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Volume 16, Number 14,
Issue of July 15, 1996
pp. 4322-4334
Copyright ©1996 Society for Neuroscience
Cannabinoid Receptor Agonists Inhibit Glutamatergic Synaptic
Transmission in Rat Hippocampal Cultures
Maoxing Shen1,
Timothy
M. Piser1,
Virginia S. Seybold2, and
Stanley A. Thayer1
Departments of 1 Pharmacology and 2 Cell
Biology and Neuroanatomy, University of Minnesota Medical School,
Minneapolis, Minnesota 55455
 ABSTRACT
- INTRODUCTION
- MATERIALS AND METHODS
- RESULTS
- DISCUSSION
- FOOTNOTES
- REFERENCES
ABSTRACT 
Activation of cannabinoid receptors inhibits voltage-gated
Ca2+ channels and activates
K+ channels, reminiscent of other
G-protein-coupled signaling pathways that produce presynaptic
inhibition. We tested cannabinoid receptor agonists for effects on
excitatory neurotransmission between cultured rat hippocampal neurons.
Reducing the extracellular Mg2+ concentration to
0.1 mM elicited repetitive, transient increases
in intracellular Ca2+ concentration
([Ca2+]i spikes) that
resulted from bursts of action potentials, as measured by combined
whole-cell current clamp and indo-1-based microfluorimetry.
Pharmacological characterization indicated that the
[Ca2+]i spikes required
glutamatergic synaptic transmission. Cannabinoid receptor ligands
inhibited stereoselectively the frequency of
[Ca2+]i spiking in the
rank order of potency: CP 54,939 > CP 55,940 > Win 55,212-2 > anandamide, with EC50 values of 0.36, 1.2, 2.7, and 71 nM, respectively. CP 55,940 was potent,
but not efficacious, and reversed the inhibition produced by Win
55,212-2, indicating that it is a partial agonist. Inhibition of
[Ca2+]i spiking by Win
55,212-2 was prevented by treatment of cultures with active, but not
heat-treated, pertussis toxin. Win 55,212-2 (100 nM) inhibited stereoselectively CNQX-sensitive
excitatory postsynaptic currents (EPSCs) elicited by presynaptic
stimulation with an extracellular electrode, but did not affect the
presynaptic action potential or currents elicited by direct application
of kainate. Consistent with a presynaptic site of action, Win 55,212-2 increased both the number of response failures and the coefficient of
variation of the evoked EPSCs. In contrast, cannabimimetics did not
affect bicuculline-sensitive inhibitory postsynaptic currents. Thus,
activation of cannabinoid receptors inhibits the presynaptic release of
glutamate via an inhibitory G-protein.
Key words:
cannabinoid;
glutamate;
presynaptic inhibition;
G-protein;
intracellular calcium;
indo-1;
patch clamp;
hippocampal
culture
INTRODUCTION
In addition to its widespread recreational use,
 -9-tetrahydrocannabinol, the principal psychoactive ingredient in
marijuana, has significant therapeutic potential (Abood and Martin,
1992 ). Cannabinoids have been reported to be clinically effective
analgesics and useful in the treatment of glaucoma, bronchial asthma,
diarrhea, muscle spasticity, and convulsions (Howlett, 1995). However,
established clinical use of cannabinoids has been limited to their use
as antiemetics and appetite stimulants in cancer and AIDS patients
(Weinroth et al., 1995). Potential clinical applications have provided
a rationale for synthesis of water-soluble cannabinoid analogs (e.g.,
CP 55,940 and CP 54,939) (Johnson and Melvin, 1986) and
aminoalkylindoles (e.g., Win 55,212-2) (Bell et al., 1991; D'Ambra et
al., 1992) that have proven to be highly selective and potent
activators of cannabinoid receptors in vitro and in
vivo (Devane et al., 1988; Compton et al., 1992; Compton et al.,
1993).
The cannabinoid receptor is a member of the seven helix
transmembrane, G-protein-linked receptor superfamily (Matsuda et al.,
1990). Both mRNA for this receptor, and binding sites for radiolabeled
cannabinoids, are distributed widely throughout the CNS, including
cerebral cortex, hippocampus, basal ganglia, and cerebellum (Herkenham
et al., 1990; Jansen et al., 1992; Mailleux and Vanderhaeghen, 1992;
Thomas et al., 1992; Matsuda et al., 1993). Identification of an
endogenous ligand, anandamide (Devane et al., 1992; Deutsch and Chin,
1993; Felder et al., 1993; Dimarzo et al., 1994), that activates
cannabinoid receptors suggests that anandamide, in conjunction with the
cannabinoid receptor, forms a neuromodulatory system (Mechoulam et al.,
1994).
Activation of cannabinoid receptors inhibits adenylate cyclase via an
inhibitory G-protein (Howlett et al., 1986; Bidaut-Russell et al.,
1990; Childers et al., 1992; Compton et al., 1993). Similar to other
receptors that interact with inhibitory G-proteins, cannabinoid
receptors also couple to ion channels (Martin et al., 1994).
Cannabimimetics inhibit N- and Q-type voltage-gated
Ca2+ channels via pertussis toxin (PTX)-sensitive
G-proteins (Caulfield and Brown, 1992; Mackie and Hille, 1992; Mackie
et al., 1995; Pan et al., 1996). Cannabinoids enhance activation of
A-type K+ currents in cultured hippocampal
neurons via PTX-sensitive G-proteins (Deadwyler et al., 1993), and an
inwardly rectifying K+ channel in
Xenopus oocytes co-injected with GIRK1 and cannabinoid
receptor mRNA (Henry and Chavkin, 1995). Cannabinoids also inhibit
long-term potentiation of the Schaeffer collateral commissural
fiber-CA1 synapse (Nowicky et al., 1987; Collins et al., 1994),
suggesting that the cannabinoid system may modulate glutamatergic
synaptic transmission. Thus, cannabinoid receptor signal transduction
is reminiscent of several well-characterized neurotransmitter receptor
systems, including those of adenosine and the opioids, that couple to
inhibitory G-proteins to produce presynaptic inhibition of synaptic
transmission in the hippocampus (Thompson et al., 1993).
In this report, we test directly the hypothesis that activation of
cannabinoid receptors inhibits glutamatergic synaptic transmission. Our
data are consistent with this hypothesis in that synaptic activity
blocked completely by glutamate receptor antagonists also was inhibited
by cannabinoid receptor agonists. Additional pharmacological
characterization of this effect determined that both endogenous and
synthetic cannabinoid receptor agonists activate potently and
stereoselectively a presynaptic receptor that inhibits the release of
glutamate via an inhibitory G-protein. Modulation of synaptic glutamate
release may account for the psychoactive, analgesic, and anticonvulsant
effects of the cannabinoids.
MATERIALS AND METHODS
Materials. Materials were obtained from the following
companies: indo-1 AM and indo-1 pentapotassium salt, Molecular Probes,
Eugene, OR; PTX, List Biological Laboratories, Campbell, CA;
anandamide, ( )-bicuculline methchloride, kainic acid, NMDA,
(±)2-amino-5-phosphonopentanoic acid, CGS19755, and CNQX, RBI,
Natick, MA; Win 55,212-2 and Win 55,212-3, Sterling-Winthrop,
Rensselaer, NY, or RBI; CP 54,939 (desacetyllevonantradol) and CP
55,940 (levorotatory enantiomer), Pfizer, Groton, CT; media and sera,
GIBCO, Grand Island, NY; and all other reagents, Sigma, St. Louis,
MO.
