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The Journal of Neuroscience, July 15, 1998, 18(14):5136-5150
Electrophysiological Characterization of a Putative Supporting
Cell Isolated from the Frog Taste Disk
Albertino
Bigiani1,
Andrea
Sbarbati2,
Francesco
Osculati2, and
Pierangelo
Pietra1
1 Dipartimento di Scienze Biomediche, Sezione di
Fisiologia, Università di Modena, 41100 Modena, Italy, and
2 Istituto di Anatomia ed Istologia, Università di
Verona, 37134 Verona, Italy
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ABSTRACT |
Chemosensory cells in vertebrate taste organs have two obvious
specializations: an apical membrane with access to the tastants occurring in food, and synapses with sensory axons. In many species, however, certain differentiated taste cells have access to the tastants
but lack any synaptic contacts with axons, and a supportive rather than
chemosensory function has been attributed to them. Until now, no
functional data are available for these taste cells. To begin to
understand their role in taste organ physiology, we have characterized
with patch-clamp recording techniques the electrophysiological properties of a putative supporting cell the so-called wing
cellisolated from frog taste disks. Wing cells were distinguished
from chemosensory elements by the presence of a typical, sheet-like
apical process. Their resting potential was approximately  52 mV, and
the average input resistance was 4.8 G . Wing cells possessed
voltage-gated Na+ currents sensitive to TTX, and an
inactivating, voltage-gated K+ current sensitive to
TEA. Current injections elicited single action potentials but not
repetitive firing. We found no evidence for voltage-gated
Ca2+ currents under various experimental conditions.
Amiloride-sensitive Na+ channels, thought to be
involved in Na+ chemotransduction, were present in
wing cells. Many of the membrane properties of wing cells have been
also reported for chemosensory taste cells. The presence of ion
channels in wing cells might be suggestive of a role in controlling the
microenvironment inside the taste organs or the functioning of
chemosensory cells or both. In addition, they might participate
directly in the sensory transduction events by allowing loop currents
to flow inside the taste organs during chemostimulation.
Key words:
frog; supporting cell; wing cell; gustatory; patch clamp; voltage-gated channel; amiloride-sensitive Na channel
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INTRODUCTION |
Taste buds are the peripheral
detectors of chemicals occurring in food. These pear-shaped sensory
organs are made up of ~100 specialized epithelial cells called taste
cells. On the basis of their structural features, taste cells have been
divided into several categories, such as elongated cells (Type I, Type
II, Type III) and basal cells (stem cells, Merkel-like cells) (for review, see Roper, 1989 ; Lindemann, 1996). Elongated cells reach the
apex of taste buds (taste pore) where interaction with chemical stimuli
occurs. Therefore, they are thought to be involved in the initial
events of gustatory chemotransduction. On the contrary, basal cells lie
at the bottom of the sensory organ without sending processes to the
taste pore. Because sensory information needs to be transferred to
afferent nerve fibers to reach the brain, taste chemosensory cells
should present synaptic contacts with axons (Lindemann, 1996). However,
in many vertebrate species (including mammals), not all elongated cells
form synapses. This morphological observation has led to postulation of
the existence of supporting (nonsensory) cells in taste buds (for
review, see Roper, 1989; Lindemann, 1996). Putative supporting cells
are considered secretory elements lacking specialized contacts with
axons. Until now, information on the membrane properties of these
cells, which could help to define their role in taste bud physiology,
is not available, whereas a great deal of information about the
electrophysiological properties of chemosensory cells has been obtained
by applying the patch-clamp technique to taste cells identified with
morphological techniques (Avenet and Lindemann, 1987; McPheeters et
al., 1994; Bigiani et al., 1996).
We have examined the question of the membrane properties of taste
supporting cells by applying the patch-clamp technique to cells
isolated from frog taste organs. In this amphibian, taste cells are
clustered in quite large structures called taste disks. Frog taste
disks contain all the main morphotypes of taste cells described in
vertebrates, and their ultrastructure is well documented (for review,
see Osculati and Sbarbati, 1995). We have focused our attention on a
cell type termed wing cell (Jaeger and Hillman, 1976; Richter et al.,
1988; Osculati and Sbarbati, 1995). Wing cells (also termed Type I
cells) are differentiated cells that lack any obvious synaptic contacts
with afferent axons (for review, see Osculati and Sbarbati, 1995). Wing
cells possess a sheet-like process that reaches the free surface of the
taste disk, and therefore they can be readily identified after
isolation and distinguished from chemosensory cells, which present a
rod-like apical process (Avenet and Lindemann, 1987; Richter et al.,
1988). This paper describes the membrane properties of wing cells and
compares these properties with those from chemosensitive rod cells
(Avenet and Lindemann, 1987, 1988; Miyamoto et al., 1991).
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MATERIALS AND METHODS |
Isolation of taste cells. Frogs of the species
Rana esculenta (complex) were obtained from commercial
suppliers and maintained in the laboratory at ~10°C with access to
tap water. Animals were decapitated and pithed, and their tongues were
removed. In frogs, taste cells are clustered in taste disks located at
the top of fungiform papillae (Jaeger and Hillman, 1976). Isolated
taste disks were obtained by cutting the stem of fungiform papillae with fine scissors under a dissection microscope. From one tongue, ~150 fungiform papillae were cut off and then washed in an amphibian physiological solution (APS) containing (in mM): 110 NaCl,
2 KCl, 2 CaCl2, 1 MgCl2, 20 glucose, 10 HEPES, buffered to pH 7.2 with NaOH. Isolated taste cells
were obtained by applying an enzymatic-mechanical treatment to
dissociated fungiform papillae, as described previously (Fujiyama et
al., 1993, 1994; Okada et al., 1994). Briefly, 1 mg/ml papain (Sigma,
St. Louis, MO) was added to a divalent ion-free APS containing 2 mM EDTA and 1 mg/ml L-cysteine, and the
solution was left at 23°C for 10 min to activate papain. The
fungiform papillae were rinsed in divalent ion-free APS containing 2 mM EDTA for 10 min and then incubated at 23°C for 10 min
in the activated papain solution. After enzymatic treatment, fungiform
papillae were rinsed twice with standard APS and transferred (~10
taste disks at a time) into the recording chamber (a standard glass slide onto which a silicone ring of 1-2 mm thickness and 15 mm inner
diameter was pressed). Individual taste cells were obtained by gentle
trituration with a glass pipette having an opening of ~100 µm.
