Local alpha -Bungarotoxin-Sensitive Nicotinic Receptors Modulate Hippocampal Norepinephrine Release by Systemic Nicotine

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Vol. 289, Issue 1, 133-139, April 1999

Local $alpha$ -Bungarotoxin-Sensitive Nicotinic Receptors Modulate Hippocampal Norepinephrine Release by Systemic Nicotine¹

Yitong Fu, Shannon G. Matta and Burt M. Sharp

Department of Pharmacology, University of Tennessee, Memphis, Tennessee; and Minneapolis Medical Research Foundation, Minneapolis, Minnesota

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Previous studies have shown that nicotinic receptors (NAChRs) accessible from the cerebral aqueduct of the brainstem mediatethe hippocampal norepinephrine (NE) release induced by i.v. nicotine.The present study was designed to investigate the role of hippocampalNAChRs in this process. Nicotinic antagonists were microinjectedor microdialyzed into the hippocampus (HP) before administeringnicotine (0.09 mg/kg over 60 s, i.v.) to freely moving rats. $alpha$ -Bungarotoxin(0.3 nmol by microinjection) blocked nicotine-induced hippocampalNE release by 47% (p < .05) and abolished the effect of 0.065mg/kg nicotine. Methyllycaconitine (1.4-5.6 mM in the dialysate)inhibited the stimulatory effect of nicotine 0.09 mg/kg by 48to 75% (p < .05). In contrast, mecamylamine (2.9-5.8 mM) and dihydro- $beta$ -erythroidine(7-14 mM) were completely ineffective. The role of hippocampalNAChRs was demonstrated further by selectively desensitizing thesereceptors before the systemic infusion of nicotine. To do so,the HP was pretreated with nicotine (0.1 mM) delivered throughthe microdialysis probe; this concentration was calculated toyield tissue concentrations similar to those produced by the systemicinfusions of nicotine. Dialyzing this concentration of nicotineinto the HP inhibited the NE response to i.v. nicotine by 34%(p < .05), and 1.0 mM nicotine reduced the response by 40%. Thesestudies indicate that $alpha$ -bungarotoxin-sensitive hippocampal NAChRs,probably containing $alpha$ 7 subunits, modulate hippocampal NE releasebecause of systemicnicotine.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

The hippocampus (HP) receives its major norepinephrinergic projections from the locus coeruleus (LC) (Aston-Jones et al.,1995). Previous studies have shown that systemic administrationof nicotine stimulates hippocampal norepinephrine (NE) release.This NE release was blocked by injecting the nicotinic receptor(NAChR) antagonists mecamylamine (Mec), dihydro- $beta$ -erythroidine(DH $beta$ E), or methyllycaconitine (MLA) into the cerebral aqueductimmediately upstream from the LC (Fu et al., 1998a) or by directlydelivering Mec into the LC (Mitchell, 1993). Thus, NAChRs on ornear the norepinephrinergic neurons in the LC are involved inthe hippocampal NE response to systemic nicotine. Based on thedifferential potencies and efficacies of these nicotinic antagonists, $alpha$ 3 subunit-containing NAChRs appeared to be involved (Fu et al.,1998a). In contrast, the selective NAChR antagonist, $alpha$ -bungarotoxin( $alpha$ -BTX), was ineffective. Recently, the NAChR $alpha$ 6 subunit was foundto be selectively expressed in the catecholaminergic nuclei ofthe rat brain, especially within the LC (Le Novere et al., 1996).Although the pharmacology of $alpha$ 6 subunit-containing NAChRs hasnot been described, it is possible that these receptors also areinvolved in the hippocampal NE response to systemicnicotine.

As shown in those studies, NAChR antagonists, delivered upstream of the LC, maximally inhibited hippocampal NE release by63 to 87% (Fu et al., 1998a). These findings suggest that nicotinemay directly affect other brain regions, such as the HP itself,to stimulate hippocampal NE release. Indeed, in vitro studieswith hippocampal slices or synaptosomes have shown that nicotinecan stimulate NE release (Sacaan et al., 1995; Clarke and Reuben,1996; Sershen et al., 1997). An in vivo microdialysis study, however,reported that Mec (dialyzed into the HP) failed to block hippocampalNE secretion by i.p. nicotine (Mitchell, 1993). In that study,additional NAChR antagonists were nottested.

