Abstract
Phencyclidine (PCP) and ketamine are dissociative anesthetics capable of inducing analgesia, psychomimetic behavior, and a catatonic state of unconsciousness. Despite broad similarities, there are notable differences between the clinical actions of ketamine and PCP. Ketamine has a lower incidence of adverse effects and generally produces greater CNS depression than PCP. Both noncompetitively inhibit NMDA receptors, yet there is little evidence that these drugs affect GABAA receptors, the primary target of most anesthetics. α6β2/3δ receptors are subtypes of the GABAA receptor family and are abundantly expressed in granular neurons within the adult cerebellum. Here, using an oocyte expression system, we show that at anesthetically relevant concentrations, ketamine, but not PCP, modulates α6β2δ and α6β3δ receptors. Additionally, at higher concentrations, ketamine directly activates these GABAA receptors. Comparatively, dizocilpine (MK-801 [(+)-5-methyl-10,11-dihydro-5H-dibenzo [a,d] cyclohepten-5,10-imine maleate]), a potent noncompetitive antagonist of NMDA receptors that is structurally unrelated to PCP, did not produce any effect on α6β2δ receptors. Of the recombinant GABAA receptor subtypes examined (α1β2, α1β2γ2, α1β2δ, α4β2γ2, α4β2δ, α6β2γ2, α6β2δ, and α6β3δ), the actions of ketamine were unique to α6β2δ and α6β3δ receptors. In dissociated granule neurons and cerebellar slice recordings, ketamine potentiated the GABAergic conductance arising from α6-containing GABAA receptors, whereas PCP showed no effect. Furthermore, ketamine potentiation was absent in cerebellar granule neurons from transgenic functionally null α6−/− and δ−/−mice. These findings suggest that the higher CNS depressant level achieved by ketamine may be the result of its selective actions on α6β2/3δ receptors.
- ketamine
- α6β2/3δ GABAA receptors
- granule neurons
- slice recording
- cerebellum
- transgenic mice
- tonic conductance
Introduction
Ketamine and phencyclidine (PCP) are chemical congeners belonging to a class of pharmacological agents known as dissociative anesthetics. These drugs produce similar clinical actions, although the impact of ketamine on CNS functioning differs from that of PCP and its analogues (Greifenstein et al., 1958; Johnstone et al., 1959; Collins et al., 1960; Chen, 1965; Domino et al., 1965; Corssen and Domino, 1966). Ketamine has a lower potency, a shorter duration of action, a faster rate of induction, results in a lower incidence of adverse emergence reactions, and is an effective anesthetic across different animal species (PCP shows species selectivity). Furthermore, ketamine lacks the convulsive side effects that PCP produces at higher doses. Collectively, these studies suggest that ketamine possesses a higher CNS depressant activity and produces a better quality of anesthesia than PCP (McCarthy et al., 1965).
It has been established that dissociative anesthetics are noncompetitive inhibitors of NMDA excitatory ligand-gated ion channels (Lodge and Anis, 1982; Anis et al., 1983; MacDonald et al., 1987, 1991; ffrench-Mullen and Rogawski, 1989; Rogawski and Wenk, 2003). These drugs also modulate the activity of nicotinic acetylcholine, muscarinic, and opioid receptors, and voltage-gated ion channels, but at significantly higher concentrations than needed to block NMDA receptors (Finck and Ngai, 1982; Ramoa et al., 1990; Hustveit et al., 1995; Hirota and Lambert, 1996; Scheller et al., 1996; Brau et al., 1997; Furuya et al., 1999; Flood and Krasowski, 2000; Yamakura et al., 2000; Schnoebel et al., 2005). Studies conducted at low doses of ketamine suggest that the inhibition of NMDA receptors results in its psychomimetic and analgesic properties (Tricklebank et al., 1987; Klepstad et al., 1990; Oye et al., 1992). However, the mechanism by which ketamine produces a higher CNS depression than PCP at high doses has remained an enigma (Kress, 1997).
GABAA receptors are the prime target for the hypnotic class of anesthetic compounds (Franks and Lieb, 1994; Macdonald and Olsen, 1994). A number of studies also implicated GABAA receptors in ketamine anesthesia (Scholfield, 1980; Gage and Robertson, 1985; Bennett et al., 1988; Irifune et al., 1992, 2000; Lin et al., 1992; Wakasugi et al., 1999), although these provided either indirect evidence for the action of ketamine on GABAA receptors, or the concentration of ketamine used was significantly higher than the anesthetically relevant concentration.
