Abstract
Classical benzodiazepines (BZs) exert anxiolytic, sedative, hypnotic, muscle relaxant, anticonvulsive, and amnesic effects through potentiation of neurotransmission at GABAA receptors containing α1, α2, α3 or α5 subunits. Genetic studies suggest that modulation at the α1 subunit contributes to much of the adverse effects of BZs, most notably sedation, ataxia, and amnesia. Hence, BZ site ligands functionally inactive at GABAA receptors containing the α1 subunit are considered to be promising leads for novel, anxioselective anxiolytics devoid of sedative properties. In pursuing this approach, we used two-electrode voltage clamp experiments in Xenopus oocytes expressing recombinant GABAA receptor subtypes to investigate functional selectivity of three newly synthesized BZ site ligands and also compared their in vivo behavioral profiles. The compounds were functionally selective for α2-, α3-, and α5-containing subtypes of GABAA receptors (SH-053-S-CH3 and SH-053-S-CH3-2′F) or essentially selective for α5 subtypes (SH-053-R-CH3). Possible influences on behavioral measures were tested in the elevated plus maze, spontaneous locomotor activity, and rotarod test, which are considered primarily predictive of the anxiolytic, sedative, and ataxic influence of BZs, respectively. The results confirmed the substantially diminished ataxic potential of BZ site agonists devoid of α1 subunit-mediated effects, with preserved anti-anxiety effects at 30 mg/kg of SH-053-S-CH3 and SH-053-S-CH3-2′F. However, all three ligands, dosed at 30 mg/kg, decreased spontaneous locomotor activity, suggesting that sedation may be partly dependent on activity mediated by α5-containing GABAA receptors. Hence, it could be of importance to avoid substantial agonist activity at α5 receptors by candidate anxioselective anxiolytics, if clinical sedation is to be avoided.
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INTRODUCTION
Since their clinical introduction in the early 1960s, benzodiazepines (BZs) have been extensively prescribed worldwide to cope with anxiety, insomnia, muscle spasms, and epilepsy. The basic characterization of the diverse pharmacological effects of BZs: anxiolytic, sedative, hypnotic, muscle relaxant, anticonvulsive, and amnesic, has been considered to represent one of the major successes of behavioral pharmacology (Sanger et al, 2003). In recent years, much effort has been expended to improve the understanding of the molecular and neuronal substrates of these effects, with the final goal to clinically separate wanted from unwanted effects (Sieghart and Sperk, 2002). Among the latter effects, psychomotor and cognitive impairments are common, and more serious neuropsychiatric reactions such as amnesic and aggressive episodes may occur (Lader, 1999).
BZs act as facilitators of fast inhibitory neurotransmission in the mammalian brain mediated through GABAA receptors, which are involved in the regulation of vigilance, anxiety, muscle tension, epileptogenic activity, and memory functions (Rudolph and Möhler, 2004). The vast majority of GABAA receptors are associations of two α subunits, two β subunits, and a single γ subunit, which form a central ion channel, and approximately 80% of all GABAA receptors contain a BZ-binding site located at the interface of the γ2 subunit and the respective α subunit (α1, α2, α3 or α5) (Chang et al, 1996; Sigel and Buhr, 1997). It has been postulated that the four BZ site-building α subunits, with their distinct patterns of anatomical distribution in the brain, participate differently in the various effects of BZs. Indeed, recent genetic and pharmacological studies pointed to the specific contribution of individual receptor subtypes to the spectrum of behavioral actions of BZ site ligands. Specifically, sedative effects of BZs were principally attributed to α1-containing GABAA receptor subtypes, anxiolytic actions to the α2-/α3-containing receptors, anterograde amnesic effects to the α1/α5 subtypes, anticonvulsant activity partially to the α1-containing receptors, and muscle relaxant effects largely to α2-containing receptors (Atack et al, 2006a; Low et al, 2000; McKernan et al, 2000; Rudolph and Möhler, 2006; Rudolph et al, 1999). Moreover, it appears that L-838417, a ligand with zero efficacy at the α1 subtype, is unable to engender sedation in rodents (McKernan et al, 2000) or monkeys (Rowlett et al, 2005), and similar conclusions were drawn from behavioral experiments with other compounds functionally selective for receptors other than α1-containing receptors (Atack et al, 2006c; Dias et al, 2005; Licata et al, 2005). Since the α1-subunit is critically involved in much of the unwanted psychomotor activity of nonselective BZs, ‘α1-neutral' agonists at BZ site are being pursued in the quest for anxioselective anxiolytics (Basile et al, 2004; Whiting, 2006).
