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The voltage dependence of the mechanoelectrical transducer modifies low frequency outer hair cell electromotility in vitro
Hearing Research 113 (1997) 133^139
The voltage dependence of the mechanoelectrical transducer modi¢es low frequency outer hair cell electromotility in vitro Andrei N. Lukashkin, Ian J. Russell * School of Biological Sciences, University of Sussex, Falmer, Brighton, BN1 9QG, UK
Received 21 February 1997; revised 25 June 1997; accepted 18 July 1997
Abstract
The fast outer hair cell (OHC) electromotility is voltage dependent and is driven by changes in the OHC transmembrane potential. Those changes include the receptor potential generated by the variable conductance of the mechanoelectrical transducer (Evans and Dallos, 1993). In the experiments described here, we show that the voltage dependence of the mechanoelectrical transducer influences the low frequency motile responses of OHCs to an external electrical field. OHCs were fully inserted into a glass suction pipette, the microchamber, so that only the cuticular plate and hair bundle were exposed to the bath solution. With this technique, a rectification of the mechanical response, equivalent to an excitatory displacement of the hair bundle, was observed when the command voltage inside the microchamber depolarized the apical membrane. The shape of the response persisted when the OHC voltage-gated conductances were blocked. Following treatment of the hair bundle with BAPTA or dihydrostreptomycin, which are known to impair transduction function (Assad et al., 1991; Kroese et al., 1989), rectification of the motile response disappeared. Keywords :
Cochlea; Outer hair cell; Hair cell transducer; Electromotility; Cochlear ampli¢er
1. Introduction
It is commonly accepted that the sensory function of the cochlea is mediated by the inner hair cells (IHCs), which have multiple a¡erent innervation (Spoendlin, 1988). The motile outer hair cells (OHCs), having rich e¡erent innervation, have been proposed to provide mechanical feedback to the cochlea (Davis, 1983). In this scheme, OHCs in£uence the micromechanics of the cochlea partition to provide both the gain and the compression of cochlear responses which enables the cochlea to function as a sensitive, highly tuned frequency analyzer with an impressive dynamic range. OHCs are capable of changing their length when the potential across the OHC membrane changes (Brownell et al., 1985; Ashmore, 1987; Santos-Sacchi and Dilger, 1988). In situ, the receptor potentials produced by the OHCs in response to acoustic stimulation are believed to control the OHC's voltage-dependent mechanical re* Corresponding author. Tel.: +44 (1273) 678632; Fax: +44 (1273) 678433; E-mail: [email protected]
sponse. OHC electromotility has been observed not only under the action of intra- or extracellularly applied electrical ¢elds but also under mechanical stimulation of the stereocilia (Evans and Dallos, 1993). In Evans and Dallos's experiments, the OHC body was fully inserted into a microchamber so that the basolateral and apical membranes created a voltage divider. In this electrical circuit, the motile response was driven by changes in the intracellular potential, which, in turn, were modulated by the variable mechanoelectrical transducer conductance. Consequently, the intrinsic properties of the mechanoelectrical transduction process may a¡ect OHC electromotility. One of these intrinsic properties is the voltage sensitivity of the mechanoelectrical transducer conductance which has been demonstrated for di¡erent hair cell types including OHCs (Assad et al., 1989; Crawford et al., 1989 ; Kros et al., 1993). We have adopted the microchamber technique, with the OHC fully inserted, to provide a way of observing the dependence of the fast OHC electromotility on the mechanoelectrical transducer. An important aspect of this technique is
0378-5955 / 97 / $17.00 ß 1997 Elsevier Science B.V. All rights reserved PII S 0 3 7 8 - 5 9 5 5 ( 9 7 ) 0 0 1 3 5 - 4
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A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
134
that the apical and basolateral membrane conductances of the OHC are arranged in series just as they are arranged in vivo (Fig. 1a). This is not the case with the whole-cell technique where the conductance of the basolateral membrane shunts the transducer conductance or in microchamber experiments when the OHCs are only partially inserted into the microchamber. In the experiments described here, we have studied how
the
voltage
sensitivity
of
the
mechanoelectrical
transducer conductance, whereby the open probability of the transducer channels increases with OHC depolarization, may in£uence the low frequency responses of OHCs to an external electrical ¢eld. Measurements of the movement of the synaptic pole of the OHC during sinusoidal voltage changes across the cell were made for two cases. Firstly, for the intact hair bundle and secondly, when the mechanoelectrical transducer conductance was eliminated with blockers.
2. Materials and methods
Guinea pigs were anaesthetized with pentobarbitone. After cervical dislocation their temporal bones were removed. OHCs were isolated non-enzymatically or after enzymatic incubation (1 mg/ml of type IV collagenase, Sigma, Poole, Dorset) by pipetting gently the organ of Corti which had been dissected from the cochlea. OHCs were maintained in an extracellular solution which contained (mM) : 140 NaCl, 0.7 NaH2 PO4 , 5.8 KCl, 1.3 CaCl2 , 0.9 MgCl2 , 5.6
D-glucose,
10 HEPES, pH 7.4.
Vitamins and amino acids for Eagle's Minimal Essential Medium were added from concentrates (Gibco, Paisley, Strathclyde). The osmolality was near 320 mosmol/kg. The modi¢ed extracellular solution which was used to
Fig. 1. a : Elementary electrical circuit of an OHC inserted into the microchamber. Resistance of the cell's apical pole transducer. voltage-
Resistance
and
of
the
time-dependent
basolateral
Ra
includes the
Rb
membrane
Rs
conductances.
is
the
block the OHC voltage-gated conductances contained
ance. The resistance of the microchamber in series with
(mM) : 115 NaCl, 5.8 KCl, 1.3 CaCl2 , 10
is not shown because it is relatively insigni¢cant.
D-glucose,
5
CsCl, 20 TEA-Cl, 1 CdCl2 , 10 HEPES-NaOH, pH 7.4. Vitamins and amino acids were not added to the modi¢ed
solution
to
avoid
precipitation
of
the
cadmium
tive force of the basolateral membrane.
Vc
provide
estimates
of
voltage
sensitivity
Rb
is the electromo-
is the command voltage
of
conductance contained 5 mM BAPTA or 200
ducer
of the BAPTA and the dihydrostreptomycin solutions
resist-
and
The insert shows the equivalent electrical circuit which was used to
Here the resistance of the OHC apical pole
drostreptomycin (Sigma, Poole, Dorset). The osmolality
Ra
applied between the bath solution and the microchamber solution.
compounds. The solution for eliminating the transducer
WM dihy-
E
includes
shunt
resistance
membrane
Rc .
Rtr
in
parallel
with
the
the
Ra
OHC
transducer.
consists of the trans-
resistance
of
the
apical
b : Photodiode response as a function of the displace-
ment of the image of a 5 normalized to the 1
were near 320 mosmol/kg and 300 mosmol/kg respec-
Wm
Wm
diameter glass ¢ber. Responses are
¢ber displacement.
tively and with a pH of 7.4. BAPTA or dihydrostreptomycin were added to the extracellular solution with-
noic acid) (Sigma, Poole, Dorset) to prevent mechanical
out
damage the cells and to improve the resistance of the
vitamins
and
amino
acids.
All
experiments
were
U
6
performed at room temperature (22³C). The cells were
seal (up to 5 M
observed with a top-focusing microscope, using a 40
same extracellular solution which was used to maintain
water immersion objective.
Microchambers for holding the OHCs were pulled
). The microchamber contained the
OHCs, i.e. normal solution or solution with blockers of the
voltage-gated
conductances,
respectively.
The
from borosilicate glass to produce tips with aperture
OHC's bodies were sucked gently into the microcham-
diameters of about 30
ber
then
¢re
polished
to
Wm.
The microchambers were
aperture
diameters
of
8^9
Wm
and coated with linoleic acid (cis-9, cis-12-Octadecadie-
up
to
the
cuticular
plate
so
that
only
the
cell's
apical pole with the hair bundle was in the bath solution (Fig. 1a). Experiments were carried out only on
HEARES 2890 28-11-97
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
135
OHCs without any visible sign of trauma or damage of
grabber, Image Nation, Beaverton, OR, USA) before
the hair bundle.
and
during
The
absolute
Transcellular
voltage
signals
were
applied
to
the
the
application
value
of
the
of
an
cell's
electrical length
stimulus.
change
was
OHCs between the bath solution and the microchamber
found by subtracting these two images with a software
solution (Fig. 1a) with a laboratory constructed volt-
package
age-clamp ampli¢er. According to our convention, pos-
quence
itive command voltages corresponded to a positive volt-
the
age
found from the ratio between the photodiode responses
inside
the
microchamber.
