The effects of calcium channel antagonists on short- and long-term retention in mice using spontaneous alternation behavior

The effect of calcium channel antagonists (CCA's) on working and reference memory in mice was studied using spontaneous alternation (SA) behavior in a T maze. Mice were given either one or four forced trials to either the right or the left arm on the training session (T1) followed by a free choice test (T2) at varying intervals after the initial trial. Untreated animals given one forced trial exhibited significantly greater levels of SA than chance at all delay intervals out to 20 min but not at 30, 60, or 180 min. Animals given four forced trials showed significant levels of SA 24 h after exposure but not at 72 h. Additional groups of mice were treated with amlodipine, nimodipine, diltiazem, and verapamil 1 h before T1. Mice given one forced trial were tested 30, 60, or 180 min after T1 while mice given four forced trials were tested 72 h after T1. Results showed that all of the CCA's except verapamil produced significant SA at the 30-min interval and nimodipine and diltiazem also significantly increased SA at the 60-min-delay interval. No significant effects were observed at the 180-min test. In the four trial groups, all of the CCA's with the exception of verapamil produced significant levels of SA at the 72-h interval. These results indicate that representative CCA's from both the dihydropyridine and the benzothiazapine classes can facilitate both short- and long-interval SA, thereby providing further confirmation that CCA's can enhance memory processing in young animals.

Pharmacological blockade of brain alpha1-adrenoceptors as measured by ex vivo [3H]prazosin binding is correlated with behavioral immobility

The present studies examined the relationship between the blockade of central alpha1-adrenoceptors, as measured by ex vivo binding of [3H]prazosin in the cerebral cortex and the inhibition of behavioral activation to a mildly novel environment (cage change). It was found that intraventricular (i.v.t.) terazosin, a saline-soluble alpha1-adrenoceptor antagonist, dose dependently inhibited both ex vivo cortical binding and behavioral activation and that there was a highly significant positive correlation between the two with a slope near unity. Prazosin, a nonsaline soluble antagonist which had to be given intraperitoneally (i.p.), was much less potent at blocking both behavioral activity and cortical ex vivo binding, although it blocked ex vivo binding in the lung, indicating that it was effective peripherally but did not readily enter the brain. Despite this, however, the inhibition of cortical binding and behavioral activation that i.p. prazosin did produce were highly correlated with each other and had a slope near unity as with terazosin, whereas the more potent inhibition of lung binding was less well correlated with behavioral inhibition and had a slope significantly less than one. These results confirm our earlier studies, which have shown that alpha1-adrenoceptor activity is essential for gross and fine motor behavior in the mouse and that prazosin, which is used extensively in behavioral research, has difficulty entering the mouse brain.

Pharmacological evidence for the role of central alpha 1B-adrenoceptors in the motor activity and spontaneous movement of mice

Central alpha 1-noradrenergic neurotransmission has been shown to be an important complement of dopaminergic transmission in the control of motor activity but the identity of the responsible alpha 1 receptor subtype has not yet been identified. This was investigated in the present experiment by measuring the effects of intraventricular administration of a series of alpha 1 antagonists varying in affinities for the three known receptor subtypes--1a, 1b and 1d--on active behavior in mice in response to a cage change. It was found that the potency of the drugs to block both gross and small movements correlated highly with published affinities for the cloned 1b receptor but not for those of either the cloned 1a or 1d receptors. It is concluded that central alpha 1B receptors are critically involved in the mediation of the (nor)adrenergic influence on active behavior, a finding which has implications for basic and clinical research in both movement and mood disorders.

