capacity to
situate them in the first or second compartment of a stereocilium, or
in both. We assigned each channel a conductance, , of 100 pS
(Crawford et al., 1991; Denk et al., 1995; Géléoc et al.,
1997). The time course of the current through the channel was specified
by the open probability defined above. For each compartment containing
a transduction channel, the rate of change in Ca2+
concentration, [Ca2+], attributable to influx
through each transduction channel was then:
![<FR><NU><UP>d</UP>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU><UP>−</UP>p<SUB>o</SUB>f<SUB><UP>Ca</UP></SUB>&ggr;(V<SUB>M</SUB>−E<SUB>R</SUB>)</NU><DE>zℱQ<SUB>n</SUB></DE></FR>,](/content/vol18/issue16/fulltext/6300/img004.gif)
|
(A3)
|
in which Qn is the volume of
the nth compartment.
Diffusion
By Fick's second law, the rate at which the
Ca2+ concentration [Ca2+]
changes with time as a result of diffusion is:
![<FR><NU>∂[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]</NU><DE>∂t</DE></FR>=D<SUB><UP>Ca</UP></SUB> <FR><NU>∂<SUP>2</SUP>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]</NU><DE>∂x<SUP>2</SUP></DE></FR>,](/content/vol18/issue16/fulltext/6300/img005.gif)
|
(A4)
|
in which DCa is the diffusion coefficient
of the ion. This partial differential equation was approximated by
breaking the spatial coordinate into n discrete compartments
of length  x; the rate of change of the
Ca2+ concentration in the nth compartment
was then evaluated as:
![<FR><NU><UP>d</UP>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU>D<SUB><UP>Ca</UP></SUB></NU><DE>Q<SUB>n</SUB>&Dgr;x</DE></FR>{A<SUB>n<UP>−</UP>1/n</SUB>([<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>−</UP>1</SUB>−[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>)](/content/vol18/issue16/fulltext/6300/img006.gif)
|
(A5)
|
in which An 1/n
and An/n + 1 are the
cross-sectional areas between the successive compartments indicated.
For computations involving the nth compartment, the soma
represented the (n + 1)th compartment; the cross-sectional
area of the nth compartment was therefore used to calculate
flux between the nth compartment and the soma in all
differential equations. The concentration of free Ca2+ decreased along the positive x-axis
from the site of Ca2+ entry to the soma.
Extrusion
Although some kinetic parameter values have not been estimated for
the plasma-membrane Ca2+ pumps of the hair cell,
they have been defined for erythrocyte pumps (for review, see Carafoli
and Stauffer, 1994; Kubitscheck et al., 1995). Because
Ca2+ pumps from these two cell types are recognized
by a common antibody and because both bind calmodulin (Yamoah et al.,
1998), we assumed that they share similar kinetics.
To describe extrusion of Ca2+ by
Ca2+ pumps, we used an equilibrium formulation; the
pumping rate of each Ca2+ pump molecule,
 PUMP, was regarded as following Michaelis-Menten kinetics. For each compartment, the rate of change in
Ca2+ concentration as a result of pump activity was
therefore:
![<FR><NU><UP>d</UP>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU><UP>−</UP>&psgr;<SUB>n</SUB>S<SUB>n</SUB>&ngr;<SUB><UP>MAX</UP></SUB></NU><DE>N<SUB>A</SUB>Q<SUB>n</SUB><FENCE>1+<FENCE><FR><NU>K<SUB>M</SUB></NU><DE>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></DE></FR></FENCE></FENCE></DE></FR>,](/content/vol18/issue16/fulltext/6300/img008.gif)
|
(A6)
|
in which  n is the density of pump
molecules in the plasmalemmal area Sn of
the compartment, NA is Avogadro's number, MAX is the maximal turnover rate of an active
Ca2+ pump molecule, and KM is
its Michaelis constant.
We used this simplified Michaelis-Menten formulation for two reasons.
