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Volume 17, Number 11,
Issue of June 1, 1997
pp. 4101-4111
Copyright ©1997 Society for Neuroscience
The Responses of Rat Trigeminal Ganglion Neurons to Capsaicin and
Two Nonpungent Vanilloid Receptor Agonists, Olvanil and Glyceryl
Nonamide
L. Liu1,
Y.-C. Lo2,
I.-J. Chen1, and
S. A. Simon1
1 Departments of Neurobiology and Anesthesiology, Duke
University Medical Center, Durham, North Carolina 27710 and
2 Department of Pharmacology, Kaohsiung, Taiwan, 80708 Republic of China
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Capsaicin, the pungent ingredient in hot pepper, activates and
subsequently desensitizes a subset of polymodal nociceptors. Because
its initial application to skin produces pain, nonpungent analogs such
as olvanil and glyceryl nonivamide (GLNVA) were synthesized to enhance
its clinical use. To explore how these nonpungent analogs differ from
capsaicin, whole-cell patch-clamp recordings were performed on cultured
rat trigeminal ganglion neurons.
In neurons held at  60 mV, capsaicin, olvanil, and GLNVA were found to
activate one or two kinetically distinct inward currents. Two inward
currents were also activated when extracellular Ca2+ was
replaced with Ba2+ and also when intracellular chloride was
replaced by aspartate. The reversal potentials of the rapidly and
slowly activating currents were 15.3 ± 6 and 4.0 ± 2.5 mV, respectively. These data provide strong evidence for subtypes of
vanilloid receptors. One difference among these agonists is that, on
average, the activation kinetics of the currents evoked by 1 µM olvanil and 30 µM GLNVA are considerably slower than those evoked by 1 µM capsaicin. Measurements
of the peak current, Ip, versus agonist concentration
were fit to the Hill equation to yield values of the half maximal
concentrations (K1/2), and the Hill
coefficients (n). For capsaicin, olvanil, and
GLNVA, K1/2 = 0.68, 0.59, and 27.0 µM; and n = 1.38, 1.32, and 1.24, respectively.
We propose that olvanil and GLNVA are nonpungent because they activate
different subtypes of receptors and/or because of their activation
kinetics (compared with capsaicin) are, on average, slower than the
rate they inhibit action potentials from polymodal nociceptors.
Key words:
pain;
taste;
vanilloid receptors;
pungent;
olvanil;
capsaicin
INTRODUCTION
Capsaicin, the pungent ingredient in chili pepper,
produces pain and inflammation when placed on skin or mucus membranes
(Holzer, 1991 ; Szolcanyi et al., 1991). These effects result from the
activation of cation-selective channels in polymodal nociceptors
causing peptides and transmitters to be released from their peripheral and central terminals. The selectivity of capsaicin for polymodal nociceptors, coupled with the fact that on repeated applications it
produces a long-lasting desensitization of these neurons, has made it
useful clinically as an anti-nociceptive and -inflammatory compound.a
One disadvantage of using capsaicin clinically is that its initial
contact with skin produces marked pain and inflammation that sometimes
prevents continuance. To reduce these initial responses, protocols were
developed in which the capsaicin concentration, the interstimulus
interval, and the delivery vehicle were varied systematically (Craft
and Porreca, 1992). Another approach was to synthesize analogs of
capsaicin with properties that will not cause marked pain on the
initial application. This latter approach has followed the pioneering
structure activity work of Szolcsanyi and Jansco-Gabor (1975a,b), who
found that analogs with longer acyl chains or with altered phenolic
hydroxy groups were less pungent than capsaicin. Subsequently, numerous
capsaicin analogs were synthesized with the goal of finding a compound
that does not produce pain on its initial application, but that still
retains its desensitizing characteristics.
The best characterized of the long-acyl chain, less-pungent capsaicin
analogs is olvanil (Fig. 1). Olvanil, like capsaicin, has antinociceptive and -inflammatory properties (Brand et al., 1987),
and is equipotent with capsaicin in its ability to increase Ca2+ influx in cultured rat DRGs (Walpole and
Wrigglesworth, 1993), and in behavioral measurements of pain (Campbell
et al., 1993). Moreover, whole-nerve recordings from rat spinal cord
found that olvanil and capsaicin cross-desensitize, suggesting that
they activate the same receptor (Dray et al., 1990). In this regard, preliminary patch-clamp data on DRG neurons that showed that the inward
currents activated by 0.5 µM olvanil or 0.5 µM capsaicin had approximately the same magnitude and
activation kinetics (Bevan and Docherty, 1993).
Fig. 1.
Chemical structures of capsaicin, olvanil, and
GLNVA. For GLNVA, the phenolic hydroxy group of the synthetic capsaicin
analog nonanoyl-vanillamide is replaced by a glycerol moiety.
[View Larger Version of this Image (12K GIF file)]
Not all responses evoked by olvanil and capsaicin, however, were found
to be identical. For example, in whole-nerve recordings from rat spinal
cord the response evoked by 2 µM capsaicin was mimicked
by 500 µM olvanil (Dickenson et al., 1990; Dray et al., 1990). That is, olvanil was less potent than capsaicin in its ability
to activate nociceptors. Also 2-10 µM capsaicin, but not 2-10 µM olvanil, evoked the release of peptides from rat
spinal cord (Dickenson et al., 1990). In contrast, olvanil was found to
be 10 times more potent than capsaicin in increasing blood flow in
rabbit skin (Hughes et al., 1992). Finally, olvanil and capsaicin
differ in their ability to produce thermoregulatory desensitization
(Brand et al., 1987). One rationalization of these data is that there
are subtypes of capsaicin (vanilloid) receptors that respond
differently to the same agonists (Szallasi, 1994; Szallasi et al.,
1997; Appendino and Szallasi, 1997; Cruz et al., 1996).