Cell culture. Rat hippocampal neurons were grown in primary
culture as described previously (Wang et al., 1994) with minor
modifications. Fetuses were removed on embryonic day 17 from maternal
rats anesthetized with CO2 and killed by
decapitation. Hippocampi were dissected and placed in
Ca2+ and Mg2+-free
HEPES-buffered Hank's salt solution (HHSS), pH 7.45. HHSS was composed
of the following (in mM): HEPES 20, NaCl 137, CaCl2 1.3, MgSO4 0.4, MgCl2 0.5, KCl 5.0, KH2PO4 0.4, Na2HPO4 0.6, NaHCO3 3.0, and glucose 5.6. Cells were
dissociated by trituration through a 5 ml pipette and a flame-narrowed
Pasteur pipette. Cells were pelleted and resuspended in DMEM without
glutamine, supplemented with 10% fetal bovine serum and
penicillin/streptomycin (100 U/ml and 100 µg/ml, respectively).
Dissociated cells then were plated at a density of 50,000 cells/well
onto 25-mm-round 1 cover glasses that had been coated with
poly-D-lysine (0.1 mg/ml), and washed with
H2O. Neurons were grown in a humidified
atmosphere of 10% CO2 and 90% air (pH = 7.4) at 37°C, and fed every 7 days by exchange of 30% of the media
with DMEM supplemented with 10% horse serum and
penicillin/streptomycin. Cells used in these experiments were cultured
without mitotic inhibitors for a minimum of 2 weeks.
[Ca2+]i measurement.
[Ca2+]i was
determined using a previously described dual-emission microfluorimeter
(Werth and Thayer, 1994) to monitor indo-1 (Grynkiewicz et al., 1985).
Cells were loaded with 2 µM indo-1
acetoxymethyl ester for 45 min at 37°C in HHSS containing 0.5%
bovine serum albumin. Loaded cells were placed in a flow-through
chamber (Thayer et al., 1988), and experiments were performed at room
temperature. The chamber was mounted on an inverted microscope, and
cells were superfused with HHSS containing 10 µM glycine at a rate of 1-2 ml/min for 15 min
before starting an experiment. Superfusion solutions were selected with
a multiport valve coupled to several reservoirs.
For excitation of indo-1, light from a 75 W Xe arc lamp was passed
through a 350/10 nm band-pass filter (Omega Optical, Brattleboro, VT).
Excitation light was reflected from a dichroic mirror (380 nm), through
a 70 × phase-contrast oil immersion objective (Leitz, numerical
aperture 1.15). Emitted light was reflected sequentially from dichroic
mirrors (440 and 516 nm), through band-pass filters (405/20 and 495/20
nm, respectively), to photomultiplier tubes operating in
photon-counting mode (Thorn EMI, Fairfield, NJ). Cells were illuminated
with transmitted light (580 nm long pass) and visualized with a video
camera placed after the second emission dichroic. Recordings were
defined spatially with a rectangular diaphragm. The 5 V photomultiplier
output was integrated by passing the signal through an eight-pole
Bessel filter at 2.5 Hz. This signal then was input into two channels
of an analog-to-digital converter (Indec Systems, Sunnyvale, CA)
sampling at 1 Hz.
After completion of each experiment, cells were wiped from the
microscope field using a cotton-tipped applicator, and background light
levels were determined (typically <5% of cell counts).
Autofluorescence from cells that had not been loaded with dye was not
detectable. Records were corrected later for background, and the ratios
recalculated. Indo-1 was calibrated by converting the ratios to
[Ca2+]i by the equation
[Ca2+]i =
Kd (R Rmin)/(Rmax R), in
which R is the 405/495 nm fluorescence ratio. The
Kd used for indo-1 was 250 nM, and was the ratio of the emitted
fluorescence at 495 nm in the absence and presence of calcium.
Rmin, Rmax, and
were determined in ionomycin-permeabilized cells in calcium-free (1 mM EGTA) and 5 mM
Ca2+ buffers. The system was recalibrated after
any adjustments. Values of Rmin,
Rmax, and ranged from 0.35-0.38,
4.23-4.34, and 3.0-3.95, respectively.
Electrophysiology. Whole-cell recordings were obtained from
cultured neurons using pipettes (3-5 M resistance) pulled from
borosilicate glass (Narashige, Greenvale, NY) on a Sutter Instruments
(Novato, CA) P-87 micropipette puller. For recording EPSCs,
kainate-gated currents, and action potentials, pipettes were filled
with a solution containing (in mM): k-gluconate
130, KCl 10, NaCl 10, BAPTA 10, HEPES 10, glucose 10, MgATP 5, Na2GTP 0.3, pH 7.2 with KOH, 300 mOsm/kg.
Whole-cell recordings were established in an extracellular solution
containing (in mM): NaCl 127, KCl 5, CaCl2 10, MgCl2 0.9, glucose 5, and HEPES 10, pH 7.4 with NaOH. For experiments measuring
EPSCs and kainate-evoked currents, after the gigaohm seal was formed,
the external solution was changed to one containing (in
mM): NaCl 140, KCl 5, CaCl2
3, MgCl2 6, glucose 5, HEPES 10, pH 7.4 with
NaOH, 310 mOsm/kg with sucrose. High divalent ion concentrations were
used to suppress polysynaptic responses. Polysynaptic responses were
suppressed further by using sparse cultures and selecting pairs of
cells that were alone in the microscope field (400 ×). The high
extracellular Mg2+ concentration
([Mg2+]o) together with
the absence of glycine served to isolate the non-NMDA component of the
synaptic response. In some EPSC experiments, the external solution
contained 10 µM bicuculline methchloride;
results were similar with or without bicuculline in the bath. Action
potentials were recorded in an extracellular solution that contained
(in mM): NaCl 143, KCl 5, CaCl2 1.3, MgCl2 0.9, glucose 5, HEPES 10, pH 7.4 with NaOH, 310 mOsm/kg with sucrose. IPSCs
were recorded as for EPSCs, except that the extracellular solution
contained 50 µM AP-5 and 10 µM CNQX, and the pipettes were filled with a
solution containing (in mM): KCl 140, BAPTA 10, HEPES 10, glucose 10, MgATP 5, Na2GTP 0.3, QX314
1, pH 7.2 with KOH, 300 mOsm/kg. For NMDA-gated currents, the pipette
solution contained (in mM)
CsMeSO3 125, CsCl 15, CaCl2
3, BAPTA 11, HEPES 20, MgATP 5, Na2GTP 0.3, pH
7.2 with CsOH, 300 mOsm/kg, and the external recording solution
contained (in mM): KCl 5, NaCl 137, CaCl2 1.3, HEPES 20, glucose 5, and (in
µM): glycine 10, strychnine 2, bicuculline
methchloride 10, CNQX 10, and TTX 0.3, pH 7.4 with NaOH, 310 mOsm/kg
with sucrose. Combined electrophysiology and microfluorimetry
experiments were conducted in extracellular solution similar to that
used for synaptic transmission recordings except that
CaCl2 was 1.3 mM,
MgCl2 was either 0.9 or 0.1 mM, and 10 µM glycine was
added. Na2GTP was omitted from the pipette
solution, and 200 µM indo-1 pentapotassium
salt, the cell-impermeant form of the fluorescent calcium chelator, was
substituted for BAPTA. Indo-1 fluorescence was measured as described
above in [Ca2+]i measurement
except that background light levels were collected in the
cell-attached configuration. Solutions were applied by a gravity-fed
superfusion system; exchange of solutions was complete within 10 sec.
Drugs were applied until an apparent steady-state inhibition was
achieved.