To date, all apparently non-sedating BZ site ligands, which are devoid of activity at α1-containing GABAA receptors, engendered essentially antagonist (Atack et al, 2006c; Dias et al, 2005) or only partial agonist efficacy at α5-containing GABAA receptors (Griebel et al, 2001; McKernan et al, 2000). Therefore, it cannot be ruled out that substantial efficacy at α5-containing GABAA receptors may contribute to sedative effects. This is supported by data, which indicate the possibility of substantial motor influence by modulation of α5 subunit containing GABAA receptors. In the spinal cord, somatic and preganglionic motoneurons (lamina IX and lateral cell column) exhibited a moderate to strong staining for the α5 subunit (Bohlhalter et al, 1996). Knock-in mice with the GABAA receptor α5 subunit rendered insensitive to diazepam were refractory to development of tolerance to the sedative effect of diazepam dosed subchronically (van Rijnsoever et al, 2004). These two sets of evidence indicate that the motor influence of α5-GABAA receptor modulation, if present, is not necessarily an indirect consequence of the established effects on learning and memory processes (Collinson et al, 2002; Crestani et al, 2002). Hence, any activity changes seen with ligands possessing a substantial agonistic efficacy for α5 subunit containing GABAA receptors may be, at least partly, mediated by such receptors.
To test this hypothesis, we identified such ligands by using two-electrode voltage clamp experiments in Xenopus oocytes expressing recombinant GABAA receptor subtypes. Three newly synthesized BZ site ligands turned out to be functionally selective for α2, α3, and α5 subtypes of GABAA receptors (SH-053-S-CH3 and SH-053-S-CH3-2′F), or essentially selective for the α5 subtypes (SH-053-R-CH3). We then compared their in vivo behavioral profiles with that of the classical nonselective agonist diazepam. Possible influences on behavioral measures were tested in the elevated plus maze (EPM), spontaneous locomotor activity (SLA) and rotarod test that are considered primarily predictive of the anxiolytic, sedative and ataxic influence of BZs, respectively.
MATERIALS AND METHODS
Drugs
SH-053-S-CH3 and SH-053-R-CH3 (the (S) and (R) stereoisomer, respectively, of 8-ethynyl-4-methyl-6-phenyl-4H-2,5,10b-triaza-benzo[e]azulene-3-carboxylic acid ethyl ester; structures given in Figure 1) as well as SH-053-S-CH3-2′F (the (S) stereoisomer of 8-ethynyl-6-(2-fluorophenyl)-4-methyl-4H-2,5,10b-triaza-benzo[e]azulene-3-carboxylic acid ethyl ester) were synthesized at the Department of Chemistry and Biochemistry, University of Wisconsin-Milwaukee. Diazepam for behavioral studies was obtained from Galenika (Belgrade, Serbia).
Electrophysiological Experiments
Cloning of GABAA receptor subunits α1, β3, and γ2 into pCDM8 expression vectors (Invitrogen, CA) has been described elsewhere (Fuchs et al, 1995). cDNAs for subunits α2, α3, and α5 were gifts from P Malherbe and were subcloned into pCI vector. After linearizing the cDNA vectors with appropriate restriction endonucleases, capped transcripts were produced using the mMessage mMachine T7 transcription kit (Ambion, TX). The capped transcripts were polyadenylated using yeast poly(A) polymerase (USB, OH) and were diluted and stored in diethylpyrocarbonate-treated water at −70°C.
