Materials and Methods

Targeted Deletion of the α5 Gene.

The mouse gene for the nAChR α5 subunit was isolated by screening a mouse 129/SvEv genomic library (a gift from Richard Behringer, M. D. Anderson Cancer Center, Houston, TX) with a rat cDNA probe, and a detailed restriction map was obtained. Most of exon 5, which contains three of the four transmembrane domains, was replaced with a neomycin resistance cassette (Neo), electroporated into AB2.2 embryonic stem cells, and transmitted into the germline as described previously (Orr-Urtreger et al., 1997). Chimeric mice were obtained and bred with C57BL/6J mice. The mutant allele (5.6-kb fragment) was differentiated from the wild-type (20.5-kb fragment) using Southern blot analysis with a flanking genomic probe. PCR with the following primers was designed to determine the genotype for the mutation: α5 wild-type: forward, 5′-GTGAAAGAGAACGACGTCCGC-3′; reverse, 5′-GCCTCAGCCCCTGAATGGTAG-3′; α5 mutant: forward 5′-CTTTTTGTCAAGACCGACCTGTCCG; reverse, 5′-CTCGATGCGATGTTTCGCTTGGTG-3′. The wild-type product is 380 base pairs, and the mutant product is 290 base pairs.

Animals.

All mice used in this study were back-crossed onto a C57BL/6 background for seven generations. Open-field, seizure, and histology experiments were done on 2- to 6-month-old mice, with male and female mice in an approximately 50/50 ratio. Mice were generated by crossing heterozygous male and female mice, weaned at 21 days of age, and housed in groups of two to five per cage under a 12-h/12-h light cycle, with food and water ad libitum. All procedures were approved by the Institutional Animal Care and Use committee in accordance with federal guidelines.

Basal Behavioral Battery.

To examine the role of α5 nAChRs in basal behavior, α5 homozygous mutant mice and their wild-type littermates were tested in a battery of behavioral experiments (for a description of the battery of behavioral tests, see Paylor et al., 1998). Mice were examined on the following tests: 1) a neurological screen for simple sensory and motor function; 2) open-field test for exploratory activity and anxiety-related responses; 3) light-dark exploration box for anxiety-related responses; 4) rotarod test for motor coordination and skill learning; 5) acoustic startle response and prepulse inhibition of the startle response; 6) startle habituation; 7) passive avoidance test; and 8) hotplate test for analgesia-related responses.

Seizure Testing.

One day before seizure induction, mice were weighed, marked, and transferred to the testing room for acclimation. Nicotine tartrate (Sigma, St. Louis, MO), dissolved in phosphate-buffered saline (PBS) was administered i.p. in a volume of 10 μl/g of body weight. The amounts of nicotine injected were 2, 3, 5, 7, 10, and 14 mg/kg. For each genotype, 5 to 14 mice were used at each nicotine concentration, except for very low doses (2 and 3 mg/kg) on α5 −/− mice and very high doses (10 and 14 mg/kg) on α5 +/+ and α5 +/− mice, where less animals were used. On any given experimentation day, at least one mouse from each genotype received one high and one low dose of nicotine. Immediately after injection, mice were placed in a regular mouse cage with bedding, and behavioral responses were recorded by two investigators for 5 min. Experimenters were blind to the genotype of the mice. The effects of nicotine were dose-dependent. An arbitrary scale was created to assess sensitivity to nicotine as follows (Franceschini et al., 2002): 0, no obvious effects; 1, locomotor effects including sedation and increased exploratory activity; 2, tremors, tachypnea, and back arching; 3, rapid movements of the legs; 4, complete loss of righting reflex and seizures; and 5, death. Sensitivity to nicotine seizures was assessed by calculating the percentage of animals in each genotype group that had a score of 4 or 5. Data were fitted with a logistic curve to determine the EC₅₀.

Effects of Nicotine on the Open Field.

Mice (9–22 per genotype per dose) were i.p. injected with either PBS alone or nicotine (0.1, 0.25, or 0.5 mg/kg) in PBS, in a volume of 10 μl/g body weight. Immediately after injection, mice were placed in a clear Plexiglas box (40 × 40 × 40 cm) and their movements were monitored for 30 min using a computer-assisted Ethovision system (Noldus, the Netherlands). Total distance moved, average distance to the center, and the ratio of distance moved in a center square (20 × 20 cm) to total distance moved were recorded.