First, values for the detailed kinetic parameters have yet to be
reported for any plasma-membrane Ca2+ pump, let
alone for that found in hair cells. Although it is therefore not
realistic to provide more detailed, time-dependent equations for
pumping, estimates are in hand for the values of the lumped parameters
of the Michaelis-Menten formulation, the turnover number and Michaelis
constant (Carafoli and Stauffer, 1994; Kubitscheck et al., 1995; Yamoah
et al., 1998).
The second justification for the Michaelis-Menten formulation is that
it is likely to prove a sound approximation. The key assumption in our
formulation is that the rate at which Ca2+ is
extruded at any time accurately reflects the then-prevailing free
Ca2+ concentration in a stereocilium. If the binding
of Ca2+ at the pump is diffusion-limited,
kON  109
M1·sec1, the
Michaelis constant of 500 nM therefore implies that
kOFF 500 sec1. It
follows that the activity of the pump should reflect the free
Ca2+ concentration with a temporal delay of only 2 msec or so, a small lag compared with the time course over which the
Ca2+ concentration changes.
The average density of Ca2+-pump molecules in the
stereociliary membrane was fixed at 2000 µm2.
Immunocytochemical labeling indicates, however, that
Ca2+-pump molecules are concentrated at
stereociliary tips (Apicella et al., 1997; Yamoah et al., 1998). This
factor was accommodated by setting the density in the first compartment
at 150% that in compartments along the upper stereociliary shaft.
Because the first compartment is also endowed with the extra membrane
at the end of the stereocilium, that compartment contained ~180% as
many pump molecules as the subsequent ones.
Assuming that a Ca2+-pump exchanges one
H+ for one Ca2+ during each
pumping cycle, our model estimated the current resulting from Ca2+-pump activity in a single stereocilium. To
calculate the Ca2+-pump current for the entire hair
bundle, we had to estimate the number of active stereocilia in each
bundle. To do so, we divided iPEAK by 250 pA,
which was the expected transduction current for the half-maximal
stimuli used in this study if all of the transduction channels had been
functional. Note that somatic Ca2+ pumps did not
contribute to this estimated current. The hair-bundle pump current and
the fit to the transduction current were summed; the resulting
predicted whole-cell response is displayed for each cell.
Buffering
Within each compartment, Ca2+ buffering was
represented by the binding of Ca2+ to and the
unbinding of Ca2+ from three potential targets: a
mobile Ca2+ indicator, I (fluo-3); a second,
nonfluorescent mobile Ca2+ buffer, B (EGTA); and a
fixed Ca2+ buffer, F. In each case, the
stoichiometry of Ca2+ binding was one-to-one. The
indicator and mobile buffer were assigned diffusion coefficients
DI and DB,
respectively, which were assumed to be identical for their free and
Ca2+-bound forms. In the soma of Rana
pipiens hair cells, the diffusion coefficient of mobile fluo-3 is
1.8·1010
m2·sec1. Because approximately
one-third of the indicator is immobilized (Hall et al., 1997), however,
we set DI to 1.2·1010
m2·sec1. Models in which
DI was lowered and those in which a fraction of
the total indicator was immobilized gave similar results (data not
shown).
The diffusion coefficient of EGTA was set equal to
DI. In each compartment, the diffusion of both
the Ca2+-bound and the free form of each species was
independently described by relations similar to that in Equation A5.
Equilibrium conditions were not assumed. In the instance of the
Ca2+ indicator, for example:
|
(A7)
|
from which it follows that, for each compartment:
![<FR><NU><UP>d</UP>[<UP>I</UP> · <UP>Ca</UP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=k<SUB><UP>ON,I</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>I</UP>]<SUB>n</SUB>−k<SUB><UP>OFF,I</UP></SUB>[<UP>I</UP> · <UP>Ca</UP>]<SUB>n</SUB>.](/content/vol18/issue16/fulltext/6300/img010.gif)
|
(A8)
|
Similar relations described Ca2+ binding to the
mobile and fixed Ca2+ buffers in each
compartment.