This
hyperpolarizes
the
cell's basolateral
the
Rb ,
of
resistance,
believed the
to
apical
be pole
command
much
the basal pole less
(Evans
voltage,
positive
Vb ,
et
than al.,
which
the
resistance,
1991), drops
the
part
across
Ra , of
the
Ra
of the
cell's
and
Rb
values
the of
Seattle,
linearity length
WA,
of
the
changes
USA).
As
photodiode
for
other
a
conse-
response,
stimuli
were
for those stimuli and the calibrated response. Solutions
for
eliminating
the
transduction
process
were applied locally to the hair bundle through a glass pipette with a tip of 50
Wm
diameter. The £ow of the
solution was driven by gravity. Polystyrene latex beads (1.1
Wm
diameter, Sigma, Poole, Dorset) were added to
the solutions to visualize the £ow. The microchamber
WV RR c
Since
(see Fig. 1a) is
basolateral membrane is de¢ned by the ratio
Vb
voltage
membrane.
(Optimas, of
b a
1
with the inserted OHC was ¢lled with solution kept under slight positive pressure to avoid any contamination of the basolateral membranes when BAPTA and
where
Vc
is the command voltage applied between the
dihydrostreptomycin were added to the solution bath-
bath solution and the microchamber solution. The cell's
ing
motile responses were measured using a pair of photo-
OHC
the
apical
surface.
diodes (OSD15-5T, Centronics). The image of the cell's
perfusion pipette from the experimental bath when the
synaptic pole was projected onto one of the photodio-
extracellular
des. The other photodiode was used for di¡erential sub-
OHC responses modi¢ed by dihydrostreptomycin were
traction of light and electrical noise. The ¢ltered output
measured during continuous perfusion of the hair bun-
from the photodiodes was digitized and stored for later
dle with the dihydrostreptomycin containing solution.
responses
were
solution
In
experiments
measured
had
been
after
with
BAPTA,
removal
changed
for
of
the
normal.
computer analysis. The linearity of the photodiode response was con¢rmed by registering the movement of the image of a glass ¢ber driven by a piezo electric
3. Results
bimorph (Fig. 1b). In order to ¢nd the absolute value of cell's length change the image of the cell's synaptic
When fully inserted into microchamber, OHCs dem-
pole was projected simultaneously onto a CCD camera
onstrate a recti¢cation of their extension responses, i.e.
(SSC-M370CE, Sony, Japan) and written (CX frame
with hyperpolarization of the basolateral membrane, as
Fig. 2. Response waveforms of an OHC to a sinusoidal command voltage of 10 Hz before (upper row) and after (lower row) application of BAPTA to the hair bundle. The amplitude of the command voltage is indicated for each column. The response waveform is almost symmetrical for small voltages, but the recti¢cation is clearly apparent for large command voltages in the absence of BAPTA. Cell length : 48 bars : 300 nm and 200 ms.
HEARES 2890 28-11-97
Wm.
Scale
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
136
inside the microchamber, hyperpolarization of the basolateral membrane may turn o¡ these conductances. This should lead to an increase of the basolateral membrane resistance
Rb
and to an increase in the cell's mechanical
response. In order to test these two hypotheses we have carried out experiments with blockers of the voltagegated and mechanoelectrical transducer channels. Local perfusion
of
the
hair
bundle
with
BAPTA
solution
(Figs. 2 and 3a) lead to a considerable decrease in the recti¢cation which is associated with positive voltage inside
the
microchamber.
During
these
experiments
similar recti¢cation, and its reduction after BAPTA application, was obtained in solutions containing voltagegated
channels
access
of
blockers
BAPTA
to
(Fig.
the
3b).
apical,
By
restricting
sensory
pole
of
the the
OHCs, the only e¡ect of BAPTA perfusion should be the
irreversible
elimination
of
the
mechanoelectrical
transduction process (Assad et al., 1991 ; Crawford et al., 1991). Similar reduction in the recti¢cation was observed during perfusion of the hair bundle with dihydrostreptomycin cause
a
(Fig.
reversible
4).
Dihydrostreptomycin
blockade
of
the
can
mechanoelectrical
transducer channel (Kroese et al., 1989) and it was possible to observe partial recovery of the recti¢cation after washing out the dihydrostreptomycin (Fig. 4) but not Fig. 3. Mechanical responses for a fully inserted OHC as a function of command voltage. a : Measured in normal extracellular solution, cell length :
35
Wm ;
b:
measured in solution with blockers of the
Wm.
voltage-gated channels, cell length : 40
Open circles represent re-
sponses with intact hair bundle and solid circles represent responses after
application
of
BAPTA.
BAPTA
was
washed
out
with
the
after washing out the BAPTA. Residual recti¢cation of the response was occasionally observed after BAPTA or during dihydrostreptomycin perfusion. This may have occurred
because
mechanoelectrical
we
were
not
transducer
able
eliminate
the
completely.
The probability of the transducer being opened is in-
2
bathing solution before measurements were made.
to
conductance
creased in solutions with low Ca
concentration (Ha-
can be seen in Fig. 2. One can see from Eq. (1), when
cohen et al., 1989). However, this e¡ect could not be
Vc
responsible for modifying OHC electromotility in our
is held constant, the voltage drop across the baso-
lateral membrane and, therefore, the amplitude of the
increasing e¡ects.
Rb .
One
Ra
experiments
because
OHC
voltage-dependent
electro-
or
motility was measured only after the extracellular sol-
Two possibilities might account for these
ution containing BAPTA had been replaced with a nor-
cell elongation can be increased with decreasing
could
mechanoelectrical
be
the
voltage
transducer.
brane is depolarized
when
Ra
is hyperpolarized and
the
mal solution. It was sometimes possible to observe a
apical mem-
decrease in the slope of the electromotile response for
dependence
The OHC
of
the basolateral membrane
can be decreased because a
greater proportion of the mechanoelectrical transducer channels will be opened with depolarization of the apical
membrane
(Assad
et
al.,
1989 ;
Crawford
et
al.,
1989 ; Kros et al., 1993). However, it is possible that the observed recti¢cation of the curve when the voltage inside the microchamber is positive, may be generated not only by the voltage dependence of the mechanoelectrical transducer but also by the voltage-gated conductances of the basolateral membrane. For example, the OHCs may be depolarized slightly after the isolation
procedure
voltage-gated
(Evans
channels
et of
al.,
1991)
the
and
basolateral
part
of
the
membrane
(Ashmore and Meech, 1986 ; Santos-Sacchi and Dilger, 1988 ;
Housley
and
Ashmore,
1992 ;
Santos-Sacchi,
1992) may be activated. Therefore, with positive voltage
Fig. 4. E¡ect of dihydrostreptomycin on mechanical responses of a fully inserted OHC. Open circles represent responses with the intact hair bundle and solid circles represent responses during application of
dihydrostreptomycin.
Triangles
show
responses
after
10
min
washout of dihydrostreptomycin with the normal extracellular solution. Cell length : 44
HEARES 2890 28-11-97
Wm.
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
137
the largest positive command voltages (Fig. 4). This ef-
been observed for cochlear hair cells, not only for the
fect could be due to weak saturation of the electromo-
steady-state transducer current ^ displacement relation-
tility function. The saturation is most apparent when the
ships, when the voltage dependence can be attributable
elongation
blockers
to the adaptation process, but also for the peak trans-
(Fig. 4). We found it di¤cult to measure a sharp satu-
ducer current ^ displacement relationships which have
ration of the electromotile responses, as has been de-
been measured in the ¢rst few milliseconds of stimulus
scribed earlier for the OHCs in microchamber (Evans
onset, before the start of adaptation (Kros et al., 1993).
et al., 1991 ; Hallworth et al., 1993). This is probably,
In this case, true voltage sensitivity of the mechanoelec-
because only a small fraction of the command voltage is
trical transducer channels may contribute towards the
dropped across the basolateral membrane in our experi-
e¡ect observed in our experiments. Another source of
ments (see Section 4). Of the 34 OHCs tested, only 15 did
voltage dependence, that due to the voltage-dependent
not demonstrate a recti¢cation of the mechanical re-
sti¡ness of guinea pig OHC hair bundles, has been de-
sponse when the inside of the microchamber was made
scribed recently (Zhang et al., 1997). The steady-state
positive. Despite any visible sign of damage, the OHC
position of the hair bundle depends on the vector sum
mechanoelectrical
of
recti¢cation
was
abolished
transducer
appeared
with
to
have
been
compromized by the isolation procedure in these cases.
all
forces
applied
to
the
stereocilia
(Howard
and
Hudspeth, 1988), and consequently, any change in the sti¡ness of the hair bundle will lead to changes in gating spring tension and, in turn, to changes in the number of the open transducer channels.
