Actions of nicotine on the acquisition of an autoshaped lever-touch response in rats

Nicotine effects on learning in zebrafish: the role of dopaminergic systems

RATIONALE

Nicotine improves cognitive function in a number of animal models including rats, mice, monkeys, and recently, zebrafish. The zebrafish model allows higher throughput and ease in discovering mechanisms of cognitive improvement.

MATERIALS AND METHODS

To further characterize the neural bases of nicotine effects on learning in zebrafish, we determined changes in dopaminergic systems that accompany nicotine-enhanced learning.

RESULTS

Nicotine improved learning and increased brain levels of dihydroxyphenylacetic acid (DOPAC), the primary dopamine metabolite. There was a significant correlation between choice accuracy and DOPAC levels. The nicotinic antagonist mecamylamine blocked the nicotine-induced increase in DOPAC concentrations, in line with our previous finding that mecamylamine reversed nicotine-induced learning improvement.

CONCLUSIONS

Dopamine systems are related to learning in zebrafish; nicotine exposure increases both learning rates and DOPAC levels; and nicotinic antagonist administration blocks nicotine-induced rises in DOPAC concentrations. Rapid cognitive assessment of drugs with zebrafish could serve as a useful screening tool for the development of new therapeutics for cognitive dysfunction.

Chronic nicotine improves cognitive performance in a test of attention but does not attenuate cognitive disruption induced by repeated phencyclidine administration

RATIONALE

Nicotine-induced cognitive enhancement may be a factor maintaining tobacco smoking, particularly in psychiatric populations suffering from cognitive deficits. Schizophrenia patients exhibit higher smoking rates compared with the general population, suggesting that attempts to self-medicate cognitive schizophrenia deficits may underlie these high smoking levels.

OBJECTIVES

The present study explored pro-cognitive effects of nicotine in a model of schizophrenia-like cognitive dysfunction to test this self-medication hypothesis.

MATERIALS AND METHODS

We investigated whether chronic nicotine (3.16 mg/kg/day, base) would attenuate the performance disruption in the five-choice serial reaction time task (5-CSRTT, a task assessing various cognitive modalities, including attention) induced by repeated administration of phencyclidine (PCP), an N-methyl-D-aspartate receptor antagonist that induces cognitive deficits relevant to schizophrenia.

RESULTS

Chronic nicotine administration shortened 5-CSRTT response latencies under baseline conditions. Nicotine-treated rats also made more correct responses and fewer omissions than vehicle-treated rats. Replicating previous studies, repeated PCP administration (2 mg/kg, 30 min before behavioral testing for two consecutive days followed 2 weeks later by five consecutive days of PCP administration) decreased accuracy and increased response latencies, premature responding, and timeout responding. Chronic nicotine did not attenuate these PCP-induced disruptions.

CONCLUSIONS

Chronic nicotine had pro-cognitive effects by itself, supporting the hypothesis that cognitive enhancement may contribute to tobacco smoking. At the doses of nicotine and PCP used, however, no support was found for the hypothesis that the beneficial effects of nicotine on cognitive deficits induced by repeated PCP administration, assessed in the 5-CSRTT, are larger than nicotine effects in the absence of PCP.

Timing of nicotine effects on learning in zebrafish

RATIONALE

Nicotine has been shown in many, but not all, studies to improve cognitive function in a number of species including rats, mice, monkeys, and humans. Recently, we have found that nicotine also improves memory in zebrafish. Nicotinic agonists are being developed as novel treatments for Alzheimer's disease and other cognitive impairments.

OBJECTIVES

In screening the therapeutic potential of novel nicotinic agonists, it is important to have a rapid assay of cognitive improvement. Zebrafish can help with this effort.

METHODS

We have developed a method of rapidly assessing spatial position discrimination learning in zebrafish in one session of seven trials. We used this method to determine the cognitive effects of nicotine.

RESULTS

Nicotine (100 mg/l administered during 3 min of immersion) caused a significant improvement in percent correct performance. This dose was within the effective range we found to improve the choice accuracy performance of zebrafish using the more time-intensive delayed spatial alternation procedure. Interestingly, the positive effect of nicotine was seen at 20-40 min postadministration, but not earlier, and declined at 80 and 160 min posttreatment. At the 40-min postdosing interval, 200 mg/l nicotine was also found to significantly improve choice accuracy. Nicotine-induced accuracy improvement was reversed by the nicotinic antagonist mecamylamine given shortly before testing but not when given concurrently with nicotine.