Representative equations
The section above is meant to justify the various terms in the
model equations. For completeness and ease of computation, we provide
below representative relations from each of the seven families. Each
family in turn comprises n equations corresponding to the
number of compartments used in the simulation. In most simulations,
nine compartments were used, so n represented integers from
one to nine. Except where noted, the symbols are defined in the
preceding section.
The concentration of Ca2+ in each compartment is
controlled by the effects of diffusion, pumping, and binding to
indicator, mobile buffer, and fixed buffer:
![<UP>−</UP>k<SUB><UP>ON,I</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>I</UP>]<SUB>n</SUB>+k<SUB><UP>OFF,I</UP></SUB>[<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>](/content/vol18/issue16/fulltext/6300/img014.gif)
|
(A9)
|
Here NT,n is the number of
active transduction channels in the compartment. The first term, which
describes Ca2+ entry through transduction channels,
applies only in compartments that encompass such channels.
The concentrations of free and bound indicator are set by diffusion and
by binding relations:
![<UP>−</UP>k<SUB><UP>ON,I</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>I</UP>]<SUB>n</SUB>+k<SUB><UP>OFF,I</UP></SUB>[<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>;](/content/vol18/issue16/fulltext/6300/img018.gif)
|
(A10)
|
![−A<SUB>n/n<UP>+</UP>1</SUB>([<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>−[<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>+</UP>1</SUB>)}](/content/vol18/issue16/fulltext/6300/img020.gif)
|
(A11)
|
An analogous set of equations governs the concentrations of free and
bound mobile buffer:
![−k<SUB><UP>ON,B</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>B</UP>]<SUB>n</SUB>+k<SUB><UP>OFF,B</UP></SUB>[<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>;](/content/vol18/issue16/fulltext/6300/img023.gif)
|
(A12)
|
![−A<SUB>n/n<UP>+</UP>1</SUB>([<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>−[<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>+</UP>1</SUB>)}](/content/vol18/issue16/fulltext/6300/img025.gif)
|
(A13)
|
Finally, the concentrations of free and bound fixed buffer depend
exclusively on the binding and unbinding of
Ca2+:
![<FR><NU><UP>d</UP>[<UP>F</UP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=k<SUB><UP>ON,F</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>F</UP>]<SUB>n</SUB>+k<SUB><UP>OFF,F</UP></SUB>[<UP>F</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>;](/content/vol18/issue16/fulltext/6300/img027.gif)
|
(A14)
|
![<FR><NU><UP>d</UP>[<UP>F</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=k<SUB><UP>ON,F</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>F</UP>]<SUB>n</SUB>−k<SUB><UP>OFF,F</UP></SUB>[<UP>F</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>.](/content/vol18/issue16/fulltext/6300/img028.gif)
|
(A15)
|
Simplifying assumptions in the model
To describe Ca2+ homeostasis in the
stereocilium, we made several simplifying assumptions that could have
affected the quantitative results derived from modeling. We provide
below the rationales for these assumptions and estimates of their
potential impacts on our numerical results.
Diffusional exchange with recording pipettes
Because diffusional exchange of pipette and cytoplasmic
constituents is somewhat limited (Pusch and Neher, 1988), the
concentrations of fluo-3 and EGTA specified in the model may have been
overestimates. Furthermore, limited diffusional exchange implies that
endogenous mobile buffers, which are not explicitly included in the
model, could have influenced Ca2+ homeostasis in
these experiments as described for the presynaptic active zone of the
hair cell (Hall et al., 1997). For example, the apparent accumulation
of fixed buffer that we observed could have been attributable in part
to the progressive loss of endogenous mobile buffers that competed in
Ca2+ binding with stereociliary fixed buffers.
Representation of transduction-channel permeation and gating
To simplify the representation of Ca2+ influx
in the model, we made two assumptions that might have affected the
quantitative results. First, to estimate the fraction of transduction
current carried by Ca2+,
fCa, we assumed that ions traversing the
pore of the channel do not influence the movement of one another.
