Abstract
Norepinephrine (NE) secretion within the hypothalamic paraventricular nucleus (PVN) is pivotal to endocrine and behavioral responses. Activation of NE afferents to PVN also is necessary for the hypothalamo–pituitary–adrenal axis response to passively administered nicotine. The mode of drug delivery is a critical determinant of the dynamics of neurotransmitter secretion, yet the PVN NE response to nicotine self-administration (SA) is unknown. Herein, rats housed in operant chambers had unlimited 23 hr access to self-administered nicotine. In vivo microdialysis of PVN NE was performed, collecting consecutive 7 min samples over 9 hr sessions during three phases of nicotine SA: acquisition (day 1); early maintenance, once stable rates of SA were achieved (day 9.2 ± 0.6); later maintenance (day 18.6 ± 0.8). On d1, nicotine animals had an increased percentage of SA episodes (SAEs) in which NE levels were elevated (80 vs 30% with saline; p < 0.01). By early maintenance, a fourfold increase in such episodes was observed in nicotine animals (p < 0.01), and the overall NE level was greater (1.30 ± 0.24 vs 0.63 ± 0.07 pg/10 μl in saline; p < 0.05); NE increased during the first, but not the last, SAE. The pattern was similar during later maintenance, although NE responsiveness declined (overall NE level, 0.96 ± 0.19 in nicotine vs 0.52 ± 0.08 pg/10 μl in saline; p < 0.05). Therefore, nicotine SAEs were associated with sustained increases in NE secretion during all three phases of SA. However, the reduced NE responsiveness observed both within the dialysis session in each phase and by later versus early maintenance is consistent with progression of partial daily desensitization of PVN NE secretion to nicotine SA. Therefore, in rats chronically self-administering nicotine, the drug stimulates sustained PVN NE secretion that may alter neuroendocrine and behavioral responses mediated by the PVN. Compared with studies of chronic human smokers, our nicotine SA model may reflect the CNS noradrenergic responses that occur during human cigarette smoking.
Nicotine, the major psychoactive agent in tobacco, mediates a multiplicity of CNS responses by stimulating the release of neurotransmitters, including norepinephrine (NE), dopamine, and acetylcholine (Summers and Giacobini, 1995). We demonstrated that the noradrenergic system is sensitive to passive administration of nicotine, injected intravenously or directly into noradrenergic regions (Matta et al., 1995; Fu et al., 1997). Because NE plays an important role in the regulation of diverse CNS physiological responses, determining the effect of chronic exposure to nicotine on central NE secretion, especially via self-administration (SA), is essential for understanding the central actions of the drug.
NE is pivotal to numerous hypothalamic functions, including responses to stressors by the hypothalamo–pituitary–adrenal (HPA) axis and the regulation of food intake (Pacak et al., 1995; Wellman, 2000). Over 20 neuropeptides have been identified within paraventricular nucleus (PVN) neurons (Palkovits, 1988), and brainstem NE projections regulate many of these (Sawchenko and Swanson, 1982). For example, numerous stressors induce the NE-dependent release of corticotropin-releasing hormone, which stimulates ACTH secretion and adrenocortical glucocorticoid release (Pacak et al.,. 1995). Also, PVN noradrenergic input affects the prefeeding release of neuropeptide Y under food-restricted conditions (Yoshihara et al., 1996). Thus, NE is pivotal to the control of PVN neurons mediating endocrine and behavioral responses.
Nicotine stimulates NE secretion in the PVN (Sharp and Matta, 1993), which is necessary for activation of the HPA axis, because subsequent ACTH secretion can be blocked by both nicotinic receptor antagonists and NE depletion (Matta et al., 1990, 1993b). Although these studies have demonstrated the effects of investigator-initiated (i.e., passive) nicotine on NE secretion in the brainstem–PVN circuit, PVN NE response to nicotine SA is uncharacterized. From a wider perspective, the effects of nicotine SA on NE secretion anywhere in the brain are unknown.
The significance of this is underscored by evidence that other drugs of abuse activate CNS circuits in a differential manner when self-administered versus passively delivered. For example, significantly higher nucleus accumbens acetylcholine was measured in cocaine self-administering rats compared with controls (Mark et al., 1999). Therefore, the mode of administration is an important determinant of the dynamics of central neurotransmitter secretion, making it likely that nicotine self-administration will have a distinctive effect on PVN NE secretion.
Recently, we published a nicotine self-administration model in which rats have virtually unlimited SA access to intravenously administered nicotine, without previous shaping, conditioning or food deprivation, and in their home cage (Valentine et al., 1997), thereby exposing them to daily amounts of nicotine that, on a milligram per kilogram basis, are comparable with human smokers (Benowitz and Jacob, 1984). This model, which simulates basic elements of human cigarette smoking, may provide insight into the effects of nicotine on regulation of central NE secretion. In vivo PVN microdialysis was performed on rats during three stages of chronic nicotine SA: acquisition, early maintenance, and later maintenance. To our knowledge, this is the first report characterizing neurotransmitter secretion in animals with 23 hr unlimited access to self-administered nicotine and the first observation of CNS NE secretion in rats self-administering any drug.