NAChRs, assembled from various combinations of $alpha$ ( $alpha$ 2-7) and $beta$ ( $beta$ 2-4) subunits, are widely distributed throughout the centralnervous system (Karlin and Akabas, 1995; Colquhoun and Patrick,1997). In the HP, an abundance of $alpha$ 7-containing NAChRs, with highaffinity for $alpha$ -BTX, are expressed (Clarke et al., 1985; Harfstrandet al., 1988; Barrantes et al., 1995). The function of $alpha$ 7-containingNAChRs has been established in several ways. Homomeric $alpha$ 7-containingNAChRs expressed by Xenopus oocytes have been shown to conductCa²⁺ (Bertrand et al., 1993; Castro and Albuquerque, 1995). Electrophysiologicalstudies of fetal hippocampal neurons in culture have detecteda predominant nicotinic current (type IA) that appears to dependon $alpha$ 7-containing NAChRs (Alkondon and Albuquerque, 1993). Finally,presynaptic $alpha$ 7-containing NAChRs appear to modulate glutamaterelease in rat hippocampal and olfactory bulb neurons (Alkondonet al., 1996; Gray et al., 1996). The present study consideredthe potential involvement of local $alpha$ -BTX-sensitive NAChRs in thehippocampal NE response to i.v. nicotine. These NAChRs may berelatively insensitive to Mec (Briggs and McKenna, 1996).

Biochemical, physiological, and behavioral responses to nicotine decline after repeated exposure to this drug (Sharp and Beyer1986; Marks et al., 1995; Fu et al., 1998b). This reflects thedesensitization of NAChRs (Dani and Heinemann, 1996). Indeed,prior exposure to nicotine has been reported to differentiallyaffect various NAChR subtypes. In studies with transfected Xenopusoocytes, human $alpha$ 4 $beta$ 2 and homomeric $alpha$ 7 NAChRs desensitized morereadily than receptors containing $alpha$ 3 subunits (Olale et al., 1997).Moreover, much lower concentrations of nicotine were able to inducedesensitization than were required to stimulate ion conductanceor neurotransmitter release (Lippiello et al., 1995; Marks etal., 1995; Olale et al., 1997).

Systemic nicotine stimulates the secretion of NE in the HP, in part, through NAChRs in the vicinity of the LC. The presentstudy was conducted to determine the role of local (intrahippocampal)NAChRs, particularly those sensitive to $alpha$ -BTX, in this process.To do so, various NAChR antagonists were delivered through thehippocampal microdialysis probe or injected directly into theHP before i.v. nicotine. The role of hippocampal NAChRs was demonstratedfurther by selectively desensitizing these receptors before thesystemic infusion of nicotine. Substimulatory doses of nicotinewere dialyzed into the HP, and then nicotine was administeredsystemically.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Materials. Nicotine sulfate (Pfaltz and Bauer, Inc., Waterbury, CT; all dosages are given as milligrams per kilogram of the free base)was used for i.v. injection. ( $-$ )-Nicotine-free base (Sigma, St.Louis, MO) was used for intrahippocampal delivery through themicrodialysis probe. L-( $-$ )-[N-methyl-³H]nicotine (60 Ci/mmol) was obtained from NEN Life Sciences (Boston,MA). NE hydrochloride, Mec hydrochloride, DH $beta$ E hydrobromide, MLAcitrate, $alpha$ -BTX, and nomifensine maleate were purchased from RBI(Natick, MA). Sodium dihydrogen phosphate monohydrate, EDTA, acetonitrileand phosphoric acid (Fisher Scientific, Fair Lawn, NJ), 1-octanesulfonicacid sodium salt (J.T. Baker, Phillipsburg, NJ), and triethylamine(Aldrich, Milwaukee, WI) were used to prepare the mobile phase.The alert-rat microdialysis systems and CMA 110 liquid switcheswere obtained from CMA/Microdialysis (Acton, MA). For constructingdialysis probes, cellulose fiber tubing was obtained from Spectrum(Laguna Hills, CA), and silica tubing (outer diameter, 148 µm;inner diameter, 73 µm; TSP 075150) was from Polymicron TechnologiesInc. (Phoenix,AZ).