The methods used for isolating, culturing, injecting, and defolliculating of the oocytes were identical as described previously (Sigel, 1987; Sigel et al, 1990). Briefly, mature female Xenopus laevis (Nasco, WI) were anesthetized in a bath of ice-cold 0.17% Tricain (Ethyl-m-aminobenzoat, Sigma, MO) before decapitation and removal of the frog's ovary. Stage 5–6 oocytes with the follicle cell layer around them were singled out of the ovary using a platinum wire loop. Oocytes were stored and incubated at 18°C in modified Barths' medium (MB, containing 88 mM NaCl, 10 mM HEPES-NaOH (pH 7.4), 2.4 mM NaHCO3, 1 mM KCl, 0.82 mM MgSO4, 0.41 mM CaCl2, 0.34 mM Ca(NO3)2) that was supplemented with 100 U/ml penicillin and 100 μg/ml streptomycin. Oocytes with follicle cell layers still around them were injected with a total of 2.25 ng of cRNA. cRNA ratio used was 1 : 1 : 5 for the α subunits, β3, and γ2, respectively. After injection of cRNA, oocytes were incubated for at least 36h before the enveloping follicle cell layers were removed. To this end, oocytes were incubated for 20 min at 37°C in MB that contained 1 mg/ml collagenase type IA and 0.1 mg/ml trypsin inhibitor I-S (both Sigma). This was followed by osmotic shrinkage of the oocytes in doubly concentrated MB medium supplied with 4 mM Na-EGTA and manually removing the follicle cell layer. After peeling off the follicle cell layer, the cells were allowed to recover overnight before being used in electrophysiological experiments.
For electrophysiological recordings, oocytes were placed on a nylon grid in a bath of Xenopus Ringer solution (XR, containing 90 mM NaCl, 5 mM HEPES-NaOH (pH 7.4), 1 mM MgCl2, 1 mM KCl, and 1 mM CaCl2). The oocytes were constantly washed by a flow of 6 ml/min XR, which could be switched to XR containing GABA and/or drugs. Drugs were diluted into XR from dimethylsulfoxide (DMSO) solutions resulting in a final concentration of 0.1% DMSO perfusing the oocytes. Drugs were preapplied for 30 s before the addition of GABA, which was coapplied with the drugs until a peak response was observed. Between two applications, oocytes were washed in XR for up to 15 min to ensure full recovery from desensitization. For current measurements, the oocytes were impaled with two microelectrodes (2–3 mΩ), which were filled with 2 mM KCl. All recordings were performed at room temperature at a holding potential of −60 mV using a Warner OC-725C two-electrode voltage clamp (Warner Instruments, Hamden, CT). Data were digitized, recorded, and measured using a Digidata 1322A data acquisition system (Axon Instruments, Union City, CA). Results of concentration response experiments were graphed using GraphPad Prism 4.00 (GraphPad Software, San Diego, CA). Data were graphed as mean±SEM of at least four oocytes from at least two batches.
Behavioral Experiments
Experiments were carried out on male Wistar rats (Military Farm, Belgrade, Serbia), weighing 200–240 g. All procedures in the study conformed to EEC Directive 86/609 and were approved by the Ethical Committee on Animal Experimentation of the Medical Faculty in Belgrade. The rats were housed in transparent plastic cages, six animals per cage, and had free access to pelleted food and tap water. The temperature of the animal room was 22±1°C, the relative humidity 40–70%, the illumination 120 lux, and the 12/12 h light/dark period (light on at 06:00). All handling and testing took place during the light phase of the diurnal cycle. Throughout the study the animals were used only once. All drugs were dissolved/suspended with the aid of sonication in a solvent containing 85% distilled water, 14% propylene glycol, and 1% Tween 80, and were administered intraperitoneally in a volume of 1 ml/kg.
Behavior on the Elevated Plus Maze
The apparatus was constructed of sheet metal, with a black rubber floor. It consisted of a maze elevated to a height of 50 cm with two open (50 × 10 cm) and two enclosed arms (50 × 10 × 40 cm), connected by a junction area (central platform) measured 10 × 10 cm. A ledge of sheet metal (0.3 cm high) surrounding the open arms was added. The illumination in the experimental room consisted of one red neon tube fixed on the ceiling, giving light intensity of 10 lux on the surface of the arms.