Recently, glyceryl nonivamide (GLNVA, Fig. 1) another
nonpungent, anti-nociceptive capsaicin analog was synthesized (Chen et
al., 1992). Although GLNVA shares many similarities with capsaicin, there are significant differences in some of the physiological responses evoked by these compounds. For example, capsaicin elicits a
triphasic blood pressure response, bradycardia, and apnea, whereas GLNVA elicited a monophasic reduction in blood pressure with little effect on heart rate and respiration (Yeh et al., 1993). The origins of
these differences were not well understood.
To better understand how nonpungent capsaicin analogs differ from
capsaicin, we measured the currents evoked by these three compounds
from cultured rat trigeminal neurons.
MATERIALS AND METHODS
Materials. Salts were reagent grade. Unless otherwise
stated, all other drugs and enzymes were purchased from Sigma (St.
Louis, MO). Olvanil [N-(3-methyoxy-4-hydroxybenzyl)
oleamide] was the generous gift of Dr. L. Brand of Proctor and Gamble
(Cincinnati, OH). GLNVA was synthesized as described previously (Yeh et
al., 1993).
Cell culture. Rat trigeminal cells were cultured as
described previously (Liu and Simon, 1996a,c). Trigeminal ganglion
cells were obtained from Sprague Dawley rats (150-250 gm) that were anesthetized with sodium pentobarbital (50 mg/kg). The cells were washed several times in a cold (4°C) modified HBSS containing (in
mM): NaCl 130, KCl 5, KH2PO4 0.3, NaHCO3 4.0, Na2HPO4 0.3, D-glucose 5.6, and HEPES 10. They were then incubated for
40 min at 37°C in HBSS containing 1 mg/ml collagenase (Type XI-S),
triturated with a flamed Pasteur pipette to separate cells and remove
processes, and finally incubated at 37°C for 8 min with 0.1-1.0
mg/ml DNase I (Type IV). Subsequently, they were retriturated and
washed/centrifuged three times in F-14 medium (Life Technologies,
Gaithersburg, MD). They were then resuspended and placed in a Petri
dish with F-14 containing 10% fetal calf serum. The cultures were
maintained in an incubator at 37°C equilibrated with 5%
CO2. Patch-clamp experiments were performed on cells
cultured for 12-24 hr. At the beginning of each experiment, the
neurons were placed in a chamber containing Krebs-Henseleit (KH)
buffer on an inverted microscope where the projected soma diameters
were measured using a calibrated eyepiece. The composition (in
mm) of KH was: NaCl 145, KCl 5, CaCl2 2.0, MgCl2 1.0, HEPES 10, and D-glucose 10, pH 7.4. Rat trigeminal ganglion neurons had a mean membrane potential of 52
mV (Liu et al., 1993). Experiments were performed at room temperature.
Patch clamp. The chamber containing the neurons had a volume
of 500 µl and was perfused continuously by KH flowing into the chamber at a rate of 6 ml/min (Liu and Simon, 1996c). In addition, capsaicin, olvanil, GLNVA, and capsazepine (Tocris Cookson, St. Louis,
MO.) were dissolved in KH and, if necessary, a small quantity of
dimethylsulfoxide. These solutions were delivered to the cell using a
multibarreled electrode (Adams and List Associated, Westbury, NY)
placed ~20-50 µm from the cell by opening a valve. The solution in
each barrel flowed at a rate of 6 µl/sec. The onset and removal times
of the stimuli were obtained by event markers associated with the
opening or closing of the valves. In experiments in which extracellular
BaCl2 replaced CaCl2 (see below), the KH-Ca
buffer was replaced with a continuously perfusing KH-Ba buffer to
ensure that no calcium remained bathing the cell before the cell was reexposed to capsaicin in KH-Ba.
To test whether 10 µm capsazepine would inhibit the
currents activated by olvanil or GLNVA, as it does those of capsaicin (Liu and Simon, 1996c), these two agonists (in KH buffer) were initially applied to the neurons for 32 sec. After washing for 3 min,
10 µM capsazepine was applied to the cell for 3 min, and then a solution of capsazepine and olvanil or capsazepine and GLNVA was
applied for 30 sec. To test for reversibility the cells were
subsequently washed for 6 min with KH buffer, whereupon olvanil or
GLNVA was reapplied. The percentage of blockage (B), by
capsazepine was calculated using B = 100% (Ipcpz/(Ip1 + Ip2)/2), where Ipcpz is
the peak current in the presence of capsazepine, and
Ip1 and Ip2 are the peak
currents of the first and second applications of the two agonists.
Patch-clamp recordings in the whole-cell configuration were performed
with an Axoclamp 1D patch-clamp amplifier (Axon Instruments, Foster
City, CA). The output was digitized with a Digidata 1200 A/D converter
(Axon Instruments) and was sampled every 20 msec unless stated
otherwise. Series resistance was compensated at least 80%, but leak
currents were not. Electrode resistances were ~2-5 M . In control
experiments the microelectrode contained (in mM): KCl 140, CaCl2 1.0, MgCl2 2.0, BAPTA
[1,2-bis(2-aminophenoyx)ethane-N ,N,N,N-tetracetic acid] 10, HEPES 10, and K2-ATP 5 adjusted to pH 7.3. This
solution was called SIS. To eliminate Cl currents, in
most experiments the internal solution contained (in mM): K
aspartate 140, KCl 1, CaSO4 0.2 H20 1, MgSO4 2, BAPTA 10, HEPES 10, and K2-ATP 5 adjusted to pH 7.3. This solution was called Kaspartate. In other
experiments the 140 mm KCl was replaced by 70 mM
CsCl and 70 mM CsF. This solution was called Cs-SIS. Finally, to guard against the possibility of capsaicin activating secondary Ca2+-dependent currents, in some experiments the
extracellular solution contained KH with 2 mM
BaCl2 replacing 2 mM CaCl2. This
solution was called KH-Ba.