CONCLUSIONS

This position discrimination procedure in zebrafish effectively demonstrated the cognitive-enhancing effects of nicotine. This model may be useful in the early screening of novel nicotinic compounds for treatment of cognitive dysfunction.

Intrahippocampal nicotine in alcohol drinking rats--effects on lever-press response

We have previously shown differences on learning processes between alcohol drinking and non-alcohol drinking rats. Underlying these effects, functional differences in the septo-hippocampal pathway were hypothesized. We have performed a dose-response study for intrahippocampal nicotine (CA1) on acquisition and extinction of the lever-press response and antagonization test by co-administration of mecamylamine. Results show that the administration of nicotine in CAI region has a detrimental dose-dependent effect on acquisition in alcohol drinkers, with a dose of 10 nM being the most disruptive. In the controls, only doses of 10 and 20 nM had detrimental effect. The effect of nicotine (10 nM) was partially (alcoholics) or fully (controls) antagonized by mecamylamine co-administration (30 nM). Summarizing, the alcohol groups showed a dose-response curve for nicotine shifted leftwards, and a partial antagonism of these effects by mecamylamine; these effects may be consequence of the functional sensitization of the nicotinic responsivity in the CAI region which were produced by the chronic alcohol.

Effects of nicotine and chlorisondamine on cerebral glucose utilization in immobilized and freely-moving rats

Chlorisondamine blocks central nicotinic receptors for many weeks via an unknown mechanism. Intracerebroventricular administration of [(3)H]-chlorisondamine in rats results in an anatomically restricted and persistent intracellular accumulation of radioactivity. The initial aim of the present study was to test whether nicotinic receptor antagonism by chlorisondamine is also anatomically restricted. Male adult rats were pretreated several times with nicotine to avoid the disruptive effects of the drug seen in drug-naïve animals. They then received chlorisondamine (10 microg i. c.v.) or saline, and local cerebral glucose utilization (LCGU) was measured 4 weeks later after acute nicotine (0.4 mg kg(-1) s.c.) or saline administration. During testing, rats were partially immobilized. Nicotine significantly increased LCGU in the anteroventral thalamus and in superior colliculus. Chlorisondamine completely blocked the first of these effects. Chlorisondamine significantly reduced LCGU in the lateral habenula, substantia nigra pars compacta, ventral tegmental area, and cerebellar granular layer. The second experiment was of similar design, but the rats were not pre-exposed to nicotine, and were tested whilst freely-moving. Acute nicotine significantly increased LCGU in anteroventral thalamus, superior colliculus, medial habenula and dorsal lateral geniculate. Overall, however, nicotine significantly decreased LCGU. Most or all of the central effects of nicotine on LCGU were reversed by chlorisondamine given 4 weeks beforehand. These findings suggest that chlorisondamine blocks nicotinic effects widely within the brain. They also indicate that in freely-moving rats, nicotine can reduce or stimulate cerebral glucose utilization, depending on the brain area. British Journal of Pharmacology (2000) 129, 147 - 155

Nicotine improves memory in an object recognition task in rats

Nicotine was investigated for its mnemonic effect in a two trials object recognition task. In the first trial, two copies of the same object were presented. In the second trial (24 h after), one of the familiar object and a new object were presented. The time spent exploring the new object by control rats was not significantly different from the exploration time of the familiar object, indicating that they did not remember the familiar object. Rats injected with nicotine before the first trial, after the first trial or before the second trial spent more time in exploring the new object than the familiar one at the second trial. These results suggest that, in normal rats, acute nicotine enhances acquisition, consolidation and restitution of the information in an object recognition task.

Persistent nicotinic blockade by chlorisondamine of noradrenergic neurons in rat brain and cultured PC12 cells