Dissociated cells were left to settle to the bottom of the recording
chamber, which was treated previously with Cell-Tak (~3
µg/cm2; Collaborative Research, Bedford, MA) to
improve adherence of isolated cells to the glass slide. The chamber was
placed on the stage of an upright Olympus microscope (model BHWI
equipped with a 40× water-immersion objective, working distance = 3.1 mm), and taste cells were viewed with Nomarsky optics at 750×.
During the experiments, the chamber was continuously perfused with APS
(flow rate: 2-3 ml/min) by means of a gravity-driven system.
Recording techniques. In the majority of experiments,
membrane ionic currents were monitored in taste cells using whole-cell configuration of the patch-clamp technique (Hamill et al., 1981). For
testing voltage-gated Ca2+ currents, we used also
the nystatin-perforated patch recording (Horn and Marty, 1988; Korn et
al., 1991). This configuration of the patch-clamp technique allows
whole-cell membrane currents to be recorded in the virtual absence of
washout and with little disruption of endogenous cellular
Ca2+ buffering mechanisms that may be involved in
the rundown of Ca2+ currents (Belles et al., 1988;
Korn and Horn, 1989). Patch pipettes were made from soda lime glass
capillaries (Baxter Scientific Products, McGaw Park, IL) on a two-stage
vertical puller (model PB-7; Narishige, Tokyo, Japan). Pipette
resistance, when filled with standard intracellular solution, was
typically in the 4-8 M range. Cell-attached seal resistances were
in the range of 5-30 G with both types of recording configurations.
In some experiments, patch pipettes were coated with Sylgard (Dow
Corning, Midland, MI) to reduce stray capacitance.
Whole-cell membrane currents were recorded at room temperature
(20-22°C) using an Axopatch amplifier (model 1D; Axon Instruments, Foster City, CA). Signals were recorded and analyzed using a 486-based computer equipped with a Digidata 1200 data acquisition system and
pCLAMP software (Axon Instruments). Signal filtering and digitization were adjusted according to the specific features of the membrane currents. For voltage-gated currents, signals were prefiltered at 5 kHz
and digitally recorded at 25 µsec intervals; for amiloride-sensitive currents, signals were usually prefiltered at 200-500 Hz and digitized at 3-10 msec intervals.
The access resistance of the patch pipette tip was estimated by
dividing the amplitude of the voltage steps by the peak of the
capacitive transients (from which stray capacitance had been subtracted). In whole-cell configuration, values typically ranged from
~10 to 25 M. In perforated-patch configuration, after obtaining the high-resistance seal, access resistance was monitored periodically to check the diffusion of nystatin into the cell membrane. Access to
the cell interior was judged by the first appearance of a transient capacitive transient (Horn and Marty, 1988). We usually began our
experiments when the access resistance dropped to <50 M.
As a rule, we adjusted the pipette potential for zero-current flow
before establishing a seal: this zero-current potential was the
reference for subsequent measurements. Because pipette and bath
contained different solutions, a liquid junction potential (LJP)
developed at the tip of the pipette (for review, see Barry and Lynch,
1991). This potential, measured as described by Neher (1992), was ~5
mV (pipette solution negative) with the pipette solutions used in
whole-cell recordings, and ~7 mV with the pipette solution used in
perforated-patch recording. All data have been corrected for these
LJPs.
Solutions for electrophysiology. Our standard bathing medium
was the APS. Drugs were dissolved in standard or modified APS solutions
and bath-applied. Gravity-fed test solutions were controlled by
multisolenoid manifold valves (General Valve Corp., Fairfield, NJ) and
introduced through a common inlet into the recording chamber. To reveal
voltage-gated Ca2+ currents, we used the following
bath solution (concentrations in mM): 25 BaCl2, 80 TEACl, 0.001 tetrodotoxin (TTX), 20 glucose, 10 HEPES, buffered to pH 7.2 with TEAOH. Two different pipette solutions were used, depending on the configuration of the patch-clamp recording. For whole-cell recording, the pipette solution contained (in
mM): 105 KCl, 2 MgCl2, 5 EGTA, 10 HEPES,
buffered to pH 7.2 with KOH. In some experiments, KCl was replaced by
an equal concentration of CsCl, and the solution was buffered to pH 7.2 with CsOH. For perforated-patch recording, nystatin was dissolved in
dimethyl sulfoxide (DMSO) with constant stirring to yield a stock
solution of 50 mg/ml. The nystatin stock solution was prepared fresh
for each experiment. Nystatin was added to a pipette solution
consisting of (in mM): 55 CsCl, 25 Cs2SO4, 8 MgCl2, 10 HEPES, buffered to pH 7.2 with CsOH, to give a final nystatin
concentration of 250 µg/ml. The tip of the patch pipette was filled
with nystatin-free solution and backfilled with nystatin solution. All
chemicals were from Sigma, except TTX (Affinity, Nottingham, UK).
Scanning electron microscopy. After electrophysiological
recording, some wing cells were processed with standard protocols (Zancanaro et al., 1990) for observation with a scanning electron microscope. Briefly, isolated cells were fixed in the recording chamber
with 2.5% glutaraldehyde (BDH, Poole, England) in 0.1 M
sodium cacodylate buffer (SCB) at pH 7.2 for ~20 min. During this
period, patch pipette was left on the cell to avoid detachment of the
isolated cell from the bottom of the recording chamber. In whole-cell
recording, progress of fixation could be monitored by observing the
disappearance of voltage-gated currents: the patch pipette was
thereafter removed, leaving the recorded cell attached to the glass
slides. At this stage, cells were photographed for later identification
at the electron microscope. Slides were stored overnight in fixative at
4°C. Specimens were then rinsed with 0.1 M phosphate
buffer, pH 7.2, and processed for electron microscopic observations: to
this end, cells were post-fixed in 1% OsO4 in SCB for 1 hr, rinsed with distilled water, dehydrated through a graded ethanol
series, critical-point dried, and finally coated with gold. Specimens
were observed under a Zeiss 950 scanning electron microscope. To
relocate wing cells, light and electron micrographs were matched to
identify the recorded cells unequivocally.