4. Discussion
The electromotile responses of OHCs under voltage When OHCs are fully inserted into the microcham-
clamp
have
been
¢tted
with
sigmoidal
curves
which
ber (Evans et al., 1989 ; Evans and Dallos, 1993) it is
demonstrate fast saturation in the direction of extension
possible to observe aspects of the fast OHC's electro-
when the cell's membrane potential was held near
motility
mechanoelectrical
mV (Ashmore, 1987 ; Santos-Sacchi, 1989). If the fast
these
OHC
which
transducer.
This
depend is
upon
because,
the
under
conditions,
electromotility
is
controlled
only
by
the
3
70
mem-
the apical and basolateral membrane conductances of
brane potential, as a consequence of the non-linearity
the OHCs are arranged in series, just as they are in the
of the electromotile response, it should be possible to
organ of Corti in vivo (Fig. 1a).
observe some kind of recti¢cation during both elonga-
In the present report, the electromotility of OHCs,
tion and extension, depending upon the value and sign
when fully inserted into the microchamber, became rec-
of the OHC membrane potential. However, this form of
ti¢ed when the command voltage inside the microcham-
recti¢cation is not the basis of that observed in our
ber was positive, i.e. during hyperpolarization of the
experiments.
basolateral membrane and depolarization of the apical
was unknown for the OHCs in our experiments, but
membrane. The recti¢cation survived block of the volt-
it is not essential for understanding the basis of the
age-gated
the
recti¢cation of the electromechanical response described
sensory apical pole of the OHC was exposed to BAPTA
in this paper. This is because the voltage drop across
and dihydrostreptomycin, agents which are known to
the basolateral membrane
interfere with mechanoelectrical transduction (Kroese et
the command voltage for an OHC fully inserted into
al., 1989 ; Assad et al., 1991). Since recti¢cation of the
the microchamber. A value
OHC mechanical response when the inside of the mi-
the ratio of the membrane areas of excluded and in-
crochamber was positive depends on the mechanoelec-
cluded segments of the OHC as a ¢rst approximation
trical transducer, we may conclude that voltage depend-
of the voltage divider
ence
it
of
conductances
the
transducer
but
was
abolished
channels
may
when
modify
the
is
The
estimated
exact
that
resting
Vb
potential
is only a small fraction of
Rb /Ra
Rb /Ra only
membrane
can be found from
(Evans et al., 1991). Thus,
1/23^1/19
of
the
command
electromechanical response of the OHCs in vitro. The
voltage
mechanism of the voltage dependence of the mechanical
for the OHCs shown in Figs. 3 and 4. The recti¢cation
response described in this paper is a matter for specu-
of
lation. Only low frequency electrical signals have been
marked
used in these experiments and the voltage dependence
the potential change across the basolateral membrane
could be due to a number of mechanisms with relatively
is only about 4^5 mV. This change is too small to drive
slow time courses. For example, it is known that adap-
the electromotility into saturation where recti¢cation of
tation of the mechanoelectrical transducer channels in
the extension response would occur. For this to happen,
bullfrog (Hacohen et al., 1989) and turtle (Crawford et
the OHC membrane would have to be depolarized to
al., 1989) hair cells disappears when the apical mem-
about +20 mV (Santos-Sacchi and Dilger, 1988 ; San-
brane is depolarized, thus reducing the driving force
tos-Sacchi, 1989) and it is not possible to achieve this
for the calcium ions. However, an increase in the trans-
value of membrane potential under the conditions of
ducer
our experiments. The ratio
conductance
with
hair
cell
depolarization
has
the
HEARES 2890 28-11-97
is
dropped
elongation for
a
across
the
responses
command
basolateral
of
these
potential
Rb /Ra
of
membrane
OHCs 100
is
quite
mV,
when
can also be calculated
138
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
using the data of Kros et al. (1992) for the mechanoelectrical transducer conductance of OHCs of the cultured mouse cochlea (we use a value 8 nS for the total transducer conductance in our calculations) and for the part of the conductance activated at the rest (8% of the maximal value). The speci¢c conductance of the OHC's membrane can be obtained from the data of Housley and Ashmore (1992). In this case the resistance of the cell's apical pole Ra consists of the mechanoelectrical transducer resistance Rtr and the resistance of the apical membrane Rc connected in parallel (see insertion in Fig. 1). These two resistances are connected in series with the basolateral membrane resistance Rb . This way of estimating Rb/Ra provides slightly larger values of 1/ 17^1/15 for the ratio for the OHCs illustrated in Figs. 3 and 4. However, even in this case, the actual voltage change across the basolateral membrane is only about 6^7 mV for a 100 mV command voltage. The electrical circuit in Fig. 1, together with Eq. (1), can be used to provide estimates of the voltage sensitivity of the transducer. Let us assume that, for zero command voltage, the mechanoelectrical transducer is approximated by the resting transducer conductance (Kros et al., 1992) and that elongation of the OHC when the inside of the microchamber is positive is due also to the voltage sensitivity of the mechanoelectrical transducer. Then, for the three OHCs shown in Figs. 3 and 4, the mechanoelectrical transducer conductance would have increased by 0.6, 0.9 and 0.3 nS respectively for a command voltage of 100 mV, which is equivalent to depolarizing the apical membrane by about 5 mV. According to Kros et al. (1992) the mechano-sensitivity of the mechanoelectrical transducer to small displacements of the hair bundle from the resting position is 0.03 nS/ nm. Therefore, a 5 mV depolarization of the apical membrane is equivalent to an excitatory displacement of 0.5^1.5 nm for the hair bundles of the OHCs shown in Figs. 3 and 4.
the OHC electromotility, which were measured in the solution containing 1.3 mM Ca2 , may be more pronounced in situ where the Ca2 concentration of the endolymph is only 20 WM (Boscher and Warren, 1978). Hair cell depolarization also leads to the displacement of the hair bundles of frog and turtle hair cells (Crawford and Fettiplace, 1985; Assad et al., 1989; Crawford et al., 1989; Assad et al., 1991). This displacement was proposed (Assad et al., 1989) to represent a transition of the hair bundle to another resting position corresponding to an increased number of open transducer channels. However, voltage-dependent displacement of OHC bundles has yet to be observed. Passive displacement of the OHC hair bundles has been observed both in single hair cells and in isolated preparations of the organ of Corti as a result of an active tilting of the hair cell's cuticular plate during exposure to alternating external electrical ¢elds (Zenner et al., 1988; Reuter and Zenner, 1990). Therefore, the angular rotation of the OHCs hair bundles and tension in the gating springs in vivo may be governed by the shear motion of the reticular lamina and tectorial membrane, by the voltage dependence of the OHC mechanoelectrical transducer and, possibly (but see Holley, 1996) by the tilting of the cuticular plate. The co-operative outcome of these e¡ects on the angular rotation of the hair bundle will establish the actual state of the mechanoelectrical transducer and, accordingly, the receptor potential and the electromotile response of the OHC in vivo. The experiments of Russell and Koëssl (1991) can give an idea of complexity of this interaction. These authors observed voltage-dependent shifts of the IHC and OHC mechanoelectrical transducer functions in vivo which cannot be explained either by voltage dependence of the mechanoelectrical transducer (Assad et al., 1989; Crawford et al., 1989; Kros et al., 1993) or by tilting of the cuticular plate (Zenner et al., 1988; Reuter and Zenner, 1990).
4.1. Functional signi¢cance of the voltage dependence in vivo
4.2. Voltage dependence and cochlear non-linearity
The voltage dependence of the mechanoelectrical transducer has been described for di¡erent types of hair cells. Depolarization increased the number of open transducer channels for hair cells in the turtle cochlea (Crawford et al., 1989), the bullfrog vestibular system (Assad et al., 1989) and OHCs of the mouse cochlea (Kros et al., 1993) thus leading to a shift of the mechanoelectrical transducer function to the left along the axes of displacements. Voltage induced shifts of the transducer function depend strongly on the concentration of extracellular Ca2 (Hacohen et al., 1989; Crawford et al., 1991) around the apical pole of the hair cell and become more pronounced when the Ca2 concentration is lowered. Thus, the voltage dependence of
Patuzzi et al. (1989) and Santos-Sacchi (1993) proposed that the mechanoelectrical transducer function generates a dominant non-linearity which could distort the OHC's electromotility in vivo. Experimental and model investigations have con¢rmed that the non-linearity of the hair cell mechanoelectrical transducer can give rise to non-linear phenomena, such as distortion products and two-tone suppression with patterns similar to those which have been recorded from the peripheral auditory system (Weiss and Leong, 1985; Frank and Koëssl, 1996; Lukashkin and Russell, 1997). It is known that non-linear systems can change their behavior crucially with slight changes in their parameters (e.g. see Andronov et al., 1966). For example, slight changes of the mechanoelectrical transducer operating point, i.e.