Calcium channel antagonists enhance retention of passive avoidance and maze learning in mice

Although a number of studies have shown that treatment with calcium channel antagonists (CCAs) can ameliorate impairments in learning and memory in aged animals, evidence for a general nootropic effect of CCAs in neurologically normal young adult animals is ambiguous. This study attempts to resolve some of this ambiguity by comparing the effects of several CCAs on retention of passive avoidance learning and acquisition and retention of appetitively motivated spatial discrimination learning in young adult mice. Animals were trained in a step through passive avoidance apparatus and, immediately after training, injected subcutaneously with different doses of nimodipine, nifedipine, amlodipine, flunarazine, diltiazem, or verapamil. Retention was tested 24 h after training. In the maze-learning task mice were treated with the same doses of the aforementioned CCAs immediately after a brief training session in a linear maze and retention was tested 24 h after training. The most effective dose of each agent in the maze-retention experiment was administered to additional groups of animals 1 h prior to training to determine the effects of CCAs on acquisition processes. The effects of central administration of CCAs were examined by intracerebroventricular injection of different doses of amlodipine immediately after passive avoidance training. Results showed (1) all peripherally administered drugs except verapamil facilitated retention of passive avoidance training in a dose-dependent manner, (2) all drugs dose dependently facilitated retention of linear maze learning, (3) all doses of the drugs (except verapamil) which facilitated maze retention also facilitated maze learning, and (4) central administration of the dihydropyridine amlodipine produced a dose-dependent facilitation of the retention of passive avoidance learning. These data indicate that drugs which block calcium channels can enhance retention of two different types of learning in mice.

Enoxaparin, a low molecular weight heparin decreases infarct size and improves sensorimotor function in a rat model of focal cerebral ischemia

Possible neuroprotective effects of the low molecular weight heparin (LMWH) enoxaparin sodium (Lovenox) were evaluated in a rat model of focal ischemia. Male Sprague-Dawley rats were subjected to 90 min of occlusion of the right middle cerebral artery using the intraluminal suture method. Enoxaparin at doses of 0, 10 or 15 mg/kg was administered to groups of rats 1, 8, 24 and 32 h after artery occlusion. Motor impairment was evaluated by performance on the traverse beam and accelerating rotarod tests. Animals were sacrificed 48 h after occlusion and brain sections were stained with 2% 2,3,5-triphenyltetrazolium chloride for determination of infarct volume. Forty percent of the rats receiving 15 mg/kg enoxaparin died as a result of intracranial hemorrhage. Untreated rats exhibited large lesions involving the caudate putamen and much of the cortex. In enoxaparin - treated rats the damage was mainly confined to the caudate putamen. The sensorimotor behavior of the 10 mg/kg enoxaparin group was significantly better than that of untreated animals. Motor performance of the survivors in the 15 mg/kg group was poor due to hypoactivity and weakness resulting from excessive bleeding. These results suggest that LMWH may have a neuroprotective function.

Chronic administration of the Ca(2+) channel blocker amlodipine facilitates learning and memory in mice

Acute administration of the Ca(2+) channel antagonist amlodipine has been shown to facilitate memory for several types of learning in adult animals and to improve retention in aging mice. This study reports three experiments investigating the effect of chronic amlodipine treatment on retention in mice. In the first experiment, groups of mice were treated with either amlodipine or vehicle once a day for 14 days prior to training on a spatial discrimination task. Immediately after training, animals were given a single dose of amlodipine or the vehicle and tested for retention 24 h later. Both groups showed facilitated retention, thereby demonstrating that chronic amlodipine treatment did not produce desensitization to the facilitating effects of a post training treatment. In the second experiment, chronic treatments were administered once daily for 14 days beginning 24 h after training on one-way active avoidance and retention was tested on day 15. Results showed that chronic amlodipine attenuated spontaneous forgetting, but surprisingly, a similar enhancement could be achieved by a single treatment administered 1 day after training. In the third experiment, amlodipine was given either before or immediately after 10 daily training sessions in the one-way active avoidance task. Results showed that chronic treatment accelerated rate of learning. These findings confirm the memory facilitating properties of amlodipine under conditions of chronic drug administration.