Animals. Adult male Holtzman rats (250-350 g, HSD, Madison, WI) were given access to standard rat chow and water ad libitum. They werehoused individually on a 12-h reversed light cycle (lights offat 9:00 AM, on at 9:00 PM) for 14 days before the microdialysisexperiments. This reversed light cycle was used to conduct theseexperiments during the rat's active (dark) phase. After the ratshad been housed under this reversed light/dark cycle for 7 days,they were anesthetized with xylazine-ketamine (5:35 mg/kg b.wt.,i.m.; Parke-Davis, Morris Plains, NJ), and chronic guide cannulas(20 gauge) were stereotaxically implanted into the HP, accordingto the atlas coordinates of Paxinos and Watson (1986). The coordinateswere AP, $-$ 3.0 mm, DV, $-$ 2.6 mm, and ML, 1.4 mm, from bregma witha flat skull. For rats receiving an injection of $alpha$ -BTX into theHP, a double-guide cannula was implanted (20 gauge for the dialysisprobe attached to a 23-gauge for microinjection; Fu et al., 1997),with the 20-gauge cannula targeted at the above coordinates. Fivedays later, rats received jugular cannulas under Innovar Vet anesthesia(3.75 mg/kg droperidol plus 0.08 mg/kg fentanyl, i.m.; Far-Vet,St. Paul, MN) and were allowed to recover for another 2 days.All procedures were conducted in accordance with National Institutesof Health Guidelines Concerning the Care and Use of LaboratoryAnimals and were approved by the Animal Care and Use Committeeof the Minneapolis Medical ResearchFoundation.

In Vivo Microdialysis. The microdialysis method was described previously (Fu et al., 1997). Briefly, a 2-mm concentric probe (molecular mass cutoff,13,000 Da; outer diameter, 235 µm) was constructed in our laboratory.The recovery rate of individual probes was determined by in vitrodialysis for 60 min at 22°C in a solution of 200 pg NE/16 µl.The probes we perfused at 1 µl/min with standard perfusate (seebelow), and three 20-min samples were obtained; the average recoveryrate was 7.1% ± 1.0 (n = 10). On the day of microdialysis, ratswere moved into the alert-rat microdialysis chambers in an isolateddarkroom lit with a red safe-light; all connections were madequickly to minimize stress to the animal. The probe was perfusedat 1 µl/min with a solution of Krebs-Ringer Buffer (KRB: 147 mMNaCl, 4.0 mM KCl, and 3.4 mM CaCl₂ in polished water; 0.2-µm filtersterilized and degassed) containing 5 µM nomifensine (NE uptakeblocker; Schacht et al., 1982). Two hours after insertion of theprobe through the guide cannulas, three consecutive samples werecollected to measure basal NE levels before drug administration.Samples were collected over 20 min into vials containing 1 µlof 5% perchloric acid to prevent the degradation of NE. At theend of the experiments, the position of the probe was verifiedby histological examination; only data obtained from animals withprobes identified in the correct location of the HP were usedfor analysis. The histological verification of probe placementin the HP has been published previously (Fu et al., 1998a).

HPLC-Electrochemical Analysis. Samples (16 µl) were injected immediately by a CMA 200 refrigerated autosampler onto a 150 × 3-mm ODS C18 column (ESA, Bedford,MA) perfused by BAS 200A HPLC pumps (BAS, Inc., West Lafayette,IN) at 0.5 ml/min with a mobile phase containing 80 mM sodiumdihydrogen phosphate monohydrate, 2.0 mM 1-octanesulfonic acidsodium salt, 100 µl/liter triethylamine, 5 nM EDTA, and 10% acetonitrile,pH 3.0. Samples were analyzed by an ESA Coulochem II 5200A electrochemicaldetector with an ESA 5041 high-sensitivity microbore analyticalcell and an ESA 5020 guard cell (ESA). Electrochemical detectionwas performed at 220 mV and 1.0 nA with the guard cell at 350mV. The limit of detection for NE was 0.5 pg. Representative HPLCchromatograms have been published previously (Fu et al., 1998a).

Experimental Protocols. In all experiments, on day 1 a probe was inserted for 10 min and then removed without further microdialysis. On days 3 and5, probes were reinserted and the rats received randomized treatments.Previous studies have shown that there were no significant "withinrat" changes in basal NE levels nor in NE responses to nicotinewhen using this protocol of testing on days 3 and 5 in the samerat (Fu et al., 1998a).