Chlorisondamine (CHL) blocks behavioural responses to nicotine for several weeks or months in rats. Persistent blockade has also been demonstrated ex vivo, in assays of nicotine-evoked striatal dopamine release. Central administration of [3H]-CHL leads to long-term retention of radiolabel in nigrostriatal dopaminergic neurons and in few other cell groups. We investigated whether an analogous blockade also occurs in noradrenergic neurons in the brain and in cultured pheochromocytoma (PC12) cells, which have a similar noradrenergic phenotype. Administration of CHL (10 mg kg(-1) s.c. or 10 microg i.c.v.), 21 days prior, resulted in a near-total block of nicotine-evoked release of hippocampal [3H]-noradrenaline ([3H]-NA) from superfused rat synaptosomes; NMDA-evoked [3H]-NA release was unaffected. Three weeks after administration of [3H]-CHL (10 microg i.c.v.), preferential accumulation of radiolabel was observed in the locus coeruleus, which provides the entire noradrenergic innervation to hippocampus, as well as in previously noted structures. In rat pheochromocytoma (PC12) cells, nicotine evoked [3H]-NA release (EC50 approximately 30 microM). This effect was blocked by co-incubation with mecamylamine (10 microM) or CHL (1 microM) but was not affected by alpha-bungarotoxin. As in the hippocampus, the nicotinic agonist cytisine was at least as efficacious as nicotine. Acute exposure of PC12 cells to CHL 10 or 100 microM (but not 1 microM), followed by 90 min wash-out, almost completely blocked release evoked by 30 microM nicotine. More prolonged (24 h) exposure to CHL 100 microM (but not 1 or 10 microM), followed by 3 days of wash-out, partially inhibited release evoked by nicotine, leaving responses to high K+ unchanged. A significant (30%) reduction was also seen 5 days after exposure. We conclude that persistent nicotinic blockade by CHL is neither restricted to mesostriatal dopamine neurons, nor to the CNS, nor to neurons possessing the same nicotinic receptor pharmacology. In addition, the persistent blockade does not appear to result from an acute blocking action, but may be dependent upon intracellular accumulation of the antagonist.

Chronic nicotinic agonist and antagonist effects on T-maze alternation

A variety of studies have found that nicotine improves working memory function. However, other studies have either not found improvements or have found nicotine-induced deficits. The demands of the particular memory test may be critical for the expression of the nicotine effects. In several studies, we have found that chronic nicotine administration improves working memory performance in the radial arm maze. Chronic mecamylamine coadministration reversed this effect. The current study was conducted to determine the effects of chronic nicotine and mecamylamine on choice accuracy in a T-maze spatial alternation task. The same dose and duration of nicotine administration that we have previously found to significantly improve choice accuracy in the radial-arm maze was not effective in altering T-maze spatial alternation. The critical difference in task demands may be the presence with T-maze alternation of proactive interference. During a session, a choice alternative repeatedly changes valence from correct to incorrect and back again. In contrast, with the radial-arm maze as run in our studies, in a session the valence of an arm only changes once from correct to incorrect. Previous work with nicotine effects on spatial alternation in an operant task found evidence that nicotine increased the negative effect of proactive interference on performance. In the current study, chronic mecamylamine caused a significant deficit in T-maze spatial alternation. This same dose did not produce a deficit in the radial-arm maze and, in fact, caused an improvement during the first week of administration.

Effects of stimulation or blockade of central nicotinic-cholinergic receptors on performance of a novel version of the rat stimulus discrimination task

This study evaluated the effects of two central nicotinic-cholinergic receptor agonists and an antagonist on performance accuracy of a rat, delayed stimulus discrimination task (DSDT). Rats were trained to discriminate between an auditory and visual stimulus by pressing a right or left lever. To diminish the rat's ability to use mediating spatial strategies to solve the task, computer automated, retractable doors separated the animal from the levers during delay intervals, thus reducing positioning at the lever. After stable baselines were achieved, rats were grouped and administered placebo (saline) and nicotine, lobeline or mecamylamine in a randomized dose series. Each group received two complete series of the selected compound on different occasions. Mecamylamine impaired DSDT accuracy in a dose-dependent manner while optimal doses of nicotine and lobeline significantly improved accuracy. Nicotine differed from lobeline in regard to its interaction with a dose of mecamylamine (1.0 mg/kg) that had not impaired DSDT accuracy. Combined administration of lobeline and mecamylamine was followed by a significantly increased level of DSDT accuracy that was similar to the improvement following administration of lobeline alone. In contrast, combined administration of nicotine and mecamylamine did not result in increased DSDT accuracy. Furthermore, lobeline administration similarly improved accuracy of trials associated with both the light and the tone, while nicotine improved accuracy of trials associated with the light to a much greater degree. These data suggest that the increases in DSDT accuracy associated with lobeline may be expressed through non-nicotinic mechanisms or a nicotinic receptor which is not blocked by mecamylamine.