Because ions do interact within the pore (Lumpkin et al., 1997) and
because the channel is Ca2+-selective (Corey and
Hudspeth, 1979; Ohmori, 1985; Jørgensen and Kroese, 1994, 1995), our
value for this parameter is likely to be an underestimate. Second, we
ignored the stochastic nature of ion-channel opening and specified
Ca2+ entry as a continuous process whose magnitude
varies with the channel open probability. Given that each stereocilium
contains only one or two channels, more accurate fits to the imaging
data might have been achieved by simulating the flickering of a
transduction channel based on its estimated open probability. Our
line-scan images of stereociliary tips in fact displayed rapid
fluctuations in fluorescence intensity (data not shown) that might have
reflected the flickering of transduction channels.
To the extent that these assumptions and those mentioned in the
previous paragraph introduced errors, they should have led to
underestimation of the Ca2+ influx and the
stereociliary buffering capacity.
Diffusion through the stereociliary cytoskeleton
We assumed that the entire cytoplasmic volume of the stereocilium
is accessible to the diffusion of Ca2+ and mobile
buffers. Because a stereocilium from the bullfrog's sacculus contains
~600 actin microfilaments (Jacobs and Hudspeth, 1990), however, the
accessible cytoplasmic volume is lower. The accessible stereociliary
volume is limited further by the amount of water that is ordered by
intracellular proteins, a value that is highly debated in the
literature (for review, see Franks, 1993; Luby-Phelps, 1998). To
estimate the fraction of stereociliary volume occupied by actin and its
associated water, we used three calculations. In these calculations, we
considered the cylindrical shaft of a typical saccular stereocilium
with a length of 5 µm and a diameter of 0.45 µm (Jacobs and
Hudspeth, 1990); the internal volume of the stereocilium is thus 800 al.
The volume of actin in a stereocilium may first be estimated by
assuming that each actin microfilament is a solid cylinder with a
diameter of 9.5 nm (Milligan et al., 1990). In this case, the volume of
actin in the stereocilium is estimated to be 210 al or 26% of the
stereociliary volume. Because a microfilament is a double-stranded
helix, not a solid cylinder, this value is an overestimate of the
volume of actin.
The volume of actin may also be estimated from the mass of
stereociliary actin and its partial specific volume,
 ACTIN, which is the volume of water
displaced by 1 gm of solute. One reservation about this estimate is
that the partial specific volume of actin in cytoplasm may not equal
that measured in water. For G-actin·ADP, ACTIN
is 0.732 ml·gm1 (Smith, 1970). Because the partial
specific volume of a protein is determined primarily by its amino-acid
content (Creighton, 1993), ACTIN of an F-actin
monomer should be very similar.
The mass of actin in a stereocilium may be estimated from the length of
the cytoskeletal microfilaments, which is 3 mm in the stereocilium
under consideration. A single twist of a microfilament helix, which
contains 26 actin monomers, is 72 nm in length; the relative molecular
mass of each monomer is 42 kDa (Bremer and Aebi, 1992). The mass of
actin in a stereocilium is thus 76 fg. The volume of actin in the
stereocilium is therefore estimated at 56 al, which represents 7% of
the total stereociliary volume.
To estimate the maximum volume of water that may be ordered by
stereociliary actin, we used the frictional coefficient
f/f0, which is an index of the
shape and hydration state of macromolecules. For G-actin·GDP,
f/f0 is 1.575 (Smith, 1970). On the
assumption that an actin monomer is a perfect sphere, the maximum
hydration  of actin may be estimated (Tanford, 1961):
|
(A16)
|
in which WATER is the specific volume of
water (1.0 ml/gm). The maximum hydration of actin is therefore 2.1 gm
of H2O per gram of actin, and the volume of this water of
hydration is 160 al. Hydrated actin is thus estimated to occupy <27%
of the total stereociliary volume.
For two reasons, this calculation yields an overestimate of the volume
of water associated with stereociliary actin. First, the crystal
structure of an actin monomer shows that it is not a perfect sphere as
we have assumed (Bremer and Aebi, 1992). Because its shape contributes
to the measured value of f/f0,
the actin monomer must be less hydrated than we have estimated with
this calculation. Second, because actin molecules in a microfilament associate with each other and with acting-binding proteins, the surface
area of a monomer that is exposed to hydration, and thus the degree of
hydration, must be less in F-actin than in G-actin.