Brain alpha 1-adrenergic neurotransmission is necessary for behavioral activation to environmental change in mice

Terazosin, a water-soluble alpha 1 antagonist that can be administered in high doses intraventricularly was used to study the relationship between brain alpha 1 adrenoceptor neurotransmission and behavioral activation in the mouse. The antagonist was found to produce a dose-dependent, complete inhibition of motor activity and catalepsy which were reversed preferentially by coinfusion of an alpha 1 agonist (phenylephrine) compared to a D1 (SKF38393) or a D2 agonist, (quinpirole). Blockade of central beta-1 (betaxolol), alpha-2 (RX821002) or beta-2 (ICI 118551) adrenoceptors had smaller or non-significant effects. Terazosin's selectivity for alpha 1 receptors versus dopaminergic receptors was verified under the present conditions by showing that the intraventricularly administered antagonist protected striatal and cerebral cortical alpha 1 receptors but not striatal or cortical D1 receptors from in vivo alkylation by N-ethoxycarbonyl-2-ethoxy-1, 2-dihydroxyquinoline. That its effect was due to blockade of brain rather than peripheral receptors was shown by the finding that intraperitoneal doses of terazosin three to 66 times greater than the maximal intraventricular dose produced less behavioral inhibition. Intraventricular terazosin also produced hypothermia and a reduced respiratory rate suggestive of a reduced sympathetic outflow. However, external heat did not affect the inactivity, and captopril, a hypotensive agent, did not mimic it. Terazosin did not impair performance on a horizontal wire test or the ability to make co-ordinated movements in a swim test suggesting that its activity-reducing effect was not due to sedation and may have a motivational or sensory gating component. It is concluded that central alpha 1-noradrenergic neurotransmission is required for behavioral activation to environmental change in the mouse and may operate on sensorimotor and motivational processes.

Alpha-1-noradrenergic neurotransmission, corticosterone, and behavioral depression

BACKGROUND

Impaired brain alpha-1 noradrenergic neurotransmission has been implicated in some of the symptoms of depressive illness but has been difficult to investigate experimentally because of the insensitivity of current animal models of depression. The present experiment addressed this problem by examining the effects of pharmacologic blockade and corticosteroid-induced desensitization of alpha-1 receptors on two newer, more sensitive models in mice: the inhibition of nest-leaving and the tail suspension tests (TST).

METHODS

Male mice were administered either prazosin, betaxolol, atipamezole, corticosterone, or repeated restraint stress prior to measurement of either nest-leaving or TST. General behavioral function was assessed in horizontal wire, swim, and latency to escape footshock tests.

RESULTS

Prazosin increased depressive behavior in the nest-leaving and TSTs, whereas corticosterone and restraint stress did so only in the more sensitive nest-leaving test. Betaxolol also reduced nest-leaving, suggestive of an alpha-1 beta-1 receptor synergy. The effects of these agents could not be attributed to hypotension, sedation, or general behavioral impairment.

CONCLUSIONS

The fact that a reduction in alpha-1 noradrenergic neurotransmission increases depressive behavior, coupled with the fact that this change can result from elevated corticosteroid secretion, provides further support for a role of this factor in depressive illness. As not all alpha-1 functions are reduced in depression, it is likely that only a subgroup or specific locality of alpha-1 receptors are affected.

Greater behavioral effects of stress in immature as compared to mature male mice

The effect of sexual maturity on behavioral effects of stress was examined in male mice. Immature (4-week-old) or mature (8-week-old) animals were subjected to either social stress (exposure to an isolated adult male) or restraint stress for 5 days and examined for body weight, food intake, or plus-maze behavior. Social stress reduced food intake, body weight, and open-arm entries in 4-week-old but not 8-week-old mice. Restraint reduced body weight in 4-week-old but not 8-week-old mice. It is concluded that immature male mice show greater behavioral disturbances after stress than their mature counterparts. The findings are in agreement with much anecdotal evidence that children are more vulnerable to stress than adults.