Whole-cell currents were recorded using an Axopatch 200A patch-clamp
amplifier and the BASIC-FASTLAB interface system (Indec systems). For
combined electrophysiology and microfluorimetry, membrane potential
recordings were filtered at 25 Hz (four-pole Bessel low-pass filter)
and sampled every 8 msec (slow sweeps, see Fig. 2) or were filtered at
200 Hz and sampled every 1 msec (fast sweeps, see Fig. 2). Synaptic
transmission and current-clamp recordings were filtered at 2 kHz and
sampled every 100 µsec. EPSCs were elicited every 10 sec, and IPSCs
were elicited every 15 sec by a 0.1 msec pulse delivered by a
concentric-bipolar, extracellular, stimulating electrode positioned
near the cell body of a nearby neuron. The postsynaptic cell was
voltage clamped at 70 mV. Action potentials were evoked every 5 sec
by current injection through the patch pipette or every 15 sec by a
concentric-bipolar, extracellular, stimulating electrode positioned
near the cell body and recorded in whole-cell current-clamp mode.
Kainate and NMDA-gated currents were recorded from cells held at 70
mV and elicited by a 15 sec bath application of agonist (100 µM) applied every 5 min. These currents were
filtered at 20 Hz and sampled every 10 msec. Displayed currents were
not corrected for leak.
Fig. 2.
Low
[Mg2+]o-induced
[Ca2+]i spiking is driven
by bursts of action potentials.
[Ca2+]i (upper
trace) and membrane potential (Vm,
lower trace) recorded from a hippocampal neuron in
whole-cell current clamp. Initially, the neuron was bathed in a
solution containing 0.9 mM
[Mg2+]o; the
arrow indicates the onset of exposure to 0.1 mM
[Mg2+]o. Action
potentials are truncated in this record by low sampling rate (125 Hz)
and filter setting (25 Hz). Data collection was interrupted briefly
after ~1 min and again after ~3 min, as indicated by
gaps in the traces. Inset,
[Ca2+]i (two upper
traces) and Vm (two lower
traces) recorded from the same neuron with a higher sampling rate
(1 kHz) and filter setting (200 Hz) during a burst in either 0.9 or 0.1 mM
[Mg2+]o. The onset of the
bursts have been aligned to illustrate that the burst in low
[Mg2+]o lasts longer,
contains more action potentials, and triggers a much larger
[Ca2+]i transient. All
traces are representative of four experiments.
[View Larger Version of this Image (37K GIF file)]
Data analysis. The frequency of
[Ca2+]i spiking was
calculated from data collected during a 10 min window starting 5 min
after changing the bath to 0.1 mM
[Mg2+]o for control
(Fcontrol) and from a 5 min window starting
5 min after drug application for drug-treated (F). Percent
inhibition was calculated by the formula
((Fcontrol F)/Fcontrol) × 100. The
concentration-response curve was fit by a logistic equation of the
form % inhibition = ((IMax IMin)/(1 + (X/EC50)b)) + IMin, where X is the agonist
concentration, IMin and
IMax are the % inhibition calculated for
X = 0, and for an ``infinite'' concentration,
respectively, and b is a slope factor that determines the
steepness of the curve (De Lean et al., 1978).
EC50 values were calculated by a nonlinear,
least-squares curve fitting algorithm using Fig.P software
(Biosoft).
Whole-cell currents were analyzed as follows. The mean current measured
during the 5 msec (EPSC and IPSC) or 5 sec (kainate-gated current and
NMDA-gated current) before the stimulus artifact was designated as
holding current and the maximum inward current measured at any point
between the upstroke and decay of the current was designated as peak
current for a given response. Percent inhibition was calculated by the
formula ((Imax I)/Imax) × 100, in which
I for a given treatment was determined by subtracting the
average holding current from the average peak current of several sweeps
obtained after inhibition had reached apparent equilibrium during that
treatment, and Imax was determined by
applying the same procedure to several sweeps obtained just before drug
application.
Synaptic responses were analyzed for changes in the number of
failures and changes in the coefficient of variation (CV). The failure
of synaptic transmission was assessed by inspecting visually individual
sweeps for significant deflection from the baseline noise during 20 msec after the stimulus artifact (Ulrich and Huguenard, 1995). CV
analysis was used to determine synaptic site of action of cannabinoid
agonists (Faber and Korn, 1991). CV was calculated from 10 to 30 consecutive sweeps. CV = (varsignal)0.5/M,
where M is the mean EPSC amplitude and the
varsignal is the variance of the recorded
EPSC amplitudes corrected for the variance of the background noise
using the relation varsignal = varEPSC varnoise. Background noise was estimated by
subtracting two periods of averaged recording of baseline before the
stimulus artifact from each other (Sayer et al., 1989). Changes in the
ratio of the CVs squared (r), r = CV2control/CV2drug were compared with
the modification factor ( ), = Mdrug/Mcontrol
(Ulrich and Huguenard, 1995).
Changes in the action potential were assessed by measuring the resting
membrane potential, action potential threshold, action potential
duration, and action potential amplitude. Resting membrane potential
was determined by calculating the mean membrane potential during the 5 msec preceding current injection. Action potential threshold was
defined as the inflection point of the derivative of the membrane
potential during current injection. Amplitude was measured from
threshold to the peak, and the action potential duration was measured
at half peak amplitude.
Data are presented as mean ± SEM. Statistical comparisons were
made by Student's t test or ANOVA with Bonferroni
post-test.
RESULTS
Reduced [Mg2+]o induces a stable pattern
of glutamatergic synaptic activity
Reducing [Mg2+]o
elicits a repetitive pattern of excitatory electrical activity and
[Ca2+]i spiking in
synaptically connected central neurons in primary culture (Kudo and
Ogura, 1986; Abele et al., 1990; Rose et al., 1990; Robinson et al.,
1993). In rat hippocampal cultures, reducing
[Mg2+]o to 0.1 mM elicited repetitive
[Ca2+]i spikes (Fig.
1A). Spike frequency and amplitude decreased
over the first 5 min to stabilize at a mean frequency of 0.15 ± 0.08 Hz (mean ± SD, n = 215) and amplitude of 395 ± 32 nM (n = 26). This frequency is
in good agreement with the frequency of
[Ca2+]i spikes observed
in response to treatment of cultured cortical (Robinson et al., 1993)
and hippocampal (Kudo and Ogura, 1986; Ogura et al., 1987) neurons with
Mg2+-free buffers.
[Ca2+]i spiking was
dependent on glutamatergic synaptic activity, as indicated by complete
block of spiking by the non-NMDA receptor antagonist CNQX (Fig.
1B). Superfusion of 10 µM CNQX onto
cells spiking in the presence of 0.1 mM
[Mg2+]o blocked spiking
activity completely and reversibly in each of five cells tested. The
spiking activity also had a component mediated by NMDA receptors, as
indicated by inhibition of
[Ca2+]i spiking by the
NMDA receptor antagonist CGS19755 (Fig. 1C). Superfusion of
10 µM CGS19755 reduced
[Ca2+]i spiking frequency
by 61 ± 19% and decreased amplitude by 74 ± 11% (n = 5). TTX (1 µM) completely blocked all
[Ca2+]i spiking activity
induced by 0.1 mM
[Mg2+]o (Fig.
1D, n = 5). This pharmacological
characterization of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking reveals
that activation of glutamatergic synapses is required to produce the
spikes. The sensitivity of the 0.1 mM
[Mg2+]o-induced spiking
to all drugs tested in this study was independent of the initial
frequency of spiking. Recording changes in
[Ca2+]i spike frequency
provides a relatively straightforward method to study the effects of
drugs on glutamatergic synaptic activity (Abele et al., 1990; Rose et
al., 1990; Robinson et al., 1993).
Fig. 1.
Pharmacological characterization of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking in
cultured rat hippocampal neurons. A, Stable
[Ca2+]i spiking was
induced by superfusion with 0.1 mM
[Mg2+]o during the time
indicated by the horizontal bar (n = 26).