Histology.

Mice (n = 3 per genotype) were decapitated under anesthesia, and their brains were removed and frozen in isopentane (−30°C, 30 s). Fresh-frozen brains were cut (20-μm sections) in a cryostat and sections were mounted onto either gelatin-coated slides (for receptor binding and histological staining) or slides with an additional coating of poly(l-lysine) kept at −20°C (for in situ hybridization). Slide-mounted sections for receptor binding were stored at −20°C until use. Sections for in situ hybridization and histological staining were postfixed in 4% paraformaldehyde (30 min, room temperature), washed three times in PBS, and stored desiccated at −20°C until use. Slide-mounted brain sections for Nissl staining were stained with cresyl violet. Acetylcholinesterase histochemistry was performed as described previously (Orr-Urtreger et al., 2000).

In Situ Hybridization.

Mouse DNA templates encoding the intracellular loop of various nAChR subunits were prepared by RT-PCR using RNA from the mouse septal neuroblastoma cell line SN56 as template. Primers for RT-PCR were designed with available rat nAChR cDNA sequences. The size and cDNA region of each nAChR subunit probe has been reported (Franceschini et al., 2002). In situ hybridization was performed as described previously (Broide et al., 1996). Briefly, sense and antisense ³⁵S-UTP–labeled (PerkinElmer Life Sciences, Boston, MA) cRNA riboprobes were synthesized and hybridized to proteinase K-treated brain sections overnight at 60°C. Sections were washed and exposed to X-ray film for 3 to 7 days.

Receptor Autoradiography.

Slide-mounted brain sections were processed for ¹²⁵I-α-BTX binding as described previously (Broide et al., 1996). Briefly, slides were incubated for 2 h at room temperature in binding buffer A (50 mM Tris base, pH 7.4, 120 mM NaCl, and 0.1% bovine serum albumin) containing 5 nM¹²⁵I-α-BTX (specific activity, 10–20 μCi/μg; PerkinElmer Life Sciences). Nonspecific binding was defined on adjacent sections in the presence of 10 μM α-cobratoxin. Slides were washed twice for 10 min in ice-cold binding buffer A, rinsed in water, dried, and exposed to β-Max (Amersham Biosciences, Piscataway, NJ) or BIOMAX (Eastman Kodak, Rochester, NY) film for 3 to 7 days.

Brain sections were processed for¹²⁵I-epibatidine binding by incubation in binding buffer B (50 mM Tris base, pH 7.4, 120 mM NaCl, 5 mM KCl, 2.5 mM CaCl₂, and 1 mM MgCl₂) in the presence of 500 pM ¹²⁵I-epibatidine (specific activity, 2200 Ci/mmol; PerkinElmer Life Sciences). Nonspecific binding was assessed on adjacent sections in the presence of 100 μM nicotine. Slides were then washed twice in ice-cold binding buffer B, rinsed once in water, dried, and exposed to β-Max film for 3 to 12 h.

Data Analysis and Statistics.

X-ray films were analyzed, and signals were quantified using computer-assisted densitometry (NIH Image program, http://rsb.info.nih.gov/nih-image/). Relative optical densities for discrete brain regions were measured and presented as a percentage of readings from wild-type brains in the same films. Care was taken to avoid overexposure and to make sure that the signal of interest was always within the linear range of the film. All data were examined by multivariate analysis of variance, followed by Newman-Keuls post hoc comparisons.

Results

Generation of α5 nAChR Subunit Null Mice.

Mice deficient in the α5 subunit were generated by replacing a 4-kb region containing most of exon 5 with a Neo-loxP-3′hprt cassette. This construct was then introduced into AB 2.2 embryonic stem cells from the 129/SvEv mouse strain, followed by transmission to the germline (Fig. 1A) (Orr-Urtreger et al., 1997). Southern blot analysis using a flanking genomic probe detected a new 5.6-kb mutant fragment in the heterozygote (+/−) and homozygote (−/−) mice (Fig. 1B) in addition to the 20.5-kb fragment in wild-type mice. The effect of the mutation on mRNA transcripts was examined using Northern blotting, and no detectable transcripts were found in homozygous mutant mice (Fig. 1C).