The first series of experiments was conducted to determine whether the administration of NAChR antagonists into the HP wouldblock nicotine-induced NE secretion in that region. Three NAChRantagonists, Mec, DH $beta$ E, or MLA, were perfused directly into theHP through a microdialysis probe ( $alpha$ -BTX was microinjected; seebelow). Briefly, after three 20-min basal samples were collected,perfusates (1 µl/min) containing Mec (2.9 or 5.8 mM), DH $beta$ E (7or 14 mM), MLA (0.4, 1.4, 2.8, or 5.6 mM), or KRB (vehicle control)were dialyzed for 40 min, and then perfusion was switched backto KRB. At the end of the first 20 min of antagonist perfusion,0.09 mg/kg nicotine or saline (vehicle control) was administeredi.v. over 60 sec and dialysis samples were collected every 20min for 1 h thereafter. In addition, seven rats were used to testthe effect of 2.8 mM MLA on hippocampal NE release in responseto 0.065 mg/kg nicotine. Each rat was microdialyzed twice, randomlyreceiving 0.065 mg/kg KRB/nicotine or 0.065 mg/kg MLA/nicotine.Because the relatively high molecular mass of $alpha$ -BTX limits itsdiffusion through the microdialysis membrane, $alpha$ -BTX was injecteddirectly into the HP through a second guide cannula (23 gauge,attached to the 20-gauge probe cannulas) in a different cohortof rats. Four microliters of 0.3 nmol of $alpha$ -BTX [diluted with artificialcerebrospinal fluid (CSF) containing 300 µg/ml bovine serum albuminin 0.05 M phosphate buffer, pH 7.2] or CSF alone (vehicle control)was microinjected over 16 min; 4 min later rats were infused with0.065 mg/kg nicotine i.v. over 44 s, 0.09 mg/kg nicotine over60 s, or saline and dialysate samples were collected for the next60 min. Higher doses of $alpha$ -BTX (>0.3 nmol) were not tested becausethey frequently elicited agitated behavioralresponses.

A second series of experiments was designed to establish further the role of endogenous NAChRs in the hippocampal NE responseto systemic nicotine. We hypothesized that desensitizing NAChRsin the HP would reduce the NE secretory response to systemic nicotine.To test this, hippocampal NAChRs were pre-exposed to nicotineby delivering it through the microdialysis probe, followed byi.v.nicotine.

First, to calculate the approximate tissue concentration of nicotine achieved in the HP after the drug is administered throughthe microdialysis probe, [³H]nicotine was added to the perfusion solution. One hour aftermicrodialysis probes were inserted into the guide cannulas andperfused with KRB (as per the standard method), a solution ofnicotine (5 mM) containing [³H]nicotine (15-22 mCi/mmol) was perfused through the probe for20 min. The rats were sacrificed immediately by cardiac injectionwith lethal doses of Nembutal. The brains were removed, frozen,and cryosectioned into consecutive 20-µm slices; every five consecutivesections (100 µm total) were collected into scintillation vialsand counted for [³H]nicotineradioactivity.

Second, to determine the dose of nicotine that would desensitize hippocampal NAChRs without inducing NE release, 1, 2.5, 5,or 10 mM nicotine or KRB was delivered through the microdialysisprobe into the HP, and NE release was measured in this region.As described above, after three 20-min basal samples were collected,nicotine was perfused for 20 min, then replaced by KRB, and sampleswere collected thereafter every 20 min for 1h.

Finally, to demonstrate whether the selective desensitization of NAChRs in the HP could reduce the NE secretory response tosystemic nicotine, nicotine (0.01, 0.1, or 1 mM) or KRB was perfusedthrough the probe for 20 min, followed by 0.09 mg/kg i.v. nicotineor saline; dialysis samples were collected for 60 minthereafter.