The GABAA receptor subtypes α6β2/3δ are expressed at high levels exclusively within mature cerebellar granule neurons (Laurie et al., 1992; Wisden et al., 1996) and show high sensitivity to GABA (Saxena and Macdonald, 1996; Storustovu and Ebert, 2006; Hadley and Amin, 2007).
We investigated the effects of ketamine, PCP, and MK-801 [(+)-5-methyl-10,11-dihydro-5H-dibenzo [a,d] cyclohepten-5,10-imine maleate] (a potent noncompetitive inhibitor of NMDA receptor) on α6- and δ-containing GABAA receptors. We show that ketamine, but not PCP or MK-801, within an anesthetically relevant concentration range, potentiated the GABA current arising from α6- and δ-containing GABAA receptors in oocytes, dissociated granule neurons, and cerebellar slices isolated from rodents. The potential role of GABAA α6β2/3δ receptors in ketamine anesthesia is discussed.
Materials and Methods
cRNA quantitation and oocyte injection.
Xenopus laevis frogs were anesthetized by bathing in a solution containing 0.1% MS-222 (tricaine methane sulfonate; Sigma-Aldrich). Before ovariectomy, the toe of the frog was pinched to assess the state of anesthesia. After surgery, the frog was killed by decapitation according to the protocol approved by the Institutional Animal Care and Use Committee. Oocyte preparation, in vitro transcription of complementary rat RNA (cRNA), and the drug perfusion system have been described previously (Walters et al., 2000). The quality of cRNA was determined by electrophoresis of the cRNA on a 1% formaldehyde-containing agarose gel and then quantified spectrophotometrically. Two to four preparations of cRNAs were tested for each subunit. The cRNA mixture (in diethylpyrocarbonate-treated water) was injected into Xenopus laevis oocytes using a Picospritzer II (General Valve Corporation). The ratio of the coinjected subunits α:β:γ/δ was1:1:1.8 except for expression of α6β2δ receptors in the low-affinity state where the amount of β2 was relatively decreased to one-tenth (1:0.1:1.8) (Hadley and Amin, 2007). Five to ten nanograms of α6, β2, and δ cRNA mixture per oocyte was used for the ketamine studies.
Oocytes electrophysiology.
Recording microelectrodes were fabricated with a Narishige PP-83 puller filled with 3 m KCl, and had input resistances of 0.7–1.6 MΩ. A Turbo TEC-05 (NPI Electronic) two-electrode voltage-clamp amplifier (Adams and List) was used to record the currents. In all oocyte recordings, membrane potential was clamped to −70 mV. Data were visualized on a Gould TA-240 chart recorder during the experiments and stored online using Pulse Fit (HEKA).
Cerebellar preparation.
Sprague Dawley rats, C57BL/6 mice, δ−/−mice (provided by G. Homanics, University of Pittsburgh, Pittsburgh, PA) (Mihalek et al., 1999), and α6−/−mice [provided by W. Wisden (University of Aberdeen, Aberdeen, UK) and E. Korpi (University of Turku, Turku, Finland)] (Jones et al., 1997) were reared in the central animal facilities of the University of Mainz and the University of Leipzig and transferred to the local adaptation facilities several days before experiments. All procedures followed the German guidelines for animal care. Male animals between postnatal day 20 (P20) and P48 were decapitated and their brains rapidly removed into ice-cold carboxygenated (5% CO2/95% O2) cutting solution (see below, Solutions and drugs). The cerebellar vermis was trimmed and then glued to the stage of an IntegraSlice 7550MM (cyanoacrylate glue; Campden Instruments). Sagittal slices of ∼200 or ∼500 μm thickness were prepared and maintained in a continuously carboxygenated perfusion chamber at room temperature (21°C) containing artificial CSF (ACSF) (see below, Solutions and drugs) for 1 h. Single slices (∼200 μm) were transferred to a recording chamber (RC-26GLP; Warner Instruments), placed under an upright fixed stage microscope (Axioskop FS; Zeiss), and perfused at ∼4 ml/min with carboxygenated ACSF. Using Nomarski optics and an enhanced infrared video system (Luigs and Neumann), whole-cell patch-clamp recordings of individual cells within the second or third layer of the inner granule cell area were obtained. To account for possible regional differences in the expression of the α6-subunit (Mellor et al., 1998), we restricted slice studies to lobes VIII to X of the cerebellar cortex.
Preparation of dissociated granule neurons.
To obtain dissociated cells, slices of ∼500 μm thickness were transferred to preheated cutting solution (35°C, bubbled with carbogen) supplemented with 0.5–1 mg/ml pronase. After 20–40 min, slices were transferred to ice-cold HEPES-buffered cutting solution and carefully triturated with fire-polished glass pipettes of decreasing tip diameter. An aliquot (∼ 20 μl) of dissociated-cell suspension was plated onto poly-l-lysine-coated coverslips and allowed to settle in ACSF for ∼20 min before recordings.