Intraneuronal accumulation and persistence of radiolabel in rat brain following in vivo administration of [3H]-chlorisondamine

1. Chlorisondamine (CHL), a bisquaternary amine, produces a remarkably long-lasting blockade of central responses to nicotine. The mechanism underlying this blockade is not known. The main aim of this study was to test for possible accumulation of [3H]-CHL in rat brain during the period of chronic blockade. 2. Rats received CHL, either systemically (10 mg kg-1) or centrally (10 micrograms i.c.v.). Seven days later, striatal synaptosomes prepared from these animals were tested for nicotine-induced [3H]-dopamine release. This experiment showed that i.c.v. administration of CHL was as effective as systemic administration in producing ex vivo blockade of central nicotinic receptors. 3. Rats received bilateral i.c.v. infusions of [3H]-CHL (10 micrograms) and radioactivity was subsequently quantified in dissected cerebral cortex, striatum, hippocampus, midbrain and cerebellum. Radiolabel was detected at all three survival times (1, 7, and 21 days). Regional heterogeneity was apparent at 7 and 21 days survival. Radiolabel was almost exclusively confined to the insoluble subcellular fraction in all areas sampled. 4. The anatomical distribution of radiolabel was also visualized in brain sections. Rats received bilateral i.c.v. infusions of [3H]-CHL (10 micrograms) and were killed at 1, 7, 21 or 84 days. Immediately before they were killed, all rats were tested behaviourally, and central nicotinic blockade was demonstrated at 1, 7 and 21 days; partial recovery was observed at 84 days. Particularly at longer survival times, tritium was found to be heavily concentrated in the substantia nigra pars compacta, ventral tegmental area, dorsal raphé nucleus, and the granular layer of the cerebellum. 5. The possibility of retrograde axonal transport of radiolabel was then examined. Rats received a unilateral intrastriatal infusion of [3H]-CHL (0.34 or 0.034 micrograms) one week before they were killed. Autoradiographic labelling was largely confined to the site of infusion and to the ipsilateral substantia nigra pars compacta and dorsal raphé nucleus. 6. Thus, after i.c.v. administration, CHL (and/or centrally-formed derivatives) is initially widely distributed within the brain and is then selectively retained within a few brain areas. A persistent accumulation occurs within putative dopaminergic and 5-hydroxytryptaminergic neurones, at least partly through uptake by terminals and/or axons followed by retrograde transport. This persistent and anatomically-selective intraneuronal accumulation possibly underlies the long-term central nicotinic blockade associated with chlorisondamine.

Effects of nicotinic dimethylaminoethyl esters on working memory performance of rats in the radial-arm maze

Nicotine has been found to improve memory performance in a variety of tests, including the radial-arm maze. This improvement, together with the consistent finding of a decline in cortical nicotinic receptor concentration in Alzheimer's patients, has fueled the search for novel nicotinic ligands with therapeutic potential. In the current studies, a series of nicotinic compounds was tested for effects on working memory performance in the radial-arm maze. One of the three compounds tested, DMAE II (dimethylaminoethanol cyclohexyl carboxylate fumurate), produced significant improvements in working memory performance. In the first experiment, this drug produced a biphasic dose-response curve with improved performance at the 20-mg/kg dose but not at 10 or 40 mg/kg. In a second round of DMAE II administration, the same rats showed a significant improvement with the 40-mg/kg dose. In the second experiment, a new set of rats also showed a biphasic dose-response to DMAE II. The 20-mg/kg dose caused a significant improvement whereas the 40-mg/kg dose did not. Interactions of DMAE II with nicotine and mecamylamine were also studied. Nicotine (0.2 mg/kg) by itself caused a significant improvement in working memory performance. No additive effects of DMAE II with nicotine were seen. In fact, some attenuation of response was seen with the combination. Choice accuracy data for mecamylamine could not be analyzed because of excessive sedation and nonresponding. These studies show that, like nicotine, the nicotinic ligand DMAE II causes an improvement in radial-arm mace choice accuracy. The lack of additivity with nicotine may have been to the partial agonist effects of DMAE II.