Note that the frequency of
[Ca2+]i spiking was high
initially, then decreased to become stable after 5 min of exposure to
0.1 mM
[Mg2+]o.
[Ca2+]i spiking required
low Mg2+ buffer, because spiking disappeared when
[Mg2+]o was restored to
0.9 mM. In separate experiments, CNQX (10 µM, n = 5) (B) and
TTX (1 µM, n = 5)
(D) blocked low
[Mg2+]o-induced
[Ca2+]i spiking
completely, whereas CGS19755 (10 µM,
n = 5) (C) inhibited, but did not completely
block, spiking. Treatments were applied during the times indicated by
the horizontal bars. Scale bars apply to all
traces. Low [Mg2+]o was
applied throughout the recordings shown in
B-D.
[View Larger Version of this Image (65K GIF file)]
Low [Mg2+]o (0.1 mM)-induced
[Ca2+]i spiking is driven by bursts of action
potentials
To characterize the nature of the electrical activity that
underlie [Ca2+]i spikes,
we conducted combined whole-cell current-clamp and microfluorimetric
recordings. In Figure 2, membrane potential (lower
trace) was recorded simultaneously with indo-1-based
[Ca2+]i measurements
(upper trace). Virtually all neurons in these hippocampal
cultures had some level of spontaneous activity. Typically, as shown in
the initial 1 min of the recording in Figure 2, we observed either
occasional, single action potentials that failed to produce a
detectable increase in
[Ca2+]i or a spontaneous
burst of action potentials that produced a small transient
[Ca2+]i increase as shown
in Figure 2 immediately preceding the reduction in
[Mg2+]o. After reducing
[Mg2+]o to 0.1 mM, periodic bursts of action potentials were
generated coincident with large
[Ca2+]i spikes. In Figure
2 inset, a recording of a spontaneous burst and a burst recorded in 0.1 mM
[Mg2+]o are superimposed.
Similar high time-resolution recordings from four cells revealed that
exposure to 0.1 mM
[Mg2+]o increased burst
duration dramatically (3.4 ± 0.6 sec) and the number of action
potentials per burst (30 ± 6) relative to spontaneous bursts in
physiological [Mg2+]o
(1.0 ± 0.2 sec and 11 ± 2 action potentials). The increased burst
intensity in low [Mg2+]o
also produced a threefold increase in
[Ca2+]i spike amplitude.
A similar pattern of bursting electrical activity has been observed in
hippocampal and cortical cultures after complete removal of
[Mg2+]o (Abele et al.,
1990; Rose et al., 1990; Robinson et al., 1993). We found that reducing
[Mg2+]o to 0.1 mM rather than omitting it altogether decreased
the frequency slightly and enhanced the stability and periodicity of
bursts, rendering the method more suitable for assessing effects of
drugs on glutamatergic synaptic activity (Abele et al., 1990).
Cannabinoid receptor agonists inhibit stereoselectively
[Ca2+]i spiking
We evaluated the effects of cannabimimetics on 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking. Our
initial test for a potential role of cannabinoid receptors in
modulating glutamatergic synaptic activity was to take advantage of the
stereoisomers of Win 55,212, which differ in affinity for cannabinoid
receptors by well over 1000-fold (D'Ambra et al., 1992; Jansen et al.,
1992; Kuster et al., 1993). As shown in Figure 3,
superfusion with 10 nM Win 55,212-3, the inactive
isomer, was without effect, although subsequent application of the
active enantiomer, Win 55,212-2, completely blocked low
[Mg2+]o-induced
[Ca2+]i spiking. Overall,
10 nM Win 55,212-2 inhibited spiking frequency by
86 ± 4%, whereas 10 nM Win 55,212-3 did not
affect [Ca2+]i spiking in
any of the seven cells tested.
Fig. 3.
Stereospecific inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking by
cannabinoid receptor agonists. Win 55,212-3 and Win 55,212-2 (10 nM) were applied sequentially, as indicated by
horizontal bars. The cell was exposed to 0.1 mM
[Mg2+]o throughout the
recording. Win 55,212-3, a biologically inactive stereoisomer of the
potent cannabinoid receptor agonist Win 55,212-2, did not affect low
[Mg2+]o-induced
[Ca2+]i spiking, but Win
55,212-2 blocked [Ca2+]i
spiking completely. The trace shown is representative of seven
experiments.
[View Larger Version of this Image (63K GIF file)]
Synthetic cannabinoid receptor agonists are potent inhibitors of
[Ca2+]i spiking frequency
We tested two classes of synthetic cannabinoid receptor agonists
for their ability to inhibit, in a concentration-dependent manner, low
[Mg2+]o-induced
excitatory activity. CP 54,939 and CP55,940 are chemical derivatives of
cannabinol (Johnson and Melvin, 1986). Win 55,212-2 is an
aminoalkylindole, a group of compounds with potent cannabimimetic
actions (Bell et al., 1991; D'Ambra et al., 1992). As shown in Figure
4, these compounds all potently reduced the frequency of
0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking.
Increasing the concentration of these cannabimimetic drugs produced a
graded reduction in the frequency of the spikes. Spike amplitude also
decreased with increasing concentrations of the drugs, although this
effect was more variable and only became apparent at concentrations
that produced at least 50% inhibition of spike frequency.
EC50 values were calculated by fitting the
concentration response data plotted in Figure 4D with a
logistic equation as described in Materials and Methods.
EC50 values for CP 54,939, CP 55,940, and Win
55,212-2 were 0.36 ± 0.05, 1.2 ± 0.7, and 2.7 ± 0.3 nM, respectively, in reasonable agreement with
previously published potency and rank order, which varies somewhat
between preparations (see Discussion). The slope factors (b)
for CP 54,939, CP 55,940, and Win 55,212-2 were 0.89 ± 0.09, 0.98 ± 0.46, and 1.6 ± 0.26, respectively. Because known drug concentrations
were perfused continually in these experiments, b can be
interpreted as the Hill coefficient nH (De
Lean et al., 1978). Thus, for CP 54,939 and CP 55,940, a single class
of noncooperative binding sites is suggested, because b
approximates 1. Interestingly, the b value for Win 55,212-2, an aminoalkylindole, appears greater than the values calculated for the
cannabinoid analogs CP 54,939 and CP 55,940. A more complete structure
activity relationship is required to determine the significance of this
observation to the interaction of these drugs with the cannabinoid
receptor.
Fig. 4.
Inhibition of low
[Mg2+]o-induced
[Ca2+]i spiking by the
aminoalkylindole Win 55,212-2 and the synthetic cannabinoids CP54,939
and CP55,940. A-C, Representative traces
illustrate concentration-dependent inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking by Win
55,212-2, CP54,939, and CP55,940. Drug application is indicated by the
bars, and 0.1 mM
[Mg2+]o was superfused
throughout the recordings. Scale bars apply to all traces.
D, Concentration-response curves of Win 55,212-2, CP54,939,
and CP55,940 inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spike frequency.
CP54,939 (solid circles) was the most potent of the tested
compounds, EC50 0.36 ± 0.05 nM. Win 55,212-2 (open circles) also
was a potent inhibitor of low Mg2+-induced
[Ca2+]i spiking,
EC50 2.7 ± 0.3 nM.
CP55,940 (solid squares) maximally inhibited spiking
frequency by only 44 ± 10%, although it was very potent,
EC50 1.2 ± 0.7 nM. Data
points represent at least three experiments and are expressed as
mean ± SEM. Curves were fit by a logistic equation of the form % inhibition = ((IMax IMin)/(1 + (X/EC50)b)) + IMin, where X is the drug
concentration, IMin and
IMax are the % inhibition calculated for
X = 0 and for an ``infinite'' concentration,
respectively, and b is a slope factor that determines the
steepness of the curve. EC50 values were
calculated by a nonlinear, least-squares curve fitting algorithm using
Fig.P software (Biosoft) and are expressed as mean ± SEM.