MATERIALS AND METHODS
Materials. (−)Nicotine hydrogen tartrate (all doses based on the free base) and norepinephrine hydrochloride were purchased from Sigma (St. Louis, MO). Sodium dihydrogen phosphate monohydrate, EDTA, acetonitrile, phosphoric acid (all from Fisher Scientific, Fair Lawn, NJ), 1-octanesulfonic acid sodium salt (J. T. Baker, Phillipsburg, NJ), and triethylamine (Aldrich, Milwaukee, WI) were used to prepare the mobile phase for HPLC with electrochemical detection. Concentric dialysis probes were constructed with cellulose fiber dialysis tubing obtained from Spectrum (Laguna Hills, CA) and silica tubing (outer diameter, 148 μm; inner diameter, 73 μm) from Polymicron Technologies Inc. (Phoenix, AZ). Operant chambers, circuit boards, interface modules, and SA software were purchased from Coulbourn Instruments (Allentown, PA).
Nicotine self-administration. Self-administration was performed according to our previously published protocol with the following modifications (Valentine et al., 1997). Seven days after acclimation to a reverse light cycle and handling, male Lewis rats (Harlan Sprague Dawley, Indianapolis, IN), weighing 250–350 gm (3.5 months old at onset of the acquisition phase of SA), were anesthetized with xylazine–ketamine (13 and 87 mg/kg, i.m., body weight, respectively; Parke-Davis, Morris Plains, NJ). Chronic guide cannulas (20 gauge) were stereotaxically implanted bilaterally into the PVN; atlas coordinates were as follows: anteroposterior, −1.8 mm; dorsoventral, −7.5 mm; mediolateral, ±0.2 mm, from bregma with a flat skull (Paxinos and Watson, 1986). After 7 d of recovery, rats received jugular cannulas under xylazine–ketamine anesthesia and then were immediately placed into operant chambers located within individual sound- and light-attenuating environmental enclosures, where they resided for the duration of the study. The jugular line, exteriorized through a polyethylene button placed between the shoulder blades, was protected by a metal spring attached to the button and connected to a dual channel swivel located outside the environmental enclosure. The lines for the microdialysis probe (see below) also were channeled through this protective metal tether and exited outside the enclosure. Rats were allowed to recover for 3 d, during which time they received progressively higher injections of heparinized saline (hourly injections from 100 to 200 U/ml in 50 μl) and a daily injection of the antibiotic Baytril (7.6 mg/kg in 0.1 cc, i.v.; Bayer Corp., Shawnee Mission, KS). After recovery, rats were randomly assigned to treatment groups, and the jugular lines were filled with either 0.03 mg/kg nicotine in 200 U/ml heparinized saline (50 μl delivered over 0.81 sec per 300 gm body weight) or heparinized saline. The nicotine solution was prepared every 7–14 d and stored in a foil-wrapped glass bottle at 4°C. Every day, the nicotine solution remaining in the syringe was discarded and the syringe was refilled.
Each environmental enclosure was equipped with its own ventilation fan and house light; the light was scheduled to turn off daily at exactly 12:30 P.M. and on again at 12:30 A.M. The interior operant chamber contained two levers positioned 5 cm above the floor and a green cue light 1 cm above each that signaled the availability of nicotine. One lever was randomly assigned as the active bar and would signal the computer-driven pump to deliver a 50 μl/0.81 sec bolus injection of nicotine or saline when pressed by the rat; pressing the other bar had no consequence. Injections were followed by a 7 sec time-out, during which the green light above the active bar was not illuminated and nicotine or saline were unavailable. Rats were not shaped, conditioned, or food deprived in preparation for lever pressing and were allowed to acquire self-administration behavior throughout the 23 hr.
Environmental enclosures, operant chambers, and syringe pumps were controlled by Coulbourn Habitest Universal LabLink interfaces and computers located in an adjacent room. Each morning, during the final hour of the lights-on cycle (i.e., at 11:30 A.M.), the clock for the computer program (Coulbourn L2t2) had to be manually reset, necessitating a short interruption in nicotine availability. To accommodate this, as well as to accomplish animal husbandry needs, measurements of body weight, and data downloading, all of the environmental enclosures were opened and the green cue lights were turned off to signal this interruption to the rats. Levers were not retracted, and lever press activity was not recorded. Exactly 1 hr later (12:30 P.M.), house lights shut off, cue lights were illuminated, nicotine (or saline) was again available, and enclosure doors were shut. All procedures were conducted in accordance with the NIH Guidelines Concerning the Care and Use of Laboratory Animals and were approved by the Animal Care and Use Committee of the University of Tennessee.