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RESULTS |
Identification of isolated supporting (wing) cells
Frog taste disks contain elongated cells (classified as Type I,
Type II, and Type III cells) and basal cells (for review, see Osculati
and Sbarbati, 1995). Wing cells (Type I cells) possess one apical
sheet-like process reaching the free surface of the taste organ. The
apical process characterizes these cells, and we used it as a
morphological marker. In fact, after the papain-low Ca treatment, wing
cells could be readily identified by the presence of their typical
process (Fig. 1A),
whereas other isolated taste cells, such as those with a rod-like
apical process (Type II and Type III, which are considered to be
chemosensory) (Avenet and Lindemann, 1987; Richter et al., 1988;
Osculati and Sbarbati, 1995), could be easily distinguished from wing
cells (Fig. 1B). Under our experimental conditions,
wing cells retained their typical morphology after isolation and
plating on the glass slide. Some wing cells were fixed after patch
recordings and processed for scanning electron microscopy to further
confirm their identity. Figure 2 shows an
electron micrograph of the wing cell shown in Figure 1. It can be noted
that the wide apical process presents several plasmalemmal pits and
ridges that may represent the contact points with adjacent cells in the
intact taste disk (Osculati and Sbarbati, 1995). In this study, we
present data obtained from 137 unambiguously identified wing cells.
Just for the purpose of comparison, we also report data obtained from
26 rod cells (i.e., the chemosensory cells according to Avenet and
Lindemann, 1987; Richter et al., 1988; Osculati and Sbarbati, 1995). A
detailed analysis of membrane properties of rod cells is included in
published reports (Avenet and Lindemann, 1987, 1988; Miyamoto et al.,
1988, 1991).
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Figure 1.
Differential interference contrast
photomicrographs of living taste cells isolated from the frog taste
disk. A, A wing (supporting) cell characterized by its
wide, sheet-like apical process. B, A chemosensory cell
characterized by the rod-like apical process. Scale bar, 5 µm.
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Figure 2.
Whole-cell currents recorded from the wing cell
shown in Figure 1A. The cell membrane was held at
85 mV and stepped in 10 mV increments from 75 to +45 mV.
Capacitative and leakage currents were not subtracted from the records.
Bath perfusion was APS; pipette solution was standard 105 mM KCl. After recording and adequate processing, this cell
was observed at the scanning electron microscope to confirm its
identity. From the photomicrograph on the right it is possible to
recognize readily the typical wide process that characterizes wing
cells. Scale bar, 5 µm.
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Passive membrane properties
After the patch was broken and whole-cell recordings were
established, wing cells had a zero-current voltage
(V0, assumed to be an estimation of the
cell resting potential) of 52 ± 6 mV (mean ± SD; range
41 mV to 61 mV; n = 19) when normal APS was used in
the bath and the pipette filling solution contained 105 mM
KCl. Changes in V0 during recordings were
frequently observed and were probably related to variations in the
pipette-membrane seal resistance (Barry and Lynch, 1991). Under the
same conditions, V0 of rod cells was 58 ± 8 (mean ± SD; range 48 mV to 74 mV; n = 8), which was significantly different (t test;
p = 0.03) from that of wing cells. We are unsure of the
physiological relevance of this significance given the high values for
the input resistance (Rin) of isolated
taste cells. As reviewed recently by Barry and Lynch (1991), the
patch-clamp technique has limitations in both cell-attached and
whole-cell modes when cells with Rin in the gigaohm range are studied. Patch-clamp measurements of
V0 may require significant corrections;
otherwise they could lead to erroneous conclusions (Bigiani et al.,
1996). Cell membrane capacitance (Cm) was
significantly larger in wing cells (20.0 ± 4.0 pF, mean ± SD; range 12.9 pF to 28.6 pF; n = 28) than in rod cells
(6.0 ± 2.2, mean ± SD; range 2.9 pF to 8.8 pF;
n = 11). This is consistent with differences in
membrane surface area of the apical processes between wing and rod
cells. The somata of these cell types were of similar dimensions (Fig.
1). Finally, input resistance (Rin) of
wing cells evaluated as slope resistance of the current-voltage (I-V) relationship at a holding potential
of 85 mV was 4.8 ± 2.3 G (mean ± SD; range 1.2 G to
10.1 G; n = 30), quite similar (t test;
p = 0.29) to that measured in rod cells (4.1 ± 2.2 G, mean ± SD; range 1.2 G to 9.9 G;
n = 19). Rin is usually taken as
an estimation of the cell membrane resistance in patch-clamp studies,
and the values we reported are in the range of those obtained for taste
cells of other vertebrates (Kinnamon and Roper, 1988; Spielman et al.,
1989; Akabas et al., 1990; Béhé et al., 1990; Sugimoto and
Teeter, 1990; Bigiani and Roper, 1993; Chen et al., 1996; Miyamoto
et al., 1996).
Membrane currents under voltage clamp
The presence of voltage-gated ion channels in wing cells was
investigated by recording membrane currents elicited by voltage steps
from a holding potential of 85 mV. This value was chosen as standard
reference potential to compare membrane currents from different taste
cells. With normal APS in the bath and the pipette filling solution
containing 105 mM KCl, depolarizing voltage pulses elicited
the current time courses shown in Figure 2. After an early capacitive
transient, current showed a fast inward transient (plotted downward)
followed by a pronounced outward trace, which developed more slowly and
inactivated partially at positive voltages. These currents were
observed in all wing cells that we tested under the above ionic
conditions (n = 64), although their intensity varied
from cell to cell (see below).