Granule neurons electrophysiology.
Whole-cell recordings were obtained with thick-walled borosilicate electrodes (1.5 mm outer diameter, 0.5 mm inner diameter; 8–12 MΩ resistances; Vitrex 11394; Science Products) using standard procedures (Hamill et al., 1981). Recordings were routinely filtered at 1 kHz, amplified and recorded on a personal computer using an EPC-9 amplifier and Pulse 8 software (HEKA). Current responses were recorded under voltage-clamp conditions at a holding potential of −60 mV and series resistances within 20–35 MΩ were compensated (70–80%; Pulse software; HEKA). Adequate clamp conditions (error <5 mV) (Rossi et al., 1994) were verified by the fast activation of routinely recorded voltage-gated Na+ currents (300 μs time to peak).
Solutions and drugs.
For oocyte recording, the extracellular oocyte ringer (OR2) solution contained (in mm) 83.5 NaCl, 2.5 KCl, 10 HEPES, 1 CaCl2, and 1 MgCl2, pH 7.5. For cerebellar recording, the ACSF was bubbled with carbogen and contained (in mm) 135 NaCl, 5 KCl, 2 CaCl2, 1 MgCl2, 10 glucose, 30 Na2HCO3, and 1.5 NaHPO4, pH 7.4. For tissue preparation and cutting, the solution contained (in mm) 60 NaCl, 140 sucrose, 5 KCl, 0.3 CaCl2, 6 MgCl2, 10 glucose, 30 Na2HCO3, and 1.5 NaHPO4, pH 7.4. For cell dissociation, Na2HCO3 and NaHPO4 were replaced by HEPES. For dissociated granule neurons or slice recordings, drugs were diluted in (in mm) 150 NaCl, 5 KCl, 2 CaCl2, 1 MgCl2, 10 glucose, and 10 HEPES, with pH 7.4 (NaOH). All solutions were adjusted to ∼305 mOsmol with sucrose or H2O. Patch electrodes were filled with (in mm) 125 CsCl, 2 MgCl2, 10 EGTA, 10 tetra-ethyl-ammonium chloride (TEA), 4–5 Na2-ATP, 0.5 Na-GTP, and 10 HEPES, pH 7.3 (CsOH), adjusted to ∼295 mOsmol with sucrose or H2O.
All solutions were made from analytical grade salts. TEA, picrotoxinin, furosemide, ketamine, and bicuculline were purchased from Sigma-Aldrich. For some experiments, a premade ketamine solution (ketalar, 100 mg/ml) was used without noticeable differences. GABA was diluted from a 100 mm fresh or frozen stock solution to the final concentrations, furosemide from a 100 mm stock solution in 200 mm NaOH, picrotoxinin from a 10 mm stock solution in ethanol, bicucculine from a 100 mm in DMSO, and ketamine from a 100 mm in water. DMSO or ethanol at their highest concentrations used (0.1 and 0.5%, respectively, for oocytes) did not alter the responses. For oocyte recordings, stock solutions were diluted in the recording OR2 solution.
For slice recordings, drugs were applied focally using a gravity-fed Y-tube system described previously (Hevers and Luddens, 2002). In short, a 5-mm-long fused-silica tube (MicroFil; World Precision Instruments) was inserted into a sharply bent Teflon tube connected on one side to a vacuum source and on the other to the drug reservoirs. Focal drug application was initiated by interrupting the vacuum line with the tip, positioned in close proximity (<50 μm) to the cell, allowing a solution exchange within ∼150 ms. For dissociated cells, a parallel three-barrel system was used in which the middle barrel contained buffer and the outside barrels contained different drugs. The middle barrel outlet was positioned in close proximity to the cells and switched to one of the drug lines with a stepping motor (Warner SF-77B; Warner Instruments) or a piezo translator (Burleigh LSS-3200; NPI Electronic).
Data analysis.
We estimated the EC50 value for GABA and ketamine direct action by fitting the data from concentration–response relationships to the logistic equation according to the following formula (Sigmaplot 2000 or origin 6.0; OriginLab): I = Imax/(1+ (EC50/[A])n).
The data for the GABA concentration response relationship of α6β2δ receptors was fitted with a sum of two logistic equations: I = Imax1/(1+ (EC501/[A])n1 + Imax2/(1+ (EC502/[A])n2), where I is the peak current at a given concentration of agonist A, Imax, Imax1 and Imax2 are the maximum currents, EC50, EC501, and EC502 are the concentrations of agonist yielding the half maximal currents, and n, n1, and n2 are the Hill coefficients of the curves.