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Figure 1

Generation of α5-mutant mice. A, wild-type allele and targeting vector, depicted with restriction enzyme sites. Exon 5 is shown as a black box, and the probe used for Southern blotting as an open box underneath the wild-type allele. Restriction enzymes: E,EcoRI; E109I, Eco109I; S,SacI; X, XhoI. TK, thymidine kinase; Hprt, hypoxantine phosphoribosyltransferase. B, Southern blot analysis of tail DNA from α5 +/+, α5 +/−, and α5 −/− mice using the probe shown in A. C, Northern blot analysis for the expression of the α5 subunit in the brains of α5 +/+, α5 +/−, and α5 −/− mice. Rat cDNA was used as probe. As control, a probe for glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was used.

α5(−/−) mice are viable and fertile, are born in the expected proportion from mating of heterozygote mice, grow to normal size, and show no obvious physical or neurological deficits. In a battery of behavioral tests (Paylor et al., 1998) the α5 −/− mice behaved like their wild-type littermates (Table 1).

α5 Null Mice Are Resistant to Nicotine-Induced Seizures.

Intraperitoneal injection of nicotine induced seizures in a dose-dependent manner in wild-type mice. However, only a small number of α5 −/− mice suffered seizures at very high nicotine concentrations, making these animals almost refractory to nicotine-induced seizures (Fig. 2A). In +/+ and +/− mice, the EC₅₀ values of nicotine were 4.1 ± 0.1 and 4.3 ± 0.05 mg/kg, respectively, consistent with previous results (Broide et al., 2002; Franceschini et al., 2002). Only 35% of the α5 −/− tested went into seizure, and for that group of animals, the EC₅₀ was 8.4 mg/kg. In addition, at every dose tested, α5 mutant mice were less sensitive to the effects of nicotine (Fig. 2, B–D).

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Figure 2

Nicotine-induced seizures and behavior. A, dose-response curves for the convulsant effects of nicotine in α5 +/+, α5 +/−, and α5 −/− mice. Data show the percentage of mice undergoing seizure that either survived (score 4) or died (score 5). B–D, decreased sensitivity to the effects of nicotine in α5 −/− at different doses. The percentage of animals that obtained each score is depicted for three doses of nicotine: 2 (B), 4 (C), and 8 mg/kg (D).

Experimentally Naive α5 Null Mice Are Resistant to the Hypolocomotive Effects of Nicotine.

In the open field, nicotine initially produces a sedative effect in both mice and rats (Decker et al., 1995; Nagahara and Handa, 1999). We observed the locomotor effect of nicotine on α5 −/− mice and their +/+ littermates, starting immediately after i.p. injection of nicotine or saline. In our hands, the effect of nicotine was largest during the first 5 min; at 30 min, the locomotion values returned to normal at every dose tested (not shown). To determine whether nicotine had different pharmacodynamics in the mutant mice, we ran the open-field test for 30 min and found that nicotine had no effect on α5 −/− mice for the whole period of observation. In the α5 −/− mice, the hypolocomotive effects of nicotine could be observed beginning at 1 mg/kg. Figure3 shows data for the first 5 min in the open field after i.p. injection of nicotine. In α5 +/+ animals, the lowest dose of nicotine (0.1 mg/kg) produced a small hyperlocomotive effect that failed to show statistical significance. At 0.25 mg/kg, nicotine had a sedative effect that was also not statistically significant. At 0.5 mg/kg, nicotine had a major effect on locomotion, decreasing it from 1840 ± 109 to 834 ± 75 cm (p < 0.0005). At 1 mg/kg, locomotion was further decreased in the α5 +/+ mice, but in some cases, the animals manifested the typical effects observed with high nicotine doses, such as rapid movements of the legs (wild run). In α5 −/− mice, nicotine doses up to 0.5 mg/kg had no effect, but 1 and 3 mg/kg decreased locomotion from 1814 ± 117 to 942 ± 151 and 452 ± 86 cm, respectively. The ratio of distance moved in a center square (20 × 20 cm) to total distance moved, a measure of anxiety, was not statistically different between α5 +/+ and α5 −/− mice at any dose.