Data Analysis and Statistics. Chromatographic data were collected and analyzed with the PowerChrom system (AD Instruments, Castle Hill, NSW, Australia)and expressed either as pg/16-µl sample or as a percentage ofbasal NE levels. Basal values were defined as the average NE levelsof the three samples before nicotine, antagonist, or vehicle administration.Data were analyzed by one-way ANOVA using StatView, and resultswere considered significant at p < .05. The number shown in parentheses(n) in the text and graphs is the number of rats within a specifictreatment group. The calculation of in vivo spread of nicotinewas obtained from the percentage of [³H]nicotine in the HP tissue compared with the total amount ofradioactivity initially perfused through theprobe.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Figure 1 demonstrates that i.v. nicotine-induced NE release in the HP was inhibited by administering $alpha$ -BTX or MLA, but notMec or DH $beta$ E, in this region. As shown in Fig. 1A, microinjecting0.3 nmol $alpha$ -BTX into HP did not affect NE secretion. However, $alpha$ -BTX(0.3 nmol) significantly reduced NE release because of nicotine(0.065 or 0.09 mg/kg i.v.; p < .05). Similarly, MLA (0.4-5.6 mMin dialysate) alone did not affect basal NE levels (data not shown).Figure 1B shows that MLA, at concentrations of 1.4 mM or higher,inhibited the NE response to 0.09 mg/kg nicotine (p < .05-.01).An additional experiment showed that 2.8 mM MLA blocked 62% ofthe NE response to 0.065 mg/kg nicotine (p < .05). In contrast,Fig. 1C shows that neither Mec (2.9 or 5.8 mM) nor DH $beta$ E (7 or14 mM) inhibited nicotine-induced NE release.

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Fig. 1. Systemic (i.v.) nicotine stimulates hippocampal NE secretion that is blocked by selective administration of NAChR antagonists into the HP. NE levels are expressed as percentage of average basal levels (obtained at 20, 40, and 60 min). Peak NE levels were measured in samples collected 20 min after initiation of i.v. nicotine infusion. A, time course for NE release in the HP after hippocampal injection of 0.3 nmol $alpha$ -BTX or CSF followed by an infusion of nicotine (0.065 mg/kg per 44 s or 0.09 mg/kg per 60 s). Basal level of NE (mean ± S.E.M.) for 0.065 mg/kg CSF/nicotine group was 6.7 ± 0.3 pg/16 µl (n = 6); basal levels for 0.09 mg/kg CSF/nicotine were not different. Peak NE responses to 0.065 mg/kg or 0.09 mg/kg nicotine were reduced significantly by $alpha$ -BTX (F = 4.21, p = 0.028). B, results for similar experiments with MLA in the dialysate. MLA dose dependently blocked the NE response to 0.09 mg/kg nicotine (F = 3.59, p = 0.033). C, lack of blockade by two doses of Mec or DH $beta$ E administered in the dialysate. A-C, +p < .05 compared with CSF/nicotine 0.065; * or **p < .05 or 0.01, respectively, compared with CSF or KRB/nicotine 0.09 (n = 6 rats per group).

Figure 2 shows the peak NE response to intrahippocampal nicotine administered for 20 min through the microdialysis probe.Enhanced NE secretion was observed only in samples collected duringthe interval of nicotine perfusion. At concentrations of 2.5 mM(in the dialysis probe) or higher, nicotine produced a significantdose-dependent increase in NE secretion (p < .05-.01).

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Fig. 2. Hippocampal NE release is dose dependently stimulated by local perfusion of nicotine into the HP. Peak NE levels were measured in samples collected for 20 min during local perfusion of nicotine. Peak NE levels were expressed as a percentage of preinfusion basal levels. Estimated nicotine concentration in the HP is based on data of [³H]nicotine delivered through the probe. Nicotine (2.5-10 mM) significantly increased NE secretion in the HP (F = 5.04, p = 0.026). *p < .05, **p < .01, compared with control (0 mM nicotine) (n = 5 rats per treatment).

After delivering [³H]nicotine through the intrahippocampal microdialysis probe, 0.37 ± 0.05% (n = 3) of the nicotine perfusedwas detected in the surrounding brain parenchyma. The radial distributionof [³H]nicotine is shown in Table 1. Approximately 80% of the radioactivitywas measured within 0.6 mm and 93.4% was measured within 1.0 mmof the central axis of the probe. Based on the assumption of aspherical distribution, 4.2 µm³ was calculated as the volume containing 93.4% of the [³H]nicotine. Therefore, a 1 mM concentration of nicotine in themicrodialysate would yield a tissue concentration of 17.6 µM inthe HP. The lowest dose of nicotine (2.5 mM in the microdialysate)that induced significant NE release in the HP (Fig. 2) would beexpected to yield high tissue concentrations (i.e., 44 µM).