Current-voltage response. P-clamp software (Axon
Instruments) was used to obtain all the current-voltage
(I-V) curves. In these experiments the extracellular
solution contained KH plus 0.3 mM TTX. The intracellular
solution contained SIS. The cells were held at either 70 or 80 mV,
and the current was ramped periodically to 70 or 80 mV in times ranging
from 0.2 to 2 sec. In most experiments the voltage cycle was 0.2 sec.
The current was sampled every 0.375 msec. The ramp was applied before,
during, and after agonist application. Because the amplifier sometimes saturated when the potential reached 80 mV, we present I-V
curves for the range ±60 mV.
Tachyphylaxis experiments. Unless stated otherwise, after
the application of capsaicin, olvanil, or GLNVA, the cell was washed for 6 min with KH buffer before reapplication of the agonists.
RESULTS
Currents activated by capsaicin, olvanil, and GLNVA
We have shown previously that in rat trigeminal ganglion neurons
held at 60 mV and bathed in KH/SIS buffers, 1 µM
capsaicin activated inward currents in ~60% of the neurons (Liu and
Simon, 1996c). Moreover, we found that capsaicin can activate one (Fig. 2A-C) or more kinetically distinct
inward currents (Fig. 2D, Liu et al. 1996d). These
inward currents can vary widely in their activation kinetics as
characterized by the time to peak ( p). Although
most had peak times between 1 and 9 sec (4.2 ± 3.1; mean ± SD) (Liu and Simon, 1996c) others had peak times of ~40 sec (41.4 ± 16.4 sec; mean ± SD) (Liu and Simon, 1996b) (Fig.
2D). These currents also varied in their
desensitization kinetics (compare Fig. 2A-C) and the
extent to which they desensitized, which ranged from 100% (Fig.
2A) to not desensitizing (Liu and Simon, 1996c). Another common feature of the capsaicin-activated currents is that
after the cell is washed, the current increases transiently before
returning to baseline (Fig. 2B-D). This transient
increase is ascribed to a transition from a desensitized channel state to an open state before reaching a closed state (Liu and Simon, 1996c).
Fig. 2.
Currents evoked from rat trigeminal ganglion cells
by initial applications of 1 µM capsaicin
(A-D), 1 µM olvanil (E,
F), and 30 µM GLNVA (G,
H). Holding potential (HP) = 60 mV. KH, external solution; Kaspartate, internal solution. Bars indicate
duration of stimuli.
[View Larger Version of this Image (11K GIF file)]
Under the same conditions, midrange concentrations (see below) of
olvanil (1 µM) and GLNVA (30 µM) also
activate inward currents. Approximately 64% of the cells were
activated by 1 µM olvanil (25/39) or 30 µM
GLNVA (26/41). Like capsaicin, olvanil may activate currents with one
(Figs. 2E, 4A) or two peaks (Figs.
2F, 6A, 9). The primary difference
between capsaicin and olvanil is that the time to peak of the
olvanil-induced currents was on average markedly longer, being
p = 25.2 ± 8 sec (n = 25). Specifically, when 1 µM olvanil was initially
applied to a neuron, rapidly activating currents, such as seen in
Figure 2F, were observed in only 3 of 25 cells. For
these cells the mean p was 4.3 sec. The
olvanil-induced currents desensitize and slowly return to baseline
after wash (Fig. 2E). After washing, transient inward
currents were observed frequently (Fig. 4A). Of the
25 cells that were activated by 1 µM olvanil, none
exhibited rapidly activating and completely desensitizing currents such as those shown in Figure 2A for
capsaicin.
Fig. 4.
Capsazepine inhibits olvanil and GLNVA-induced
currents. A, Olvanil (1 µM) activates an
inward current. After a 3 min wash with KH, the cell was incubated with
10 µM capsazepine in KH for 3 min before the application
of 10 µM capsazepine plus 1 µM olvanil (middle trace). After a 6 min wash, olvanil was
reapplied. B, Same as above except for 30 µM GLNVA. HP = 60 m. Bars indicate duration of stimuli.
[View Larger Version of this Image (11K GIF file)]
Fig. 6.
Current versus time responses at 60 mV for 1 µM olvanil, 1 µM capsaicin, and 30 µM GLNVA obtained in the same neuron using the methods
described in Figure 5. Between applications the cell was washed for 6 min. A, The top traces show the currents
obtained from the family of  I-V curves at 60 mV.
It is evident that olvanil and capsaicin evoke two inward currents,
whereas GLNVA evokes a single slowly activating current. The labels
a and b refer to the times the
I-V plots in 6B were obtained.
B, Two I-V plots corresponding to the
times shown in the top traces. Note that the reversal
potential for GLNVA at the two different times is approximately the
same. External solution, KH + 0.3 µM TTX; internal solution, SIS. Bar indicates duration of stimuli.
[View Larger Version of this Image (20K GIF file)]
Fig. 9.
Tachyphylaxis of olvanil and GLNVA. Currents
evoked by seven repeated 30 sec applications of 1 µM
olvanil (A) and 30 µM GLNVA (B) in KH buffer. Between applications the cells were
washed 2 min 30 sec with KH buffer. HP = 60 mV.