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Figure 3

Reduced effect of low doses of nicotine in the open field in α5 −/− mice. Dose-dependent effects of nicotine on the total distance moved in the open field during 5 min for α5 +/+ and α5 −/− mice, immediately after i.p. injection of nicotine or vehicle. *, p < 0.0005; **, p< 0.0001 compared with 0 mg/kg in the corresponding genotype (analysis of variance and Newman-Keuls post hoc comparison).

α5 Mutant Mice Show Normal Neuroanatomy.

The brains of α5 +/− and −/− mice did not show any gross anatomical difference compared with wild-type littermates. For example, the hippocampus, one of the regions in which the α5 subunit is expressed, displayed normal layering within all substructures, as assessed by Nissl (Fig.4, A–C) and Acetylcholinesterase staining (Fig. 4, D–F). All other regions of the brain examined were also normal (data not shown), including the IPN and VTA/SNc, which express high levels of α5 mRNA.

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Figure 4

Normal anatomy in α5 −/− mouse brains. A–F, transverse sections of mouse brains at the hippocampus level. A–C, sections stained with cresyl violet. D and F, sections stained for acetylcholinesterase. Normal hippocampal formations with correct layers are seen in α5 −/− mice. Scale bar, 200 μm.

α5 Mutant Mice Have Normal Levels of α4, α6, α7, β2, and β4 nAChR Subunits.

To determine whether other nAChR subunits that are potentially relevant to nicotine-induced seizures might be differentially regulated in the absence of the α5 subunit, we performed in situ hybridization experiments to examine the patterns and levels of mRNA distribution for the α4, α6, α7, β2, and β4 nAChR subunits in brains of α5 +/+, +/−, and −/− mice (Fig.5). As described previously (Broide et al., 2002; Franceschini et al., 2002) α4 mRNA levels were high in the thalamus (Th), medial habenula (MHb), SN, and VTA, and moderate in cortex (Ctx), hippocampus (Hi), and hypothalamus (Hy). α6 mRNA was high in SN and VTA, and moderate in the superior colliculus (SC). α7 signal was high in Hi, Hy, amygdala, SC, and inferior colliculus, with lower levels in the Ctx and caudate putamen (Cpu). Strong signal for β2 was found in the Th, Hi, and MHb, with lower levels in the Ctx, Cpu, SN, and olfactory bulb. β4 mRNA signal was restricted to the olfactory bulb, MHb, IPN, and pineal gland. There were no statistically significant differences between α5 +/+, +/−, and −/− mice in the levels of α4, α6, α7, β2, and β4 transcripts for all brain regions examined (Table 2).

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Figure 5

Normal levels of expression of other nAChR subunits in α5 −/− mouse brains. Autoradiographic images of brain sections at the levels of the hippocampus and substantia nigra from α5 +/+, α5 +/−, and α5 −/− mice. Sections show the distribution of mRNA for the α4 (A–C), α5 (D–F), α6 (G–I), α7 (J–L), β2 (M–O), and β4 (P–R) subunits. Scale bar, 1 mm.

To study the levels of nAChR receptor subtypes expressed in α5 mutant and wild-type mice, we performed receptor binding experiments on brain sections from α5 +/+, +/−, and −/− mice. First, we used 500 pM¹²⁵I-epibatidine, which binds, at this concentration, to at least two subtypes of nicotinic receptors, probably containing α3, α4, α6, β2, and β4 subunits (Zoli et al., 1998; Whiteaker et al., 2000b; Champtiaux et al., 2002). In +/+ littermates, high levels of ¹²⁵I-epibatidine binding were observed in the Th, SC, MHb, and IPN. More modest levels were found in the Ctx and Cpu (Fig. 6). A similar pattern of ¹²⁵I-epibatidine binding site distribution was observed in both α5 +/− and −/− mouse brains (Fig. 6). In addition, we used ¹²⁵I-α-BTX to study α7-containing nAChR levels in α5 +/+, +/−, and −/− brains. High levels of ¹²⁵I-α-BTX binding were found in the Hi, Hy, amygdala, SC, and inferior colliculus of +/+ mouse brains. Lower levels of ¹²⁵I-α-BTX binding were found in the Ctx and Cpu. The same pattern of expression was observed in both α5 +/−, and −/− brains. ¹²⁵I-Epibatidine and¹²⁵I-α-BTX binding signals were quantified by measuring relative optical densities from three brains per genotype. No statistically significant differences were found among α5 +/+, +/−, and −/− mice in any of the brain regions analyzed (Table 2).