Voltage-gated Na+ currents
The transient inward current was blocked reversibly by 0.5 µM TTX (Fig. 3A)
and disappeared when choline or
N-methyl-D-glucamine (NMDG) replaced
Na+ in the bath (data not shown): in short, it was a
Na+ current. Properties of this current were
additionally studied by replacing KCl of the pipette solution with CsCl
to eliminate outward currents. With good space-clamp conditions,
thresholds for Na+ current activation ranged from
45 to 35 mV. The peak current was reached between 15 and 5 mV
and averaged 750.7 ± 301.5 pA (mean ± SD; range 355.2
to 1416.2 pA; n = 22). Figure 3B shows a
typical example of the voltage dependence of these
Na+ currents. The I-V
relationship for voltage-gated Na+ current in wing
cells resembled that obtained from rod cells of the frog (Avenet and
Lindemann, 1987; Miyamoto et al., 1988, 1991) as well as of taste cells
from other vertebrate species (Kinnamon and Roper, 1988; Akabas et al.,
1990; Béhé et al., 1990; Sugimoto and Teeter, 1990; Herness
and Sun, 1995).
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Figure 3.
Voltage-gated Na+ currents in
wing cells. A, Whole-cell currents elicited in an
isolated wing cell by a series of depolarizing pulses between 75 and
+35 mV, in 10 mV increments, from a holding potential of 85 mV.
During bath perfusion with 0.5 µM TTX, the transient
inward current was completely blocked, indicating that it was a
Na+ current. Im,
Membrane currents. Capacitative and leakage currents were not
subtracted from the records. Pipette solution was standard 105 mM KCl. B, A family of
Na+ currents recorded from an isolated wing cell.
Currents (Im) were elicited by
stepping the membrane held at 85 mV from 75 to +85 mV in 10 mV
increments. Capacitative and leakage currents were subtracted from the
records. Bath, APS; pipette solution, standard 105 mM CsCl.
Current-voltage relationship for the peak transient inward current
reveals that voltage-gated Na+ current activated at
approximately 40 mV and reached a maximum value at approximately 15
mV in this wing cell.
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To study the voltage-dependence of the steady-state inactivation, the
largest peak current (I), as obtained with pulsed
depolarization from different holding potentials
(Vh, at which cells were held for 10 sec), was normalized to Imax, measured at
a holding potential of 105 mV. The plot of
I/Imax as a function of
Vh resulted in a sigmoid curve (Fig.
4A) that could be
fitted by the equation I/Imax = 1/{1 + exp [(V V0.5)/k]}, where
V0.5 is the membrane potential at which the current is 50%
inactivated, and k the slope. The value for the
half-inactivation voltage was 70.7 mV and k was 6.8 mV
(Fig. 4A) (pooled data from seven cells). We recall that according to Avenet and Lindemann (1987), inactivation was half-maximal at 67 mV in rod taste cells of the frog, whereas Herness
and Sun (1995) reported a V0.5 of 65 mV and a
k of 6.4 mV for rat taste cells.
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Figure 4.
Properties of the inactivation of voltage-gated
Na+ currents in wing cells. A,
Voltage-dependence of the steady-state inactivation. Maximal peak
inward Na+ currents recorded after holding the
membrane for 10 sec at 105, 95, 85, 75, and 65 mV
(Vh). Note that the
Na+ currents decreased at less negative potentials
(inactivation). Capacitative and leakage currents were subtracted from
the records. Bath solution, APS; pipette solution, standard 105 mM CsCl. In the steady-state inactivation-voltage
relationship (bottom), the maximal peak
Na+ currents (I)
obtained for holding potentials between 105 and 45 mV were
normalized with respect to that obtained with
Vh = 105 mV
(Imax), and then plotted against the
holding potential. Each point represents the mean ± SD of two to
seven values from seven wing cells. Data were fitted by a sigmoid
curve. The calculated half-maximal voltage
(V0.5) was 70.7 mV, and the slope
was 6.8 mV. B, Recovery from inactivation for
voltage-gated Na+ currents at 85 mV.
Na+ currents were elicited with a two-pulse
protocol. The first 20 msec pulse moved the voltage from a holding
potential of 85 to 15 mV. After a variable delay spent at 85 mV,
a second 20 msec pulse of the same amplitude was applied to the cell
membrane and the current was recorded. Current elicited by the second
pulse was measured and normalized to the first preceding pulse and
plotted against the interpulse interval. Data points could be fitted
approximately by a single exponential function with a time constant of
18.6 msec for the cell shown here.
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Recovery from inactivation was measured with a two-pulse protocol
(Hille, 1992). The first pulse moved the voltage from 85 to 15 mV,
causing activation followed by full inactivation of the
Na+ channels. A second pulse, of the same amplitude,
was applied after a variable delay (t) spent at 85 mV
(Fig. 4B). At this voltage, recovery from
inactivation was approximately described by an exponential function,
[1 exp(t/ )], with a time constant () of
15.5 ± 5.6 msec (mean ± SD; n = 4). This
value is in good agreement with the time constants observed in frog
chemosensory cells [15.6 msec (Avenet and Lindemann, 1987) and 9.7 msec (Miyamoto et al., 1991)].
Voltage-gated K+ currents
The outward currents that remained after the voltage-gated
Na+ current was blocked with TTX (Fig.
3A) were carried by potassium ions, as indicated by their
sensitivity to TEA (Fig. 5A)
and by their reduction when CsCl was used instead of KCl in the pipette solution (Fig. 3B). K+ current
inactivated over time and was voltage-dependent, as indicated by the
I-V curve in Figure 5B. This curve
shows that the current begins activating at potentials above 40 mV,
whereas at potential values ranging from 40 to +10 mV, current
increases almost linearly and reaches a plateau at a membrane
depolarization >10-20 mV. Finally, its magnitude decreases by further
depolarization (Fig. 5B). This behavior suggests possible
involvement of a Ca2+-activated
K+ current. Indeed, the I-V
curve seemed to show initial features of the "N" shape
characteristic of these currents (Hille, 1992). We assessed whether
this was the case by adding to the bath 10 mM
Co2+, a known Ca+ channel blocker
(Hagiwara and Byerly, 1981). Under this condition there was a reduction
of K+ currents at a given membrane potential, but
the overall shape of the I-V curve did not
change (Fig. 6). This suggests that in the presence of Co2+, the threshold for outward
current activation was shifted in a positive direction, presumably
because of the effect of the high concentration of divalent cations on
the external surface charge of the membrane (Hille, 1992). We found no
compelling evidence for a Ca-mediated K+
conductance. Furthermore, as will be shown below, there is no evidence
for voltage-gated Ca2+ currents.