The Effect of Stress on Spontaneous Nest Leaving Behavior in the Mouse: An Improved Model of Stress-Induced Behavioral Pathology

The present experiments were conducted to develop a more sensitive and reliable model of stress-induced behavioral pathology in the mouse. Male mice were housed singly in nest cages connected to either a circular tunnel, a recreational cage or a large box with food foraging apparatus. Spontaneous nocturnal out of nest activity or food foraging behavior in these environments was continuously monitored for a two week period during which time the effects of stress were examined. It was found that both repeated restraint and aggression stress markedly and persistently reduced out of nest nocturnal activity or food foraging behavior in all 3 environments but did not alter activity in a novel open field or plus maze or food or saccharin intake in the nest cage. In a preliminary experiment the reduction in out of nest activity by stress was attenuated by prior chronic treatment with the antidepressant, desmethylimipramine. Plasma corticosterone was elevated immediately after aggression stress but reduced 5 hr after chronic aggression stress. The reduction in activity did not appear the result of increased anxiety as measured by spontaneous risk assessment behavior in the nest. It is concluded that the decrease in out of nest activity after stress in the present studies models a withdrawn behavioral state and may be due to either or both a decrease in appetitive motivation to leave the nest or an increased aversion to the external environment which does not apparently involve anxiety.

Blockade of effect of stress on risk assessment behavior in mice by a beta-1 adrenoceptor antagonist

Previous studies have shown that acute stress impairs risk assessment behavior in mice. The present study was undertaken to determine the role of beta adrenoceptors, which are known to be stimulated by stress, in this effect. Mice were treated with either a beta-1 antagonist, betaxolol, a beta-2 antagonist, ICI 118551, an alpha-1 antagonist, prazosin, or an alpha-2 antagonist, yohimbine, and 30 min later were subjected to a 1-h session of restraint stress. Thirty minutes after the stress the animals were tested for the entry latency, number of headpokes prior to entry, and the path of entry into a white open field from a small dark box. In agreement with previous findings, stress was found to markedly reduce risk assessment behaviors as reflected by a reduced entry latency, a reduced number of headpokes and a changed entry path from wall hugging to central entry. Betaxolol was found to prevent all of the above effects of stress dose dependently, whereas ICI 118551, prazosin, and yohimbine had no reversal effects. It is concluded that beta-1 receptor activation and possibly brain glycogen depletion is involved in the effects of stress on risk assessment behavior.

Delayed arousal from anesthesia: a further similarity between stress and beta-1 adrenoceptor blockade

The present studies investigated the role of beta adrenergic receptors in mediating arousal from anesthesia and the effects of stress on this process. In support of previous findings by others, it was found that blockade of beta-1 and beta-2 receptors by propranolol delayed arousal from halothane anesthesia and that this effect was attributable to blockade of beta-1 receptors because it was duplicated by betaxolol but not by ICI 118,551. Restraint stress also produced a delay in arousal from both halothane and hexobarbital anesthesia. This effect, which was observed at 0.5 but not 24 h after the stress, could not be explained by a stress-induced alteration in the metabolism of the anesthetic, as no difference in brain concentration of hexobarbital was found between stressed and control mice. The parallel effects of beta-1 blockade and stress further supports the hypothesis that stress produces an impairment in function at either the beta-1 receptor or some process coupled to this receptor.

Pavlovian fear conditioning in mice anesthetized with halothane

Pavlovian fear conditioning was employed to investigate learning during general anesthesia. Mice were given three CS-UCS presentations while anesthetized with halothane. The CS was a 10-s tone and the UCS a 0.4-mA shock delivered intramuscularly to the hindlimbs via needle electrodes. Anesthetized control groups received either CS only, UCS only, or CS followed by a 3-min delayed UCS. Strength of fear conditioning was assessed by measuring duration of suppression of drinking induced by tone presentation in a test session conducted 24 h after training. Results showed that mice trained under anesthesia exhibited a significant amount of conditioned suppression relative to the anesthetized control groups. These results show that Pavlovian fear conditioning can occur under halothane anesthesia.