In vivo microdialysis. The microdialysis procedure was performed as described previously (Fu et al., 1997) with concentric microdialysis probes (molecular weight cutoff, 13,000 Da; outer diameter, 235 μm; 2 mm dialysis membrane) constructed in our laboratory. The recovery efficiency for NE was 6.4 ± 0.6% (n = 10). Twelve hours before a microdialysis session, heparin was removed from the intravenous solution to minimize intracranial hemorrhage during probe insertion. On the morning of microdialysis, 3 hr before lights out, a probe was inserted into the guide cannula, connected to the dual channel swivel, and perfused at 1.4 μl/min with a solution of Krebs' Ringer's buffer (KRB). During the daily 1 hr interval when nicotine was unavailable (animal husbandry and equipment maintenance period), five consecutive 7 min microdialysis samples were obtained. Immediately thereafter, at lights out, nicotine was again made available, and the collection of 7 min samples (into 1 μl of 5% perchloric acid) continued for 9 hr. This 9 hr period permitted the characterization of PVN NE release during approximately three-fourths of an animal's active lever presses, all of which resulted in the delivery of nicotine injections (Valentine et al., 1997).
Pilot studies showed a reduced number of active lever presses in a fraction of the animals during an initial microdialysis session. This, however, stabilized during the second microdialysis session (active lever presses, 35 ± 4 during the second 9 hr microdialysis session vs 35 ± 3 during the corresponding 9 hr period on the previous nondialysis day; n = 12). Therefore, a preliminary microdialysis session was always conducted without sample collection 48 hr before the actual session. In all experiments performed during acquisition, early maintenance, and late maintenance, the same side of the PVN was microdialyzed twice, separated by 48 hr. Probe position was verified histologically (Fu et al., 1997); only data from animals with correct placement were analyzed.
The KRB dialysis solution used in these investigations contained 147 mm NaCl, 4.0 mm KCl, and 3.4 mmCaCl2 (0.2 μm filter sterilized and degassed) with 5 μm nomifensine (NE reuptake blocker) (Schacht et al., 1982). It has been reported that the concentration of calcium in KRB microdialysate can affect striatal dopamine release in response to D2 receptor agonists, in that lower concentrations of calcium (1.2 versus 3.4 mm) enhanced the potency of the agonists (Timmerman and Westerink, 1991). Therefore, in a pilot study, microdialysis was performed during the early maintenance phase to determine whether 1.8 mm calcium KRB would modify the NE response to nicotine SA. The calcium concentration did not affect NE secretion [e.g., incremental NE responses to a self-administration episode (SAE)] or any of the parameters of nicotine SA (e.g., total number of nicotine injections per 23 hr).
The animals in these investigations were housed in their operant chambers, apparently resulting in very low stress and in correspondingly low PVN NE levels. The levels in microdialysates from these animals were usually ∼20–25% of those obtained from animals moved from group housing in a vivarium to acute chambers within several hours. Therefore, 3.4 mm calcium and nomifensine were used in combination to permit reliable detection of basal PVN NE levels, which otherwise would be undetectable in ∼80% of animals.
HPLC with electrochemical detection. As reported previously (Fu et al., 1997, 1998), microdialysate samples (10 μl) were automatically injected by a CMA 200 refrigerated autosampler (CMA Microdialysis, North Chelmsford, MA) onto a 150 × 2 mm ODS C18 column (ESA Inc., Chelmsford, MA) connected to an ESA model 580 HPLC pump. The mobile phase, containing 80 mmsodium dihydrogen phosphate monohydrate, 2.0 mm1-octanesulfonic acid sodium salt, 100 μl/l triethylamine, 5 nm EDTA, and 10% acetonitrile, pH 3.0, was perfused at 0.25 ml/min. NE levels were determined using an ESA 5041 high-sensitivity analytical cell and an ESA Coulochem II 5200A electrochemical detector at a potential of 220 mV with the current gain at 5 nA. Under these conditions, the limit of detection for NE was 150 fg. The sample-to-sample variation in 10 consecutive injections of NE standard (500 fg) was calculated to be 5.16 ± 2.91% (mean ± SD). Representative NE microdialysate chromatograms have been published previously (Fu et al., 1997).
Experimental protocols. The first experiment was designed to characterize the NE secretory response to nicotine SA during the first day of the acquisition phase. The acquisition phase was defined as the interval from the first day nicotine was available for SA (day 1) until maintenance criteria were achieved (see below). The second series of experiments characterized the NE response to nicotine SA at early and later time intervals during the maintenance phase of SA. The criterion for maintenance was a mean value for active lever presses during 3 consecutive days of ≥40 presses, with a variance ≤15%. This criterion was applied to each animal, and only animals meeting this criterion were included in the analyses. In addition, active lever presses during the 3 consecutive days were significantly greater than inactive presses. Maintenance was achieved within 5.8 ± 2.0 d (mean ± SD), and dialysis was conducted 3 d later. The right or left PVN was randomly selected for early maintenance microdialysis, and the contralateral PVN was dialyzed during later maintenance, 10–12 d thereafter.