To determine the impact of a reduced stereociliary volume on the output
of our Ca2+ regulation model, we fit the
experimental data set shown in Figure 3 with a model in which the
stereociliary volume was reduced by 27%. A fit similar to that shown
in Figure 3 was obtained by changing the fixed buffer concentration to
0.9 µM and the sensitivity to 458; all other parameter
values remained as listed in Table 1. When the stereociliary volume was
adjusted, the free Ca2+ concentration in compartment
2 was estimated to peak at 20 µM. Neither the time course
of the change in free Ca2+ concentration nor the
estimated free Ca2+ concentration in the lower half
of the stereocilium was noticeably changed by the altered stereociliary
volume. The effect of ignoring the volume of hydrated actin in our
calculations was therefore to underestimate slightly the concentration
of fixed buffer in the stereocilium and the free
Ca2+ concentration in the upper half of the
stereocilium. Because we used the maximum possible volume of hydrated
actin in these calculations, the actual impact of the stereociliary
actin volume on the results of our model is less than that estimated
here.
Electrodiffusion
The flow of transduction current down a stereocilium produces a
voltage drop that could drive Ca2+ toward the soma.
The potential importance of this electrodiffusive effect may be
assessed by considering the steady-state profile of
Ca2+ concentration in the presence of an ionic flux
J with an average velocity . When Fick's laws are
modified to accommodate this effect [Berg (1993), his Equations
4.4-4.5] and when Ca2+ buffers are in equilibrium
with the local Ca2+ concentration, it may be shown
that the Ca2+ concentration at a distance
x from an open channel at the stereociliary tip is:
![[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]=[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB><UP>SOMA</UP></SUB>e<SUP><UP>−</UP>(&ngr;/D<SUB><UP>Ca</UP></SUB>)(L<UP>−</UP>x)</SUP>+<FENCE><FR><NU>J</NU><DE>&ngr;</DE></FR></FENCE>[1−e<SUP><UP>−</UP>(&ngr;/D<SUB><UP>Ca</UP></SUB>)(L<UP>−</UP>x)</SUP>].](/content/vol18/issue16/fulltext/6300/img031.gif)
|
(A17)
|
From the formulation of Ohm's Law in terms of mobility [Hille (1992),
his Equation 10-6]:
|
(A18)
|
in which z is the valence of the ion, u is
the electrical mobility of an unbuffered ion, and V is
the potential difference along a stereocilium of length L.
The average ionic velocity is related to the diffusion constant by the
Nernst-Einstein relation [Hille (1992), his Equation
10-7]:
|
(A19)
|
in which k is the Boltzmann constant, T is
the temperature, and e is the charge of the electron.
Equating the mobility in these expressions, substituting into the
expression for Ca2+ concentration, and solving, we
find that:
![[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]=[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB><UP>SOMA</UP></SUB>e<SUP><UP>−</UP>[(L<UP>−</UP>x)/&lgr;]</SUP>+<FENCE><FR><NU>J</NU><DE>D</DE></FR></FENCE>&lgr;[1−e<SUP><UP>−</UP>[(L<UP>−</UP>x)/&lgr;]</SUP>],](/content/vol18/issue16/fulltext/6300/img034.gif)
|
(A20)
|
in which the space constant of the
Ca2+-concentration profile  is given by:
|
(A21)
|
This solution may be compared with that obtained for unidimensional
diffusion from a source to a sink in the absence of an electric
field [Berg (1993), his Fig. 2.2]:
![[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]=[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB><UP>SOMA</UP></SUB>+<FENCE><FR><NU>J</NU><DE>D</DE></FR></FENCE>(L−x).](/content/vol18/issue16/fulltext/6300/img036.gif)
|
(A22)
|
As would be expected, the qualitative effect of electrophoresis is
to oppose the movement of somatic Ca2+ into the
stereocilium and to decrease the contribution of
Ca2+ influx through transduction channels to the
stereociliary Ca2+ concentration.