Acute stress disrupts risk assessment behavior in mice

The effects of stress on risk assessment behavior in mice were studied by examining latency to emerge from a safe compartment into a large, well-lit open field. In the first experiment different groups of mice were exposed for 1 h to tube restraint, fixed interval 2-min foot shock, or attack by an aggressive conspecific. Nonstressed controls were left undisturbed in the home cage. Thirty minutes following stress animals were placed in the safe compartment and latency to emerge was recorded. Results showed all of the stressed groups exhibited significantly faster emergence latencies than nonstressed controls. In the second experiment the duration of this effect was examined by testing different groups at varying intervals following tube restraint stress. Results showed that mice tested 0.5 and 1 h following stress exhibited short entry latencies and reduced head poke responses. Performance had returned to nonstress levels 3 h after stress. These data suggest that stress reduces caution by disrupting risk assessment behaviors.

Potentiation by propranolol of stress-induced changes in passive avoidance and open-field emergence tests in mice

Noradrenergic and serotonergic systems are known to be stimulated during various forms of stress. The present study examined the effect of the beta-adrenergic serotonin1A receptor blocker propranolol on the ability of stress to elicit behavioral inhibition in mice. Mice were given the drug before immobilization or tube-restraint stress, and then were tested for either passive avoidance performance or time to emerge into an open field. Propranolol markedly potentiated stress-induced increases in latency in both of these tests, suggesting that it exacerbated reactions to stress. These results agree with previous data indicating that under certain conditions, propranolol can potentiate the effects of stress in rodents. The results support the hypothesis that the response of the noradrenergic and/or serotonergic systems to stress may have anxiolytic or antistress effects.

Beta adrenoceptor blockade mimics effects of stress on motor activity in mice

Reduced central noradrenergic function has been implicated as a factor in reduced behavioral activity after stress. The present studies examined the role of reduced beta adrenergic neurotransmission in mediating this effect. This was done by testing the ability of beta receptor antagonists to mimic the behavioral actions of stress. Mice were subjected to stress or given various beta antagonists and tested for swimming behavior, locomotor activity, or grooming behavior. As previously reported, stress reduced swimming and locomotor activity and increased grooming. Both the nonselective antagonist, l-propranolol, and the beta-1 selective antagonist, betaxolol, produced the same effects as stress on all three measures. A beta-2 selective antagonist, ICI 118,551, was effective only on swimming, whereas a membrane stabilizing agent, d-propranolol, was effective only on grooming behavior. The peripherally active beta-1 antagonist, atenolol, was not effective on any measure. The nonspecific dopaminergic receptor blocker, fluphenazine, reduced locomotion but tended also to reduce grooming. The results indicate that blockade of beta-1 receptors in the CNS selectively mimics the action of stress on gross motor activity in mice and, along with previous data, suggest that stress leads to a relative deficiency in central beta-1 noradrenergic neurotransmission in these animals.

The 5-HT1A agonist tandospirone disrupts retention but not acquisition of active avoidance learning

To determine the effects of the 5-HT1A partial agonist tandospirone on acquisition and retention, mice were trained on a one-way active avoidance task and tested for retention 24 h later. Groups of mice were injected with either saline or 1, 5, or 10 mg/kg tandospirone 30 min before acquisition. Training was complete when animals achieved a criterion of five avoidances in a block of six trials. Results showed that tandospirone did not alter the rate of acquisition of the avoidance response, but retention was significantly disrupted by the 1- and 5-mg/kg doses. These findings confirm previous suggestions that 5-HT1A agonists can cause anterograde amnesia.