Effects of nicotinic acetylcholine receptor ligands on behavioral vigilance in rats

The effects of nicotinic receptor ligands on performance in a task measuring sustained attention, or vigilance, were tested. This task required the animals to discriminate between signal and non-signal events. The sequence of signal (central panel light illumination for 500, 50 or 25 ms) and non-signal presentations was randomized over three blocks of 54 trials each (27 signal trials, 9 per length, and 27 non-signal trials). A left lever press following a signal was counted as a hit, and a right lever press following a non-signal event was counted as a correct rejection. Hits and correct rejections were rewarded, whereas misses and false alarms (defined as incorrect right and left lever presses, respectively) were not. Baseline performance was characterized by a signal length dependent ability of the animals to discriminate between signal and non-signal events. Administration of nicotine (0.19, 0.62, 1.9 mumol) or of two novel nicotinic receptor agonists, ABT-418 and A-82695, did not produce main effects on vigilance performance. Lobeline (1.9, 6.2, 19 mumol), a nicotinic receptor ligand with mixed agonist/antagonist activities, impaired the animals' ability to discriminate between signal and non-signal events. The antagonist mecamylamine (5, 15, 50 mumol) potently impaired performance while increasing the number of errors of omission. The lack of effect of nicotine largely corresponds with the findings from previous studies on the acute effects of nicotine in intact subjects and non-smoking humans. While the detrimental effects of lobeline may have been related to the antagonist effects of this compound, the reasons for the differences between the effects of nicotine and lobeline still remain unsettled. These data support the hypothesis that nicotine receptor mechanisms are maximally activated in intact animals performing this task, and suggest that effects of acute nicotinic agonist treatment would not produce further cognitive benefit for these animals.

Regulation of nicotinic receptors in rat brain following quasi-irreversible nicotinic blockade by chlorisondamine and chronic treatment with nicotine

1. Chronic administration of nicotinic agonists in vivo increases the density of brain nicotinic binding sites. It has been proposed that this up-regulation results from agonist-induced functional blockade of nicotinic receptors. This hypothesis was tested by examining post mortem [3H]-nicotine and [125I]-alpha-bungarotoxin ([125I]-alpha BTX) binding following treatment in vivo with the quasi-irreversible and insurmountable CNS nicotinic blocker chlorisondamine, given either alone or in combination with chronic nicotine administration. 2. In rats that had not received chlorisondamine pretreatment, chronic nicotine administration (0.6 mg kg-1 s.c., twice daily for 12 days) increased [3H]-nicotine binding density (Bmax) in forebrain tissue sections by 19%, with no change in the apparent dissociation constant (KD). Chlorisondamine (10 mg kg-1, s.c.), given once prior to the chronic treatment phase, neither increased [3H]-nicotine binding by itself, nor altered the extent of nicotine-induced up-regulation. Nevertheless, chlorisondamine pretreatment resulted in a persistent blockade of CNS nicotinic receptors, as demonstrated by complete block of acute locomotor responses to nicotine. 3. In a second experiment, [3H]-nicotine and [125I]-alpha BTX binding was measured in tissue homogenates prepared from several brain regions. In the absence of chlorisondamine pretreatment, chronic nicotine administration (1 mg kg-1 s.c., twice daily for 12 days) increased the Bmax of [3H]-nicotine binding in the cerebral cortex (by 34%), striatum (by 28%), midbrain (by 16%) and hippocampus (by 36%); KD was unchanged. As before, this up-regulation was neither mimicked nor blocked by chlorisondamine pretreatment (10 mg kg-1, s.c., given twice), despite persistent blockade of acute locomotor responses to nicotine. Chronic nicotine treatment also increased the Bmax (but not KD) of [125I]-alpha BTX binding in cerebral cortex (by 35%), hippocampus (by 46%) and midbrain (by 35%). Chlorisondamine altered neither Bmax nor KD when given alone, but significantly attenuated the nicotine-induced up-regulation of toxin binding sites in midbrain, with a similar trend in the other two regions.4. The finding that chronic receptor blockade neither mimicked nor blocked the agonist-induced up-regulation of [3H]-nicotine binding sites suggests that up-regulation of these receptors is not determined by their functional status. In contrast, it appears that chronic nicotine-induced up-regulation of[125I]-alpha BTX binding sites may result from receptor activation.