HEARES 2890 28-11-97
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139 shift
the
mechanoelectrical
transducer
function
along
the axes of displacements for several nanometers, could modify the pattern of the distortion products and twotone suppression (Weiss and Leong, 1985 ; Frank and
139
Evans, B.N., Dallos, P., 1993. Stereocilia displacement induced somatic motility of cochlear outer hair cells. Proc. Natl. Acad. Sci. USA 90, 8347^8351. Frank, G., Ko ë ssl, M., 1996. The acoustic two tone distortions 2f1-f2 and f2-f1 and their possible relation to changes in the gain and the
Ko ë ssl, 1996 ; Lukashkin and Russell, 1997). On the oth-
operating point of the cochlear ampli¢er. Hear. Res. 98, 104^115.
er hand, hair cell depolarization a¡ects not only the
Hacohen, N., Assad, J.A., Smith, W.J., Corey, D.P., 1989. Regulation
mechanoelectrical channels are
transducer
open at
rest)
operating
but also
point
other
(more
transducer
parameters (Assad et al., 1989 ; Crawford et al., 1989 ; Kros et al., 1993). Therefore, the voltage dependence of the mechanoelectrical transducer is one of the factors which determine the speci¢c type of non-linearity of the cell's mechanical response and, consequently, the speci¢c type of active non-linear cochlear function.
of tension on hair-cell transduction channels : displacement and calcium dependence. J. Neurosci. 9, 3988^3997. Hallworth, R., Evans, B.N., Dallos, P., 1993. The location and mechanism of electromotility in guinea pig outer hair cells. J. Neurophysiol. 70, 549^558. Holley, M.C., 1996. Outer hair cell motility. In : Dallos, P., Popper, A.N., Fay, R.B. (Eds.), The Cochlea. Springer, New York, p. 421. Housley, G.D., Ashmore, J.F., 1992. Ionic currents of outer hair cells isolated from the guinea-pig cochlea. J. Physiol. (London) 448, 73^98. Howard, J., Hudspeth, A.J., 1988. Compliance of the hair bundle associated with gating of mechanoelectrical transduction channels
Acknowledgments
in the bullfrog's saccular hair cell. Neuron 1, 189^199. Kroese, A.B.A., Das, A., Hudspeth, A.J., 1989. Blockage of the trans-
This work was supported by the MRC. A.N.L. is a Wellcome Prize Research Student. The authors thank
duction channels of hair cells in the bullfrog's sacculus by aminoglycoside antibiotics. Hear. Res. 37, 203^218. Kros,
C.J.,
Ru ë sch,
A.,
Lennan,
G.W.T.,
Richardson,
G.P.,
1993.
James Hartley for designing and constructing the elec-
Voltage dependence of transducer currents in outer hair cells of
tronic
neonatal mice. In : Duifhuis, H., Horst, J.W., van Dijk, P., van
equipment
and
Matthew
Holley
and
Guy
Ri-
chardson for their critical reading of early versions of
Netten, S.M. (Eds.),
Biophysics of
Hair
Cell
Sensory Systems.
World Scienti¢c, Singapore, pp. 141^150.
this manuscript.
Kros, C.J., Ru ë sch, A., Richardson, G.P., 1992. Mechano-electrical transducer currents in hair cells of the cultured neonatal mouse
References
cochlea. Proc. Roy. Soc. London B 249, 185^193. Lukashkin, A.N., Russell, I.J., 1997. The receptor potential non-line-
Andronov, A.A., Vitt, A.A., Khaikin, S.E., 1966. Theory of Oscilla-
arities generated by the mechanoelectrical transducer to two-tone stimulation.
tors. Pergamon Press, Oxford. Ashmore, J.F., 1987. A fast motile response in guinea-pig outer hair cells : the cellular basis of the cochlear ampli¢er. J. Physiol. (Lon-
In :
Lewis,
E.R.,
Long,
G.R.,
Leake,
P.A.,
Steele,
C.R. (Eds.), Diversity in Auditory Mechanics. World Scienti¢c, Singapore, 587^593. Patuzzi, R.B., Yates, G.K., Johnstone, B.M., 1989. Outer hair cell
don) 338, 323^347. Ashmore, J.F., Meech, R.W., 1986. Ionic basis of membrane potential in outer hair cells of guinea pig cochlea. Nature 322, 368^371.
receptor current and sensorineural hearing loss. Hear. Res. 42, 47^72.
Assad, J.A., Hacohen, N., Corey, D.P., 1989. Voltage dependence of
Reuter, G., Zenner, H.P., 1990. Active radial and transverse motile
adaptation and active bundle movement in bullfrog saccular hair
responses of outer hair cells in the organ of Corti. Hair. Res. 43, 219^230.
cells. Proc. Natl. Acad. Sci. USA 86, 2918^2922. Assad, J.A., Shepherd, G.M.G., Corey, D.P., 1991. Tip-link integrity
Russell, I.J., Ko ë ssl, M., 1991. The voltage responses of hair cells in
and mechanical transduction in vertebrate hair cells. Neuron 7,
the basal turn of the guinea-pig cochlea. J. Physiol. (London) 435, 493^511.
985^994. Boscher, S.K., Warren, R.L., 1978. Very low calcium content of cochlear endolymph, an extracellular £uid. Nature 273, 377^378. Brownell, W.E., Bader, C.R., Bertrand, D., de Ribaupierre, Y., 1985. Evoked mechanical responses of isolated cochlear hair cells. Sci-
Santos-Sacchi, J., 1989. Asymmetry in voltage-dependent movements of isolated outer hair cells from the organ of Corti. J. Neurosci. 9, 2954^2962. Santos-Sacchi, J., 1992. On the frequency limit and phase of outer hair cell motility : e¡ects of the membrane ¢lter. J. Neurosci. 12,
ence 227, 194^196. Crawford, A.C., Fettiplace, R., 1985. The mechanical properties of ciliary bundles of turtle cochlear hair cells. J. Physiol. (London)
1906^1916. Santos-Sacchi, J., 1993. Harmonics of outer hair cell motility. Biophysical J. 65, 2217^2227.
364, 359^379. Crawford, A.C., Evans, M.G., Fettiplace, R., 1989. Activation and adaptation of transducer currents in turtle hair cells. J. Physiol.
Santos-Sacchi, J., Dilger, J.P., 1988. Whole cell currents and mechanical responses of isolated outer hair cells. Hear. Res. 35, 143^150. Spoendlin, H., 1988. Neural anatomy of the inner ear. In : Jahn, A.F.,
(London) 419, 405^434. Crawford, A.C., Evans, M.G., Fettiplace, R., 1991. The actions of calcium on the mechano-electrical transducer current of turtle hair
Santos-Sacchi, J. (Eds.), Physiology of the Ear. Raven Press, New York, pp. 201^219. Weiss, T.F., Leong, R., 1985. A model for signal transmission in an
cells. J. Physiol. (London) 434, 369^398. Davis, H., 1983. An active process in cochlear mechanics. Hear. Res.
ear having hair cells with free-standing stereocilia. IV. Mechanoelectric transduction stage. Hear. Res. 20, 175^195.
9, 79^90. Evans, B.N., Dallos, P., Hallworth, R., 1989. Asymmetries in motile
Zenner, H.P., Zimmermann, R., Gitter, A.H., 1988. Active move-
responses of outer hair cells in simulated in vivo conditions. In :
ments of the cuticular plate induce sensory hair motion in mam-
Kemp, D., Wilson, J.P. (Eds.), Cochlear Mechanisms : Structure, Function and Models. Plenum Press, New York, pp. 205^206. Evans, B.N., Hallworth, R., Dallos, P., 1991. Outer hair cell electromotility : the sensitivity and vulnerability of the DC component.
malian outer hair cells. Hear. Res. 34, 233^240. Zhang, M., Evans, B.N., Dallos, P., 1997. Voltage-dependent ciliary sti¡ness in cochlear outer hair cell. Abstr. Assoc. Res. Otolaryngol. 20, 64.
Hear. Res. 52, 288^304.