Because the results reported herein show a reduction in the NE response to nicotine SA by the end of the 9 hr microdialysis period, subsequent experiments were designed to further clarify this observation. First, to test whether the efficiency of the probe decreased during the 9 hr microdialysis period, the in vitro NE recovery rate was measured in six microdialysis probes both before and after 9 hr ofin vivo microdialysis. Second, to determine whether the reduction in NE secretion was attributable to diminished responsiveness to nicotine, rats were given two consecutive injections of nicotine at the onset of lights out and then again 7 hr later. This experiment was performed when rats were in the early maintenance phase of nicotine SA, a time when NE secretion showed reduced responsiveness to nicotine. Therefore, to ensure that elevations of PVN NE were readily detectable, two consecutive injections of nicotine, rather than one, were given via computer-generated signals (0.03 mg/kg twice, separated by a 7 sec delay). All other nicotine was delivered as usual in response to active lever presses. Third, to determine whether the reduced NE response to nicotine SA was attributable to the depletion of axonal NE stores, 1 hr after the second pair of programmed nicotine injections, yohimbine (an α2 adrenergic antagonist; 6.0 mg/kg, i.p.) (Sharp and Matta, 1993), was administered to the same animals. Last, to determine whether the reduction in NE responsiveness to the second set of computer-programmed nicotine injections reflected a diurnal influence, two groups of animals that received saline after pressing the active lever were each tested by receiving two consecutive computer-driven injections of nicotine at only one of the two time points discussed above (0 or +7 hr).
Data analysis. To obtain sufficient sample for the detection of PVN NE, the collection interval for each microdialysis samples was 7 min. However, rats often pressed the active lever more than once within the 7 min collection interval, summating the NE release and frequently extending it into the next sample. Therefore, all active lever presses occurring within 7 min of each other defined a single SAE. The NE release (i.e., incremental NE response) associated with such an SAE was calculated as the difference between the average microdialysate NE level in the two SAE samples (obtained during and immediately after that SAE) and the average NE levels present in the two samples immediately preceding the SAE (baselines). An SAE associated with increased NE secretion (i.e., at least 10% above the baseline NE levels) was defined as an increasing SAE (iSAE). The value of 10% was selected to capture a wide range of SAE-associated changes in NE release while excluding those that were within the range of variation attributable to HPLC measurement [sample-to-sample variation of 5.16 ± 2.9% (mean ± SD)]. Finally, the overall mean level of microdialysate NE was calculated using the values of all of the samples collected during the 9 hr session.
Data (mean ± SE) were expressed as picograms of NE per 10 μl of microdialysate. Data were analyzed using one-way or two-way ANOVA and post hoc testing with Fisher's least significant difference (SPSS 7.5; SPSS, Chicago, IL) or appropriate t tests.
RESULTS
Figure 1 shows the location within the PVN of the membrane area of all microdialysis probes used in these investigations. Histological evaluation showed that the membrane areas were all situated within the PVN, and the upper aspect of the membrane was located within the thalamus. In the few experiments in which the tip of the probe was located in the thalamus (data not shown), NE was undetectable in the microdialysate.
PVN NE secretion and SAEs during the acquisition phase
Figure 2A shows microdialysate NE levels in the PVN of a representative rat self-administering nicotine on the first day the drug was made available. Because the animal was acquiring the association between active lever pressing and receiving nicotine, the active lever was pressed only six times. The first four active lever presses occurred in very close succession, thereby constituting a single SAE (because lever presses were not recognized during the 7 sec time-out after an active lever press, each active lever press shown resulted in a single programmed injection of nicotine). Two additional SAEs, at 344 and 403 min, took place during the 9 hr microdialysis session. The first SAE, at 3 min, resulted in a large increase in NE secretion (iSAE, inverted triangle with dot), and the other two iSAEs were accompanied by small NE responses (>10% of baseline). In comparison, an animal receiving saline (Fig.2B) had five SAEs, only one of which (at 198 min) was associated with a small increase in NE secretion and could be designated as an iSAE.
In Figure 3, the top two panels show the relationship of SAEs to NE release on day 1 of acquisition in rats receiving nicotine (n = 6) versus saline (n = 6) when the active lever was pressed.A1 shows that nicotine produced a doubling in the mean number of SAEs associated with increasing NE levels (iSAEs;t = 3.99; p < 0.01). A2shows that, compared with saline, nicotine increased the fraction of total SAEs that were accompanied by increasing NE levels (iSAE/total SAEs) from ∼30 to 80% (t = 7.58; p< 0.01), without affecting the number of SAEs (Table1). This demonstrates that, on the day drug SA was first initiated, animals receiving nicotine had an increased number of iSAEs.