The pharmacology of the nicotinic antagonist, chlorisondamine, investigated in rat brain and autonomic ganglion

1. A single administration of the ganglion blocker, chlorisondamine (10 mg kg-1, s.c.) is known to produce a quasi-irreversible blockade of the central actions of nicotine in the rat. The mechanism of this persistent action is not known. It is also unclear whether chlorisondamine can block neuronal responses to excitatory amino acids and whether chronic blockade of nicotinic responses also occurs in the periphery. 2. Acute administration of chlorisondamine (10 mg kg-1, s.c.) to rats resulted in a blockade of central nicotinic effects (ataxia and prostration) when tested 1 to 14 days later, but caused no detectable cell death in tissue sections sampled throughout the rostrocaudal extent of the brain which were stained in order to reveal neuronal degeneration. 3. Long-term blockade of central nicotinic effects by chlorisondamine was not associated with significant alterations in the density (Bmax) of high-affinity [3H]-nicotine binding to forebrain cryostat-cut sections. 4. In cultured dissociated mesencephalic cells of the foetal rat, chlorisondamine and mecamylamine inhibited [3H]-dopamine release evoked by N-methyl-D-aspartate (NMDA, 10(-4) M), but only at high concentrations (IC50 approx. 600 and 70 microM, respectively). A high concentration of chlorisondamine (10(-3) M) had no effect on responses to quisqualate (10(-5) M) and only slightly reduced responses to kainate (10(-4) M). Mecamylamine (10(-3) M) was ineffective against both agonists. 5. In adult rat hippocampal slices, chlorisondamine depressed NMDA receptor-mediated synaptically-evoked field potentials, but again only at high concentrations (10(-4)-10(-3) M). Synaptic responses that were mediated by non-NMDA excitatory amino acid receptors were less affected. 6. In rat isolated superior cervical ganglion, electrically-evoked synaptic transmission was reduced 1 h after acute in vivo administration of chlorisondamine (0.1 mg kg-1, s.c.). However, in vivo administration of a higher dose (10 mg kg-1, s.c.) did not significantly affect ganglionic transmission when tested two weeks later, despite the continued presence of central nicotinic blockade.7. These results indicate that the persistent CNS nicotinic blockade by chlorisondamine is not accompanied by changes in nicotinic [3H]-nicotine binding site density or by neuronal degeneration in the brain; that at doses sufficient to produce nicotinic receptor blockade, chlorisondamine acts in a pharmacologically selective manner; and that chronic central blockade is not accompanied by long-term peripheral ganglionic blockade.

Blockade of nicotinic receptor-mediated release of dopamine from striatal synaptosomes by chlorisondamine administered in vivo

1. The chronic nicotinic blockade produced following in vivo administration of chlorisondamine was investigated in vitro. Nicotine-induced [3H]-dopamine release from striatal synaptosomes was used as a measure of central nicotinic receptor function. 2. In synaptosomal preparations from rats pretreated with a single administration of chlorisondamine (10 mg kg-1, s.c.), 1, 7, 21, 42, 63 or 84 days before they were killed, responses to (-)-nicotine (10(-6) M) were blocked. 3. In vivo administration of chlorisondamine (10 mg kg-1, s.c.), 7 days before rats were killed, produced a nicotinic blockade in vitro that was insurmountable even with a high concentration of (-)-nicotine (10(-4) M). 4. Both in vitro and in vivo administration of chlorisondamine blocked nicotinic responses to acetylcholine (10(-4) M). In contrast, neither in vitro nor in vivo administration of chlorisondamine reduced [3H]-dopamine release induced by high K+ (20 x 10(-3) M) or (+)-amphetamine (10(-6) M). 5. Nicotinic blockade resulting from in vitro administration of chlorisondamine (10(-5) M) recovered partially after 60 min wash-out, and completely by 90 min. In contrast, no recovery was seen in synaptosomes prepared from rats pretreated with chlorisondamine (10 mg kg-1, s.c.) in vivo. 6. Thus, in vivo treatment with chlorisondamine results in a quasi-irreversible, insurmountable block of CNS nicotinic receptors. The persistence of this block ex vivo indicates that physical trapping by the blood brain barrier is not solely responsible for the persistent blockade seen in vivo. The resistance of this blockade to prolonged in vitro wash-out suggests that the underlying mechanism differs from that associated with in vitro administration.