Acute but not chronic activation of the NMDA-coupled glycine receptor with D-cycloserine facilitates learning and retention

The memory-enhancing potential of D-cycloserine (cycloserine) a partial agonist at the glycine recognition site on the NMDA receptor, was evaluated in mice using a thirst-motivated linear maze learning task. Immediate acute post-training injections (10, 20 and 80 mg/kg) significantly improved retention relative to vehicle-injected controls. Retention was also facilitated if cycloserine (3 and 10 mg/kg but not 20 or 40 mg/kg) was administered 20 min before the retention test. Acquisition of the habit was accelerated if cycloserine (3 mg/kg) was injected 20 min before the training session. Acute post-training injections failed to facilitate retention if mice were pretreated with cycloserine (3 mg/kg) b.i.d. for 15 days before training on the maze. These results indicate that acute cycloserine administration can enhance consolidation and retrieval of memory but that desensitization may occur with chronic exposure to the drug.

Effect of the calcium channel blocker amlodipine on memory in mice

Five experiments were performed to investigate the effects of amlodipine, a calcium channel antagonist of the 1,4-dihydropyridine class, on consolidation and retrieval of memory in mice. In a single-trial passive avoidance task, amlodipine was administered pretraining, posttraining, or pretesting. Results of temporal and dose-response studies showed that memory enhancement (significant increase in step-through latency) occurred when amlodipine (5, 7, 9, 15, and 30 mg/kg) was given either immediately post-training or (15 mg/kg) 15 min pretesting. Using a conditioned emotional response task, tone was paired with shock using Pavlovian conditioning procedures. Strength of conditioning was assessed by measuring suppression of drinking in the presence of a tone. Amlodipine (7 mg/kg) given immediately following both high- and low-intensity shock significantly enhanced conditioned suppression. In the third experiment thirsty mice were trained on a spatial discrimination task in a linear maze. Correct choices were reinforced with liquid reinforcement. Amlodipine (10 mg/kg) injected immediately after the training session produced a significant enhancement of discrimination performance on a 24-h retention test. In the fourth experiment mice were given 25 training trials in a two-way active avoidance task and were treated with either amlodipine (10 mg/kg) or saline after training. Amlodipine-treated mice made significantly more avoidances on the test session than control animals. The final experiment demonstrated that the deficit in approach-avoidance behavior seen in 18-month-old mice could be reversed by amlodipine treatment after the training session. These studies suggest that amlodipine can facilitate memory consolidation and retrieval.

Selective dorsal rhizotomy: outcome and complications in treating spastic cerebral palsy

Selective dorsal rhizotomy has shown great promise as a treatment for the functional disabilities and deforming hypertonia of spastic cerebral palsy. At New York University Medical Center, 200 children underwent this procedure between 1986 and 1990. All groups, whether walkers, crawlers, or nonlocomotors, showed improvement in the tone and range of most muscles tested. Half of these patients experienced complications. Thirty-five of these were serious and included bronchospasm (5.5%), aspiration pneumonia (3.5%), urinary retention (7%), and sensory loss (2%). There are, however, clear indications that warn of these complications; monitoring and prophylactic treatment can minimize their effects, and the possibility of such problems is more than offset by the proven benefits of this operative procedure.

5-HT1A receptor agonists induce anterograde amnesia in mice through a postsynaptic mechanism

The effect of the 5-HT1A receptor partial agonist tandospirone on memory was investigated in mice using a single trial, step-through passive avoidance task. Tandospirone disrupted performance in a dose-dependent manner when administered before the training trial but not when injected immediately post-training. The pre-training effect was not the result of reduced responsiveness to foot shock because tandospirone did not alter current threshold intensity to elicit flinch, run and vocalization responses. The performance deficit was alleviated by treatment with d-amphetamine prior to the retention test. The memory impairment by tandospirone was mimicked by the 5-HT1A receptor agonist 8-OH-DPAT (8-hydroxy-dipropylaminotetralin HBr) and blocked by the 5-HT1A receptor antagonist BMY7378 (8-[2-[4-(2-methoxyphenyl)-1-piperazinyl]ethyl]-8-azaspirol-[4]- decane-7,9-dione). BMY7378 alone was ineffective. Treatment with the 5-HT synthesis inhibitor PCPA (parachlorophenylalanine) resulted in apparent enhancement rather than disruption of the avoidance behavior. However, the anterograde amnestic effects of tandospirone and 8-OH-DPAT were not affected by PCPA, and lack of interactions between PCPA and the 5-HT1A agonists revealed in the statistical analyses indicated that the effects of PCPA were not mediated by 5-HT1A receptors. It is concluded that 5-HT1A receptor agonists and partial agonists produce a reversible anterograde amnesia that is mediated by postsynaptic 5-HT1A receptors.