The quantitative importance of electrophoresis reflects the ratio of
the thermal to the electrical energy imparted to a migrating ion. This,
in turn, depends critically on the electrical field within the
stereocilium. Consider a stereocilium 0.45 µm in diameter, with 73%
of its volume occupied by a solution similar to 120 mM KCl
and with a conductivity near 1.5 S·m1 (Kaye and Laby,
1986; Lide, 1996); this process has a resistance per unit length of 5.7 T·m1. The opening of a single transduction channel
yields a longitudinal current of ~7 pA, which in turn produces a
field of 40 V/m. Substitution into Equation A21 indicates that the
space constant is 320 µm, or over 50-fold the length of a
stereocilium; the exponential terms in Equation A20 accordingly deviate
from unity by <2%, and the second right-hand term in Equation A20
differs from that in Equation A22 by under 1%. At least in the steady
state, then, the electrical field has little effect on the distribution
of Ca2+ along a stereocilium; even if several
transduction channels were simultaneously open, the effect of
electrodiffusion on Ca2+ movement would be
negligible. For transient responses such as those in the experimental
work reported here, in which the electrophoretic effect declines as
channels close, the effect of electrodiffusion should be still
smaller.
Optical sampling
The line-scan images of fluorescence signals inevitably included
blurring characterized by the point-spread function of the objective
lens. To determine whether blurring along the length of the
stereocilium was of importance in our consideration of longitudinal
movements of Ca2+ and its buffers, we convolved the
predictions of the model of longitudinal fluorescence profiles with a
unidimensional representation of the point-spread function, a Gaussian
whose full width at half-maximum was 0.4 µm. Even for the calculated
responses with the steepest longitudinal gradients in fluorescence
(e.g., Fig. 10A), the convolution had a negligible
effect along most of the stereocilium. The only noticeable distortion
occurred at the distal stereociliary tip, where the abrupt end in the
model was converted by convolution to a sigmoidal fluorescence profile.
For this reason, compartment 1, which represented the stereociliary
tip, was not analyzed in comparisons of experimental and model results.
Because the impact of optical sampling was so slight, we did not
otherwise correct the predictions of the model for the effects of
optical sampling.
Implementation of the model
Calculation of predicted fluorescence signals
To fit experimental fluorescence data with the
Ca2+-regulation model, we calculated the
fluorescence signal resulting from Ca2+-bound and
-unbound fluo-3 in the stereocilium. In addition to the concentration
of each species, three factors were considered in calculating the
predicted fluorescence traces.
Control experiments confirmed that the confocal microscope was linear
in its response to fluorescence (data not shown). For that reason, the
output of the confocal system, in grayscale units, was assumed to be
related to the concentration of Ca2+-bound indicator
by a multiplicative constant, the sensitivity.
The fluorescence ratio of free to Ca2+-bound fluo-3
was required to calculate fluorescence responses. To determine this
value in vitro, we used the same line-scan protocol as that
used for our experiments to measure the fluorescence of 0.5 mM fluo-3 in the presence of either 10 mM
bis(2-aminophenoxy)ethane-N,N,N',N'-tetra-acetic acid
(BAPTA) or 11 mM CaCl2. Under these conditions,
unliganded fluo-3 had a fluorescence yield 2.9% that of the
Ca2+-bound form.
Although the background fluorescence intensity of a stereocilium was
negligible, the calculated fluorescence response included the baseline
intensity of an image, caused by instrument noise, that can be measured
in the absence of sample illumination (Webb and Dorey, 1995). In most
images, this dark signal contributed 5 grayscale units. In a few cases,
however, the black level control of the microscope was set slightly
higher and the dark signal contributed 18 grayscale units.
Model calculations
The complete model for n stereociliary compartments,
usually nine, was represented by a family of 7n linear,
first-order, ordinary differential equations, examples of which are
shown in the Representative equations section. A copy of the model
program is available on request.