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Figure 5.
Voltage-gated K+ currents in
wing cells. A, TEA sensitivity of the outward currents
recorded from an isolated wing cell. Voltage-gated
Na+ currents were blocked by adding 0.5 µM TTX to all solutions. Membrane currents
(Im) were elicited by a series of
depolarizing pulses between 75 and +35 mV, in 10 mV increments, from
a holding potential of 85 mV. Capacitative and leakage currents were
subtracted from the records. Outward currents recorded in regular APS
(control, top) were totally abolished by
5 mM TEA (middle). The effect was
reversible, as indicated by the recovery of the currents during washout
(bottom). Pipette solution was standard 105 mM KCl. B, Voltage-dependence of
K+ currents recorded from an isolated wing cell. A
family of currents (Im) was elicited
by stepping the cell membrane, held at 85 mV, from 75 to +45 mV in
10 mV increments. Capacitative and leakage currents were subtracted
from the records. Bath perfusion was APS + 0.2 µM TTX to
block voltage-gated Na+ currents. Pipette solution
was standard 105 mM KCl. In the
I-V plot, both the peak value ( ) and
the value measured at the end of the voltage pulse ( ) are shown. It
can be noted that the peak current after reaching a maximal value
between approximately 20 and 40 mV decreases with further
depolarization.
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Figure 6.
Effect of Co2+ on the
voltage-gated K+ currents recorded from an isolated
wing cell. A, Sample currents elicited by a series of
depolarizing voltage pulses from a holding potential of 85 mV when
the cell was bathed in regular APS (top) and in the
presence of 10 mM Co2+
(bottom). TTX (0.5 µM) was added to all
bath solutions to block voltage-gated Na+ channels.
Pipette solution was standard 105 mM KCl. Capacitative and
leakage currents were not subtracted from the records.
B, I-V plots for the peak
value (circles) and the value at the end of the voltage
pulses (squares) of the outward current elicited in
regular APS (filled symbols) and during
Co2+ application (open symbols).
Co2+ caused the I-V
relationship to shift in a positive direction.
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In regular APS, the K+ current reached a peak
between 20 and 60 mV and averaged 645.0 ± 269.9 pA (mean ± SD; range 315 to 1334.4 pA; n = 24). During a prolonged
depolarization (200 msec), the K+ current displayed
a strong inactivation. Figure
7A shows an example of the
K+ current elicited in a wing cell by stepping the
membrane to +15 mV from a holding potential of 85 mV: at this
voltage, the time course of inactivation could be fitted with a single
exponential function with a time constant of 24.7 ± 2.5 msec
(mean ± SD; n = 3), which is consistent with the
presence of a single channel type. Finally, inactivation of these
currents was voltage dependent, as typifies A current in molluscan
neurons (Connor and Stevens, 1971). Figure 7B shows the
effect of holding potential (Vh) on the
inactivation of K+ currents as recorded from an
isolated wing cell: currents were totally abolished by depolarizing the
cell membrane at approximately 30 mV or more. Inactivating
K+ currents have been described in rod taste cells
of the frog (Avenet and Lindemann, 1987; Miyamoto et al., 1991) as well
as in taste cells of other vertebrates (Béhé et al., 1990;
Sugimoto and Teeter, 1990; Bigiani and Roper, 1993; Chen et al., 1996).
These cells also showed sustained K+ currents,
indicating that more than one type of potassium channel contributed to
the outward currents. On the contrary, our data suggest that only one
type of voltage-gated K+ channel occurs in the
membrane of the wing cells.
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Figure 7.
Properties of the inactivation of voltage-gated
K+ currents in wing cells. A, Time
course of inactivation of the K+ current recorded
from an isolated wing cell. The membrane was held at 85 mV and
stepped for 200 msec to +15 mV. The decay of the current was fit
(solid line) with a single exponential function with a
time constant of 21.8 msec in this cell.
Im, Membrane current.
B, The effect of holding potential
(Vh) on the inactivation of
K+ currents in another wing cell. Currents were
elicited by a series of depolarizing voltage pulses in 10 mV increments
from different holding potentials (Vh: 85,
75, 55, 45, and 35 mV). All records are from the same cell.
Bath solution was APS + 0.5 µM TTX to block voltage-gated
Na+ channels. Pipette solution was standard 105 mM KCl. Capacitative and leakage currents were subtracted
from the records. The corresponding I-V
plots for the peak K+ currents elicited at different
holding potentials are shown on the right.
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Lack of voltage-gated Ca2+ currents
To test for the presence of voltage-gated Ca2+
currents in whole-cell configuration, we designed specific pipette and
bath solutions aimed at completely eliminating voltage-gated
Na+ and K+ currents and
potentiating the currents through the Ca2+ channels
in the recorded cells (see Materials and Methods). However, we were not
able to detect voltage-gated Ca2+ currents in any
wing cells tested (n = 9 cells; data not shown). We
obtained the same negative results when we added 2 mM ATP
to the pipette solution (n = 6 cells; data not shown)
to reduce rundown of Ca2+ currents (Bean, 1992). We
also use the perforated-patch recording (Horn and Marty, 1988; Korn et
al., 1991) to test for Ca2+ currents in wing cells.
However, even in this experimental condition, no
Ca2+ current could be detected (n = 5 cells; data not shown). Therefore, we concluded that active
voltage-gated Ca2+ channels were not present in the
wing cells investigated.
Action potentials in response to current injections
The presence of voltage-gated Na+ currents
suggested that wing cells can generate action potentials. Under
current-clamp conditions, when the cell was held hyperpolarized at
approximately 80 mV and stimulated with depolarizing current pulses,
it was possible to generate action potentials (Fig.