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TABLE 1
Distribution of [³H]nicotine in HP after 20-min perfusion through microdialysis probe

The role of hippocampal NAChRs in the NE response to systemically administered nicotine was investigated further by selectivelydesensitizing intrahippocampal NAChRs and then delivering i.v.nicotine. Concentrations of nicotine (0.01, 0.1, and 1 mM) thatfailed to stimulate NE release (Fig. 2) were used to selectivelypretreat hippocampal NAChRs by delivering the drug through themicrodialysis probe; 20 min thereafter, 0.09 mg/kg nicotine wasinfused i.v. Figure 3A shows the effect of pretreatment with 0.1mM nicotine, which was calculated to yield a concentration ofnicotine in the HP (1.8 µM) similar to that achieved by i.v. nicotine(0.09 mg/kg/60 s) (Hieda et al., 1998). This pretreatment reducedthe NE response to i.v. nicotine (0.09 mg/kg) by 34% (p < .05).Additionally, pre-exposure to 1 mM nicotine resulted in a 40%decrease (p < .01), whereas 0.01 mM nicotine did not result insignificant inhibition. Figure 3B shows a linear decrease in responsivenesswith increasing pretreatment doses of nicotine (expressed as logdose).

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Fig. 3. Pretreatment with intrahippocampal nicotine reduced NE secretion in response to i.v. nicotine. A, time course of hippocampal NE response to i.v. nicotine after pretreatment with nicotine. Pretreatment with nicotine, at a dialysate dose of 0.1 mM or 1.0 mM, decreased i.v. nicotine-induced NE release (F = 3.25, p = 0.041). B, a linear decrease in NE secretion with increasing pretreatment doses of nicotine (expressed as log µM). Estimated nicotine concentration in the HP is based on data of [³H]nicotine delivered through the probe. *p < .05, compared with KRB/nicotine 0.09 (n = 5-6 rats per treatment).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The present study shows that the hippocampal NE response to i.v. nicotine was inhibited by selectively administering $alpha$ -BTXor MLA into this region, whereas Mec and DH $beta$ E were ineffective.These findings suggest that hippocampal NAChRs sensitive to $alpha$ -BTXare involved in NE release by systemic nicotine. Further evidencefor the involvement of hippocampal NAChRs in the NE response tosystemic nicotine was obtained in studies showing that desensitizationof NAChRs in the HP reduced the NE response to i.v.nicotine.

Based on the in vivo diffusion of [³H]nicotine from the microdialysis probe, a dialysate concentration of 0.1 mM nicotine wouldbe expected to yield a peak tissue concentration of 1.8 µM. Thislevel is very close to the concentration predicted in brain parenchyma(approximately 2 µM) after 0.09 mg/kg nicotine i.v. (Hieda etal., 1998). It has been reported that EC₅₀ concentrations of nicotinewithin the nanomolar range are sufficient to desensitize NAChRs,especially those composed of $alpha$ 7 or $alpha$ 4 $beta$ 2 subunits (Hsu et al.,1996; Olale et al., 1997). Therefore, a dialysate concentrationof 0.1 mM nicotine would be enough to desensitize a large fractionof the NAChRs in rat brain regions containing an abundance ofthese NAChRs (Clarke et al., 1985; Harfstrand et al., 1988; Wadaet al., 1989). Microdialyzing 0.1 mM nicotine into the HP significantlyreduced the NE response to i.v. nicotine, further demonstratingthat hippocampal NAChRs activated by systemic nicotine modulatethe NE secretory response. However, the desensitization of hippocampalNAChRs inhibited NE release by only 40%, which is somewhat lessthan the 47% reduction by $alpha$ -BTX. The limited efficacy of desensitizationis more apparent when compared with the effect of $alpha$ -BTX in animalsreceiving a lower dose of nicotine (0.065 mg/kg); $alpha$ -BTX abolishedthe NE response. These observations suggest that nondesensitizingNAChRs also are involved in nicotine-induced NE release. Thesereceptors may be nonhomonomeric $alpha$ 7-containing NAChRs that retaintheir sensitivity to $alpha$ -BTX andMLA.