From the total concentrations of indicator, mobile buffer, and fixed
buffer in the soma and the estimated somatic free
Ca2+ concentration, we calculated the equilibrium
concentrations of the free and bound species of each buffer. The
results were used as starting values for the respective parameters in
all compartments of the model. The starting value for the
Ca2+ concentration in each compartment was the
estimated somatic free Ca2+ concentration.
The sets of seven simultaneous equations for all n
compartments were solved with Mathematica (version 2.2.2; Wolfram
Research Inc., Champaign, IL) by an iterative, numerical procedure. On a Macintosh computer (PM G3, PM 8600/300, or PM 9500/132; Apple Computer, Cupertino, CA), the computation time required to solve the
equations for a single, nine-compartment stereocilium was 1-5 min; the
optimization procedure described below took as long as 3 d to
reach a solution.
We performed several tests to confirm the internal consistency of the
model. In agreement with an explicit analytical solution, the model
yielded a linear concentration gradient along a stereocilium in the
instance of a steady Ca2+ source at the
stereociliary tip and in the absence of Ca2+ pumps.
The total amount of Ca2+ calculated to diffuse from
a stereocilium into the soma or to be extruded by pumps was found to be
equal within 6% to that entering through transduction channels.
Increasing the number of stereociliary compartments from 9 to as many
as 23 did not appreciably alter the results of the model. Finally, the
validity of our representation of the stereociliary taper was confirmed
by demonstrating in a simplified model that the free diffusion of
Ca2+ through the taper was similar in our
two-compartment rendition of the taper to that calculated with a
43-compartment representation.
To determine the goodness of fit of the model to experimental data, we
compared the predicted fluorescence traces point-by-point with data
imported into Mathematica; the squared errors for compartments 2, 4, 6, and 8 were then calculated. After a reasonable fit had been achieved
for each stereocilium, the model was refined for five stereocilia
simultaneously by use of an optimization routine that minimized the
summed squared error.
The graphical output of Mathematica provided preliminary figures, which
were prepared for publication with Canvas (version 3.5 or 5.0.2; Deneba
Software, Miami, FL).
Parameter values
Parameter values were obtained in one of four ways (see Table 1).
First, many values, such as the Ca2+-binding
constants for fluo-3, were taken from the literature. Second, the
values of some parameters were measured for each stereocilium to be
fit. These parameters included the length of the stereocilium, the
concentrations of fluo-3 and EGTA in the internal solution, and the
whole-cell response before, during, and after hair-bundle deflection.
Third, the values of some free parameters, including the concentration
and binding constants of the fixed buffer, were chosen to achieve the
best fit to the data derived from multiple stereocilia. Finally, three
free parameters were varied for each stereocilium to refine its fit:
the sensitivity of the confocal system, the number of transduction
channels in the first compartment, and the somatic
Ca2+ concentration, which was allowed to vary
between 0.015 and 0.70 µM. A total of eight free
parameters was included in the model.
Table 1 provides a list of parameter values for a typical experiment.
These specific values were used in calculating the responses for Figure
3. For all other fits, the parameter values that differed from those in
Table 1, excepting the dark signal, are provided in the figure
legends.