[View Larger Version of this Image (64K GIF file)]
CP55,940 is a partial agonist
Because CP 55,940, even at 1000 nM, a
concentration over 800 times the EC50, produced
maximal reduction in
[Ca2+]i spiking frequency
of only 44 ± 10%, we explored the possibility that this compound was
a partial agonist in this system. This experiment is shown in Figure
5. We elicited
[Ca2+]i spiking in a
hippocampal neuron by reducing the
[Mg2+]o to 0.1 mM, which was maintained throughout the
recording. Spiking then was blocked completely by application of the
full agonist Win 55,212-2 (100 nM). In the
continued presence of Win 55,212-2, application of 100 nM CP 55,940 restored
[Ca2+]i spiking activity
to 48 ± 9% of control, indicating that CP 55,940 antagonized the
activity of Win 55,212-2. Thus, CP 55,940 is a partial agonist. Partial
agonist properties for cannabinoid receptor-mediated inhibition of
Ca2+ currents have been described previously for
anandamide in NG108-15 cells (Mackie et al., 1993) and for CP 55,940 in
sympathetic neurons injected with rat brain cRNA encoding the
cannabinoid receptor (Pan et al., 1996).
Fig. 5.
CP55,940 is a partial agonist. A, The
synthetic cannabinoid CP55,940 (100 nM) partially
reverses 100 nM Win 55,212-2 inhibition of low
[Mg2+]o-induced
[Ca2+]i spiking.
Application of Win 55,212-2 and CP55,940 is indicated by the
bars, and 0.1 mM
[Mg2+]o buffer was
superfused throughout the recording. B, Histogram
summarizing reduction in
[Ca2+]i spike frequency
produced by Win 55,212-2 and CP55,940 (n = 8).
Error bars represent SEM. Asterisks indicate
significantly different from Win 55,212-2 application alone;
p < 0.01 (ANOVA with Bonferroni post-test).
[View Larger Version of this Image (33K GIF file)]
Anandamide inhibits [Ca2+]i spiking
Anandamide is synthesized and metabolized in brain (Devane et al.,
1992; Deutsch and Chin, 1993; Dimarzo et al., 1994) and binds to
cannabinoid receptors, inhibiting both adenylate cyclase and
voltage-gated Ca2+ channels (Felder et al.,
1993). Thus, anandamide represents an endogenous cannabinoid
receptor ligand. In the present study, anandamide reduced the frequency
of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking with an
EC50 of 71 ± 39 nM (Fig.
6), in reasonable agreement with potency and affinity
values reported for anandamide, which range from 20 nM, the IC50 for
Ca2+ channel inhibition (Mackie et al., 1993), to
543 nM, the Ki for
displacement of [3H]-CP 55,940 from cloned
cannabinoid receptors expressed in murine Ltk (L)-cells (Felder et al.,
1993). Anandamide (3 µM) inhibited
[Ca2+]i spiking by 84 ± 8% (n = 3), similar to the maximal block observed with
Win 55,212-2 and CP 54,939. However, the concentration-response curve
was very broad, spanning a four-log change in concentration, and the
slope factor, b, was 0.59 ± 0.19, considerably less than 1. The shallow slope of the dose-response curve may have resulted from
nonspecific inhibition of glutamatergic synaptic transmission at high
concentrations. A significant decrease in anandamide concentration
owing to metabolism was unlikely, because the bath was superfused
continually with drug; the 200 µl chamber was perfused at a rate of
1-2 ml/min, resulting in a complete bath exchange every 10 sec.
Because partial agonist properties of anandamide have been reported
previously (Mackie et al., 1993; Fride et al., 1995), we conducted
experiments similar to those described above using CP 55,940 (Fig. 5)
to test directly whether anandamide was a partial agonist in inhibiting
[Ca2+]i spiking in the
present study. Coapplication of 100 nM, 300 nM, 1 µM, and even 3 µM (n = 3) anandamide together
with 100 nM Win 55,212-2 failed to reverse
inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking produced
by Win 55,212-2 alone (data not shown). Thus, we were unable to detect
partial agonist properties of anandamide in inhibiting
[Ca2+]i spiking in the
present study.
Fig. 6.
Anandamide inhibits glutamatergic synaptic
transmission. A, B, Representative traces
illustrate anandamide inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking.
Anandamide (10 nM) (A) or (1000 nM) (B) was superfused onto the cells
at the times indicated by the horizontal bars.
[Mg2+]o (0.1 mM) was superfused throughout the recording.
C, Concentration-response curve of inhibition of low
[Mg2+]o-induced
[Ca2+]i spike frequency
by anandamide. Data points represent at least three experiments and are
expressed as mean ± SEM. EC50 = 71 ± 39 nM. The curve was fit by a logistic
equation of the form % inhibition = ((IMax IMin)/(1 + (X/EC50)b)) + IMin, where X is the drug
concentration, IMin and
IMax are the % inhibition calculated for
X = 0 and for an ``infinite'' concentration,
respectively, and b is a slope factor that determines the
steepness of the curve. EC50 values were
calculated by a nonlinear, least-squares curve fitting algorithm using
Fig.P software (Biosoft) and are expressed as mean ± SEM.
[View Larger Version of this Image (33K GIF file)]
Cannabinoid receptor agonists inhibit
[Ca2+]i spiking via an
inhibitory G-protein
Cannabinoid receptor-mediated inhibition of adenylyl cyclase
(Howlett et al., 1986), activation of K+ channels
(Deadwyler et al., 1993; Henry and Chavkin, 1995), inhibition of
Ca2+ channels (Caulfield and Brown, 1992; Mackie
and Hille, 1992; Mackie et al., 1993; Mackie et al., 1995; Pan et al.,
1996), and, potentially, activation of phospholipase
A2 (Audette et al., 1991) are mediated by
coupling to inhibitory G-proteins. We investigated whether inhibition
of [Ca2+]i spiking by
cannabimimetics described here also was mediated by an inhibitory
G-protein by treating the cultures with PTX. Cultures treated with
either 500 ng/ml PTX for 24 hr, 1 µg/ml cholera toxin (CTX) for 4 hr,
or 500 ng/ml heat-inactivated (15 min, 95°C) PTX for 24 hr were
compared with untreated control cultures. As shown in Figure
7A, Win 55,212-2 (100 nM) failed to inhibit 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking in
cultures pretreated with PTX (n = 9). In contrast,
heat-inactivated PTX was without effect, as indicated by a full
inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking by 100 nM Win 55,212-2 (n = 6). Treating
the cultures with CTX did not affect the inhibition of
[Ca2+]i spiking produced
by Win 55,212-2 (n = 6). These results are summarized
in Figure 7C, in which Win 55,212-2 induced inhibition of
0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking was left
intact after treatment with CTX or heat-inactivated PTX, but prevented
by prior treatment with PTX (p < 0.001).
Fig. 7.
Treatment with PTX prevents inhibition of
glutamatergic synaptic transmission by Win 55,212-2. A, PTX
pretreatment (500 ng/ml, 24-28 hr) prevented 100 nM Win 55,212-2 inhibition of 0.1 mM
[Mg2+]o-induced
[Ca2+]i spiking.
B, Heat-inactivated PTX (15 min, 95°C) pretreatment (500 ng/ml, 24-28 hr) did not affect 100 nM Win
55,212-2 inhibition of low
[Mg2+]o-induced
[Ca2+]i spiking.