Additional analyses were done to evaluate the magnitude of NE release associated with SAEs during the first day of nicotine SA. Figure4A shows that the mean NE increment associated with all iSAEs in the 9 hr session was more than threefold greater in rats self-administering nicotine than saline (t = 5.39; p < 0.01). In addition, in nicotine-treated rats, the average NE increment during the very first iSAE also was greater (t = 2.69; p < 0.025) (Fig. 4B). In contrast, the average NE increment of the last iSAE was not significantly different between these two groups (t = 1.38; p > 0.05) (Fig. 4C). In the animals receiving nicotine, comparison of the NE increments associated with the first versus the last iSAE (Fig.4B,C) also showed that the first NE response was significantly higher than the last (t = 2.72; p < 0.025). Figure 4D showed that the overall mean NE levels, calculated from all of the samples collected during the 9 hr microdialysis session, were similar in both the nicotine and saline groups (0.60 ± 0.36 vs 0.64 ± 0.26 pg/10 μl; t = 0.57; p > 0.05). Thus, receiving nicotine on the first day it was made available resulted in iSAEs associated with significantly greater incremental NE responses compared with animals receiving saline. These nicotine-induced NE increments were associated with the first, but not the final, iSAEs recorded during the microdialysis session. These findings suggest that the NE response to self-administered nicotine may decline with repeated dosing and/or prolonged access to the drug during the initial 9 hr that it is available. It is important to note that on day 1 of acquisition, the rats are just beginning to acquire the association between lever pressing and receiving nicotine. Because this association is not well established on day 1, the PVN NE response to nicotine is not necessarily characteristic of nicotine SA.
The numbers of active and inactive lever presses were compared during both the first 23 hr SA session in which acquisition microdialysis was performed and the 3 d interval that defined the achievement of early maintenance. The following number of active versus inactive lever presses occurred within the first 23 hr SA session during which microdialysis was performed: 30.3 ± 13.4 active lever presses versus 30.7 ± 10.1 inactive lever presses in the nicotine SA group (t = 0.03; p > 0.05;n = 6); and 22.0 ± 4.3 active lever presses versus 36.8 ± 15.3 inactive lever presses in the saline group (t = 1.09; p > 0.05; n= 6). During the 3 consecutive days that defined the achievement of early maintenance, the number of active lever presses was twofold greater than inactive presses in rats self-administering nicotine (e.g., on the third consecutive day, active lever presses was 68.6 ± 4.4, and inactive lever presses was 34.4 ± 8.6;F(2,102) = 12.06 for two-way ANOVA of active vs inactive lever presses by 3 consecutive days,p < 0.01; post hoc comparison of lever presses on the third consecutive day, t = 3.55,p < 0.01). In contrast, no difference was found in active versus inactive lever presses in rats receiving saline (e.g., on the third consecutive day, active lever presses was 23.1 ± 6.6, and inactive lever presses was 35.7 ± 8.3;F(2,72) = 1.87, p > 0.05].
PVN NE secretion and SAEs during the early maintenance phase
When microdialysis was performed in the early phase of maintenance, rats had achieved stable rates of SA and had been self-administering nicotine for 9.2 ± 0.6 d (range of 7–13 d). Figure 5, A andB, shows SAEs and PVN NE secretion during 9 hr dialysis sessions in two rats receiving nicotine (n = 12) versus saline (n = 7), respectively. A demonstrates that many iSAEs occurred throughout the session, whereas few iSAEs occurred in a saline rat (B). In contrast to the acquisition phase, the early maintenance phase of nicotine SA was associated with a twofold increase in the mean number of SAEs (p < 0.01) (Table 1). In addition, a fourfold increase in the number of iSAEs was observed (F(3,31) = 10.47; p < 0.01) (Fig. 3B1). The percentage of all SAEs associated with an NE increment (iSAE/total SAEs) also was higher in rats receiving nicotine (F(3,31) = 4.77;p < 0.01) (Fig. 3B2).
Figure 6A shows that the mean NE increment associated with all iSAEs during the 9 hr dialysis session was significantly higher in rats self-administering nicotine (F(3.,31) = 3.57;p < 0.05). The mean NE increment of the very first iSAE also was greater in nicotine than saline rats (F(3,31) = 2.60; p < 0.05) (Fig. 6B), whereas the mean NE increment of the last iSAE was not different (F(3,28) = 0.75; p > 0.05) (Fig. 6C). Comparison within the group receiving nicotine (Fig.6B,C) also indicated that the NE increment of the first iSAE was significantly higher than the last in the same animals (t = 2.32; p < 0.05). Figure 6D demonstrates that the overall mean level of NE was twofold greater in rats self-administering nicotine compared with those receiving saline (F(3,31) = 2.97; p < 0.05). Thus, during the early maintenance phase, nicotine SA was associated with a significant increase in both the number of iSAEs and the NE increments achieved during these episodes. These NE increments were associated with early, but not late-occurring, iSAEs. Thus, despite the decline in the amount of NE secreted during late-occurring iSAEs, the overall level of NE present in the microdialysates obtained throughout the session was significantly elevated in the nicotine SA group.
The numbers of active and inactive lever presses were compared during the 23 hr SA session in which early maintenance microdialysis was performed. The following number of active versus inactive lever presses occurred: 50.9 ± 4.8 active lever presses versus 31.5 ± 5.7 inactive lever presses in the nicotine SA group (t = 2.95; p < 0.01; n = 12); and 27.0 ± 6.7 active lever presses versus 31.7 ± 12.6 inactive lever presses in the saline group (t = 1.62;p > 0.05; n = 7). Thus, active lever presses exceeded inactive presses only in the nicotine SA group.