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Figure 6

Normal levels of ¹²⁵I-epibatidine and¹²⁵I-α-BTX in α5 −/− brains. Autoradiographic images of brain sections at the levels of the hippocampus from α5 +/+, α5 +/−, and α5 −/− mice. Sections show the distribution of¹²⁵I-epibatidine (A-C) and ¹²⁵I-α-BTX (D-F) binding sites. Scale bar, 1 mm.

Discussion

We have shown in the present study that mice lacking the α5 nAChR subunit survive to adulthood and have no readily detectable abnormalities. In a battery of behavioral tests, α5 −/− mice showed no significant difference from their wild-type littermates. Because each of the tests performed measures a behavior that is influenced by multiple genes (Flint, 2003), our data suggest that α5 does not have a major effect on the behavioral traits studied. Although α5 −/− mice display normal behavior in basal conditions, they are significantly less sensitive to the effects of nicotine than the wild-type littermates. This resistance to nicotine treatment was observed at both low and high nicotine doses and affected not only seizure sensitivity but also other behavioral effects, particularly those related to locomotor activity. Twice as much nicotine was needed in α5 −/− mice to elicit the effects observed in their wild-type littermates. Thus, although α5-containing nAChRs may not be essential for the expression of certain behaviors in basal conditions, they might be important mediators of the effects of nicotine.

Nicotine-induced seizures have been examined in different strains of mice, and using different pharmacological techniques. Previous studies pointed to the α7 subunit as the main candidate responsible for nicotine-induced seizures (Miner et al., 1984, 1985; Miner and Collins, 1989), but α7 −/− mice in a C57BL background display normal sensitivity to high doses of nicotine (Franceschini et al., 2002). In contrast, mice engineered to have a partial gain of function of α7-containing receptors display increased sensitivity to nicotine-induced seizures (Broide et al., 2002; Gil et al., 2002). These results suggest that the role of α7 subunits in nicotine-induced seizures is complex and is probably influenced by the genetic background of the animals tested (Miner et al., 1984, 1985;Miner and Collins, 1989). Studies with strain-specific variants of different nAChR subunits have also implicated α4-, α5-, and α6-containing receptors as possible mediators of nicotine-induced seizures (Stitzel et al., 1998, 2000), and our experiments confirm the role of α5 in mediating the convulsant effects of nicotine.

There is abundant evidence that tonic and clonic seizures can originate in the hippocampus (Stitzel et al., 2000; McCormick and Contreras, 2001). Because the expression of α5 is restricted to the hippocampal CA1 region, it is tempting to speculate that nicotine-induced seizures are mediated by the activation of neuronal circuits within this area. The majority of hippocampal neurons display a rapidly activating and desensitizing current that is mediated by α7-containing nAChRs (Alkondon and Albuquerque, 1993; Orr-Urtreger et al., 1997; Zarei et al., 1999). A smaller proportion of neurons expresses nAChR currents with slower kinetics, and these cells are thought to express β2-containing nAChRs (Sudweeks and Yakel, 2000; Khiroug et al., 2002). Because the CA1 region is the only place in the central nervous system where α5 and α7 subunits are coexpressed (Figs. 5 and 6), and because there is evidence that the α7 nAChR subunit might form both homomeric and heteromeric channels (Cuevas and Berg, 1998; Yu and Role, 1998b; Khiroug et al., 2002), one possibility is that α5 and α7 subunits coassemble, probably with β2, to form functional nAChRs in CA1. Alternatively, α5 could participate in receptors containing the α4 and β2 subunits, because those subunits are also expressed in this hippocampal region, and 25% of brain α4β2-containing nAChRs might include the α5 subunit (Gerzanich et al., 1998).