Bar indicates duration of stimuli.
[View Larger Version of this Image (8K GIF file)]
The currents activated by 30 µM GLNVA were similar to
those induced by 1 µM olvanil, in the sense that most
(24/26) of the GLNVA-induced currents activated slowly
(p = 26.6 ± 11.4 sec; n = 26). One example is shown in Figure 2G. In the remaining
two neurons, the GLNVA-induced currents exhibited multiple peaks (Figs. 2H, 8). In these neurons the more rapidly activating
current had a mean time to peak of 3.7 sec. Rapidly desensitizing
currents, such as those seen in Figure 2A,B for
capsaicin, were never observed with 30 µM GLNVA. In
summary, at midrange concentrations, the currents activated by olvanil
and GLNVA, on average, activate more slowly than those evoked by
capsaicin.
Fig. 8.
Dose-response for capsaicin, olvanil, and GLNVA
obtained at a holding potential of 60 mV. The data represent the
mean ± SD for capsaicin (n = 9), olvanil
(n = 7), and GLNVA (n = 6). The solid lines were fit to the Hill equation (see text).
HP = 60 mV. The capsaicin data were from Liu and Simon
(1996c).
[View Larger Version of this Image (15K GIF file)]
When two inward currents are activated by a single agonist it is
important to determine whether the more slowly activating current
arises as a consequence of the activation of the more rapidly
activating current. One possibility is that at 60 mV the secondary
inward current could be a Ca2+-activated Cl
current. We have eliminated this possibility by first showing that two
inward currents can also be activated when the intracellular solution
contains K aspartate (Fig. 2) (Liu and Simon, 1996c). We now show that
two inward currents can also be activated when Ca2+ in the
KH buffer is replaced by Ba2+ (KH-Ba). Figure
3 shows the results of an experiment in which 1 µM capsaicin activated two distinct inward currents.
After wash, reapplication of capsaicin (in KH-Ba) also evoked two
inward currents, although the magnitude of these currents was smaller
by ~85%. The partial reversibility of the currents eliminates the
possibility that the inhibition was not entirely the result of
"rundown" or tachyphylaxis (Figs. 9, 10). We found that replacement
of 2 mM Ca2+ by 2 mM
Ba2+ inhibited the rapid and slowly capsaicin-activated
currents by 68 ± 31% and 62 ± 20% (n = 8), respectively. Because Ba2+ cannot activate most
Ca2+- activated currents (Hille, 1993), these data suggest
that the slowly activating current is not a Ca2+-activated
current. In a subsequent publication we will show that Ba2+
blocks capsaicin-activated currents (Liu and Simon, unpublished observations).
Fig. 3.
Barium reduces capsaicin-activated currents.
Left trace, Capsaicin dissolved in KH buffer evoked two
inward currents. After wash, a Ca2+-free, but
Ba2+-containing KH buffer (KH-Ba) was exchanged for the KH
buffer to rid the chamber of calcium. After a 3 min incubation period, capsaicin in KH-Ba was reapplied (middle trace). After
wash in KH, reapplication of capsaicin in KH (right
trace) partially reversed the inhibition by Ba2+.
SIS, internal solution. HP = 60 mV. Bars indicate duration of stimuli.
[View Larger Version of this Image (5K GIF file)]
Fig. 10.
Results of tachyphylaxis experiments. The results
of six olvanil (O1-O6) and five GLNVA (G1-G5) experiments are
presented to illustrate the heterogeneity of the responses.
A, Plots of the %Ip remaining with
respect to the initial application (=100%). For example, for olvanil
neuron "O1" the current disappeared completely after the third
application. B, The mean ± SD of the data
presented in Figure 10A. The
asterisk for the seventh application of GLNVA data are
presented because in two of the five experiments the cell died.
Capsaicin data are from Liu and Simon (1996b).
[View Larger Version of this Image (35K GIF file)]
Capsazepine inhibits olvanil- and GLNVA-induced currents
Capsazepine has been shown to be a specific and competitive
inhibitor of capsaicin-induced responses (Bevan et al., 1992). To
determine whether olvanil and GLNVA activate the same class of
receptors as capsaicin we investigated whether the currents activated
by these two agonists can also be inhibited by capsazepine. We
considered initially the currents activated by olvanil. Figure 4A shows a cell in which 10 µM capsazepine partially inhibited the olvanil-induced
current by 88%. After wash, the magnitude of current increased after
reapplication of olvanil, showing that the current was indeed inhibited
by capsazepine. On average the olvanil-induced current was reduced
91.4 ± 9.2% (n = 6) by capsazepine. Complete
reversibility of the olvanil-induced currents was never attained, most
likely because of the relatively rapid olvanil-induced tachyphylaxis
(Figs. 9, 10). The partial inhibition can be taken as evidence of
multiple subtypes of vanilloid receptors.
The GLNVA-induced currents were reversibly inhibited by capsazepine
(Fig. 4B). On average, 10 µM
capsazepine inhibited 94.5 ± 7.5% (n = 6) of the
currents evoked by 30 µM GLNVA.
I-V relationships
Capsaicin
I-V relationships for capsaicin were obtained
previously by applying it to cells at several different holding
potentials. Between applications the cell was washed for 6-8 min.