5-HT1A agonists disrupt memory of fear conditioning in mice

A series of experiments was carried out to analyze the effects of the 5-HT1A agonists tandospirone or buspirone on the retention of fear conditioning in mice. Fear was produced by pairing tone and shock in a conditioned emotional response (CER) paradigm and strength of conditioning was assessed by measuring suppression of drinking in presence of tone. Fear conditioning was disrupted if tandospirone and buspirone were administered before the conditioning session but not before the test trial. Diazepam disrupted conditioning at both times. Tandospirone did not disrupt performance if conditioning was tested 1 hr rather than 24 hr after training, suggesting that disrupted memory rather than impaired acquisition was responsible for the deficit. The effect of tandospirone on fear conditioning could be reversed by administration of d-amphetamine prior to the retention test, which suggests that information was stored but is inaccessible to normal retrieval cues. Tandospirone and buspirone also retarded extinction, a clear indication that the disruption caused by these drugs is unrelated to their anxiolytic action.

Effect of propofol on memory in mice

The amnestic effects of the intravenous hypnotic anesthetic agent 2,6-diisopropylphenol (propofol; Diprivan) were studied in a single-trial passive avoidance task. Mice were injected with propofol 10 min before or immediately after training. Memory was impaired in a dose-dependent fashion when the anesthetic was administered before learning, but no amnesia was apparent with posttraining injections. Examination of the acquisition of passive avoidance using a multitrial task showed that propofol-treated mice learned the response normally but forgot the learning significantly faster than vehicle-treated controls. The anterograde amnesia was not the result of state-dependent learning. Propofol also disrupted extinction of fear conditioning when the anesthetic was given during the extinction session. Propofol-induced amnesia could be attenuated by amphetamine (1 mg/kg) injected 30 min before the retention test.

Halothane anesthesia causes state-dependent retrieval failure in mice

Effects of exposure to halothane on memory processing was studied using single-trial inhibitory avoidance learning to measure retention. Mice were anesthetized with halothane either before training, immediately after training, or both before training and before testing. Results showed that memory was not impaired by posttraining halothane exposure, indicating that the anesthetic does not cause retrograde amnesia. Mice trained after recovery from halothane showed a robust memory loss 24 h later. This deficit could be alleviated by reexposure to the anesthetic before the retention test. Mice given multiple training trials following recovery from the anesthetic showed a normal rate of learning when compared with controls, but deficient retention. This indicates that the performance deficit was the result of impaired retention (anterograde amnesia) rather than disrupted acquisition. Anterograde amnesia occurred when training was delayed up to 2 h after recovery from anesthesia. These findings indicate that the memory impairment following halothane anesthesia is the result of a state-dependent retrieval failure.

Milacemide enhances memory storage and alleviates spontaneous forgetting in mice

The objective of this study was to evaluate the effectiveness of milacemide as a memory-enhancing drug in mice. Experiment 1 showed that forgetting of active avoidance learning produced by a 14-day training to test delay could be alleviated by milacemide (10 mg/kg) administered before the retention test. Experiment 2 demonstrated that the same dose of milacemide could also attenuate spontaneous forgetting of passive avoidance learning, thereby ruling out nonspecific effects as an explanation for the enhancement of performance following pretesting drug administration. A third experiment showed that the facilitation of retrieval induced by milacemide could be blocked by the NMDA receptor antagonist AP-7, suggesting that the effects of milacemide on memory may be mediated by NMDA receptor activation. A final experiment demonstrated that retention was improved when milacemide was administered immediately following active avoidance training, indicating that the drug can also facilitate remembering by its actions on consolidation and storage processes.