Although our data would agree with the hypothesis of nicotine-induced seizures originating in the hippocampus, there is evidence that the IPN is able to mediate seizure activity in rodents and humans (Myers and Shapiro, 1979; Olsen et al., 1985; Chiba and Wada, 1995). Hence, α5-containing receptors in the IPN might also mediate the effects of nicotine. This hypothesis is supported by the fact that partial kainic acid-induced lesions in the IPN of the rat suppress the hypolocomotive effect of nicotine in the open field (Hentall and Gollapudi, 1995). Expression of α5 is also high in the VTA/SNc area. There are numerous reports of seizures originated in the substantia nigra, but the pars reticulata (which does not express the α5 subunit), not the pars compacta (SNc), seems to be responsible for these effects. Furthermore, seizures originated in the pars reticulata are mainly clonic, whereas nicotine-induced seizures are clearly tonic-clonic (Gale, 1985; Fan et al., 2000; Deransart et al., 2001). Instead of mediating the convulsant effects of nicotine, α5-containing nAChRs in the VTA/SNc might be important for the locomotor effects elicited by nicotine. In experimentally naive rats, nicotine decreases locomotion, but in a familiar environment, it enhances locomotion (Museo and Wise, 1990;Stolerman et al., 1995; Louis and Clarke, 1998). The locomotor alterations produced by nicotine's activation of dopaminergic neurons in the mesencephalon might be one of the effects that reinforce the use of tobacco (Di Chiara, 2000). Dopaminergic neurons in the VTA/SN area express mRNA encoding for the α3, α4, α5, α6, α7, β2, β3, and β4 nAChR subunits (Wada et al., 1989, 1990; Klink et al., 2001). A series of studies points to the α4, α6, α7, and β2 subunits as important for nicotine's effects on DA release and locomotor responses (Pidoplichko et al., 1997; le Novere et al., 1999; Ross et al., 2000; Broide et al., 2002; Champtiaux et al., 2002). Klink et al. (2001) recently proposed the existence of four main nAChR subtypes in VTA/SN neurons, two of which might incorporate α5 in α4α6α5(β2)₂ and (α4)2α5(β2)₂ receptors. Therefore, it is possible that the nicotine-induced locomotor effects are mediated by channels located in the VTA/SN area that contain both α4 and α5 subunits.

A latent possibility in most knock-out mice experiments is that of compensation by up-regulation of genes with functions similar to the one ablated. Alternatively, it is possible that the lack of a particular gene creates a general defect in some tissue, creating an indirect phenotype. To assess these possibilities, we studied the brain anatomy, the mRNA expression of other nAChR subunits, and the binding of nicotinic drugs in α5 −/− mice. None of these experiments revealed any differences between α5 +/+, α5 +/−, and α5 −/− mouse brains. These results indicate that the α5 null mutation does not result in the total loss of any binding site. However, it is possible that, although there is no difference in mRNA expression and toxin binding, the functionality of nAChRs is changed in α5 −/− mice by post-translational modifications, receptor clustering, or other alternative mechanisms. Possible changes in affinity for nAChR ligands were not addressed but will have to be examined in future studies. Overall, our data argue that the reduced sensitivity to nicotine observed in the α5 −/− mice is a direct consequence of the lack of α5-containing receptors.

In conclusion, our data demonstrate that α5-containing nAChRs influence the expression of nicotine-induced seizures and other behavioral manifestations after short-term administration of nicotine. Our data could be relevant for the study of certain human pathologies such as idiopathic epilepsies, in which mutations on nAChR subunits have been reported to be the genetic cause (Itier and Bertrand, 2002). In addition, our results demonstrated that α5-containing nAChRs are critical mediators of behavioral effects that might be relevant for the mechanisms underlying nicotine addiction. We have studied a range of doses that covers from the very low doses, which are similar to those obtained from smoked tobacco and are enough to produce dependence in animals (Corrigal, 1999), to the high doses that are necessary to produce seizures and death. At every dose tested, the effect of short-term nicotine administration is significantly reduced in α5 −/− mice. Although short-term nicotine administration might not be a perfect model for smokers, the first cigarette of the day, which could be considered “short-term”, is usually reported as the most pleasurable one. Therefore, although the long-term effects of cigarette smoking may include many receptors and brain regions (Buisson and Bertrand, 2002), we have shown that α5-containing nAChRs participate in the short-term effects of nicotine, which are important for the emergence and maintenance of the smoking habit.