Using this protocol, I-V plots were obtained that were
slightly rectifying and that had reversal potentials of ~4 mV (Liu
and Simon, 1996b,c). These small reversal potentials represent the
slowly activated currents and indicate the presence of a nonselective
cation channel (Oh et al., 1996). Although numerical values of the
reversal potential of the rapidly activating current were not reported,
it was nevertheless noted that it was more positive than 4 mV (Liu and
Simon, 1996c). The "repeated application" method has the advantage
of knowing that the currents activated were those actually activated by
capsaicin, but it has the disadvantage of not knowing how the magnitude
and kinetics of the currents changed because of rundown
(tachyphylaxis). Using the voltage-ramp method (see Materials and
Methods) the full I-V curve as well as the
voltage-dependent kinetics can be obtained with a single application.
Consequently, problems associated with rundown or tachyphylaxis are
avoided.
To obtain I-V relationships and kinetics of the responses
to capsaicin, voltage ramps were generated before, during, and after application of 1 µM capsaicin. The currents activated
"before" (even in the presence of 0.3 µM TTX, 50 µM verapamil, and intracellular Cs+) were
frequently voltage-dependent (Fig. 5A). These
voltage-dependent currents, however, were prominent only during the
first 50 (or so) cycles whereupon they diminish after repeated cycling
to an extent that the I-V curve becomes smaller and
approximately linear near the 100th cycle. At this juncture the
background (BKG) I-V curve was defined. The two
I-V plots labeled a and b in Figure 5A were obtained at different times after the application of
capsaicin, with a being obtained at the earlier time. Figure
5B shows a plot of I versus
V where I = Icap IBKG, where
IBKG is the background current obtained just
before the application of capsaicin, and where
Icap is the current obtained two times
(a and b) after its application. It is important
to note that the reversal potential for these two I-V
curves a and b are 14.5 and 0 mV, respectively. Note also that in both plots the outward currents are larger than the
inward currents. The I-V curve representing the slower
activating current is the one commonly reported, because it has a
reversal potential near 0 mV. For six cells in which two currents were activated by capsaicin, the reversal potentials obtained at the peaks
of the rapidly and slowly activating currents were 15.3 ± 6.0 and
4 ± 2.5 mV, respectively. These values are significantly different (p < 0.05) using the paired
t test. Because the reversal potential of the rapidly
activating current is greater than that of the slowly activating
current, it follows that it is more cation-selective.
Fig. 5.
I-V relationship using the
voltage-ramp method. A, A voltage ramp from 70 to 70 mV was applied every 0.2 sec to a neuron before, during, and after
application of 1 µM capsaicin. Several of the 100 "before" traces were labeled. Note that the amplitude of the
voltage-dependent currents decreases with repeated cycling. Trace 100 was taken as the background current (BKG). The curves labeled a and b were taken ~4 and ~30
sec after application of 1 µM capsaicin.
B, Plots of two of the current-voltage curves. I is the measured current minus the BKG. The
a-BKG and b-BKG labels refer to the two
I-V curves in 5A. C,
I versus time plots at seven different
potentials that range from 60 to +60 mV. The 60 mV trace was
constructed from the currents at 60mV from the family of
I-V curves shown in 5B. Each
circle represents the current at 60 mV for one of the
family of I-V curves. In this figure every
fourth data point is shown. For clarity, the six other
I-time relationships are shown as continuous
at 60 mV. External solution, KH + 0.3 µM TTX. Internal
solution, Cs-SIS. Bar indicates duration of
stimulus.
[View Larger Version of this Image (17K GIF file)]
Using the data obtained from the entire family of I-V
curves, plots of I versus time at different
potentials could be generated. Figure 5C shows such plots at
seven different potentials (from 60 to +60 mV) for 1 µM
capsaicin. The trace labeled 60 mV was constructed from the currents
at 60mV from the family of I-V curves shown in Figure
5B. Each circle represents the current at 60 mV for one of
the I-V curves. The peak times for the fast and slow
currents were 2.8 and 30 sec, respectively. These values are consistent
with those obtained using the voltage-clamp method (Fig. 2). For
clarity, the six other I-time relationships were shown as continuous. In summary, using the voltage-ramp method we found
that capsaicin can activate two currents with kinetics and reversal
potentials that are distinctly different, that the I-V
curves are nonlinear, and that the voltage-ramp method is a valid
method to obtain the kinetic responses to capsaicin at different
voltages.
I-V plots for capsaicin, olvanil, and GLNVA
Using the protocol described above we now present the results of
an experiment (Fig. 6) in which 1 µM
olvanil, 1 µM capsaicin, and 30 µM GLNVA
were applied consecutively to a neuron. Between applications the cell
was washed for 6 min. The currents generated by these three agonists
(at 60 mV) are shown in Figure 6A. The I-V relationships taken at two "widely
separated" times (Fig. 6A, arrows) are presented in
Figure 6B. The envelope of the olvanil-induced currents, seen at 60 mV, indicates the presence of two inward currents with peak times of ~4 and ~18 sec, respectively. The I-V curves corresponding to the peak of the
rapidly activating current (a in Fig. 6B)
and the recovery phase of the slower current (b in Fig.
6B) demonstrate clearly the existence of two distinct inward currents, because they have reversal potentials of 27 and 5 mV
for the more rapidly and slowly activating currents, respectively. The
application of capsaicin (middle trace) also evoked two
currents with peak times of 4 and ~13 sec. That two currents are
present in this trace is confirmed by the I-V
curves where the reversal potentials of the more rapidly a-
and slowly b-activating currents were 25 and 7 mV,
respectively. This result is important because it shows that both
compounds can activate the same currents. The application of 30 µM GLNVA, evoked only a slowly activating and desensitizing current (p = 18 sec) that
transiently increased after wash. The two I-V
curves obtained during the activation and desensitization phases had
similar reversal potentials (approximately 5 mV), indicating that
GLNVA activated only a single current, the slowly activating current.