The animals were tested 20 min after injection of drugs or solvent. At the beginning of the experiment, single rats were placed in the center of the maze, facing one of the enclosed arms, and their behavior was recorded for 5 min. A digital camera was mounted above the maze and the image was transmitted to a notebook computer in the neighboring room, running the ANY-maze Video Tracking System software (Stoelting Co., Wood Dale, IL, USA). An entry into an open or closed arm was scored when 90% of the animal crossed the virtual line separating the central square of the maze from the arm, whereas an exit occurred when more than 90% of the animal left the respective arm. After each trial, the maze was cleaned with dry and wet towels.
Measurement of Locomotor Activity
Immediately after receiving the appropriate treatment, single rats were placed in a clear Plexiglas chamber (40 × 25 × 35 cm). Activity under dim red light (20 lux) was recorded for a total of 45 min, without any habituation period, using ANY-maze software (as described above). For purposes of improving data analysis, the central 20% of the chamber (200 cm2) was virtually set as a central zone. The minimum percentage of animal that must have been in the zone for an entry to occur was set at 70%, and 50% of the animal must have remained in the zone for an exit not to occur.
Rotarod Performance
Rotarod test (Ugo Basile, Comerio, Italy) measured the capacity of the animal to maintain itself on the rod revolving 10 r.p.m. During two consecutive days, the rats were trained to walk on the revolving rod until they could complete three 180 s sessions (each day) without falling of. In the morning of the third day, the final selection was made. Only animals capable of remaining 180 s on the rod, without any fall, were chosen for further testing. The animals which were not able to remain on the rod for 180 s when tested 20 min after treatment were considered incapacitated.
Statistical Analysis
All numerical data presented in the figures were given as the mean±SEM. For electrophysiological data Student's t-test was used. Data from the EPM and activity assay were assessed by a one-way ANOVA. If the ANOVA was significant, each treatment condition was compared with control by a Dunnett's test (α=0.05). ED50 value for rotarod incapacitation was calculated by probit analysis according to the method of Litchfield and Wilcoxon. Statistical analyses were performed with ANY-maze software.
RESULTS
Electrophysiological Experiments
In vitro data for SH-053-S-CH3 (Figure 2a) and SH-053-R-CH3 (Figure 2b) demonstrated that at concentrations up to 1 μM both ligands significantly and dose-dependently stimulated GABA EC3 response of α5-containing receptors up to 300 and 200% of control current, respectively. These compounds, thus, are high-efficacy agonists at the α5-containing GABAA receptors comparable to diazepam (see legend to Figure 2), with very low efficacies at α1 containing subtypes. However, although SH-053-S-CH3 exerted substantial potentiation of an EC3 GABA response at α2 and α3-containing GABAA receptors, the influence of SH-053-R-CH3 at these receptors was comparable to its minor effect at the α1 subtype (cf. molecular modeling in Figure 1). The in vitro concentration–effect curves for SH-053-S-CH3-2′F (Rowlett JK, Furtmüller R, Cook JM, unpublished results) were similar to those for SH-053-S-CH3, but with a higher magnitude of efficacies at the respective α2, α3, and α5 GABAA receptor subtypes in the concentration range 0.1–10 μM.
Elevated Plus Maze
SH-053-S-CH3
Activity-related parameters: The influence of treatment on closed arm entries did not reach statistical significance (F(4,27)=1.19, p=0.337); statistical analysis by ANOVA showed a significant effect of treatment neither on total arm entries (F(4,27)=1.72, p=0.175) nor on total distance travelled (F(4,27)=1.80, p=0.157).
Anxiety-related parameters (Figure 3): There was a close to significant effect of treatment on distance travelled in open arms (F(4,27)=2.37, p=0.078) (Figure 3a). The overall influence of treatment on the percentage of open-arm entries has reached statistical significance (F(4,27)=3.13, p=0.031) (Figure 3b), Dunnett's test pointed to the anxiolytic influence of diazepam (p=0.038) and SH-053-S-CH3 dosed at 30 mg/kg (p=0.049). The influence on the percentage of time on open arms also was significant (F(4,27)=2.75, p=0.049) (Figure 3c), but post hoc testing did not detect a significant effect of any single treatment.