PVN NE secretion and SAEs during the later maintenance phase
By the time microdialysis was performed in the later phase of maintenance, animals had been self-administering nicotine for 18.6 ± 0.8 d (range of 14–25 d). Figure7 shows the SAEs and PVN NE levels in representative animals receiving nicotine (A;n = 10) or saline (B; n = 6) in response to active lever presses. Comparison of the two indicates that total SAEs continued to remain elevated in the animal self-administering nicotine. This also was apparent in the group data shown in Table 1. Similar to the observations made during the early maintenance phase, the mean number of total injections, as well as SAEs, were significantly greater in nicotine-treated rats. Furthermore, Figure 3C shows that the number of iSAEs continued to be significantly greater in the nicotine rats (F(3,31) = 10.47; p < 0.01) (C1), although the percentage of iSAEs/total SAEs was not different (C2). Thus, in late maintenance, the number of SAEs and iSAEs remained elevated in nicotine SA animals.
Similar to the NE responsiveness noted during the early maintenance phase, Figure 8A shows that the mean NE increment of all iSAEs was greater in the nicotine group during later maintenance (F(3,31) = 3.57; p < 0.05). In addition, the average NE increment of the first, but not the last, iSAE was significantly greater in the nicotine group [Fig.8B (F(3,31) = 2.60;p < 0.05), C(F(3,28) = 0.75; p > 0.05]. The overall mean NE level in the nicotine group was 79% higher than in saline rats (F(3,31) = 2.97;p < 0.05) (Fig. 8D). Comparing the average NE increment of all iSAEs during early versus later maintenance (Figs. 6A, 8A, respectively), there was a considerable reduction in NE responsiveness by the later phase. Thus, PVN NE secretion was enhanced by nicotine SA during later maintenance, although to a lesser extent than in early maintenance.
The numbers of active and inactive lever presses were compared during the 23 hr SA session in which later maintenance microdialysis was performed. The following number of active versus inactive lever presses occurred: 45.2 ± 7.3 active lever presses versus 29.7 ± 5.9 inactive lever presses in the nicotine SA group (t = 2.08; p < 0.05; n = 10); and 22.3 ± 5.0 active lever presses versus 29.2 ± 10.5 inactive lever presses in the saline group (t = 0.61;p > 0.05; n = 6). Thus, active lever presses exceeded inactive presses only in the nicotine SA group.
Differences in intra-day PVN NE secretion during early and late-occurring iSAEs
The foregoing data analyses showed that NE responsiveness to nicotine SA declined throughout the microdialysis session in all stages of SA. To clarify this, several potential factors were evaluated. First, to test whether the efficiency of the probe decreased during the 9 hr microdialysis period, the in vitro NE recovery rate was measured in six microdialysis probes both before and after 9 hr ofin vivo microdialysis. Microdialysis probe efficiency did not change during the 9 hr session: 5.7 ± 0.4% before microdialysis, 5.2 ± 0.5% after (t = 0.79; p > 0.05). Second, to determine whether the reduced NE response associated with late-occurring iSAEs was specific to nicotine SA or attributable to the depletion of axonal NE, yohimbine (6 mg/kg, i.p.) was administered during early maintenance nicotine SA, 8 hr after the beginning of a microdialysis session. Figure 9 shows that peak NE release occurred 21–28 min after yohimbine, and no difference was seen between the two groups (F(13,102) = 0.94;p > 0.05; n = 4). Thus, the secretory pool of PVN NE was not depleted during nicotine SA.
Third, to determine whether the intra-day differences in PVN NE secretion reflect reduced responsiveness to nicotine, groups self-administering nicotine during the early maintenance phase or receiving saline were each given two consecutive passive injections of nicotine in the morning and then again 7 hr thereafter. Figure10 shows the incremental NE response to passively administered injections of nicotine in rats that had been receiving saline (A) versus nicotine (B) when they pressed the active lever. In the saline group, the variance in the incremental response to the first injection of nicotine was attributable to a single animal that, for unknown reasons, had both a higher NE baseline and response. In both groups, the NE response to the initial pair of passive nicotine injections was significantly greater than to the second set (t = 4.03,p < 0.01 for saline; t = 3.05,p < 0.05 for nicotine; n = 4 each group). These findings indicate that reduced NE responsiveness to repeated treatment with passive nicotine occurred in both groups, even when nicotine was administered as long as 7 hr apart. These experiments also showed that the incremental NE response to the first set of passive nicotine injections was sixfold greater in the saline group, previously naı̈ve to nicotine compared with the nicotine SA group (t = 3.941; p < 0.05). This suggests that previous chronic exposure to self-administered nicotine reduced the NE responsiveness to passive delivery of the drug, even when administered early in the microdialysis session.