Determinations of the statistical significant were performed either using the student t test or ANOVA as appropriate, requiring a p value of <0.05 for statistical significance. All statistical calculations are presented as means ± SE.
Results
α6β2δ receptors show high sensitivity to ketamine
The degree a drug inhibits or potentiates the activity of a GABAA receptor depends markedly on the level of receptor channel activation by GABA (Morris et al., 1999; Walters et al., 2000). To test the modulatory activity of ketamine on α6β2δ receptors, we determined the GABA concentration–response relationship for α6β2δ receptors to establish the concentrations eliciting 1, 3, 8, and 16% of the maximal current (EC1,GABA EC3,GABA, EC8,GABA, and EC16,GABA, respectively). Three to four days after cRNA injection, GABA-activated currents were recorded (Fig. 1 A,B). The GABA data for α6β2δ receptors were fitted with a logistic equation (see Materials and Methods) and the extrapolated EC values were tested and adjusted empirically. These experiments revealed both a high-affinity and a low-affinity state of the α6β2δ receptors [the detailed characterization of GABA concentration–response relationship for these receptors has recently been described further (Hadley and Amin, 2007)]. A significant level of spontaneous channel activity accompanies the high-affinity state.
The sensitivity of α6β2δ receptors to ketamine was examined next at the presence of EC1,GABA EC3,GABA, EC8,GABA, and EC16,GABA values (Fig. 1C,D). Ketamine at 10 μm increased the EC1,GABA current by 46 ± 8%, whereas at 20, 50, and 100 μm the increases in GABA currents by ketamine were 100 ± 14%, 261 ± 30%, and 540 ± 60%, respectively. Ketamine at 10 to 100 μm augmented the EC3,GABA currents from ∼30–260% (Fig. 1). At EC8,GABA and EC16,GABA, ketamine produced a moderate increase in the GABA currents; i.e., for 10 and 100 μm ketamine, the increase of the EC16,GABA currents ranged from 10 to 91%, respectively. After ketamine application, the subsequent GABA currents were similar in magnitude to the preceding GABA control. Therefore ketamine exhibited little to no residual effects (data not shown).
The high sensitivity of ketamine is unique to α6β2δ receptors
We compared the sensitivity of ketamine to α1β2γ2, α6β2γ2, α1β2δ, α4β2δ, α4β2γ2, α1β2, and α6β2δ GABAA receptors at their respective EC3,GABA value (Fig. 2). Ketamine produced diminutive effects on α1β2γ2, α4β2γ2, and α6β2γ2 receptors. Ketamine (100 μm) increased the respective EC3,GABA currents between 22 and 39%, the values being significantly below those induced by 20 μm ketamine on α6β2δ receptors. The increases by 50 and 100 μm ketamine for α4β2δ receptors were 37 ± 6% and 66 ± 10%, respectively, whereas the corresponding values for α1β2δ receptors were 39 ± 7% and 74 ± 9%. Thus, ketamine produced a modest potentiation at the EC3,GABA currents for α1β2δ and α4β2δ receptors. The α1β2 GABA current (EC3) increased by 46 ± 5% and 81 ± 7% at 50 and 100 μm ketamine, respectively.
In summary, the presence of the γ2 subunit within GABAA receptors reduced the effects of ketamine, whereas those receptors containing the δ subunits (or α1β2 alone) exhibited relatively higher sensitivity to ketamine. However, both α6 and δ subunits were needed to confer the highest sensitivity to ketamine. Thus, among the tested GABAA receptor subtypes, the high sensitivity to ketamine is unique to α6β2δ receptors.
Ketamine directly activates α6β2δ and α6β3δ receptors
Intravenous anesthetics such as pentobarbital modulate and directly activate most, if not all, GABAA receptor subtypes. To examine whether ketamine can also act as an agonist, we bath applied ketamine in concentrations ranging from 5 to 5000 μm on oocytes expressing α6β2δ receptors (Fig. 3A). Ketamine directly activated α6β2δ receptors at concentrations as low as 50 μm, with an EC50 of 577 ± 63 μm and a Hill slope of 1.20 ± 0.09 (n = 4). When higher concentrations of ketamine were removed, the residual current increased before returning to the baseline, suggesting that ketamine possessed a low-affinity blocking action (Fig. 3A). This apparent block by ketamine at higher concentrations resembled the direct action of pentobarbital on GABAA receptors.