SH-053-S-CH3-2′F
Activity-related parameters: Statistical evaluation by ANOVA did not show significant influences of treatment on closed-arm entries, total-arm entries or total distance travelled ((F(4,45)=1.29, p=0.290), (F(4,45)=0.13, p=0.969), and (F(4,45)=0.25, p=0.911), respectively).
Anxiety-related parameters (Figure 4): Although the influence of treatment on distance travelled in open arms was not significant (F(4,45)=1.92, p=0.124) (Figure 4a), the overall effect on the percentage of open arm entries (Figure 4b) and the percentage of time on open arms (Figure 4c) has reached statistical significance ((F(4,45)=2.94, p=0.031) and (F(4,45)=2.92, p=0.031), respectively). For both of these parameters, post hoc testing revealed the equivalent influence of diazepam and SH-053-S-CH3 dosed at 30 mg/kg (p values 0.018 for the percentage of open-arm entries and 0.017 for the percentage of time on open arms).
SH-053-R-CH3
When tested at doses up to 30 mg/kg, SH-053-R-CH3 failed to induce any significant change of the measured EPM parameters (data not shown).
Locomotor activity assay
Whole chamber activity: An ANOVA showed a significant effect of treatment on total distance travelled during 45 min of monitoring (F(4,31)=3.86, p<0.001) (Figure 5, whole bars). According to Dunnett's test, the activity-decreasing effect of all four tested compounds (diazepam 1.25 mg/kg, SH-053-S-CH3, SH-053-S-CH3-2′F and SH-053-R-CH3 at 30 mg/kg each) was significant related to solvent. When the ANOVA was applied on the 5 min intervals of travelled distance (Figure 6), it turned out that locomotor activity was significantly depressed in the time period 5–20 min (SH-053-S-CH3 30 mg/kg, SH-053-S-CH3-2′F 30 mg/kg, and SH-053-R-CH3 30 mg/kg), whereas diazepam 1.25 mg/kg decreased locomotion in the period 5–15 min.
Central/peripheral distance: An ANOVA showed a significant effect of treatment on distance travelled in the arbitrarily set central parts of the chamber during 45 min of monitoring (F(4,31)=2.73, p=0.047) (Figure 5, hatched bars). The respective p values for diazepam 1.25 mg/kg, SH-053-S-CH3 30 mg/kg, SH-053-S-CH3-2′F 30 mg/kg, and SH-053-R-CH3 30 mg/kg were 0.491, 0.029, 0.067, and 0.207, related to solvent. According to ANOVA, the influence of treatment on activity in peripheral parts of the chamber (Figure 5, open bars) was more distinct: F(4.31)=3.59, p=0.016; all the four treatments significantly decreased activity when related to control by Dunnett's test.
Rotarod test: When one monitors the influence on rotarod performance as a quantal phenomenon (ie all or none effect), the minimal incapacitating doses of SH-053-S-CH3 and SH-053-S-CH3-2′F were 200 mg/kg for both substances. The median incapacitating doses of diazepam, SH-053-S-CH3, and SH-053-S-CH3-2′F were 2.99, 213.67, and 218.80 mg/kg, respectively. Due to the shortage of substance, the median incapacitating dose of SH-053-R-CH3 was not found; at doses up to 100 mg/kg it did not induce any manifest incapacitation in this test.
DISCUSSION
The present experiments demonstrated the anxiolytic potential of two newly synthesized compounds functionally selective for α2-, α3-, and α5-containing GABAA receptors, SH-053-S-CH3, and SH-053-S-CH3-2′F, which is mainly devoid of ataxic, but not of sedative actions characteristic of nonselective BZs. Furthermore, a stereoisomer of SH-053-S-CH3 functionally selective for GABAA receptors containing the α5 subunit, SH-053-R-CH3, exerted in the locomotor activity paradigm a significant hypolocomotor effect comparable to diazepam, without observable anti-anxiety or ataxic activity in the EPM, and rotarod test, respectively.