Thus, it follows that either the rapidly activating current was
desensitized by capsaicin, or that in this neuron the rapidly
activating current was not activated by GLNVA. Whatever the case, it is
clear from this experiment that the two currents are
separable.
For cells in which these agonists evoke multiple currents, the
I-V curves and the reversal potentials are clearly
comprised of two distinct contributions. Consequently, the numerical
values obtained for the I-V curves and the reversal
potentials are not truly reflective of a single transport pathway. The
reversal potentials for the rapidly activating response were 18 mV
(range, 4-35 mV), and those for the slowly activating induced were
~5 mV (range, 5 to 11.5 mV). We take this heterogeneity in reversal
potential to reflect different subtypes of vanilloid receptor
channels.
Dose-response for olvanil and GLNVA
Figure 7 shows the responses of two rat trigeminal
ganglion neurons held at 60mV to increasing concentrations of olvanil and GLNVA. In these experiments olvanil and GLNVA was applied for 10 and 30 sec, respectively. Olvanil was applied for shorter times to
reduce tachyphylaxis. Between applications the cells were washed for 6 min.
Fig. 7.
Dose-response for olvanil and GLNVA.
Bar indicates duration of stimuli. HP = 60
mV.
[View Larger Version of this Image (11K GIF file)]
Olvanil did not evoke a response at 0.03 µM, but evoked a
small inward current at 0.1 µM (threshold). Increasing
the olvanil concentration decreased the time to peak and increased the
magnitude of the current until it remained unchanged with increasing
concentration. The largest change in the magnitude of the currents
occurred between 0.3 and 1 µM olvanil.
A dose-response series for GLNVA is also shown in Figure 7. In this
neuron, 0.3 µM GLNVA did not evoke a current, 1 µM GLNVA evoked a small inward current (threshold), and
increasing the GLNVA concentration decreased the time to peak and
increased the magnitude of the current until saturation. Note that the
activation kinetics were slow even at 100 µM GLNVA.
In constructing dose-response curves, the peak currents,
Ip, are usually plotted against the agonist concentration.
In constructing plots of Ip versus concentration for
olvanil, however, we were aware that 10 sec may not have been
sufficiently long for the current to reach its absolute
maximum (see trace for 0.3 µM olvanil). Nevertheless, to
obtain some facsimile of the "true" dose-response plot, we had to
choose conditions in which tachyphylaxis (Figs. 9, 10) is kept
reasonably small and yet apply the agonist sufficiently long so that
the currents increase with concentration. By averaging data from
experiments such as those shown in Figure 7, we constructed dose-response curves for capsaicin (Liu and Simon, 1996c), olvanil (n = 7), and GLNVA (n = 6). (For the
seven olvanil experiments, four of them had data points for all six
concentrations and three had data points for five concentrations.)
These data, shown in Figure 8, were then fit to the Hill
equation, Ip/Ipmax = 1/(1 + (K1/2/C)n), where
K1/2 is the half maximal concentration,
n is the Hill coefficient, and Ipmax
is the maximum current. For capsaicin, olvanil, and GLNVA, it was found
that Ipmax = 7.10, 7.19, and 5.86 nA,
respectively; K1/2 = 0.68, 0.59, and 27.0 µM, respectively; and n = 1.38, 1.32, and
1.24, respectively. The Ip-concentration plots for olvanil
and capsaicin are indistinguishable. The parameters used to fit to the
GLNVA data should be considered tentative, because the response profile
did not, on average, reach saturation even at 100 µM.
Tachyphylaxis
Tachyphylaxis is defined as the diminution of a response to a drug
on repeated applications. Because of the pioneering work of Jancso et
al. (1967) many in vivo and in vitro studies have shown that capsaicin induces tachyphylaxis (Holzer, 1991; Liu and
Simon, 1996b,c). In line with the rest of this paper, here we compare
the tachyphylaxis produced by capsaicin (Liu and Simon, 1996b),
olvanil, and GLNVA. In neurons held at 60 mV, we found that 1 µM olvanil (Fig. 9A) and 30 µM GLNVA (Fig. 9B) produce tachyphylaxis. In
these experiments, either 1 µM olvanil or 30 µM GLNVA were applied for 30 sec up to seven times with
each application separated by a 2 min, 30 sec wash. The first olvanil
application produced a response with a peak at 27.6 sec. The second
application greatly reduced Ip by 81%. Subsequent
applications slightly reduced the current and by the seventh
application the current was essentially eliminated. The decrease in
current on repeated applications cannot be attributable entirely to
"rundown" because much smaller decreases are seen with 1 µM capsaicin (Liu and Simon, 1996b) (Fig.
10), 100 µM piperine (Liu and Simon,
1996b), and 30 µM GLNVA (Figs. 9B, 10).
Figure 9B shows the currents evoked by repeated applications
of 30 µM GLNVA. The initial GLNVA application induced a
large inward current. After wash, the second application produced a current having a smaller magnitude and with slower activation kinetics.
The third GLNVA application produced a small increase in the current,
and the fourth to seventh applications produced approximately the same
magnitude of currents.