For α6β2δ receptors, the relative maximal current of ketamine (1.8 mm) to GABA (50 μm) was 0.51 ± 0.06 (n = 10), indicating that ketamine is a partial agonist on α6β2δ receptors. In contrast, ketamine did not directly activate α1β2δ, α6β2γ2, α4β2δ, and α4β2γ2 receptors, with the relative efficacies ranging from 0.01 to 0.02 for ketamine (1.8 mm) to GABA (1.2 mm).
In addition to the β2 subunit, the β3 subunit is abundantly expressed in adult cerebellar granule neurons. Thus, we examined the modulatory and direct actions of ketamine on α6β3δ receptors as well (Fig. 3B). At 10, 20, 50, and 100 μm ketamine potentiated the EC3,GABA by 43 ± 6%, 72 ± 16%, 177 ± 35%, and 416 ± 128%, respectively, similar to those of α6β2δ receptors. Ketamine also directly activated α6β3δ receptors with an EC50 of 245 ± 26 μm and slope of 1.9 ± 0.1 (n = 11). Thus, ketamine at low concentrations (10–20 μm) significantly potentiated the GABA current of α6β3δ receptors and at higher concentration directly activated these receptors.
In summary, ketamine directly activated α6β2δ and α6β3δ receptors. The direct and modulatory actions of ketamine resemble those of the classical intravenous anesthetic pentobarbital. However, direct activation of ketamine appeared to be selective to α6β2/3δ receptors, whereas pentobarbital directly activates most GABAA receptors, including α1β2/3γ2 receptors.
MK-801 or PCP do not modulate α6β2/3δ receptors
PCP blocks NMDA receptors by an order of magnitude higher than that of ketamine. MK-801, a dissociative anesthetic chemically unrelated to PCP, possesses an even greater affinity to, and inhibits NMDA receptors with higher potency than PCP (Wong et al., 1986; Huettner and Bean, 1988; MacDonald and Nowak, 1990; MacDonald et al., 1991). Furthermore, the blocking action of MK-801 on the NMDA receptor is less dependent on the membrane potential than ketamine or PCP (Halliwell et al., 1989; Dravid et al., 2007). We examined whether the sensitivity of α6β2δ and α6β3δ receptors to ketamine extends to PCP or MK-801. First, the modulatory effect of PCP at the EC3,GABA value for α6β2δ and α6β3δ receptors was examined (Fig. 4A,B). PCP produced no significant potentiation of the GABA current arising from α6β2δ receptors even at 50 μm, a concentration significantly higher than the anesthetically relevant concentrations. Second, the effect of MK-801 up to 50 μm was tested on α6β2δ receptors (Fig. 4C). As with PCP, MK-801 did not affect the EC3,GABA currents arising from α6β2δ receptors. Thus, among the three dissociative anesthetics tested, α6β2δ receptors are uniquely sensitive to ketamine.
Action of ketamine on the α6β2δ receptors within a low- or high-affinity state
The affinity state of the α6β2δ receptors toward GABA expressed in Xenopus oocytes can be controlled by (1) the expression level and (2) the alteration of the ratio of β2 to α6 and δ subunits (Hadley and Amin, 2007). The ketamine data for α6β2δ receptors shown up to here was obtained using a cRNA injection ratio for α6:β2:δ of 1:1:1.8 (5–10 ng of cRNA per injection), where both the high- and low-affinity states of the receptor coexist. The high-affinity state exhibits constitutive activity. Previous studies have shown that injection using a lower ratio of β subunit cRNA, i.e., 1:0.1:1.8, results in a preponderance of α6β2δ receptors in the low-affinity state (Hadley and Amin, 2007). To investigate the sensitivity of α6β2δ receptors to ketamine in the high- versus low-affinity state, we injected oocytes with either the standard ratio of 1:1:1.8 with 10–15 ng of cRNA per injection (see Materials and Methods) or with a low β2 subunit ratio of 1:0.1:1.8 to express the α6β2δ receptors in predominantly the high- or low-affinity state, respectively. For the α6β2δ receptor in the low-affinity state, the percentage increases of the GABA current at EC3,GABA by 50 and 100 μm ketamine were 106 ± 5% and 356 ± 11%, respectively (Fig. 5), compared with the α6β2δ receptor in the high-affinity state, whereas the increase was 79 ± 1% and 173 ± 8% for 50 and 100 μm ketamine, respectively. Furthermore, ketamine on its own showed low efficacy (Imax ketamine/Imax GABA ∼ 0.1) for α6β2δ receptors in the low-affinity state. Collectively, ketamine can significantly potentiate the GABA currents arising from α6β2δ receptors in either the low or the high-affinity states yet the direct activation by ketamine appears to be selective for α6β2δ receptors in the high-affinity state.