Blockade of nicotinic receptor-mediated release of dopamine from striatal synaptosomes by chlorisondamine and other nicotinic antagonists administered in vitro

1. Central nicotinic receptor function examined in vitro, by measuring nicotine-induced [3H]-dopamine release from rat striatal synaptosomes. 2. The agonists (-)-nicotine, acetylcholine, 1,1-dimethyl-4-phenylpiperazinium (DMPP) and cytisine (10(-7)-10(-4) M) all increased [3H]-dopamine release in a concentration-dependent manner. Cytisine did not produce a full agonist response, compared to the other agonists. 3. The actions of nicotine, acetylcholine and cytisine were largely dependent on external Ca2+. In contrast, DMPP (10(-5) and 10(-4) M) evoked a marked release of [3H]-dopamine even in the absence of Ca2+. Nevertheless, in the presence of external Ca2+, responses to DMPP were completely blocked by the nicotinic antagonists chlorisondamine and mecamylamine (5 x 10(-5) M); in the absence of external Ca2+, blockade was only partial. 4. Chlorisondamine, mecamylamine and dihydro-beta-erythroidine (10(-8)-10(-4) M) produced a concentration-dependent block of responses to nicotine (10(-6) M). Approximate IC50 values were 1.6, 0.3 and 0.2 x 10(-6), respectively. Chlorisondamine and mecamylamine blocked responses to nicotine (10(-7)-10(-4) M) insurmountably, whereas dihydro-beta-erythroidine behaved in a surmountable fashion. 5. The occurrence of use-dependent block was tested by briefly pre-exposing the synaptosomes to nicotine during superfusion with antagonist, and determining the response to a subsequent nicotine application. Consistent with a possible channel blocking action, brief pre-exposure to agonist increased the antagonist potency of chlorisondamine (approximately 25 fold). No significant use-dependent block was detected with dihydro-beta-erythroidine.

Nicotinic systems and cognitive function

Nicotinic acetylcholine receptors have been found to be important for maintaining optimal performance on a variety of cognitive tasks. In humans, nicotine-induced improvement of rapid information processing is particularly well documented. In experimental animals nicotine has been found to improve learning and memory on a variety of tasks, while the nicotinic antagonist mecamylamine has been found to impair memory performance. Nicotine has been found to be effective in attenuating memory deficits resulting from lesions of the septohippocampal pathway or aging in experimental animals. Nicotinic receptors are decreased in the cortex of patients with Alzheimer's disease. Preliminary studies have found that some aspects of the cognitive deficit in Alzheimer's disease can be attenuated by nicotine. Nicotine may prove to be useful therapeutic treatment for this and other types of dementia.

Behavioral effects of acute p-xylene inhalation in rats: autoshaping, motor activity, and reversal learning

p-Xylene is a ubiquitous solvent and chemical precursor used in industry, gasoline, and household products. While the population at risk for exposure is thus quite large, little is known about its neurobehavioral effects. To evaluate the possibility that p-xylene affects cognitive behavior, male Long-Evans hooded rats inhaled p-xylene at concentrations of 0 or 1600 ppm, 4 hr per day for 1 to 5 days, and were evaluated after exposure on two learning tasks and a test of motor activity. Autoshaping was carried out across 5 successive days with p-xylene exposure in the morning followed by testing in the afternoon. For this test, the retraction of a single response lever on a variable-time 35-sec schedule was followed by delivery of a food pellet. When the force required to depress the lever was low (0.10 N), response acquisition was faster in animals having inhaled 1600 ppm p-xylene than in air-exposed controls. When the force was increased to 0.20 N, however, p-xylene-exposed rats acquired the response no faster than controls. In contrast, inhaled p-xylene at 1600 ppm suppressed response rates in an automaintained reversal learning paradigm without affecting reversal rate. Studies of motor activity showed that while vertically-directed activity was unaffected by p-xylene, horizontally-directed activity was increased by about 30% for the first 15 min of each daily 25-min test.(ABSTRACT TRUNCATED AT 250 WORDS)

Nicotine impairs acquisition of radial maze performance in rats

The effects of nicotine (NIC) and scopolamine (SCOP) on radial maze acquisition were examined using an 8-arm radial maze. In Experiment 1, food-deprived Sprague-Dawley rats were trained to eat food pellets located at the ends of each arm of the radial maze without repeating arm choices. Both NIC (0.45 mg/kg, SC) and SCOP (0.25 mg/kg, IP) impaired acquisition when they were administered before, but not after the daily training sessions. Experiment 2 examined the effect of nicotine on working and reference memory in rats trained to a criterion of 3 correct choices out of the first 4 choices with only 4 of the 8 arms baited. NIC (0.1-0.45 mg/kg) had no effect on working memory (reentry into baited arms) or reference memory (entry into unbaited arms) errors. It is concluded that NIC impairs processes involved in the acquisition but not maintenance of radial maze performance. Neither NIC nor SCOP affects post-training consolidation processes.