HEARES 2890 28-11-97
The voltage dependence of the mechanoelectrical transducer modi¢es low frequency outer hair cell electromotility in vitro Andrei N. Lukashkin, Ian J. Russell * School of Biological Sciences, University of Sussex, Falmer, Brighton, BN1 9QG, UK
Received 21 February 1997; revised 25 June 1997; accepted 18 July 1997
Abstract
The fast outer hair cell (OHC) electromotility is voltage dependent and is driven by changes in the OHC transmembrane potential. Those changes include the receptor potential generated by the variable conductance of the mechanoelectrical transducer (Evans and Dallos, 1993). In the experiments described here, we show that the voltage dependence of the mechanoelectrical transducer influences the low frequency motile responses of OHCs to an external electrical field. OHCs were fully inserted into a glass suction pipette, the microchamber, so that only the cuticular plate and hair bundle were exposed to the bath solution. With this technique, a rectification of the mechanical response, equivalent to an excitatory displacement of the hair bundle, was observed when the command voltage inside the microchamber depolarized the apical membrane. The shape of the response persisted when the OHC voltage-gated conductances were blocked. Following treatment of the hair bundle with BAPTA or dihydrostreptomycin, which are known to impair transduction function (Assad et al., 1991; Kroese et al., 1989), rectification of the motile response disappeared. Keywords :
Cochlea; Outer hair cell; Hair cell transducer; Electromotility; Cochlear ampli¢er
1. Introduction
It is commonly accepted that the sensory function of the cochlea is mediated by the inner hair cells (IHCs), which have multiple a¡erent innervation (Spoendlin, 1988). The motile outer hair cells (OHCs), having rich e¡erent innervation, have been proposed to provide mechanical feedback to the cochlea (Davis, 1983). In this scheme, OHCs in£uence the micromechanics of the cochlea partition to provide both the gain and the compression of cochlear responses which enables the cochlea to function as a sensitive, highly tuned frequency analyzer with an impressive dynamic range. OHCs are capable of changing their length when the potential across the OHC membrane changes (Brownell et al., 1985; Ashmore, 1987; Santos-Sacchi and Dilger, 1988). In situ, the receptor potentials produced by the OHCs in response to acoustic stimulation are believed to control the OHC's voltage-dependent mechanical re* Corresponding author. Tel.: +44 (1273) 678632; Fax: +44 (1273) 678433; E-mail: [email protected]
sponse. OHC electromotility has been observed not only under the action of intra- or extracellularly applied electrical ¢elds but also under mechanical stimulation of the stereocilia (Evans and Dallos, 1993). In Evans and Dallos's experiments, the OHC body was fully inserted into a microchamber so that the basolateral and apical membranes created a voltage divider. In this electrical circuit, the motile response was driven by changes in the intracellular potential, which, in turn, were modulated by the variable mechanoelectrical transducer conductance. Consequently, the intrinsic properties of the mechanoelectrical transduction process may a¡ect OHC electromotility. One of these intrinsic properties is the voltage sensitivity of the mechanoelectrical transducer conductance which has been demonstrated for di¡erent hair cell types including OHCs (Assad et al., 1989; Crawford et al., 1989 ; Kros et al., 1993). We have adopted the microchamber technique, with the OHC fully inserted, to provide a way of observing the dependence of the fast OHC electromotility on the mechanoelectrical transducer. An important aspect of this technique is
0378-5955 / 97 / $17.00 ß 1997 Elsevier Science B.V. All rights reserved PII S 0 3 7 8 - 5 9 5 5 ( 9 7 ) 0 0 1 3 5 - 4
HEARES 2890 28-11-97
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
134
that the apical and basolateral membrane conductances of the OHC are arranged in series just as they are arranged in vivo (Fig. 1a). This is not the case with the whole-cell technique where the conductance of the basolateral membrane shunts the transducer conductance or in microchamber experiments when the OHCs are only partially inserted into the microchamber. In the experiments described here, we have studied how
the
voltage
sensitivity
of
the
mechanoelectrical
transducer conductance, whereby the open probability of the transducer channels increases with OHC depolarization, may in£uence the low frequency responses of OHCs to an external electrical ¢eld. Measurements of the movement of the synaptic pole of the OHC during sinusoidal voltage changes across the cell were made for two cases. Firstly, for the intact hair bundle and secondly, when the mechanoelectrical transducer conductance was eliminated with blockers.
2. Materials and methods
Guinea pigs were anaesthetized with pentobarbitone. After cervical dislocation their temporal bones were removed. OHCs were isolated non-enzymatically or after enzymatic incubation (1 mg/ml of type IV collagenase, Sigma, Poole, Dorset) by pipetting gently the organ of Corti which had been dissected from the cochlea. OHCs were maintained in an extracellular solution which contained (mM) : 140 NaCl, 0.7 NaH2 PO4 , 5.8 KCl, 1.3 CaCl2 , 0.9 MgCl2 , 5.6
D-glucose,
10 HEPES, pH 7.4.
Vitamins and amino acids for Eagle's Minimal Essential Medium were added from concentrates (Gibco, Paisley, Strathclyde). The osmolality was near 320 mosmol/kg. The modi¢ed extracellular solution which was used to
Fig. 1. a : Elementary electrical circuit of an OHC inserted into the microchamber. Resistance of the cell's apical pole transducer. voltage-
Resistance
and
of
the
time-dependent
basolateral
Ra
includes the
Rb
membrane
Rs
conductances.
is
the
block the OHC voltage-gated conductances contained
ance. The resistance of the microchamber in series with
(mM) : 115 NaCl, 5.8 KCl, 1.3 CaCl2 , 10
is not shown because it is relatively insigni¢cant.
D-glucose,
5
CsCl, 20 TEA-Cl, 1 CdCl2 , 10 HEPES-NaOH, pH 7.4. Vitamins and amino acids were not added to the modi¢ed
solution
to
avoid
precipitation
of
the
cadmium
tive force of the basolateral membrane.
Vc
provide
estimates
of
voltage
sensitivity
Rb
is the electromo-
is the command voltage
of
conductance contained 5 mM BAPTA or 200
ducer
of the BAPTA and the dihydrostreptomycin solutions
resist-
and
The insert shows the equivalent electrical circuit which was used to
Here the resistance of the OHC apical pole
drostreptomycin (Sigma, Poole, Dorset). The osmolality
Ra
applied between the bath solution and the microchamber solution.
compounds. The solution for eliminating the transducer
WM dihy-
E
includes
shunt
resistance
membrane
Rc .
Rtr
in
parallel
with
the
the
Ra
OHC
transducer.
consists of the trans-
resistance
of
the
apical
b : Photodiode response as a function of the displace-
ment of the image of a 5 normalized to the 1
were near 320 mosmol/kg and 300 mosmol/kg respec-
Wm
Wm
diameter glass ¢ber. Responses are
¢ber displacement.
tively and with a pH of 7.4. BAPTA or dihydrostreptomycin were added to the extracellular solution with-
noic acid) (Sigma, Poole, Dorset) to prevent mechanical
out
damage the cells and to improve the resistance of the
vitamins
and
amino
acids.
All
experiments
were
U
6
performed at room temperature (22³C). The cells were
seal (up to 5 M
observed with a top-focusing microscope, using a 40
same extracellular solution which was used to maintain
water immersion objective.
Microchambers for holding the OHCs were pulled
). The microchamber contained the
OHCs, i.e. normal solution or solution with blockers of the
voltage-gated
conductances,
respectively.
The
from borosilicate glass to produce tips with aperture
OHC's bodies were sucked gently into the microcham-
diameters of about 30
ber
then
¢re
polished
to
Wm.
The microchambers were
aperture
diameters
of
8^9
Wm
and coated with linoleic acid (cis-9, cis-12-Octadecadie-
up
to
the
cuticular
plate
so
that
only
the
cell's
apical pole with the hair bundle was in the bath solution (Fig. 1a). Experiments were carried out only on
HEARES 2890 28-11-97
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
135
OHCs without any visible sign of trauma or damage of
grabber, Image Nation, Beaverton, OR, USA) before
the hair bundle.
and
during
The
absolute
Transcellular
voltage
signals
were
applied
to
the
the
application
value
of
the
of
an
cell's
electrical length
stimulus.
change
was
OHCs between the bath solution and the microchamber
found by subtracting these two images with a software
solution (Fig. 1a) with a laboratory constructed volt-
package
age-clamp ampli¢er. According to our convention, pos-
quence
itive command voltages corresponded to a positive volt-
the
age
found from the ratio between the photodiode responses
inside
the
microchamber.