Action of ketamine on cerebellar granule neurons
We investigated the action of ketamine on granule neurons in rat cerebellar slices from P20–P48 when the expression of α6 and δ subunit reaches high levels (Laurie et al., 1992). Individual granule neurons from the inner granule layer were voltage clamped (−60 mV) in whole-cell recording configurations using equimolar Cl− concentrations. In these recordings, granule neurons showed a tonic current that could be blocked by adding the GABAA receptor antagonist bicuculline (20 μm), or the specific α6-containing GABAA receptor antagonist furosemide (300 μm) (Korpi et al., 1995; Korpi and Luddens, 1997) (Fig. 6A,B). Ketamine (1 mm) evoked currents that ranged in amplitude from 15 to over 100 pA (58.5 ± 8.6 pA; n = 11). Bicuculline (20 μm) and furosemide (300 μm) blocked the ketamine-induced currents within the granule neurons, indicating that these currents arose from α6-containing GABAA receptors (Fig. 6C).
We next examined the potentiation of the tonic current by 10, 30, 100, 300, and 1000 μm ketamine (Fig. 7). The level of bicuculline-dependent block of the tonic current was used as the denominator to determine the ketamine potentiation. Ketamine, at a concentration as low as 30 μm, produced a significant increase in the tonic current, resulting in 20 ± 15% potentiation (p = 0.0003; n = 10). Furthermore, 100, 300, and 1000 μm ketamine increased the tonic current by 50, 130, and 280%, respectively. Thus, ketamine at clinically relevant concentrations (see Discussion) of 30 or 100 μm can increase the tonic current significantly.
Ketamine does not induce currents in α6−/−or δ−/− transgenic mice
To further elucidate the involvement of α6 and test whether δ subunits play a role in the ketamine-induced currents recorded in cerebellar slices, we used mice in which the functional expression of α6- and δ- (α6−/−) or δ-subunits (δ−/−) alone was abolished (Jones et al., 1997). The GABAergic tonic background conductance was found to be absent or nearly absent within the cerebellar slice recordings from granule neurons of α6−/− or δ−/−mice, respectively (Fig. 8). In contrast to experiments from wild-type animals, ketamine (1 mm) did not induce a current in granule cells from either α6−/− or δ−/−mice. These experiments demonstrate that the δ subunit and, likely, the α6 subunit are needed to confer ketamine sensitivity to cerebellar granule neurons.
Ketamine's modulation of dissociated granule neurons
The tonic activation of extrasynaptically localized α6β2/3δ receptors may indicate the omnipresence of low concentrations of GABA at these receptor sites. To differentiate the modulatory effects in the presence of GABA versus a direct effect of ketamine on granule neurons, we developed a preparation of dissociated granule neurons from mice and rats up to an age of P28. In this procedure, neurons resembled granule neurons with small globular shape with several offshoots and dendrites (Fig. 9A). The cell capacitance was not significantly (p = 0.29) altered a few hours after dissociation (2.76 ± 0.27 pF; n = 6) when compared with granule neurons within the slice (2.89 ± 0.16 pF; n = 15). We verified presence of α6- and δ-containing GABAA receptors within the dissociated neuron using furosemide, 3-carbomethoxy-4-ethyl-6,7-dimethoxy-β-carboline (DMCM), and 4,5,6,7-tetrahydrois-oxazolo[5,4-c]-pyridin-3-ol (THIP). Furosemide inhibited, whereas DMCM potentiated, the GABA-induced current in these cells (Fig. 9B). Furthermore, 1 μm THIP, a concentration that can selectively activate α6- and δ-containing GABAA receptors (Storustovu and Ebert, 2006; Saarelainen et al., 2008), evoked 37.5 ± 4.8 pA compared with 38.3 ± 5.2 pA (n = 11) of current for 1 μm GABA within these dissociated granule neurons. These data suggest the presence of α6- and δ-containing GABAA receptors within the dissociated granule neurons. Ketamine produced a marked potentiation of the GABA current (1 μm), whereas, in contrast to slice recordings, bicuculline did not change the control current (Fig. 9C).