C, Histogram summarizing the effects of pretreating cultured
hippocampal neurons with PTX, CTX (1 µg/ml, 4 hr), and
heat-inactivated PTX on 100 nM Win 55,212-2 inhibition of low
[Mg2+]o-induced
[Ca2+]i spiking
(n = 9 for control and PTX treated, n = 6 for CTX treated and heat-inactivated PTX treated). Error
bars represent SEM. Asterisks indicate significantly
different from control; p < 0.001 (ANOVA with
Bonferroni post-test).
[View Larger Version of this Image (39K GIF file)]
Cannabinoid receptor agonists inhibit the presynaptic release
of glutamate
Data presented thus far indicate clearly that cannabinoid receptor
agonists interfere with an excitatory pattern of electrical activity
that requires activation of glutamatergic synapses. To test whether the
cannabimimetics were acting directly on glutamatergic synaptic
transmission, and further resolve whether the effects of these drugs
were pre- or postsynaptic, we recorded excitatory postsynaptic currents
(EPSCs) using the whole-cell configuration of the patch clamp. The
presynaptic cell was stimulated with an extracellular bipolar
concentric electrode, and EPSCs were recorded in extracellular solution
that contained no glycine and 6 mM
[Mg2+]o to reduce the
probability of polysynaptic responses. As shown in Figure
8, presynaptic stimulation for 100 µsec elicited
reproducible EPSCs. Experiments in which EPSCs exhibited a
multicomponent waveform or were not coupled strictly in one-to-one
fashion with the stimulus were not included in the data set. The 14 experiments that met these criteria had a mean latency of 4.1 ± 0.7 msec, a mean rise time (t1/2) of 1.5 ± 0.1 msec, a mean amplitude of 463 ± 97 pA, and an average recovery time
constant ( ) of 4.6 ± 0.4 msec. In nine experiments, superfusion of
10 µM CNQX inhibited reversibly synaptic
transmission by 93 ± 2% (Fig. 8A, B); the
noncompetitive NMDA receptor antagonist CGS19755 (10 µM) had no effect (3 ± 11% inhibition,
n = 4), indicating that under these conditions, the
EPSCs were mediated entirely by glutamate activation of non-NMDA
receptors. As shown in Figure 8, A and B,
superfusion of 100 nM Win 55,212-3, the inactive
enantiomer, did not affect EPSC amplitude (0.3 ± 0.8%;
n = 6) significantly. In contrast, the active compound
Win 55,212-2 (100 nM) inhibited EPSC amplitude by
86 ± 4% (p < 0.05; n = 10, paired t test). We also tested the partial agonist CP 55,940 (1 µM) for effects on EPSCs and found, similar
to [Ca2+]i spiking
experiments, that CP 55,940 showed modest efficacy producing maximal
inhibition of 60 ± 6% (n = 5). Furthermore, the
inhibition produced by 100 nM Win 55,212-2 (92 ± 3%) was partially reversed by 100 nM CP 55,940 (71 ± 4%, n = 4, p < 0.01, paired
t test).
Fig. 8.
Cannabinoid receptor activation inhibits
glutamatergic neurotransmission. A, Plot of EPSC amplitude
versus time showing that Win 55,212-3 (100 nM)
had no effect, but Win 55,212-2 (100 nM) elicited
substantial and reversible inhibition of EPSC amplitude. CNQX (10 µM) blocked EPSCs completely, whereas CGS19755
(10 µM) had no effect. Drugs were applied as
indicated by the horizontal bars. Data collection was
stopped briefly during the break in the plot at ~15 min.
B, EPSCs recorded during the experiment in A.
Traces are time-superimposed averages of three EPSCs recorded during
the indicated treatment. The large spike at the
left of the records is stimulus artifact. Scale
bars apply to both sets of currents. C, Win 55,212-2 (100 nM) did not inhibit whole-cell currents
evoked by application of 100 µM kainate. CNQX
(10 µM) blocked kainate currents completely.
The horizontal bars indicate kainate application.
D, Win 55,212-2 (100 nM) did not
affect the action potential waveform elicited by current injection. In
normal recording solution, current injection evoked an action potential
followed by a secondary EPSP (D1). Win 55,212-2 blocked the
EPSP (D2). TTX (0.3 µM) abolished
both action potential and secondary EPSP (D3). CNQX (10 µM) also blocked secondary EPSP (D5)
reversibly (D6). The bars below each trace
indicate when current was injected.
[View Larger Version of this Image (23K GIF file)]
Win 55,212-2 (100 nM) did not significantly
affect inward currents elicited by exogenously applied kainate (100 µM), as shown in Figure 8C. When Win
55,212-2 was present during the second application of kainate, the
second response was 99 ± 4% (n = 5) of the first.
CNQX blocked completely the kainate-induced currents (n = 4). Thus, 100 nM Win 55,212-2 did not affect
directly AMPA- or kainate-activated ion channels. Although the
recording conditions used for evoked synaptic currents eliminate an
NMDA receptor-mediated component, the 0.1 mM
[Mg2+]o induced
[Ca2+]i spiking activity
was inhibited significantly by NMDA receptor antagonists. Thus, we
tested NMDA-activated currents for sensitivity to cannabimimetics. In
control experiments, the second current evoked by 100 µM NMDA was 91 ± 5% of the first
(n = 7). Win 55,212-2 (100 nM)
did not affect the second response significantly (79 ± 4%), relative
to the rundown seen in control (n = 7).
Because -9-tetrahydrocannabinol at micromolar concentrations will
inhibit voltage-gated Na+ channels (Turkanis et
al., 1991), we explored the possibility that Win 55,212-2 might inhibit
the presynaptic action potential evoked by field stimulation. Action
potentials were evoked in six cells held in whole cell current clamp by
direct current injection. Win 55,212-2 (100 nM)
had no effect (paired t test) on resting membrane potential
(60 ± 1 vs 59 ± 1 mV), action potential threshold (36 ± 3 vs
34 ± 3 mV), action potential duration (1.2 ± 0.2 vs 1.1 ± 0.1 msec), or action potential amplitude (87 ± 4 vs 88 ± 4 mV). In four
cells, current injection elicited a rapid action potential followed by
a secondary depolarization that we determined was an excitatory
postsynaptic potential (EPSP) (Fig. 8D1). Presumably, the
action potential was exciting a local circuit, possibly an autapse,
that fed back onto the current-clamped cell. Win 55,212-2 (100 nM) had no effect on the evoked action potential,
although it blocked the EPSP completely (Fig. 8D2). TTX
blocked both the action potential and EPSP (Fig. 8D3). After
washout of TTX (Fig. 8D4), 10 µM
CNQX was found to block the EPSP completely (Fig. 8D5).
Thus, in the same cell, we found that Win 55,212-2 had no effect on the
action potential waveform at a concentration that blocked the EPSP
completely. Similar results were obtained in cells stimulated by
extracellular electrode (n = 3). We hypothesize that
Win 55,212-2 activates presynaptic cannabinoid receptors that
subsequently inhibit the release of glutamate into the synaptic
cleft.
In experiments such as that represented in Figure 8A,
fluctuation in the amplitude of the EPSCs reflects probabilistic
release of transmitter. We analyzed synaptic transmission experiments
for changes in the CV of the evoked EPSCs as described by Faber and
Korn (1991). This analysis assumes CV2 to be
inversely proportional to quantal content and independent of the size
of a quantum. Thus, the ratio of the squared CVs (r) before
and after drug treatment (r = CV2control/CV2drug) should remain at
unity for a purely postsynaptic effect that would alter the size of the
quanta, not the probability, of their release. A presynaptic site of
action for the cannabinoids predicts that these drugs should produce a
reduction in r at least as much as a reduction in the
amplitude of the EPSCs. In Figure 9A,
r values calculated for Win 55,212-2 (solid
circles), CP 55,940 (solid triangles), and CNQX
(open squares) are plotted versus the modification factor
(). is the fraction of EPSC amplitude that remains in the
presence of drug ( = EPSCdrug/EPSCcontrol).