Fourth, to determine whether there was a diurnal influence on NE responsiveness to nicotine that might have an impact on the intra-day differences observed, two groups of animals that received saline after pressing the “active” lever were each tested by receiving two consecutive passive injections of nicotine at only one of the two time points discussed above (0 or +7 hr). No differences were observed in the NE released by two consecutive nicotine injections, whether delivered at lights off (0 hr) or 7 hr thereafter [NE increment (picograms per 10 μl): 1.6 ± 0.3 or 1.1 ± 0.2, respectively; t = 0.832; p > 0.05;n = 5].
Last, to assess whether nicotinic acetylcholine receptors (nAChRs) may have resensitized during the nicotine-free interval that separated the last nicotine injection in the previous SA session from the first injection on the day of microdialysis, the following were calculated: (1) the mean duration of this time period; and (2) the linear regression between the duration of the nicotine-free interval and the peak NE response to the first iSAE in individual rats. The following nicotine-free intervals were found: during early maintenance, 256.6 ± 65.6 min; during late maintenance, 267.8 ± 69.5 min. These prolonged nicotine-free intervals suggest that resensitization may have occurred followed by subsequent desensitization during the microdialysis session (induced by frequent nicotine injections). However, the linear regression analysis between the nicotine-free interval and the peak NE response failed to show significance (early maintenance, r = 0.40,p = 0.19, n = 12; later maintenance,r = 0.05, p = 0.69, n = 10). This analysis indicates that the extent of this nicotine-free time interval was not a significant factor in determining the magnitude of the NE response to the first iSAE.
DISCUSSION
During early acquisition or the early and later maintenance phases of nicotine SA, rats had a significantly greater number of iSAEs, as well as a higher average NE increment in all iSAEs, compared with saline animals. These results demonstrate that PVN NE secretion is induced in coordination with the self-administration of nicotine (0.03 mg/kg, i.v.). These findings, along with data showing that the overall NE level was higher in rats during the early and later maintenance phases of nicotine SA, indicate that nicotine SA stimulated the secretion of PVN NE. Comparisons of early to later maintenance also indicated that lesser amounts of PVN NE were secreted in response to nicotine SA during later maintenance. Moreover, nicotine SA was associated with diminishing NE responsiveness within each daily SA session, regardless of the phase of SA. Therefore, a dose of 0.03 mg/kg nicotine stimulates sustained PVN NE secretion in rats self-administering the drug, although the magnitude of the response declines both within each daily session and with the duration of SA. To our knowledge, this is the first report on CNS NE secretion in rats self-administering any drug and the first observation of neurotransmitter secretion in animals with unlimited access to self-administered nicotine.
The PVN NE secretory response to nicotine SA may depend on activation of nAChRs located in the brainstem. This is supported by data showing that mecamylamine, an nAChR antagonist, blocked intravenously administered nicotine-induced NE secretion in the PVN when the antagonist was microinjected into the fourth ventricle (Fu et al., 1997). The nucleus tractus solitarius (NTS) has been identified as the brainstem site containing the noradrenergic neurons that mediate nicotine-stimulated PVN NE secretion. Within the A2 and C2 regions of the NTS, intravenously administered nicotine stimulated c-fos expression in neurons coexpressing tyrosine hydroxylase, the rate-limiting enzyme in catecholamine biosynthesis. Activation of these NTS neurons also was blocked by administering mecamylamine into the fourth ventricle (Valentine et al., 1996). Comparing locus ceruleus and NTS, higher concentrations of systemic nicotine were required to activate locus ceruleus neuron c-fos expression (Matta et al., 1993a). In addition, the ED50 dose required to stimulate ACTH secretion was significantly higher for nicotine microinjected into locus ceruleus than NTS. Therefore, NTS noradrenergic inputs to PVN are more sensitive to nicotinic stimulation (Matta et al., 1993b); nonetheless, locus ceruleus noradrenergic afferents may contribute to the NE in PVN microdialysates.
Presynaptic nAChRs have been shown to mediate NE release in certain brain regions. For example, studies with hippocampal synaptosomes and slices have shown NE secretion induced by nicotinic agonists and blocked by mecamylamine (Sacaan et al., 1995; Clarke and Reuben, 1996). However, the effect of nicotine SA on PVN NE release is unlikely to depend on presynaptic nAChRs on NE terminals within the PVN, because microinjection of mecamylamine into the PVN was completely ineffective in blocking the release of NE (Fu et al., 1997) or ACTH (Matta et al., 1990) by intravenously administered nicotine.
In all three phases of nicotine SA (as shown in Figs. 4, 6, 8), the NE increment of the last iSAE was not significantly greater in nicotine SA compared with saline animals. Thus, a reduction in the NE responsiveness to nicotine SA was consistently observed within each day; this was independent of the number of days that nicotine was self-administered. Loss of efficiency of the microdialysis probe did not account for these observations. Furthermore, the reduced NE response was specific to nicotine SA, because yohimbine-induced NE secretion was unaffected when tested toward the end of a microdialysis session. Thus, nicotine SA did not deplete the secretory pools of axonal NE.