We tested the ketamine concentration response relationship in the presence of a low concentration of GABA (1 μm) for the dissociated granule neurons isolated from rats or mice (Fig. 9D,E). The half maximal potentiation was ∼300 μm for the two species (mice: 260 ± 16 μm, maximal potentiation 310 ± 50%; for rats: 198 ± 32 μm, maximal potentiation 240 ± 80%). Within these experiments, 100 μm ketamine induced a significant potentiation of the GABA current (Fig. 9F). In the presence of 3 μm GABA, 100 μm ketamine produced a 140 ± 5% potentiation (n = 26, rats and mice pooled because there were little species-dependent difference between the mice and rats in terms of ketamine modulation). Under equivalent conditions, PCP at 1 and 3 mm was ineffective in modulating the GABA current (Fig. 9F) (1 mm PCP, 106 ± 2.7%, n = 8, p = 0.78; 3 mm PCP, 112 ± 3.5%, n = 8, p = 0.67). Thus, similar to the oocyte experiments, ketamine, but not PCP, modulated the α6- and δ-containing GABAA receptors.
Ketamine evoked a relatively small current on its own with a mean value of 4.2 pA (Fig. 9C), which could be blocked by bicuculline (data not shown). These experiments suggest that α6β2/3δ receptors may be present predominately in a low-affinity state and the α6β2/3δ receptors in the high-affinity state could constitute a small fraction of the total receptor population in these dissociated granule neurons from preadolescent p28 or younger animals.
The effect of increasing concentrations of GABA on the ketamine response (1 mm) was also examined within wild-type and α6−/− or δ−/−mice dissociated granule cells (Fig. 10). For wild-type mice, the effect of ketamine was most pronounced at concentrations of GABA <100 μm with an EC50 of 57 ± 18 μm (slope = 0.98; n = 6). In contrast, ketamine potentiation was absent in the mutant α6−/− or δ−/−mice regardless of the GABA concentration, indicating the importance of α6 or δ subunits in the action of ketamine.
Collectively, these data support the findings from the oocyte and slice recording experiments, demonstrating the unique action of ketamine on the α6- and δ-containing GABAA receptors, whereas PCP had no effect.
Discussion
We demonstrated that ketamine selectively modulates rat α6β2/3δ GABAA receptors within the oocyte expression system. These receptors were highly sensitive to ketamine, but showed no response to PCP or MK-801. Ketamine-induced currents were observed in the recordings of cerebellar granule neurons from rodents, where they were confirmed to arise from α6- and δ-containing GABAA receptors. Furthermore, the ketamine-evoked currents were absent within cerebellar granule neurons of transgenic functionally null α6−/− or δ−/−mice.
The cerebellum has a primary function in motor control and learning. Previous anatomical, neuroimaging, and pyschological studies suggest that the cerebellum may also participate in higher cognitive functions. Patients with physical-induced lesions of the cerebellum exhibit both motor and cognitive disabilities. Cerebellum anomalies have been noted in patients suffering from schizophrenia, dyslexia, and autism (Martin and Albers, 1995; Timmann and Daum, 2007). Furthermore, neuroimaging recordings of volunteers performing cognitive tasks suggest that the cerebellum is involved in memory, learning, language and attention (Bellebaum and Daum, 2007; Haarmeier and Thier, 2007; Sultan and Glickstein, 2007; Thach, 2007; Timmann and Daum, 2007). Collectively, the cerebellum appears to coordinate not only motor, but also cognitive activity.
Cerebellar granule cells are the most abundant neurons in the CNS and play a pivotal role in storing motor commands (Tyrrell and Willshaw, 1992). A key characteristic of these neurons is the postnatal development of a tonic chloride current, known as tonic inhibition, which arises from GABAA receptors containing α6 subunits (Kaneda et al., 1995; Brickley et al., 1996; Tia et al., 1996; Wall and Usowicz, 1997; Hamann et al., 2002). The tonic inhibition plays an important role in tuning the indirect transmission of information from mossy fibers to the Purkinje neurons (via granule neurons) by reducing the overall gain of information transmitted through the cerebellar cortex. It is calculated that at the adult stage, contribution of the tonic inhibition to overall inhibitory conductance is at least threefold larger than phasic inhibition. Moreover, >90% of the tonic inhibition of granule neurons is mediated by α6- and δ-containing GABAA receptors (Hamann et al., 2002). Thus, the high sensitivity of α6β2/3δ receptors to ketamine has the potential to impact the informational transfer from mossy fibers to the Purkinje neurons. Ketamine/xylazine anesthesia has been used to study cerebellar circuitry in vivo. In these studies, ketamine/xylazine significantly suppresses the activity within the parallel fiber synapses, and the states of the membrane potential of the Purkinje neurons are significantly affected as well (Schonewille et al., 2006; Bengtsson and Jorntell, 2007). In addition to the α6β2/3δ GABAA receptors, there are also NMDA and AMPA receptors expressed within the granule neurons (Garthwaite and Brodbelt, 1990). Compared with the action of ketamine on the α6β2/3δ GABAA receptors, however, block of these receptors by ketamine occurs at markedly higher concentrations (Arenz et al., 2006). Given the relatively higher sensitivity of α6β2/3δ GABAA receptors to ketamine and the abundance of these receptors at the adult stage, the ketamine potentiation of the tonic current arising from α6β2/3δ GABAA receptors may have a profoundly greater impact on the overall suppression of the parallel fiber synapses than the blocking action of ketamine on the excitatory pathway during ketamine anesthesia.