These findings were somewhat unexpected, since both motor incoordination and sedation have been ascribed to the α1 subunit-mediated action of diazepam (Rudolph et al, 1999; McKernan et al, 2000). Hence, either these three compounds were not silent at the α1 subtype when dosed at 30 mg/kg, or some non-α1-subunit-containing receptors contribute to the hypolocomotor action of BZ site agonists. Although the absence of occupancy data for distinct receptor subtypes precludes drawing firm conclusions, high minimal incapacitating doses of the present functionally selective ligands in the rotarod test could be seen as indirect evidence for lack of involvement of GABAA receptors containing the α1 subunit in behavioral actions of 30 mg/kg doses. Specifically, diazepam-induced loss of motor coordination in the rotarod test was linked to the α1 subunit (Crestani et al, 2000; McKernan et al, 2000), and the sevenfold differences in effective doses of SH-053-S-CH3 and SH-053-S-CH3-2′F in rotarod vs SLA test could hardly exist if substantial modulation at α1 subunit containing GABAA receptors were attained already at 30 mg/kg. However, there may exist marked differences in fractional occupancy of GABAA receptors containing the α1 subunit needed for producing behavioral effects of a BZ site agonist in these two tests, meaning that low-to-moderate modulation at such receptors is sufficient for eliciting sedative, but not rotarod–incapacitating, action (cf. Facklam et al, 1992). Nevertheless, the latter explanation is not highly probable for the tested ligands with very low efficacies at α1-containing subtypes. Namely, even the preferential α1 subunit-selective agonist, zolpidem, does not possess more than 4.3 and 2.5 times greater potency to decrease locomotor activity compared to rotarod impairment in rats and mice, respectively (Sanger et al, 1996), whereas non-subtype-selective agonists, such as diazepam, may be even more potent in exerting rotarod impairment than locomotor hypoactivity (Savić et al, 2003).
In its broadest sense, sedation involves decreased psychomotor and cognitive performance, and in most instances it is considered an adverse effect of psychotropic drugs, which should be avoided. In animals, the psychomotor component is most frequently studied (Bourin and Briley, 2004), and measurement of motor activity in rodents represents a standard behavioral assay for testing the sedative potential of drugs (Vogel, 2002). In fact, sensitivity of preclinical tests for discerning the sedative potential of a drug is of paramount importance; several BZ site partial agonists developed as putative low-sedative anxiolytics have nevertheless appeared to be incapacitating when subsequently tested in humans (Whiting, 2006). In support of the sensitivity of the standard SLA test used in the present study, Dailly et al (2002) observed a sedative effect of diazepam (1 mg/kg i.p.) in the actimeter, but not in the light–dark test of anxiety, which also measured locomotor activity of mice. In accordance, SH-053-S-CH3, SH-053-2′F-S-CH3, and SH-053-R-CH3, all dosed at 30 mg/kg, exerted a statistically significant depression of locomotion in the SLA test in our study, whereas the influence on the standard activity parameters in the EPM (closed-arm entries and total distance travelled), if any, was far from significant. It should be emphasized that the hypolocomotor influence in the SLA test is also evident when separately analyzing activity in the peripheral zone of the chamber. Hence, the observed motor depressant effects of the tested ligands were not dependent on central zone activity, which is confounded by influences on emotional reactivity, that is, anxiety, and could be seen as a pure measure of sedation (cf. Savić et al, 2006). These results further support the routine use of the SLA test (Bourin and Briley, 2004; Vogel, 2002) in efforts to predict clinical sedation.