$alpha$ -BTX is a specific antagonist of $alpha$ 7-containing NAChRs (Pugh et al., 1995; Colquhoun and Patrick, 1997), and MLA also is specificat relatively low concentrations (Ward et al., 1990; Alkondonet al., 1992). The blockade of hippocampal NE release by both $alpha$ -BTX and MLA suggests that $alpha$ 7-containing NAChRs within the HPare activated by nicotine when it is delivered systemically. Consistentwith the findings of Mitchell (1993), Mec and DH $beta$ E were ineffectivein the present investigations. Other studies have shown that Mechas relatively low potency at $alpha$ 7 homonomers, with an IC₅₀ of 1.8µM (Briggs and McKenna, 1996). However, data on the potency ofMec at nonhomomeric $alpha$ 7-containing NAChRs and on the interactionof DH $beta$ E with $alpha$ 7-containing NAChRs are unavailable presently. Nonetheless,the lack of effectiveness of Mec and DH $beta$ E further supports theinvolvement of $alpha$ 7-containing NAChRs in hippocampal NE secretion.Further evidence for the involvement of $alpha$ 7 NAChRs in the centralsecretion of NE comes from a recent study showing that NE wassecreted in the frontoparietal cortex after the s.c. injectionof 3-(2,4-dimethoxybenzylidene)anabaseine, a selective agonistat $alpha$ 7-containing NAChRs (de Fiebre et al., 1995; Summers et al.,1997).

Based on the relative concentrations attained in the HP after the microperfusion of [³H]nicotine in the present study, perfusion with MLA (1.4-5.6 mMin dialysate) was estimated to yield micromolar tissue concentrations(25-99 µM). In contrast, nano-molar MLA is sufficient to blockthe $alpha$ 7-mediated current in cultured fetal hippocampal neurons(Alkondon and Albuquerque, 1993; Gray et al., 1996). This differencein estimated parenchymal versus in vitro concentrations may reflectthe specific subunit composition of the $alpha$ 7-containing NAChRs expressedby mature hippocampal neurons involved in the modulation of NErelease by systemic nicotine. Such NAChRs may not be equivalentto the $alpha$ 7 homooligomers expressed by transfected oocytes, whichare sensitive to nanomolar concentrations of MLA (Briggs and McKenna,1996). Similarly, much higher concentrations of $alpha$ -BTX may be requiredby nonhomomeric a7-containing NAChRs. Indeed, a study of chickembryonic sympathetic neurons showed that $alpha$ 7 antisense oligomers,but not $alpha$ -BTX alone (500 nM), were able to diminish acetylcholine-evokedcurrents (Listerud et al., 1991). These authors hypothesized that $alpha$ 7-containing NAChRs may include other subunits that influencethe $alpha$ -BTX sensitivity of the $alpha$ 7subunit.

In vitro studies with hippocampal slices and synaptosomes have shown that [³H]NE release was mediated by $alpha$ -BTX-unresponsive NAChRs. Basedon data from several laboratories, the EC₅₀ values of nicotinewere 34.6 or 91.6 µM for hippocampal slices and 6.5 µM for thesynaptosomes (Sacaan et al., 1995; Clarke et al., 1996; Sershenet al., 1997). In the present study, 44 µM intraparenchymal nicotine(estimated from 2.5 mM dialysate concentration) was the minimumconcentration required for the direct effects of the drug on hippocampalNE release. In contrast, the concentration of nicotine achievedby i.v. nicotine (0.065-0.09 mg/kg) was estimated to be 1-2 µMin brain parenchyma. In another study, peak brain nicotine levelswere 6.9 µM after an s.c. injection of 1.2 mg/kg nicotine twicea day and 1.2 µM after a constant infusion of nicotine at doseof 4.8 mg/kg/day for 10 days (Rowell and Li, 1997). Based on ourprotocols or those reported by Rowell and Li, systemically administerednicotine would not be expected to achieve the brain concentrationsrequired to induce NE release in the studies with hippocampalpreparations in vitro or when microdialyzed into the HP. Therefore,the potential role of the hippocampal $alpha$ -BTX-resistant NAChRs,reported by other laboratories (Sacaan et al., 1995; Sershen etal., 1997), in the hippocampal NE response to systemic nicotinerequires furtherclarification.