This
hyperpolarizes
the
cell's basolateral
the
Rb ,
of
resistance,
believed the
to
apical
be pole
command
much
the basal pole less
(Evans
voltage,
positive
Vb ,
et
than al.,
which
the
resistance,
1991), drops
the
part
across
Ra , of
the
Ra
of the
cell's
and
Rb
values
the of
Seattle,
linearity length
WA,
of
the
changes
USA).
As
photodiode
for
other
a
conse-
response,
stimuli
were
for those stimuli and the calibrated response. Solutions
for
eliminating
the
transduction
process
were applied locally to the hair bundle through a glass pipette with a tip of 50
Wm
diameter. The £ow of the
solution was driven by gravity. Polystyrene latex beads (1.1
Wm
diameter, Sigma, Poole, Dorset) were added to
the solutions to visualize the £ow. The microchamber
WV RR c
Since
(see Fig. 1a) is
basolateral membrane is de¢ned by the ratio
Vb
voltage
membrane.
(Optimas, of
b a
1
with the inserted OHC was ¢lled with solution kept under slight positive pressure to avoid any contamination of the basolateral membranes when BAPTA and
where
Vc
is the command voltage applied between the
dihydrostreptomycin were added to the solution bath-
bath solution and the microchamber solution. The cell's
ing
motile responses were measured using a pair of photo-
OHC
the
apical
surface.
diodes (OSD15-5T, Centronics). The image of the cell's
perfusion pipette from the experimental bath when the
synaptic pole was projected onto one of the photodio-
extracellular
des. The other photodiode was used for di¡erential sub-
OHC responses modi¢ed by dihydrostreptomycin were
traction of light and electrical noise. The ¢ltered output
measured during continuous perfusion of the hair bun-
from the photodiodes was digitized and stored for later
dle with the dihydrostreptomycin containing solution.
responses
were
solution
In
experiments
measured
had
been
after
with
BAPTA,
removal
changed
for
of
the
normal.
computer analysis. The linearity of the photodiode response was con¢rmed by registering the movement of the image of a glass ¢ber driven by a piezo electric
3. Results
bimorph (Fig. 1b). In order to ¢nd the absolute value of cell's length change the image of the cell's synaptic
When fully inserted into microchamber, OHCs dem-
pole was projected simultaneously onto a CCD camera
onstrate a recti¢cation of their extension responses, i.e.
(SSC-M370CE, Sony, Japan) and written (CX frame
with hyperpolarization of the basolateral membrane, as
Fig. 2. Response waveforms of an OHC to a sinusoidal command voltage of 10 Hz before (upper row) and after (lower row) application of BAPTA to the hair bundle. The amplitude of the command voltage is indicated for each column. The response waveform is almost symmetrical for small voltages, but the recti¢cation is clearly apparent for large command voltages in the absence of BAPTA. Cell length : 48 bars : 300 nm and 200 ms.
HEARES 2890 28-11-97
Wm.
Scale
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
136
inside the microchamber, hyperpolarization of the basolateral membrane may turn o¡ these conductances. This should lead to an increase of the basolateral membrane resistance
Rb
and to an increase in the cell's mechanical
response. In order to test these two hypotheses we have carried out experiments with blockers of the voltagegated and mechanoelectrical transducer channels. Local perfusion
of
the
hair
bundle
with
BAPTA
solution
(Figs. 2 and 3a) lead to a considerable decrease in the recti¢cation which is associated with positive voltage inside
the
microchamber.
During
these
experiments
similar recti¢cation, and its reduction after BAPTA application, was obtained in solutions containing voltagegated
channels
access
of
blockers
BAPTA
to
(Fig.
the
3b).
apical,
By
restricting
sensory
pole
of
the the
OHCs, the only e¡ect of BAPTA perfusion should be the
irreversible
elimination
of
the
mechanoelectrical
transduction process (Assad et al., 1991 ; Crawford et al., 1991). Similar reduction in the recti¢cation was observed during perfusion of the hair bundle with dihydrostreptomycin cause
a
(Fig.
reversible
4).
Dihydrostreptomycin
blockade
of
the
can
mechanoelectrical
transducer channel (Kroese et al., 1989) and it was possible to observe partial recovery of the recti¢cation after washing out the dihydrostreptomycin (Fig. 4) but not Fig. 3. Mechanical responses for a fully inserted OHC as a function of command voltage. a : Measured in normal extracellular solution, cell length :
35
Wm ;
b:
measured in solution with blockers of the
Wm.
voltage-gated channels, cell length : 40
Open circles represent re-
sponses with intact hair bundle and solid circles represent responses after
application
of
BAPTA.
BAPTA
was
washed
out
with
the
after washing out the BAPTA. Residual recti¢cation of the response was occasionally observed after BAPTA or during dihydrostreptomycin perfusion. This may have occurred
because
mechanoelectrical
we
were
not
transducer
able
eliminate
the
completely.
The probability of the transducer being opened is in-
2
bathing solution before measurements were made.
to
conductance
creased in solutions with low Ca
concentration (Ha-
can be seen in Fig. 2. One can see from Eq. (1), when
cohen et al., 1989). However, this e¡ect could not be
Vc
responsible for modifying OHC electromotility in our
is held constant, the voltage drop across the baso-
lateral membrane and, therefore, the amplitude of the
increasing e¡ects.
Rb .
One
Ra
experiments
because
OHC
voltage-dependent
electro-
or
motility was measured only after the extracellular sol-
Two possibilities might account for these
ution containing BAPTA had been replaced with a nor-
cell elongation can be increased with decreasing
could
mechanoelectrical
be
the
voltage
transducer.
brane is depolarized
when
Ra
is hyperpolarized and
the
mal solution. It was sometimes possible to observe a
apical mem-
decrease in the slope of the electromotile response for
dependence
The OHC
of
the basolateral membrane
can be decreased because a
greater proportion of the mechanoelectrical transducer channels will be opened with depolarization of the apical
membrane
(Assad
et
al.,
1989 ;
Crawford
et
al.,
1989 ; Kros et al., 1993). However, it is possible that the observed recti¢cation of the curve when the voltage inside the microchamber is positive, may be generated not only by the voltage dependence of the mechanoelectrical transducer but also by the voltage-gated conductances of the basolateral membrane. For example, the OHCs may be depolarized slightly after the isolation
procedure
voltage-gated
(Evans
channels
et of
al.,
1991)
the
and
basolateral
part
of
the
membrane
(Ashmore and Meech, 1986 ; Santos-Sacchi and Dilger, 1988 ;
Housley
and
Ashmore,
1992 ;
Santos-Sacchi,
1992) may be activated. Therefore, with positive voltage
Fig. 4. E¡ect of dihydrostreptomycin on mechanical responses of a fully inserted OHC. Open circles represent responses with the intact hair bundle and solid circles represent responses during application of
dihydrostreptomycin.
Triangles
show
responses
after
10
min
washout of dihydrostreptomycin with the normal extracellular solution. Cell length : 44
HEARES 2890 28-11-97
Wm.
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
137
the largest positive command voltages (Fig. 4). This ef-
been observed for cochlear hair cells, not only for the
fect could be due to weak saturation of the electromo-
steady-state transducer current ^ displacement relation-
tility function. The saturation is most apparent when the
ships, when the voltage dependence can be attributable
elongation
blockers
to the adaptation process, but also for the peak trans-
(Fig. 4). We found it di¤cult to measure a sharp satu-
ducer current ^ displacement relationships which have
ration of the electromotile responses, as has been de-
been measured in the ¢rst few milliseconds of stimulus
scribed earlier for the OHCs in microchamber (Evans
onset, before the start of adaptation (Kros et al., 1993).
et al., 1991 ; Hallworth et al., 1993). This is probably,
In this case, true voltage sensitivity of the mechanoelec-
because only a small fraction of the command voltage is
trical transducer channels may contribute towards the
dropped across the basolateral membrane in our experi-
e¡ect observed in our experiments. Another source of
ments (see Section 4). Of the 34 OHCs tested, only 15 did
voltage dependence, that due to the voltage-dependent
not demonstrate a recti¢cation of the mechanical re-
sti¡ness of guinea pig OHC hair bundles, has been de-
sponse when the inside of the microchamber was made
scribed recently (Zhang et al., 1997). The steady-state
positive. Despite any visible sign of damage, the OHC
position of the hair bundle depends on the vector sum
mechanoelectrical
of
recti¢cation
was
abolished
transducer
appeared
with
to
have
been
compromized by the isolation procedure in these cases.
all
forces
applied
to
the
stereocilia
(Howard
and
Hudspeth, 1988), and consequently, any change in the sti¡ness of the hair bundle will lead to changes in gating spring tension and, in turn, to changes in the number of the open transducer channels.