The mean r and for 100 nM Win
55,212-2 were 0.08 ± 0.03 and 0.18 ± 0.04, respectively
(n = 10). In nine of the experiments, 10 µM CNQX also was applied (open
squares), presumably acting postsynaptically. The mean
r and for 10 µM CNQX were 0.4 ± 0.1 and 0.09 ± 0.02, respectively (n = 9). Whereas all
of the points from cannabimimetic treatment (solid symbols)
were on or below the diagonal (slope = 1), those in the presence
of CNQX (open symbols) all were above the diagonal. Finding
that for the cannabimimetics, mean r was smaller than the
mean is consistent with a presynaptic site of action, because the
reduction in EPSC amplitude can be accounted for entirely by a
reduction in quantal content. As shown in Figure 9B, the
appropriately scaled EPSC in the presence of Win 55,212-2 could be
superimposed on the control. A reduction in the scale, but not the
shape, of the EPSC waveform after cannabinoids suggests that the same
synaptic boutons were activated under both conditions (Ulrich and
Huguenard, 1995). Win 55,212-2 (100 nM) also
increased the number of synaptic failures from 4 ± 4% in control to
40 ± 11% (Fig. 9C). CP 55,940 (1 µM) increased response failures from 3 ± 2%
to 25 ± 11%.
Fig. 9.
Cannabinoid agonists act presynaptically to
inhibit neurotransmission. A, Plot of the ratio of the CVs
squared (r = CV2control/CV2drug) versus the ratio of
the EPSC amplitude ( = Mdrug/Mcontrol)
shows that all the points generated in the presence of 100 nM Win 55,212-2 (solid circles) and 1 µM CP55,940 (solid triangles) lay
on or below the diagonal (r = ),
whereas points generated in the presence of 10 µM CNQX (open squares) lay
above the diagonal. B, After scaling to the peak
of control, the average EPSC of five sweeps in the presence of 100 nM Win 55,212-2 was superimposed on that of
control. The current surge before the EPSC is stimulus artifact.
C, Summary of successful synaptic responses during control
and after application of 100 nM Win 55,212-2. In
the presence of 100 nM Win 55,212-2, successful
synaptic responses were reduced from 96 ± 4% (control) to 60 ± 11%,
n = 10, *p < 0.01 (paired t
test).
[View Larger Version of this Image (23K GIF file)]
Thus, four lines of evidence point to a presynaptic site of action for
the reduction in glutamatergic neurotransmission produced by the
cannabinoids. Cannabinoids did not affect the action potential that
serves as the stimulus for evoked EPSCs, nor did the drugs affect the
direct activation of glutamate-gated ion channels. Cannabinoids did
increase both the coefficient of variation and the number of response
failures for evoked EPSCs.
Cannabinoid receptor activation does not affect GABA-mediated
inhibitory neurotransmission
In primary rat hippocampal cultures, the
[Ca2+]i spiking activity
results from complex electrical activity that includes an inhibitory
tone that also might be susceptible to modulation by cannabimimetics.
To test whether cannabimimetics affect inhibitory synaptic
transmission, we recorded IPSCs using the whole-cell configuration of
the patch clamp. The presynaptic cell was stimulated with an
extracellular bipolar concentric electrode, and IPSCs were recorded
with 140 mM Cl in the
patch pipette producing large inward currents (Wilcox and Dichter,
1994). As shown in Figure 10, IPSCs were blocked
completely by 10 µM bicuculline, confirming
that they were mediated by GABA-activated ion channels. The IPSCs were
not affected by 100 nM Win 55,212-2 (4 ± 6%,
n = 10). Furthermore, CP 55,940 (1 µM) had no effect on evoked IPSCs
(n = 3). Thus, cannabinoid receptor agonists had no
effect on GABAergic synaptic transmission in these rat hippocampal
cultures.
Fig. 10.
Cannabinoid receptor activation does not affect
GABA-mediated inhibitory neurotransmission. Inward IPSCs were recorded
from a 70 mV holding potential with 140 mM
internal Cl as described in Materials and
Methods. Win 55,212-2 (100 nM) had no effect on
the amplitude of IPSCs evoked by stimulation of the presynaptic cell
with an extracellular electrode. IPSCs were blocked by 10 µM bicuculline. Drugs were applied at the times
indicated by the horizontal bars. Inset,
Representative IPSC traces during control, Win 55,212-2 treatment and
bicuculline treatment were superimposed. Each trace is the average of
five consecutive sweeps recorded during the indicated treatment.
[View Larger Version of this Image (28K GIF file)]
DISCUSSION
In rat hippocampal cultures, cannabinoid receptor agonists
inhibited both glutamatergic synaptic transmission elicited by reducing
[Mg2+]o, which excites
the entire network of neurons in the culture (Robinson et al., 1993),
and glutamatergic EPSCs elicited by direct stimulation of the
presynaptic neuron. These effects were clearly mediated by cannabinoid
receptors, as indicated by pharmacological criteria: (1) The agonists
were potent; subnanomolar concentrations inhibited neurotransmission.
(2) The inhibition was stereoselective. (3) The compounds varied in
efficacy. (4) The rank order of potency was consistent with previously
reported values at cannabinoid receptors. (5) The receptors coupled to
inhibitory G-proteins, as indicated by blockade of the cannabinoid
effects by pretreatment with PTX.
We concluded that activation of cannabinoid receptors inhibited the
release of glutamate presynaptically. Win 55,212-2 decreased the
amplitude of EPSCs evoked by stimulation of the presynaptic neuron, but
did not affect currents elicited by the exogenous application of
kainate or NMDA. This effect was not a result of preventing the
stimulus from reaching the nerve terminal, because Win 55,212-2 did not
affect the evoked action potential. Indeed, in cells that participated
in local networks, the drug left the action potential intact but
completely blocked the EPSP. Furthermore, cannabimimetics did not
affect IPSCs elicited in the same manner. Win 55,212-2 increased both
the CV of the synaptic response and the number of failures, providing
additional evidence of a presynaptic site of action. CV analysis
requires certain assumptions. Of primary concern is that the same
synaptic boutons are activated in the presence of drugs. This appears
to be the case for the experiments described here, because the EPSC
waveform changed in scale but not shape. Cannabinoid activation of
K+ channels (Deadwyler et al., 1993; Henry and
Chavkin, 1995) may produce a presynaptic hyperpolarization that
contributes to the inhibition of EPSC amplitude. However, a
postsynaptic shunting of the synaptic currents is unlikely to account
for the reduction in amplitude, because even a 10-fold change in
membrane conductance would be predicted to only moderately influence
the EPSC (Spruston et al., 1993). N- and P-type
Ca2+ channels control the release of glutamate in
the hippocampus (Luebke et al., 1993; Wheeler et al., 1994; Piser et
al., 1995; Scholz and Miller, 1995), and activation of cannabinoid
receptors inhibits these channels (Mackie et al., 1993; Mackie et al.,
1995; Pan et al., 1996), suggesting that cannabimimetics may inhibit
excitatory neurotransmission by modulating the influx of
Ca2+ into the nerve terminal.