Within the HP, $alpha$ 7-containing NAChRs receptors may be located on glutamatergic or other undefined axon terminals. Nicotine(0.5 µM) has been reported to stimulate glutamate release in culturedneonatal hippocampal neurons (Gray et al., 1996). $alpha$ -BTX (50 nM)or 5 nM MLA abolished the nicotine-induced increase in miniatureexcitatory postsynaptic currents (mEPSC) that were blocked byglutamate receptor antagonists. In a minority of these experiments,the authors noted that nicotine increased the frequency of mEPSCs,but $alpha$ -BTX (50 nM) failed to block. Other studies have reportedthat glutamate may release NE from hippocampal slices (Puttfarckenet al., 1993). In addition, Toth et al. (1992) observed that nicotine(delivered by microdialysis) induced striatal dopamine release,which was largely dependent on glutamate secretion. Thus, systemicnicotine may activate $alpha$ 7-containing NAChRs located on hippocampalglutamatergic terminals, enhancing the secretion of glutamate,which, in turn, may stimulate NE secretion. $alpha$ 7-Containing NAChRsthat are relatively insensitive to $alpha$ -BTX (a subpopulation of the $alpha$ -BTX-responsive NAChRs) appear to beinvolved.

We have shown previously that NAChRs located near the LC, which gives rise to the noradrenergic cell bodies projecting tothe HP, had a significant role in mediating the hippocampal NEresponse to i.v. nicotine (Fu et al., 1998a). In contrast to thepresent studies, nanomolar amounts of Mec (and MLA or DH $beta$ E) blocked87% of the response when these agents were microinjected intothe cerebral aqueduct. However, $alpha$ -BTX was completely ineffective.Therefore, systemic nicotine affects hippocampal NE secretionby activating receptors that are 1) sensitive to MLA and $alpha$ -BTXin the HP and 2) unresponsive to $alpha$ -BTX in the brainstem (Fu etal., 1998a). The incomplete blockade of NE release by MLA deliveredthrough the probe (Fig. 1B) or by the Mec microinjected into thecerebral aqueduct (Fu et al., 1998a) is consistent with the ideathat i.v. nicotine stimulates NAChRs located at both LC and HPsites to release NE in the HP. Thus, hippocampal NE release appearsto depend, to a high degree, but not completely, on concurrentactivation of both sites by systemicnicotine.

A synergistic interaction may exist between these two neuroanatomically and pharmacologically distinct populations of NAChRs.This is supported by differences in the hippocampal nicotine concentrationsthat are required to induce NE secretion after the i.v. versusdirect intrahippocampal administration of nicotine. An estimatedtissue concentration of 17.6 µM nicotine, resulting from the intrahippocampaldialysis of 1 mM nicotine, failed to stimulate NE release. Incontrast, experiments based on the local desensitization of hippocampalNAChRs or the use of NAChR antagonists both indicated that tissueconcentrations of 2 µM nicotine, achieved after i.v. nicotine(0.09 mg/kg for 60 s), were effective. It is likely that the 2µM concentration was effective because the concurrent deliveryof nicotine (i.v.) to the HP and LC allows a synergistic interactionwhereby the activation of hippocampal NAChRs potentiates the actionof nicotine in theLC.

In summary, these investigations show that i.v. nicotine stimulates NE release in the HP by acting, in part, through hippocampalNAChRs. The hippocampal receptors involved may be nonhomonomeric $alpha$ 7-containing NAChRs, although models that selectively interferewith $alpha$ 7 subunit expression will be required for further validation.These $alpha$ -BTX-sensitive NAChRs modulate hippocampal NE release bysystemic nicotine, probably because of a synergistic interactionbetween pharmacologically distinct populations of NAChRs in theHP andLC.

	Footnotes

Accepted for publication October 30, 1998.

Received for publication May 4, 1998.

¹ This work was supported by National Institutes of Health Grant DA03977 (to B.M.S.).

Send reprint requests to: Burt M. Sharp, M.D., Department of Pharmacology, University of Tennessee, 874 Union Ave., Memphis, TN 38163. E-mail: Bsharp{at}utmem1.utmem.edu

	Abbreviations

$alpha$ -BTX, $alpha$ -bungarotoxin; CSF, cerebrospinal fluid; DH $beta$ E, dihydro- $beta$ -erythroidine; HP, hippocampus; KRB, Krebs-Ringer buffer; LC, locus coeruleus; Mec, mecamylamine; MLA, methyllycaconitine; NAChRs, nicotinic cholinergic receptors; NE, norepinephrine.

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