The results of six individual tachyphylaxis experiments with 1 µM olvanil (neurons labeled O1-O6) and five with 30 µM GLNVA (neurons labeled G1-G5) are shown in Figure
10A. For example, the olvanil trace in Figure
9A corresponds to olvanil neuron O3, and the GLNVA trace in
Figure 9B corresponds to GLNVA neuron G3. The data are
presented in this manner to illustrate the heterogeneity of the
tachyphylaxis responses. For example, olvanil neuron O1 exhibited
complete tachyphylaxis after three applications, whereas for olvanil
neuron O5, ~20% of the initial current could be evoked on the
seventh application. In contrast, for GLNVA the current was never
completely inhibited after six applications. The means of these
responses, together with those obtained previously for 1 µM capsaicin (Liu and Simon, 1996c), are shown in Figure
10B. These data can be fit to the relation
%Ip remaining = A exp (n × 3 min/) + B, where A + B = 100%, t is the time constant of the current that did not
recover in a 2 min, 30 sec wash, and n = 0, 1, 2. The
constant B, reflects the percentage of the current that can
be recovered after washing for 2.5 min. Thus, for 1 µM olvanil the data fit the equation %Ip remaining = 89%
exp(n × 3 min/2.27 min) + 7.5%; (r = 0.997). For 30 µM GLNVA the data fit %Ip
remaining = 62.2% exp(n × 3 min/2.85 min) + 37.3%; (r = 0.998), and for capsaicin we found
previously %Ip remaining = 56.8% exp(
n × 3 min/4.83 min) + 42.6%; (r = 0.994). In summary, for GLNVA and capsaicin the processes of rundown
or tachyphylaxis are quite similar, whereas for olvanil tachyphylaxis
is much more pronounced.
DISCUSSION
To understand the differences between capsaicin and two of its
nonpungent analogs, olvanil and GLNVA, whole-cell patch-clamp studies
were performed on rat trigeminal ganglion neurons. It was found that:
(1) these compounds can activate two currents that can be distinguished
by their reversal potentials and kinetics, (2) the major difference
between them is that the currents activated by the nonpungent analogs
have, on average, slower activation kinetics, and (3) the tachyphylaxis
produced by olvanil is much greater than tachyphylaxis produced by
either capsaicin or GLNVA.
Olvanil and GLNVA belong to the family of compounds that activate
vanilloid receptors
Because olvanil and GLNVA are synthetic analogs of capsaicin they
should mimic many of its physiological effects. Because these analogs
were designed with the goal of being less or nonpungent, however, it
should not be expected that they would mimic all the physiological
responses of capsaicin with the exception of pungency, because the
properties that go into making a compound less pungent may also alter
other responses. The data obtained on cultured trigeminal ganglion
neurons provide some reasons for the similar and different
physiological responses evoked by these compounds. These three agonists
are similar in that they activate inward currents in a subset of
trigeminal ganglion neurons, are inhibited by capsazepine, can activate
currents in the same cell, and can activate two distinct currents with
similar reversal potentials in the same cell (Figs. 2, 3, 4, 5, 6). These data
suggest that the similarity in their physiological responses comes from
them activating some of the same subtypes of vanilloid receptors.
Capsaicin activates distinct currents in trigeminal
ganglion neurons
There is good evidence for the existence of multiple
subtypes of vanilloid receptors. These include the following: (1)
binding studies of radiolabeled resiniferatoxin (RTX) that showed
intraspecies heterogeneity and interspecies differences, (2)
differences in the association constants and Hill coefficients in
central and peripheral vanilloid receptors (Szallazi and Blumberg,
1993; Szallazi et al., 1993, 1994, 1995), and (3) vanilloid receptors
that could be distinguished by their ability to induce vasoconstriction
and/or be inhibited by capsazepine or ruthenium red (Colquhoun et al., 1995).
Our finding that the rapid and slowly activated currents are
independent and have distinct reversal potentials as well as the
existence of capsazepine-insensitive currents is good evidence for
multiple subtypes of vanilloid receptors. These data also suggest that,
like nicotinic acetylcholine and GABA receptors (McGehee and Role,
1995), different subtypes of vanilloid receptors may coexist in an
individual neuron.
Dose-response characteristics
Olvanil was found to be equipotent to capsaicin in increasing
Ca2+ influx in rat DRGs (Walpole and Wrigglesworth, 1993)
and in behavioral measurements of pain (Campbell et al., 1993). That
olvanil and capsaicin exhibit similar dose-response curves (Fig. 8) is
consistent with these studies. Olvanil, however, was found to be 10 times more potent than capsaicin as a vasodilator (Hughes et al., 1992) and ~250 times less potent in evoking similar responses from rat spinal cord (Dray et al., 1990). These differences likely indicate the
presence of subtypes of vanilloid receptors. GLNVA was shown to be
~15 times less potent than capsaicin in blood pressure measurements obtained from rats (Yeh et al., 1993). From the dose-response curves
(Fig. 8) we found a 39-fold difference in the
K1/2 between capsaicin and GLNVA. Given the
different nature of these measurements, we consider the agreement to be
reasonable.
Tachyphylaxis
Although there have been many tachyphylaxis experiments performed
that characterize the effects of capsaicin (Holzer, 1991), there is
very little data regarding tachyphylaxis for olvanil and GLNVA. This
study represents the first patch-clamp data describing tachyphylaxis
(rundown) for these two nonpungent agonists. We found that the
tachyphylaxis experiments could all fit to the equation %Ip
remaining = A exp(n × 3 min/) + B, where A + B = 100%,
B is the percentage of the current that can be recovered after seven or more 2.5 min washes, and A is the magnitude
of the current that was not recovered. We have interpreted A
to represent the percentage of the channels that convert into a stable
long-lived desensitized state with time constant, , and B
the current that can be recovered after a 30 sec application and a 2.5 min wash (Liu and Simon, 1996c). Whatever the processes underlying this behavior, the relative magnitudes of A and B for
five capsazepine-inhibitable vanilloid receptor agonists (capsaicin,
piperine, zingerone, olvanil, and GLNVA) can be compared. We found
B = 42, 7.5, 37, 60, and 0% for 1 µM
capsaicin, 1 µM olvanil, 30 µM GLNVA, 100 µM piperine, and 30 mM zingerone (Liu and
Simon, 1996b,c), respectively. The B values fall broadly
into two groups: one containing olvanil and zingerone where little or
none of the current recovered from a desensitized state, and the other
containing capsaicin, GLNVA, and piperine, where approximately half the
current recovered. Because capsaicin, piperine, and zingerone are
pungent, whereas olvanil and GLNVA are nonpungent, it follows that the
extent that a particular agonist induces tachyphylaxis (or recovers
from desensitized states) is not correlated with its pungency.