On the other hand, it is noticeable that standard studies of motor activity, which form the very basis of knowledge of drug effects on behavior (Kelley, 1993), were not employed for characterization of recently reported putative anxioselective compounds (Atack et al, 2006c; Jennings et al, 2006; Griebel et al, 2001; Russell et al, 2006). Jennings et al (2006) reported on an α2/α3-BZ site-selective ligand from the class of imidazo[1,2-b][1,2,4]triazines with anxiolytic activity in the rat EPM test at the dose of 1 mg/kg, which showed no motor incapacitation in the mouse rotarod test at doses up to 30 mg/kg. A close congener of that compound was anxiolytic in the rat EPM test at 3 mg/kg, whereas it showed no significant activity in a surrogate assay of sedation (chain-pulling test in rats) and in the mouse rotarod test when tested in doses up to 10 mg/kg; reportedly, this compound was chosen as a clinical candidate (Russell et al, 2006). Similarly, a 1,2,4-triazolo[4,3-b]pyridazine, TPA023, exerted anxiolytic-like activity in the rat EPM and fear-potentiated startle tests at the dose of 1 mg/kg as well as in the assay of conditioned suppression of drinking at 3 mg/kg, whereas, at doses up to 30 mg/kg, it did not significantly affect behavior of rats in the chain-pulling test nor rotarod performance of mice (Atack et al, 2006c). However, the same experimental group, when testing pagoclone, detected sedative action of this BZ site agonist dosed at 1 mg/kg in the chain-pulling test, while already at 0.3 mg/kg in the SLA test (Atack et al, 2006b). The very high dose (10 mg/kg) of diazepam used as the active control in the chain-pulling test (Atack et al, 2006b) additionally supports the view of superior sensitivity of the standard SLA test.
From these reasons, it is difficult to compare behavioral profiles of the compounds described in the present paper with findings from the above-cited studies. Evidently, all three newly synthesized BZ site ligands could have acted through the α5 subtype-containing GABAA receptors, one of them (SH-053-R-CH3) as an essentially subtype-selective ligand. There exist data that support the possibility of substantial motor manifestations of α5-containing GABAA receptor modulation, besides the indirect consequences brought on by the effects on learning and memory processes, where pertinent (Collinson et al, 2002; Crestani et al, 2002). Somatic and preganglionic motoneurons in the spinal cord exhibit a moderate-to-strong staining for the α5 subunit (Bohlhalter et al, 1996), whereas the knock-in mice harboring the α5 subunit insensitive to diazepam are refractory to development of tolerance to the sedative effect of diazepam dosed subchronically, presumably due to a downregulation of α5 subunits in the dentate gyrus (van Rijnsoever et al, 2004). Hence, we hypothesize that any locomotor activity changes induced by ligands possessing a substantial α5-efficacy may be, at least partly, contributed by modulation at GABAA receptors containing this subunit. Nevertheless, as a caveat to all studies examining sedation, it should be remembered that a decrease in automatically measured locomotor activity can be due to a variety of causes other than sedation, including the occurrence of stereotyped behavior, motor impairments or pain (Porsolt et al, 1993). In addition, particular caution is needed when transposing in vitro data to the in vivo conditions. Atack et al (2006a) reported on substantial decrease of the α5 subtype-binding selectivity of the BZ site inverse agonist RY-080 (Liu et al, 1995) when binding was tested in vivo; since RY-080 exerted appreciable inverse agonist-efficacy at the α1-containing GABAA receptors (Atack et al, 2006a), interpretation of behavioral actions of such functionally nonselective ligands is especially hindered. To dissect these overlaps in activity and uncertainties, much is expected from screening of newer BZ site ligands in the future, which will be still more functionally selective than those presented in this work.
In conclusion, the present results confirm the highly diminished ataxic potential of BZ site agonists devoid of α1 subunit-mediated effects. Anti-anxiety activity of such ligands remains preserved, whereas the confounding sedation stays observable, and may be partly dependent on the α5-containing GABAA receptors. Hence, it could be of importance to avoid substantial potentiation through the α5 subunits by the candidate anxioselective anxiolytics, if the clinical sedation is to be prevented.
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Acknowledgements
This work was supported in part by NIMH 46851 (JMC) and by The Ministry of Science and Environment Protection, R Serbia—Grant No. 145022B (MMS). We acknowledge the support of this work by the Research Growth Initiative of the University of Wisconsin-Milwaukee.
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Savić, M., Huang, S., Furtmüller, R. et al. Are GABAA Receptors Containing α5 Subunits Contributing to the Sedative Properties of Benzodiazepine Site Agonists?. Neuropsychopharmacol 33, 332–339 (2008). https://doi.org/10.1038/sj.npp.1301403
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DOI: https://doi.org/10.1038/sj.npp.1301403
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