8), as shown previously in chemosensory
cells of the frog taste disk by Avenet and Lindemann (1987) and
Miyamoto et al. (1991). The threshold for action potentials was
approximately 40 mV, and their duration was approximately 5 msec.
Wing cell action potentials were similar to the "fast" action
potentials described in rat taste cells (Béhé et al., 1990;
Chen et al., 1996). In wing cells, however, action potentials could not
be generated repetitively, even with prolonged depolarizing current
pulses (data not shown). Application of TTX completely blocked the
action potential (Fig. 9), whereas TEA
increased its duration (Fig. 10). This
latter observation indicated that, as shown in rat taste cells (Chen et
al., 1996), the inactivating K+ currents played a
role in the repolarizing phase of the action potential in wing
cells.
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Figure 8.
Action potential recorded from an isolated wing
cell under current-clamp conditions. Cell membrane was held at
approximately 80 mV, and brief depolarizing current pulses in 2 pA
increments were injected. The first four pulses were subthreshold and
failed to elicit action potentials. In this cell, the firing threshold
was between 30 and 40 mV. Pipette solution was standard 105 mM KCl. Vm, Membrane
potential.
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Figure 9.
Contribution of sodium currents to action
potential in wing cells. The cell was held at approximately 80 mV,
and a 14 pA pulse of current was injected. In control conditions (bath
solution: APS) an action potential was fired (top). In
the presence of 0.5 µM TTX, the same stimulation protocol
failed to elicit a spike-like action potential (middle).
In voltage-clamp configuration, the inward Na+
currents were completely abolished (data not shown). After the drug was
washed out, wing cell membrane recovered the capability of firing
action potential (bottom). Pipette solution was standard
105 mM KCl. Vm, Membrane
potential.
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Figure 10.
Contribution of potassium currents to the
repolarization phase of the action potential in wing cells. Cell
membrane was held at approximately 80 mV, and two current pulses were
injected. The first pulse (70 pA) was subthreshold, whereas the second
one (80 pA) elicited an action potential (top,
control). When 5 mM TEA was applied,
the action potential broadened considerably (bottom). In
voltage-clamp configuration, the inactivating K+
current was completely abolished (data not shown). Pipette solution was
standard 105 mM KCl. Vm,
Membrane potential.
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Amiloride-sensitive Na+ currents
Sodium ions occurring in food are thought to be detected by taste
chemosensory cells through specific Na+ channels
sensitive to amiloride (for review, see Lindemann, 1996; Stewart et
al., 1997). These channels differ fundamentally from the
voltage-sensitive, TTX-sensitive channels (Garty and Benos, 1988). The
presence of amiloride-sensitive Na+ channels in the
cell membrane of taste cells can be shown by studying the effect of
amiloride on the whole-cell current recorded at a given holding
potential (Avenet and Lindemann, 1988; Gilbertson et al., 1993; Doolin
and Gilbertson, 1996). In isolated wing cells, we looked for evidence
of amiloride-sensitive currents by holding them at negative potentials
and by bath-applying amiloride in standard APS solution. We used an
amiloride concentration ranging from 30 to 40 µM because
these values proved to block effectively amiloride-sensitive
Na+ channels in taste receptor cells of the frog and
other vertebrates (Avenet and Lindemann, 1988; Gilbertson et al., 1993;
Doolin and Gilbertson, 1996). In 14 of 19 cells (74%), amiloride
caused a reduction in the stationary inward currents recorded when cell membrane was held at negative potentials. Figure
11 shows an example of the effect of
amiloride on the stationary inward current recorded from a wing cell
held at 75 mV. It is interesting to note that during the washout, the
membrane current transiently increased (Fig. 11, undershoot)
before relaxing to the baseline level. This increase could be
attributable to the known self-inhibition by Na+
described for the amiloride-sensitive Na+ channels
(Garty and Palmer, 1997). Moreover, the time course of the amiloride
effect on wing cells was remarkably similar to the one observed by
Avenet and Lindemann (1988) in rod taste cells of the frog. Concomitant
to the decrease in the stationary inward current we measured an
increase in the cell input resistance (Fig. 12) that was consistent with channels
being closed by amiloride. The increase in input resistance elicited by
30 µM amiloride ranged from 58 to 290% of the control
values (n = 4 cells). Replacing extracellular
Na+ with a large impermeant cation, NMDG, caused a
reduction of the stationary inward current similar to the effect of
amiloride (Fig. 13). With NMDG,
however, no undershoot was observed during the washout (Fig. 13).
Collectively these observations suggested that wing cells possessed
amiloride-sensitive Na+ channels in their
membrane.
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Figure 11.
Response of whole-cell current to amiloride in an
isolated wing cell. Cell membrane was held at 75 mV. Bath application
of 40 µM amiloride in regular APS caused a rapid decrease
in the stationary inward current (holding current) and
in current noise. Note the undershooting transient
(undershoot) on washout of amiloride. Pipette solution
was standard 105 mM CsCl.
Im, Membrane current.
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Figure 12.
Change in the input resistance of a wing cell
during response to amiloride (30 µM). Input resistance
was monitored by application of 20 mV steps from a holding potential
(Vh) of 75 mV. Input resistance
increased from 1.6 G before amiloride application to 3.9 G during
the amiloride response, suggesting that membrane conductance was
reduced. Note that during washout, cell input resistance recovered to
the control value. Im, Membrane
current.
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Figure 13.
Effect of Na+-free saline and
amiloride on the stationary inward current
(Im) recorded from an isolated wing
cell held at 60 mV. Replacing extracellular Na+
with NMDG, a large impermeant cation, induced a decrease in the
stationary inward current (top trace) similar to that
elicited by bath-applying 30 µM amiloride to the same
cell (bottom trace). However, time courses of the
current recovery during washout were markedly different.