Speculations regarding the basis of pungency of capsaicin and
its analogs
Despite the fact that capsaicin, olvanil, and GLNVA activate the
same classes of receptors they do not always produce the same physiological responses. As noted previously, one or both of these
compounds may differ from capsaicin in potency, thermoregulatory effects, peptide release, blood pressure lowering, and pungency. Although there are several reasons why olvanil and GLNVA may give different physiological responses than capsaicin, such as the possibility that capsaicin acts peripherally whereas olvanil acts centrally (Dickenson et al., 1990), our data suggest that the differences between these two nonpungent analogs and capsaicin may be
accounted for by either the presence and distribution of different
receptor subtypes and/or by the slower rate of activation of the
currents evoked by GLNVA and olvanil.
Pungency arises as a consequence of the activation of primary
nociceptors that subsequently transmit information to the higher CNS
centers. In the presence of depolarizing currents such as those
produced by capsaicin, subsets of nociceptors evoke action potentials
(Kenins, 1982) and thus transmit information to the CNS. If the
subtypes of vanilloid receptors for nonpungent analogs on the periphery
are smaller affinities (K1/2) than those that are centrally located, then the probability of them being activated at
the same concentration as capsaicin to produce nociception will be
markedly reduced, and hence they will be less pungent.
Transmission of action potentials to the CNS (and hence pungency),
however, could also be inhibited by blocking and/or inactivating voltage-dependent Na+, K+, and Ca2+
channels, because these channels are responsible for the generation, propagation, and transmission of action potentials. It is established that capsaicin blocks voltage-dependent Na+,
K+, and Ca2+ channels (Marsh et al., 1987;
Docherty et al., 1991; Kehl, 1994), which will prevent the generation
of trains of action potentials. Despite these "local anesthetic"
effects, capsaicin is pungent, meaning that action potentials are
transmitted to the higher centers and that in primary nociceptors,
depolarization precedes inhibition. To identify a compound that will
not evoke action potentials from nociceptors, and still desensitize
them, it would be advantageous to find a capsaicin analog that
preferentially activates slowly activatable subtypes of vanilloid
receptors while rapidly (relatively) inhibiting and/or inactivating
voltage-dependent Na+, K+, and Ca2+
channels. [In this regard it is important to note that it may take
several action potentials to get transmitter release to secondary neurons (Zucker and Haydon, 1988).] We propose that some of the differences between nonpungent and pungent compounds can be attributed to rates of activation of vanilloid receptors to the relative rates of
blocking or inactivating of voltage-dependent Na+,
K+, and Ca2+ channels.
We now focus on the interactions of olvanil with neurons because more
is known about it than about the interactions of GLNVA. There is no
question that olvanil inhibits Na+ channels because it
blocks evoked responses from A -fibers (Dickenson et al., 1990). The
comparatively slower activation kinetics seen in most neurons with
olvanil cannot be attributed to different K1/2
values, because on average they were the same as the capsaicin values
(Fig. 9). The generally slower activation kinetics of olvanil compared
with capsaicin may rationalize why larger olvanil concentrations are
required to evoke responses from rat spinal cords even though olvanil
and capsaicin have similar antinociceptive potencies (Campbell et al.,
1989; Dray et al., 1990). We suggest that until a sufficiently large
olvanil concentration in spinal is cord used, such that the activation
rates of olvanil become similar to those of capsaicin, its anesthetic
effects will dominate, and under these conditions olvanil will be
nonpungent.
Differences in the kinetics of various channel states is also
seen by the greater tachyphylaxis produced by olvanil than by capsaicin
(Fig. 10). This behavior likely reflects the longer time the channel
spends in a desensitized state with olvanil. This explanation may also
shed light on some properties of the ultrapotent agonist RTX that were
previously unexplained. It was found that RTX is 20,000 times as potent
as capsaicin in blocking neurogenic inflammation, but only 10 times as
pungent, as determined in eye-wiping experiments (Szallasi and
Blumberg, 1990). Because RTX, like olvanil, exhibits slow activation
kinetics (Winter et al., 1990; Liu and Simon, 1996c) the relatively
small pungency of RTX may be a consequence of its relatively rapid
blocking or inactivating of voltage-dependent channels and hence action
potentials.
FOOTNOTES
Received Dec. 20, 1996; revised March 4, 1997; accepted March 24, 1997.
This work was supported by National Institutes of Health Grant DC 01065 and by the Philip Morris Corporation.
Correspondence should be addressed to Dr. Sidney A. Simon, Department
of Neurobiology, Duke University Medical Center, Durham, NC 27710.
aIn the literature describing the effects of capsaicin
desensitization has meant the diminution of a response to capsaicin after the initial application. In this paper we will refer to this
process as tachyphylaxis or rundown. Desensitization will refer to the
diminution of the magnitude of the evoked current in the presence of an
agonist.
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