4. Discussion
The electromotile responses of OHCs under voltage When OHCs are fully inserted into the microcham-
clamp
have
been
¢tted
with
sigmoidal
curves
which
ber (Evans et al., 1989 ; Evans and Dallos, 1993) it is
demonstrate fast saturation in the direction of extension
possible to observe aspects of the fast OHC's electro-
when the cell's membrane potential was held near
motility
mechanoelectrical
mV (Ashmore, 1987 ; Santos-Sacchi, 1989). If the fast
these
OHC
which
transducer.
This
depend is
upon
because,
the
under
conditions,
electromotility
is
controlled
only
by
the
3
70
mem-
the apical and basolateral membrane conductances of
brane potential, as a consequence of the non-linearity
the OHCs are arranged in series, just as they are in the
of the electromotile response, it should be possible to
organ of Corti in vivo (Fig. 1a).
observe some kind of recti¢cation during both elonga-
In the present report, the electromotility of OHCs,
tion and extension, depending upon the value and sign
when fully inserted into the microchamber, became rec-
of the OHC membrane potential. However, this form of
ti¢ed when the command voltage inside the microcham-
recti¢cation is not the basis of that observed in our
ber was positive, i.e. during hyperpolarization of the
experiments.
basolateral membrane and depolarization of the apical
was unknown for the OHCs in our experiments, but
membrane. The recti¢cation survived block of the volt-
it is not essential for understanding the basis of the
age-gated
the
recti¢cation of the electromechanical response described
sensory apical pole of the OHC was exposed to BAPTA
in this paper. This is because the voltage drop across
and dihydrostreptomycin, agents which are known to
the basolateral membrane
interfere with mechanoelectrical transduction (Kroese et
the command voltage for an OHC fully inserted into
al., 1989 ; Assad et al., 1991). Since recti¢cation of the
the microchamber. A value
OHC mechanical response when the inside of the mi-
the ratio of the membrane areas of excluded and in-
crochamber was positive depends on the mechanoelec-
cluded segments of the OHC as a ¢rst approximation
trical transducer, we may conclude that voltage depend-
of the voltage divider
ence
it
of
conductances
the
transducer
but
was
abolished
channels
may
when
modify
the
is
The
estimated
exact
that
resting
Vb
potential
is only a small fraction of
Rb /Ra
Rb /Ra only
membrane
can be found from
(Evans et al., 1991). Thus,
1/23^1/19
of
the
command
electromechanical response of the OHCs in vitro. The
voltage
mechanism of the voltage dependence of the mechanical
for the OHCs shown in Figs. 3 and 4. The recti¢cation
response described in this paper is a matter for specu-
of
lation. Only low frequency electrical signals have been
marked
used in these experiments and the voltage dependence
the potential change across the basolateral membrane
could be due to a number of mechanisms with relatively
is only about 4^5 mV. This change is too small to drive
slow time courses. For example, it is known that adap-
the electromotility into saturation where recti¢cation of
tation of the mechanoelectrical transducer channels in
the extension response would occur. For this to happen,
bullfrog (Hacohen et al., 1989) and turtle (Crawford et
the OHC membrane would have to be depolarized to
al., 1989) hair cells disappears when the apical mem-
about +20 mV (Santos-Sacchi and Dilger, 1988 ; San-
brane is depolarized, thus reducing the driving force
tos-Sacchi, 1989) and it is not possible to achieve this
for the calcium ions. However, an increase in the trans-
value of membrane potential under the conditions of
ducer
our experiments. The ratio
conductance
with
hair
cell
depolarization
has
the
HEARES 2890 28-11-97
is
dropped
elongation for
a
across
the
responses
command
basolateral
of
these
potential
Rb /Ra
of
membrane
OHCs 100
is
quite
mV,
when
can also be calculated
138
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139
using the data of Kros et al. (1992) for the mechanoelectrical transducer conductance of OHCs of the cultured mouse cochlea (we use a value 8 nS for the total transducer conductance in our calculations) and for the part of the conductance activated at the rest (8% of the maximal value). The speci¢c conductance of the OHC's membrane can be obtained from the data of Housley and Ashmore (1992). In this case the resistance of the cell's apical pole Ra consists of the mechanoelectrical transducer resistance Rtr and the resistance of the apical membrane Rc connected in parallel (see insertion in Fig. 1). These two resistances are connected in series with the basolateral membrane resistance Rb . This way of estimating Rb/Ra provides slightly larger values of 1/ 17^1/15 for the ratio for the OHCs illustrated in Figs. 3 and 4. However, even in this case, the actual voltage change across the basolateral membrane is only about 6^7 mV for a 100 mV command voltage. The electrical circuit in Fig. 1, together with Eq. (1), can be used to provide estimates of the voltage sensitivity of the transducer. Let us assume that, for zero command voltage, the mechanoelectrical transducer is approximated by the resting transducer conductance (Kros et al., 1992) and that elongation of the OHC when the inside of the microchamber is positive is due also to the voltage sensitivity of the mechanoelectrical transducer. Then, for the three OHCs shown in Figs. 3 and 4, the mechanoelectrical transducer conductance would have increased by 0.6, 0.9 and 0.3 nS respectively for a command voltage of 100 mV, which is equivalent to depolarizing the apical membrane by about 5 mV. According to Kros et al. (1992) the mechano-sensitivity of the mechanoelectrical transducer to small displacements of the hair bundle from the resting position is 0.03 nS/ nm. Therefore, a 5 mV depolarization of the apical membrane is equivalent to an excitatory displacement of 0.5^1.5 nm for the hair bundles of the OHCs shown in Figs. 3 and 4.
the OHC electromotility, which were measured in the solution containing 1.3 mM Ca2 , may be more pronounced in situ where the Ca2 concentration of the endolymph is only 20 WM (Boscher and Warren, 1978). Hair cell depolarization also leads to the displacement of the hair bundles of frog and turtle hair cells (Crawford and Fettiplace, 1985; Assad et al., 1989; Crawford et al., 1989; Assad et al., 1991). This displacement was proposed (Assad et al., 1989) to represent a transition of the hair bundle to another resting position corresponding to an increased number of open transducer channels. However, voltage-dependent displacement of OHC bundles has yet to be observed. Passive displacement of the OHC hair bundles has been observed both in single hair cells and in isolated preparations of the organ of Corti as a result of an active tilting of the hair cell's cuticular plate during exposure to alternating external electrical ¢elds (Zenner et al., 1988; Reuter and Zenner, 1990). Therefore, the angular rotation of the OHCs hair bundles and tension in the gating springs in vivo may be governed by the shear motion of the reticular lamina and tectorial membrane, by the voltage dependence of the OHC mechanoelectrical transducer and, possibly (but see Holley, 1996) by the tilting of the cuticular plate. The co-operative outcome of these e¡ects on the angular rotation of the hair bundle will establish the actual state of the mechanoelectrical transducer and, accordingly, the receptor potential and the electromotile response of the OHC in vivo. The experiments of Russell and Koëssl (1991) can give an idea of complexity of this interaction. These authors observed voltage-dependent shifts of the IHC and OHC mechanoelectrical transducer functions in vivo which cannot be explained either by voltage dependence of the mechanoelectrical transducer (Assad et al., 1989; Crawford et al., 1989; Kros et al., 1993) or by tilting of the cuticular plate (Zenner et al., 1988; Reuter and Zenner, 1990).
4.1. Functional signi¢cance of the voltage dependence in vivo
4.2. Voltage dependence and cochlear non-linearity
The voltage dependence of the mechanoelectrical transducer has been described for di¡erent types of hair cells. Depolarization increased the number of open transducer channels for hair cells in the turtle cochlea (Crawford et al., 1989), the bullfrog vestibular system (Assad et al., 1989) and OHCs of the mouse cochlea (Kros et al., 1993) thus leading to a shift of the mechanoelectrical transducer function to the left along the axes of displacements. Voltage induced shifts of the transducer function depend strongly on the concentration of extracellular Ca2 (Hacohen et al., 1989; Crawford et al., 1991) around the apical pole of the hair cell and become more pronounced when the Ca2 concentration is lowered. Thus, the voltage dependence of
Patuzzi et al. (1989) and Santos-Sacchi (1993) proposed that the mechanoelectrical transducer function generates a dominant non-linearity which could distort the OHC's electromotility in vivo. Experimental and model investigations have con¢rmed that the non-linearity of the hair cell mechanoelectrical transducer can give rise to non-linear phenomena, such as distortion products and two-tone suppression with patterns similar to those which have been recorded from the peripheral auditory system (Weiss and Leong, 1985; Frank and Koëssl, 1996; Lukashkin and Russell, 1997). It is known that non-linear systems can change their behavior crucially with slight changes in their parameters (e.g. see Andronov et al., 1966). For example, slight changes of the mechanoelectrical transducer operating point, i.e.