The fact that previous exposure to nicotine results in reduced responsiveness to the biochemical or behavioral effects of subsequent treatment(s) has long been thought to be mediated through receptor desensitization (Marks et al., 1985; Rapier et al., 1988; Rowell and Hillebrand, 1994). Indeed, microdialysis studies have shown a rapid reduction in both PVN and hippocampal NE secretion after a single passive injection of nicotine (Sharp and Matta, 1993; Fu et al., 1998). However, once reduced, repeated nicotine administration at constant 100 min intervals resulted in similar NE responses to the second, third, and fourth injections. This suggests that the reduction in NE responsiveness to passive administration occurs rapidly but does not proceed to completion.
The pattern of reduced PVN NE secretion was different in nicotine SA rats compared with the aforementioned studies on animals receiving drug passively. In early maintenance, the first two iSAEs that occurred during the microdialysis period were separated by 82.4 ± 16.7 min, yet the NE response to the second was only 18% less than the first (0.72 ± 0.22 pg/10 μl for the first iSAE and 0.59 ± 0.15 pg/10 μl for the second). Furthermore, in later maintenance, NE secretion did not differ between the first two iSAEs (0.20 ± 0.03 pg/10 μl for the first iSAE and 0.23 ± 0.05 pg/10 μl for the second), although these two episodes were 103.5 ± 35.6 min apart. In contrast, we previously reported, using nicotine-naı̈ve animals, that the second PVN NE response was ∼50% of the first when passive nicotine injections were separated by 100 min (Sharp and Matta, 1993). This difference in the NE response to self-administered versus passive delivery of nicotine may be attributable to the fact that at least partial desensitization had already taken place by early maintenance. This is supported by the results of the experiment wherein rats were given two sets of paired passive injections. The NE response in animals that were previously self-administering nicotine was sixfold less than in animals that were naı̈ve to nicotine (Fig. 10), probably reflecting a preexisting reduction in NE responsiveness to the neuropharmacological effects of nicotine.
PVN NE responsiveness appeared to decline further during a 9 hr microdialysis session in which the NE increment of the first iSAE was significantly greater than the last in animals receiving nicotine, for both the acquisition and early maintenance phases. Moreover, in all three phases, the NE increment was only greater during the first iSAE, but not the last, in rats receiving nicotine compared with saline. This probably reflects a greater degree of desensitization that develops during the lights-off phase of the daily light cycle when the animals administered nearly 80% of their daily nicotine. In addition to desensitization, it is likely that some of the difference between the NE response to the first versus the last iSAE reflects resensitization of nAChRs resulting in increased responsiveness to the first iSAE. Although the linear regression analysis did not provide evidence of resensitization during the 4–4.5 hr nicotine-free interval (from the last injection in the previous SA session to first injection during the microdialysis session), resensitization may have taken place during the first 8 hr of the preceding “lights on” interval (inactive phase) when only ∼20% of the daily nicotine dose was delivered. During this time period, blood nicotine levels may drop sufficiently because of the greatly reduced frequency of nicotine delivery to permit resensitization. In addition to resensitization, it is possible that nicotine may have become a novel stimulus by the time that the first iSAE occurred. This might occur if some lever press activity persisted, despite the extinction of cue lights during the daily 1 hr housekeeping interval when nicotine was unavailable. Thus, the delivery of nicotine during the early iSAEs of the subsequent SA session may have become unexpected, and such novelty may have facilitated NE responses.
By late maintenance, the number of iSAEs, the average NE peak height of iSAEs, and the increment in the first peak of the day, as well as the mean value over the 9 hr microdialysis period, were still higher than saline rats. These results indicate that PVN NE continued to be released after nicotine SA at this stage. This is consistent with human cigarette smoking. When one cigarette was smoked, serum NE levels were elevated in 10 smokers after 1.5 hr without cigarettes (Pomerleau, 1992). In addition, nicotine elevated plasma hormones (e.g., arginine vasopressin and β-endorphin) in smokers instructed to smoke after overnight deprivation (Pomerleau et al., 1983). Furthermore, the first cigarette of the day tended to induce greater responses (Parrott, 1994). This phenomenon also was observed in the present study: throughout all three phases of SA, NE levels were greater during the first iSAE in rats self-administering nicotine. These NE levels were greater than those present in the last iSAE during acquisition and early maintenance. Therefore, our nicotine SA model may reflect the CNS noradrenergic responses that occur with human cigarette smoking.
The present study is the first report on NE secretion during nicotine SA. Nicotine SAEs were significantly associated with increased PVN NE secretion during acquisition, early maintenance, and later maintenance. The PVN NE secretion in response to nicotine SA may be induced through nAChRs located in brainstem noradrenergic regions (especially the NTS). However, the NE response to nicotine SA declined during each microdialysis session and also by later maintenance. These changes are consistent with the progression of partial desensitization to the effect of nicotine SA on PVN NE secretion.
Footnotes
This work was supported by National Institute on Drug Abuse Grant 03977.
Correspondence should be addressed to Dr. Burt Sharp, Department of Pharmacology, Health Science Center, University of Tennessee, 874 Union Avenue, Memphis, TN 38163. E-mail: bsharp{at}utmem.edu.