The action of ketamine on cerebellar α6β2/3δ receptors occurred at anesthetically relevant concentrations. The steady-state ketamine concentration in the plasma of anesthetized rats is ∼100 μm after the distribution phase. In the brain, the ketamine concentration has been shown to exceed 300 μm (Cohen and Trevor, 1974). Here, we demonstrate that 10–100 μm ketamine significantly potentiated GABA currents arising from α6β2/3δ receptors. Thus, the concentrations of ketamine effective at α6β2/3δ receptors are within the realm of anesthetically relevant concentrations.
The anesthetic efficacies of ketamine, PCP, and MK-801 measured by CNS depressive action do not show a strong correlation to their actions on NMDA receptors. Binding and electrophysiological studies have demonstrated that PCP and MK-801 are superior noncompetitive inhibitors of, and have markedly higher affinity for, NMDA receptors than ketamine (Chen et al., 1959; Johnstone et al., 1959; Chen, 1965; McCarthy et al., 1965; Wong et al., 1986; MacDonald et al., 1991; Rogawski and Wenk, 2003). In addition, MK-801 block can occur across different membrane potentials, whereas PCP and ketamine inhibit NMDA receptors predominately at depolarized potentials (Halliwell et al., 1989; Dravid et al., 2007). However, a number of studies have shown that PCP and MK-801 are not effective anesthetics in rats, mice or pigeons, even at near lethal doses (Chen et al., 1959; Koek et al., 1987a,b, 1988; Kelland et al., 1993; Irifune et al., 2007). Therefore, contrary to the order of their impact on NMDA receptors, ketamine is a more effective anesthetic across different animal species and appears to possess a higher CNS depressant activity than PCP and MK-801 (Chen et al., 1959; Johnstone et al., 1959; Chen, 1965; Domino et al., 1965; McCarthy et al., 1965).
In human studies, a number of patients placed under catatonic state using PCP are arousable (Johnstone et al., 1959), indicating suboptimal CNS depression, whereas patients under ketamine anesthesia do not respond to verbal commands. Furthermore, with increasing doses, PCP can induce surgically unrelated excitation (Greifenstein et al., 1958), an adverse effect absent with ketamine administration. Ketamine also produces a lower rate and a shorter duration of emergence reactions, such as vivid dreams and hallucinations, when compared with PCP.
Collectively, these observations have led to the withdrawal of PCP from further clinical trails and veterinary practice despite the higher potency of PCP in producing dissociation and having a significantly higher affinity to NMDA receptors. Although MK-801 has been extensively characterized for two decades and possesses a nearly 1000 times greater affinity for the NMDA receptors than ketamine, MK-801 has not been approved for clinical or veterinary practice. Our findings suggest the distinguishing factor is the alternative action of ketamine on the inhibitory pathway via GABAA α6β2/3δ receptors.
We have shown that ketamine, but not PCP, can increase the activity of GABAA receptors containing α6 and δ subunits within an anesthetically relevant concentration range. This is the first demonstration of two anesthetics, highly analogous in chemical structure, molecular action, and clinical effect, in which each exhibits differentiating all or none action on cerebellar α6β2/3δ GABAA receptors. The actions of ketamine are disproportionate regarding their impact on excitatory (NMDA) versus inhibitory (GABAA) pathways, with the former showing higher potency. These findings have the potential to lead to the development of PCP analogues that exhibit more balanced actions on the inhibitory versus excitatory pathways. Such anesthetics would offer a broader spectrum for desired effects, lower the incidence of adverse effects, and provide a higher margin of safety.
Footnotes
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This work was supported by grants from the German Science Foundation (Deutsche Forschungsgemeinschaft Lu 319/2–1) (H.L.), the MAIFOR program of the University of Mainz (W.H.), and American Heart Established Investigator Awards (J.A.). We thank Blake Singletary for help with editing, Stacey Kolar for help with Figures, and Ingo Bohme for genotyping the mouse lines.
- Correspondence should be addressed to Jahanshah Amin, Department of Molecular Pharmacology and Physiology, University of South Florida, Tampa, FL 33612. Jamin{at}health.usf.edu