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Variability of voltage-gated currents in wing and rod
taste cells
The voltage-gated Na+ and K+
currents showed similar properties in all the wing cells tested. For
example, the K+ currents recorded from different
wing cells always presented a marked inactivation, and all wing cells
possessed voltage-gated Na+ currents. These
observations suggested that wing cells were a homogeneous population of
taste cells as far as their voltage-gated ion channels are concerned.
In contrast, voltage-gated currents in rod cells were considerably
varied, in agreement with findings of previous studies (Avenet and
Lindemann, 1987; Miyamoto et al., 1988, 1991). Figures
14 and
15 show examples of recordings from different rod cells isolated along with the wing cells. Some rod cells
(Fig. 14) did not show any detectable voltage-gated
Na+ currents and possessed K+
currents without inactivation during the voltage protocol used (compare
Fig. 14B with Fig. 7A). Other rod cells,
however, presented voltage-gated Na+ currents in
association with noninactivating K+ currents (Fig.
15A), and some others showed membrane currents quite
indistinguishable from those observed in wing cells (Fig. 15B). Like wing cells, all the rod cells tested
(n = 5) did not present active voltage-gated
Ca2+ channels in our experimental conditions (data
not shown), in agreement with previously published data (Avenet and
Lindemann, 1987; Miyamoto et al., 1991).
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Figure 14.
Whole-cell recordings from isolated rod cells
lacking voltage-gated Na+ currents.
A, Outward currents (left) elicited in
regular APS by a series of depolarizing pulses between 75 and +55 mV,
in 10 mV increments, from a holding potential of 85 mV. The
corresponding I-V plot
(right) indicated that the outward current in this cell
activated at approximately 40 mV. These recordings were obtained from
the cell shown in Figure 1B. B,
Outward currents recorded in another rod cell. Voltage protocol was the
same as for the cell in A, but the pulse duration was
200 msec. It can be noted that in this cell the outward current did not
inactivate significantly during the stimulation period (compare with
the time course of inactivation shown in Fig. 7A).
Capacitative and leakage currents were not subtracted in these
recordings. Pipette solution was standard 105 mM
KCl.
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Figure 15.
Whole-cell recording from other rod cells showing
various membrane ionic currents. A, Transient inward
Na+ current and sustained outward
K+ currents recorded from an isolated rod cell
(left). The I-V plots for
these currents are shown on the right. Voltage-clamp
protocol: holding potential, 85 mV; depolarizing pulses in 10 mV
increments from 75 to +85 mV. Capacitative and leakage currents were
not subtracted in these recordings. B, Voltage-gated
currents recorded from another isolated rod cell (left)
with their corresponding I-V plots
(right). Note that the currents were similar to those
recorded in the wing cells (for example, compare with Fig. 2).
Voltage-clamp protocol was the same as in A.
Capacitative and leakage currents were subtracted in these recordings.
Pipette solution was standard 105 mM KCl.
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DISCUSSION |
One of the challenging issues in taste research is the evaluation
of the functional properties of the different cell types occurring in
vertebrate taste organs. The goal of our study was to contribute to the
understanding of functional diversification between taste cells. In
detail, we have examined the following question: what are the membrane
properties of taste cells lacking synaptic contacts with afferent axons
(i.e., the so-called supporting cells)? As a model we chose a cell from
the frog taste disk, the wing cell. Studies with extensive use of
serial sections have revealed that wing cells do not synapse onto
afferent nerve terminals (Osculati and Sbarbati, 1995). Wing cells are
considered secretory elements involved in the production of the
material covering the free surface of the taste organ (for review, see
Osculati and Sbarbati, 1995). Their distinctive sheet-like process
fills the space between other cells in the taste disk, and their
cytoskeleton apparently lends mechanical support to the other cellular
elements (Richter et al., 1988). Unlike wing cells, chemosensory
elements in frog taste disk are spindle-shaped, with a rod-like apical process. They are subdivided into two groups, Type II and Type III
cells (for review, see Osculati and Sbarbati, 1995). In this study, we
found that wing cells possessed some membrane properties remarkably
similar to those observed in the chemosensory elements. Voltage-gated
Na+ and K+ channels typically
found in chemosensitive rod cells are also expressed by wing cells. We
could not reveal any significant variability in the properties of these
channels among wing cells, which in this respect made up a homogeneous
cell population. By contrast, we observed a certain variability in the
membrane properties of rod cells, confirming previous data (Avenet and
Lindemann, 1987; Miyamoto et al., 1988, 1991). This result is probably
related to the heterogeneous composition of chemosensory cells.
Voltage-gated Ca2+ channels are thought to subserve
chemical transmission in taste buds (Lindemann, 1996) and are found in
many vertebrate taste cells (Kinnamon and Roper, 1988; Béhé
et al., 1990; Sugimoto and Teeter, 1990; Bigiani and Roper, 1993; Chen
et al., 1996). Consistently with the lack of chemical synapses, we
could not detect any voltage-gated Ca2+ currents in
wing cells. However, we have to point out that rod cells in frog taste
disks also do not posses voltage-gated Ca2+ channels
(Avenet and Lindemann, 1987; Miyamoto et al., 1991; present study),
despite the observation that they make synaptic contacts with afferent
nerve terminals (Osculati and Sbarbati, 1995). In conclusion, putative
supporting elements share with the chemosensory cells the absence of
these channels, at least in frog. Currently there is no obvious
explanation for this peculiarity of frog taste cells. It is to be noted
that in a recent study Kolesnikov and Margolskee (1995) described a
cyclic nucleotide-suppressible conductance permeable to
Ca2+ in frog taste cells (presumably rod ones),
which could represent the major pathway of Ca2+
influx in these cells. It would be interesting to test whether a
similar conductance is present in wing cells.