Other functional and anatomical evidence suggests a presynaptic locus
for cannabinoid receptors. Cannabinoids inhibit electrically evoked,
cholinergically mediated contraction of isolated vas deferens and ileum
(Roth, 1978; Nye et al., 1985; Pertwee et al., 1992; Compton et al.,
1993). Cannabinoids inhibit depolarization-evoked synaptosomal
Ca2+ influx (Harris and Stokes, 1982; Okada et
al., 1992), and bind with high affinity to synaptosomal membranes
(Devane et al., 1988). Lesions of striatal projections to substantia
nigra eliminated cannabinoid receptor binding in substantia nigra
(Herkenham et al., 1991; Glass et al., 1993), and Win 55,212-2 attenuated GABAergic activity in the substantia nigra evoked by
stimulation of the striatum (Miller and Walker, 1995), suggesting that
cannabinoids might modulate the release of GABA. Cannabimimetics were
without effect on IPSCs evoked in hippocampal cultures. Taken together,
these results indicate that cannabinoid receptors are distributed
widely and suggest that in many cases, they are localized
presynaptically to modulate the release of several different
neurotransmitters.
Cannabinoid mediated changes in glutamatergic neurotransmission were
consistent with other cannabinoid mediated responses. The stereoisomers
of Win 55,212-2 showed a marked difference in potency, and the three
synthetic compounds tested inhibited excitatory synaptic activity in
the rank order CP 54,939 (EC50 = 0.36 nM) > CP 55,940 (EC50 = 1.2 nM) > Win 55,212-2 (EC50 = 2.7 nM). We found
the potency of these compounds in reasonable agreement with their
binding to brain membranes (Devane et al., 1988; Kuster et al., 1993),
inhibition of electrically stimulated contraction of peripheral smooth
muscle (Pertwee et al., 1992; Compton et al., 1993), inhibition of
adenylyl cyclase in the case of CP 54,939 (Howlett et al., 1988), and
inhibition of Ca2+ currents (Mackie and Hille,
1992). The drugs were 10-fold more potent in this assay than for
binding to brain slices (Herkenham et al., 1990; Jansen et al., 1992;
Thomas et al., 1992) and 100 times more potent in this assay than for
inhibition of adenylate cyclase in the case of CP 55,940 and Win
55,212-2 (Childers et al., 1992; Compton et al., 1993). The rank order
of potency for these compounds has varied somewhat, depending on the
particular assay system, although CP 55,940 was consistently found to
be more potent than Win 55,212-2, possibly because of the interaction
of the ligands with different residues on the receptor (Song and
Bonner, 1995).
Anandamide inhibited glutamatergic synaptic transmission with an
EC50 of 71 nM, in good
agreement with the range of affinity and potency values reported for
anandamide. In murine L-cells, anandamide competes with CP 55,940 for
binding to cannabinoid receptors with a Ki
of 543 nM and inhibits cAMP production with an
IC50 of 160 nM (Felder et
al., 1993). Anandamide competes with CP 55,940 for binding to
P2 membranes with a
Ki of 101 nM (Smith
et al., 1994) and binds to mouse forebrain membranes with a
KD of 143 nM (Hillard
et al., 1995). In N18 neuroblastoma cells, anandamide inhibits
Ca2+ current with an IC50
of 20 nM, but only 61% efficacy relative to the
full agonist Win 55,212-2 (Mackie et al., 1993). Anandamide inhibits
electrically evoked contraction of ileum and vas deferens with
IC50s of 289 and 61 nM,
respectively (Pertwee et al., 1995). Thus, anandamide is ~10- to
100-fold less potent than the synthetic cannabinoids and
aminoalkylindoles tested in this study. In some preparations, the
apparent potency of anandamide is attenuated significantly by
degradation, as indicated by its enhanced potency in the presence of
phenylmethylsulphonyl fluoride, which inhibits degradation (Hillard et
al., 1995; Pertwee et al., 1995). In the present study, the
concentration-response curve for anandamide was broad,
which may have resulted from nonspecific inhibition of synaptic
activity at high concentrations of anandamide, or metabolism of the
compound, which we did not attempt to prevent. However, continual
superfusion of anandamide in the experiments reported here renders a
significant decrease in drug concentration owing to metabolism
unlikely. Consistent with this interpretation, the inhibition of
glutamatergic synaptic transmission described here is among the more
potent effects of anandamide reported to date.
The data presented here suggest that CP 55,940 is a partial agonist. CP
55,940 maximally inhibited Ca2+ spiking by only
44%, compared with complete inhibition by both Win 55,212-2, and CP
54,939. Similarly, Pan et al. (1996) found that CP 55,940 produced only
38% inhibition of N-type Ca2+ channels in rat
sympathetic neurons injected with CB1 receptor cRNA. In contrast, in
NG108-15 cells, Win 55,212-2 and CP 55,940 elicited identical
inhibition of voltage-gated Ca2+ channels, and
these compounds fully occluded Ca2+ channel
inhibition by each other (Mackie and Hille, 1992). Mackie and Hille
(1993) found that anandamide had partial agonist activity compared with
Win 55,212-2 for inhibition of Ca2+ channels in
N18 cells, and low doses of anandamide attenuated both inhibition of
adenylate cyclase and behavioral effects evoked by
-9-tetrahydrocannabinol (Fride et al., 1995). We found that
anandamide exhibited a broad dose-response curve, but micromolar
concentrations inhibited
[Ca2+]i spiking by
greater than 80%, indicating that anandamide is nearly a full agonist
for inhibition of glutamatergic synaptic transmission in hippocampal
cultures. We confirmed these results by demonstrating that CP 55,940, but not anandamide, reversed inhibition by the full agonist Win
55,212-2. Thus, the efficacy of CP 55,940 and anandamide appears to be
reversed for inhibition of Ca2+ current in N18
neuroblastoma cells versus inhibition of Ca2+
current in a neuronal expression system and inhibition of excitatory
synaptic transmission in cultured hippocampal neurons. These intriguing
discrepancies may result from differences in receptor-effector
coupling or the existence of distinct cannabinoid receptor subtypes
(Munro et al., 1993) and isoforms (Shire et al., 1995).
The partial agonist characteristics of CP 55,940 may prove to be a
desirable therapeutic attribute. Many drugs that interfere with
glutamate neurotransmission produce psychotomimetic side effects
(Piercey et al., 1988; Tricklebank et al., 1989). Better tolerated
drugs appear to be less efficacious inhibitors of glutamate receptor
activation, but retain neuroprotective efficacy, consistent with
reduction, but not abolition, of glutamate receptor activation. Such
drugs include the NMDA open-channel blocker memantine (Chen et al.,
1992) and adenosine analogs, which reduce glutamate release
presynaptically (Arvin et al., 1989; Scholz and Miller, 1991; Scanziani
et al., 1992).
Glutamate is the predominant excitatory neurotransmitter in the brain
(Orrego and Villanueva, 1993). Most neurons receive glutamatergic input
(Seeburg, 1993), and many neurotransmitters produce presynaptic
inhibition of glutamatergic synaptic transmission (Thompson et al.,
1993). For these reasons, it is possible that presynaptic inhibition of
glutamate release by the cannabinoid neuromodulatory system accounts
for many of the pharmacological effects of cannabimimetics and is
consistent with their potential clinical application as anticonvulsant,
analgesic, and neuroprotective agents.
FOOTNOTES
Received Jan. 17, 1996; revised March 26, 1996; accepted March 29, 1996.
This work was supported by grants from National Institutes of Health
(DA07304) and the National Science Foundation (IBN9412654). T.M.P. was
supported by Training Grant T32DA07234. The synthetic cannabinoids CP
54,939 and CP 55,940 were gifts of Pfizer Inc. The aminoalkylindoles
Win 55,212-2 and Win 55,212-3 were gifts from Sterling Winthrop.
Correspondence should be addressed to Stanley A. Thayer, Department of
Pharmacology, University of Minnesota Medical School, 3-249 Millard
Hall, 435 Delaware Street SE, Minneapolis, MN 55455.
Dr. Piser's present address: Cardiovascular Pharmacology, Pharmacia
and Upjohn, 301 Henrietta Street, Kalamazoo, MI
49001.
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Compound via MeSH