HEARES 2890 28-11-97
A.N. Lukashkin, I.J. Russell / Hearing Research 113 (1997) 133^139 shift
the
mechanoelectrical
transducer
function
along
the axes of displacements for several nanometers, could modify the pattern of the distortion products and twotone suppression (Weiss and Leong, 1985 ; Frank and
139
Evans, B.N., Dallos, P., 1993. Stereocilia displacement induced somatic motility of cochlear outer hair cells. Proc. Natl. Acad. Sci. USA 90, 8347^8351. Frank, G., Ko ë ssl, M., 1996. The acoustic two tone distortions 2f1-f2 and f2-f1 and their possible relation to changes in the gain and the
Ko ë ssl, 1996 ; Lukashkin and Russell, 1997). On the oth-
operating point of the cochlear ampli¢er. Hear. Res. 98, 104^115.
er hand, hair cell depolarization a¡ects not only the
Hacohen, N., Assad, J.A., Smith, W.J., Corey, D.P., 1989. Regulation
mechanoelectrical channels are
transducer
open at
rest)
operating
but also
point
other
(more
transducer
parameters (Assad et al., 1989 ; Crawford et al., 1989 ; Kros et al., 1993). Therefore, the voltage dependence of the mechanoelectrical transducer is one of the factors which determine the speci¢c type of non-linearity of the cell's mechanical response and, consequently, the speci¢c type of active non-linear cochlear function.
of tension on hair-cell transduction channels : displacement and calcium dependence. J. Neurosci. 9, 3988^3997. Hallworth, R., Evans, B.N., Dallos, P., 1993. The location and mechanism of electromotility in guinea pig outer hair cells. J. Neurophysiol. 70, 549^558. Holley, M.C., 1996. Outer hair cell motility. In : Dallos, P., Popper, A.N., Fay, R.B. (Eds.), The Cochlea. Springer, New York, p. 421. Housley, G.D., Ashmore, J.F., 1992. Ionic currents of outer hair cells isolated from the guinea-pig cochlea. J. Physiol. (London) 448, 73^98. Howard, J., Hudspeth, A.J., 1988. Compliance of the hair bundle associated with gating of mechanoelectrical transduction channels
Acknowledgments
in the bullfrog's saccular hair cell. Neuron 1, 189^199. Kroese, A.B.A., Das, A., Hudspeth, A.J., 1989. Blockage of the trans-
This work was supported by the MRC. A.N.L. is a Wellcome Prize Research Student. The authors thank
duction channels of hair cells in the bullfrog's sacculus by aminoglycoside antibiotics. Hear. Res. 37, 203^218. Kros,
C.J.,
Ru ë sch,
A.,
Lennan,
G.W.T.,
Richardson,
G.P.,
1993.
James Hartley for designing and constructing the elec-
Voltage dependence of transducer currents in outer hair cells of
tronic
neonatal mice. In : Duifhuis, H., Horst, J.W., van Dijk, P., van
equipment
and
Matthew
Holley
and
Guy
Ri-
chardson for their critical reading of early versions of
Netten, S.M. (Eds.),
Biophysics of
Hair
Cell
Sensory Systems.
World Scienti¢c, Singapore, pp. 141^150.
this manuscript.
Kros, C.J., Ru ë sch, A., Richardson, G.P., 1992. Mechano-electrical transducer currents in hair cells of the cultured neonatal mouse
References
cochlea. Proc. Roy. Soc. London B 249, 185^193. Lukashkin, A.N., Russell, I.J., 1997. The receptor potential non-line-
Andronov, A.A., Vitt, A.A., Khaikin, S.E., 1966. Theory of Oscilla-
arities generated by the mechanoelectrical transducer to two-tone stimulation.
tors. Pergamon Press, Oxford. Ashmore, J.F., 1987. A fast motile response in guinea-pig outer hair cells : the cellular basis of the cochlear ampli¢er. J. Physiol. (Lon-
In :
Lewis,
E.R.,
Long,
G.R.,
Leake,
P.A.,
Steele,
C.R. (Eds.), Diversity in Auditory Mechanics. World Scienti¢c, Singapore, 587^593. Patuzzi, R.B., Yates, G.K., Johnstone, B.M., 1989. Outer hair cell
don) 338, 323^347. Ashmore, J.F., Meech, R.W., 1986. Ionic basis of membrane potential in outer hair cells of guinea pig cochlea. Nature 322, 368^371.
receptor current and sensorineural hearing loss. Hear. Res. 42, 47^72.
Assad, J.A., Hacohen, N., Corey, D.P., 1989. Voltage dependence of
Reuter, G., Zenner, H.P., 1990. Active radial and transverse motile
adaptation and active bundle movement in bullfrog saccular hair
responses of outer hair cells in the organ of Corti. Hair. Res. 43, 219^230.
cells. Proc. Natl. Acad. Sci. USA 86, 2918^2922. Assad, J.A., Shepherd, G.M.G., Corey, D.P., 1991. Tip-link integrity
Russell, I.J., Ko ë ssl, M., 1991. The voltage responses of hair cells in
and mechanical transduction in vertebrate hair cells. Neuron 7,
the basal turn of the guinea-pig cochlea. J. Physiol. (London) 435, 493^511.
985^994. Boscher, S.K., Warren, R.L., 1978. Very low calcium content of cochlear endolymph, an extracellular £uid. Nature 273, 377^378. Brownell, W.E., Bader, C.R., Bertrand, D., de Ribaupierre, Y., 1985. Evoked mechanical responses of isolated cochlear hair cells. Sci-
Santos-Sacchi, J., 1989. Asymmetry in voltage-dependent movements of isolated outer hair cells from the organ of Corti. J. Neurosci. 9, 2954^2962. Santos-Sacchi, J., 1992. On the frequency limit and phase of outer hair cell motility : e¡ects of the membrane ¢lter. J. Neurosci. 12,
ence 227, 194^196. Crawford, A.C., Fettiplace, R., 1985. The mechanical properties of ciliary bundles of turtle cochlear hair cells. J. Physiol. (London)
1906^1916. Santos-Sacchi, J., 1993. Harmonics of outer hair cell motility. Biophysical J. 65, 2217^2227.
364, 359^379. Crawford, A.C., Evans, M.G., Fettiplace, R., 1989. Activation and adaptation of transducer currents in turtle hair cells. J. Physiol.
Santos-Sacchi, J., Dilger, J.P., 1988. Whole cell currents and mechanical responses of isolated outer hair cells. Hear. Res. 35, 143^150. Spoendlin, H., 1988. Neural anatomy of the inner ear. In : Jahn, A.F.,
(London) 419, 405^434. Crawford, A.C., Evans, M.G., Fettiplace, R., 1991. The actions of calcium on the mechano-electrical transducer current of turtle hair
Santos-Sacchi, J. (Eds.), Physiology of the Ear. Raven Press, New York, pp. 201^219. Weiss, T.F., Leong, R., 1985. A model for signal transmission in an
cells. J. Physiol. (London) 434, 369^398. Davis, H., 1983. An active process in cochlear mechanics. Hear. Res.
ear having hair cells with free-standing stereocilia. IV. Mechanoelectric transduction stage. Hear. Res. 20, 175^195.
9, 79^90. Evans, B.N., Dallos, P., Hallworth, R., 1989. Asymmetries in motile
Zenner, H.P., Zimmermann, R., Gitter, A.H., 1988. Active move-
responses of outer hair cells in simulated in vivo conditions. In :
ments of the cuticular plate induce sensory hair motion in mam-
Kemp, D., Wilson, J.P. (Eds.), Cochlear Mechanisms : Structure, Function and Models. Plenum Press, New York, pp. 205^206. Evans, B.N., Hallworth, R., Dallos, P., 1991. Outer hair cell electromotility : the sensitivity and vulnerability of the DC component.
malian outer hair cells. Hear. Res. 34, 233^240. Zhang, M., Evans, B.N., Dallos, P., 1997. Voltage-dependent ciliary sti¡ness in cochlear outer hair cell. Abstr. Assoc. Res. Otolaryngol. 20, 64.
Hear. Res. 52, 288^304.
HEARES 2890 28-11-97