| |
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Top
Abstract
Introduction
![−A<SUB>n/n<UP>+</UP>1</SUB>([<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>−[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>+</UP>1</SUB>)},](/content/vol18/issue16/fulltext/6300/img007.gif)
![<FR><NU><UP>d</UP>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<UP>−</UP><FR><NU>N<SUB>T,n</SUB>p<SUB>o</SUB>f<SUB><UP>Ca</UP></SUB>&ggr;(V<SUB>M</SUB>−E<SUB>R</SUB>)</NU><DE>zℱQ<SUB>n</SUB></DE></FR>−<FR><NU>&psgr;<SUB>n</SUB>S<SUB>n</SUB>&ngr;<SUB><UP>MAX</UP></SUB></NU><DE>N<SUB>A</SUB>Q<SUB>n</SUB><FENCE>1+<FR><NU>K<SUB>M</SUB></NU><DE>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></DE></FR></FENCE></DE></FR>](/content/vol18/issue16/fulltext/6300/img011.gif)
![+<FR><NU>D<SUB><UP>Ca</UP></SUB></NU><DE>Q<SUB>n</SUB>&Dgr;x</DE></FR>{A<SUB>n<UP>−</UP>1/n</SUB>([<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>−</UP>1</SUB>−[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>)](/content/vol18/issue16/fulltext/6300/img012.gif)
![−A<SUB>n/n<UP>+</UP>1</SUB>([<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>−[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>+</UP>1</SUB>)}](/content/vol18/issue16/fulltext/6300/img013.gif)
![<UP>−</UP>k<SUB><UP>ON,B</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>B</UP>]<SUB>n</SUB>+k<SUB><UP>OFF,B</UP></SUB>[<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>](/content/vol18/issue16/fulltext/6300/img015.gif)
![<UP>−</UP>k<SUB><UP>ON,F</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>F</UP>]<SUB>n</SUB>+k<SUB><UP>OFF,F</UP></SUB>[<UP>F</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>.](/content/vol18/issue16/fulltext/6300/img016.gif)
![<FR><NU><UP>d</UP>[<UP>I</UP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU>D<SUB><UP>I</UP></SUB></NU><DE>Q<SUB>n</SUB>&Dgr;x</DE></FR>{A<SUB>n<UP>−</UP>1/n</SUB>([<UP>I</UP>]<SUB>n<UP>−</UP>1</SUB>−[<UP>I</UP>]<SUB>n</SUB>)−A<SUB>n/n<UP>+</UP>1</SUB>([<UP>I</UP>]<SUB>n</SUB>−[<UP>I</UP>]<SUB>n<UP>+</UP>1</SUB>)}](/content/vol18/issue16/fulltext/6300/img017.gif)
![<FR><NU><UP>d</UP>[<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU>D<SUB><UP>I</UP></SUB></NU><DE>Q<SUB>n</SUB>&Dgr;x</DE></FR>{A<SUB>n<UP>−</UP>1/n</SUB>([<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>−</UP>1</SUB>−[<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>)](/content/vol18/issue16/fulltext/6300/img019.gif)
![+k<SUB><UP>ON,I</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>I</UP>]<SUB>n</SUB>−k<SUB><UP>OFF,I</UP></SUB>[<UP>I</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>.](/content/vol18/issue16/fulltext/6300/img021.gif)
![<FR><NU><UP>d</UP>[<UP>B</UP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU>D<SUB><UP>B</UP></SUB></NU><DE>Q<SUB>n</SUB>&Dgr;x</DE></FR>{A<SUB>n<UP>−</UP>1/n</SUB>([<UP>B</UP>]<SUB>n<UP>−</UP>1</SUB>−[<UP>B</UP>]<SUB>n</SUB>)−A<SUB>n/n<UP>+</UP>1</SUB>([<UP>B</UP>]<SUB>n</SUB>−[<UP>B</UP>]<SUB>n<UP>+</UP>1</SUB>)}](/content/vol18/issue16/fulltext/6300/img022.gif)
![<FR><NU><UP>d</UP>[<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB></NU><DE><UP>d</UP>t</DE></FR>=<FR><NU>D<SUB><UP>B</UP></SUB></NU><DE>Q<SUB>n</SUB>&Dgr;x</DE></FR>{A<SUB>n<UP>−</UP>1/n</SUB>([<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n<UP>−</UP>1</SUB>−[<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>)](/content/vol18/issue16/fulltext/6300/img024.gif)
![+k<SUB><UP>ON,B</UP></SUB>[<UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>[<UP>B</UP>]<SUB>n</SUB>−k<SUB><UP>OFF,B</UP></SUB>[<UP>B</UP> · <UP>Ca</UP><SUP>2<UP>+</UP></SUP>]<SUB>n</SUB>.](/content/vol18/issue16/fulltext/6300/img026.gif)