By using the freeze-fracture technique, Sbarbati et al. (1993) showed
that the apical membrane of wing cells displays intramembrane particles
similar to those found in Type III cells: accordingly, our functional
findings showed that the membrane of wing cells indeed displays ion
channels similar to those found in the chemosensory elements of frog
taste disks. Yet wing cells have not been shown to make chemical
synaptic contacts with afferent axons. On this basis, it is tempting to
speculate that the morpho-functional properties of wing cells would
resemble those of glial cells in the nervous system. It is well
established that oligodendrocytes and astrocytes in the CNS and Schwann
cells in the PNS are endowed with a vast array of voltage-gated ion
channels, neurotransmitter-gated channels, and transport mechanisms
similar to those found in the adjacent neurons (for review, see Barres
et al., 1990; Ritchie, 1992). The physiological functions of these
membrane proteins remain to be fully elucidated, although some
hypotheses have been postulated. For example, it has been proposed that
glial cells act as local sources of axolemmal Na+
channels, thereby reducing the biosynthetic load of neurons (Gray and
Ritchie, 1985; Sontheimer et al., 1996). Voltage-gated
K+ channels have been suggested to play a role in
the homeostasis of K+ released in the extracellular
space by active neurons (Ritchie, 1992). In the retina, Müller
cells are astrocyte-like cells expressing voltage-gated ion channels,
neurotransmitter receptors, and various uptake carrier systems (for
review, see Newman and Reichenbach, 1996). These properties enable the
Müller cells to control the activity of retinal neurons by
regulating the extracellular concentration of neuroactive substances
such as K+, GABA, and glutamate. In addition, it has
been proposed that voltage-gated Na+ channels in
these cells could be activated by the functioning of adjacent neurons;
this way, glial cells could sense the activity of neighboring neurons
(Chao et al., 1994). In taste organs, cells are closely apposed, and
the extracellular space around them is very narrow. The sheet-like
processes of wing cells fill the space between adjacent taste cells,
and their large surface area makes these cells suitable for controlling
the extracellular fluid inside the taste organs and perhaps for
monitoring the activity of adjacent chemosensory cells. Wing processes
also ensheathe the apical processes of chemosensory elements (Richter
et al., 1988). Therefore, in view of the narrow intercellular spaces, a
glia-like control of extracellular ion and transmitter concentrations
seems to be a plausible hypothesis. In this respect, it would be
interesting to test whether wing cells are electrically coupled as the
glial cells are in the nervous system (Dermietzel and Spray, 1993).
In addition to voltage-gated channels, wing cells also possessed
amiloride-sensitive Na+ channels, which are thought
to mediate, at least in some vertebrates, the chemotransduction of
sodium taste (for review, see Lindemann, 1996; Stewart et al., 1997).
These channels have been studied in rod taste cells of the frog by
Avenet and Lindemann (1988). Although wing cells express functional
amiloride-sensitive Na+ channels, it is possible
that their properties differ from those of the same channels occurring
in rod cells. Further investigation is required to assess, for example,
the inhibition constant of amiloride block, which in rod cells is very
low (0.3 µM) (Avenet and Lindemann, 1988). Our data did
not allow us to establish the location (apical, basolateral, or both)
of the amiloride-blockable Na+ channels in wing
cells. Iontophoretic application of amiloride could help in mapping the
amiloride sensitivity of wing cell membrane. However, the presence of
these channels raises the possibility that wing cells may be involved
in the chemotransduction of Na+ salts in taste
organs. In this regard, it is interesting to point out that
amiloride-sensitive Na+ channels have also been
identified in nontaste epithelial cells surrounding taste buds (Li et
al., 1994). It has been proposed that amiloride-sensitive
Na+ channels in these cells could play a role in the
transcellular pathway for current flow within and outside the taste
organ during activation of the chemosensory elements by sodium ions (Li
et al., 1994; Lindemann, 1996). It is then possible that during taste stimulation with Na+, loop currents flow between
receptor cells and neighboring "associated" cells such as wing
cells. In short, these cells could participate in the early signal
chain of gustatory reception.
Taste cells similar to the wing type in frog occur also in the taste
buds of other vertebrates. Type I cells in mammals present sheet-like
lateral projections filling the space between adjacent Type II and Type
III cells, thereby providing an organizing element for the structure of
the bud (rabbit: Royer and Kinnamon, 1994; rat: Pumplin et al., 1997).
Dark cells (Type I) in Necturus have a lamellar apical
process too (Delay and Roper, 1988; Kinnamon et al., 1988). Finally,
scanning electron micrographic studies have revealed the presence of
taste cells with lamellar process in mouse (Spielman et al., 1992). In
summary, given the similarity of frog wing cells to Type I cells in
other vertebrates, it would be tempting to speculate that these taste
cells could play a glial-like role in the functioning of taste sensory
organs. It is important also to point out that there is a certain
variability from one species to the other as to the structural
properties of Type I cells. For example, these cells house synaptic
contacts with afferent nerves in Necturus (Delay and Roper,
1988) and in mouse (Kinnamon et al., 1985; but see Seta and Toyoshima,
1995), whereas in frog (Osculati and Sbarbati, 1995) and rat (Takeda
and Hoshino, 1975) they do not. It is possible that variability in
structure and function of taste cell types may reflect varying
nutritional requirements among species. Along this line, a given cell
type may have both chemosensory and supportive functions in some
species, whereas in others it could be more specialized. Comparative
studies (Kim and Roper, 1995) may help in obtaining a comprehensive
picture of the morpho-functional correlation for vertebrate taste
cells.
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FOOTNOTES |
Received March 9, 1998; revised April 23, 1998; accepted April 27, 1998.
This study was supported in part by the Italian Ministero
dell'Università e della Ricerca Scientifica e Tecnologica. We
thank Dr. Stephen D. Roper (University of Miami) for critically
reviewing this manuscript. We thank Mr. Fausto Vaccari
(Università di Modena) and Mr. Paolo Bernardi (Università
di Verona) for their excellent technical assistance.
Correspondence should be addressed to Dr. Albertino Bigiani,
Dipartimento di Scienze Biomediche, Sezione di Fisiologia,
Università di Modena, via Campi 287, 41100 Modena,
Italy.
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T. Suwabe and Y. Kitada
Voltage-gated Inward Currents of Morphologically Identified Cells of the Frog Taste Disc
Chem Senses,
January 1, 2004;
29(1):
61 - 73.
[Abstract]
[Full Text]
[PDF]
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Abstract
Introduction