Prenatal treatment with a selective D1 receptor agonist (SKF 38393) alters adult [3H]paroxetine binding and dopamine and serotonin behavioral sensitivity

We have previously shown that the development of serotonin neurons can be affected by various pharmacological agents acting on the serotonin system. Receptor stimulation by high doses of 5-methoxytryptamine (5-MT) causes increased outgrowth, through release of an astroglial growth factor, while a low concentration of 5-MT has a direct inhibitory effect on neuronal outgrowth. Since 5-MT is known to be a release-regulating autoreceptor agonist, the present study was aimed at testing the hypothesis that inhibition of serotonin release causes the inhibition of outgrowth. We used the D1 receptor agonist SKF 38393 as an inhibitor of serotonin release. Pregnant Sprague-Dawley rats were treated with SKF 38393 (1 mg/kg; subcutaneously) from gestational day 12 until parturition. Development of serotonin terminal outgrowth was evaluated in the offspring using the selective uptake marker [3H]paroxetine in brainstem and frontal cortex. In saline and SKF 38393 treated animals, the developmental pattern in the frontal cortex showed the highest terminal density at day 60 and a return to normal by day 90, with no statistically significant differences between the groups. Conversely, in the brainstem, [3H]paroxetine binding developed normally until postnatal day 90, when the SKF 38393 pretreated animals showed only 58% of the binding observed in saline animals. In a fixed interval responding task, given at day 90, both dopamine and serotonin receptor systems have significantly decreased sensitively after the SKF 38393 pretreatment. In conclusion, our results show that the inhibitory effects of serotonin on the growth of serotonin neurons, may be through inhibition of neurotransmitter release. Moreover, we propose a means by which serotonin and dopamine systems could be interdependent during development.

Persistence of retrieval enhancement by amphetamine following scopolamine-induced amnesia

Little information is available on the permanence of pharmacologically-induced retrieval enhancement following amnesia. This was studied by comparing the rate of forgetting of a memory reactivated by d-amphetamine after amnesia with spontaneous forgetting of undisturbed fear conditioning. Mice were treated with either saline or scopolamine before conditioning and retention was tested three days later. Scopolamine-treated mice received either saline or amphetamine before testing while the saline controls received a second saline injection. The scopolamine-saline group exhibited robust amnesia, whereas both saline-saline and scopolamine-amphetamine groups showed good retention. To test the persistence of these effects mice in the three groups were subdivided and given a second retention test either 1 day, 1 week or 1 month after the first test. Amphetamine was not administered before the second test. The scopolamine-saline mice continued to exhibit amnesia for up to 1 month while the scopolamine-amphetamine and saline-saline groups continued to show strong memory with only a modest decrement in performance by 1 month after the first test. These results show that amphetamine results in a permanent recovery from scopolamine amnesia.

Strength of scopolamine-induced amnesia as a function of time between training and testing

Variations in the strength of scopolamine-induced amnesia as a function of age of the habit were studied in Swiss Webster mice. Animals were trained in an active avoidance task to a criterion of 9/10 avoidances and immediately following training injected with scopolamine hydrochloride (1.0 mg/kg) or saline. Retention of the avoidance learning was evaluated by testing different groups of animals 1, 3, 7, 10, 14, and 28 days following training. The retention test consisted of five trials in which the CS but not the UCS was presented. Results indicated that saline-treated mice exhibited near-perfect retention up to 14 days post-training with forgetting beginning to be apparent at 28 days. Scopolamine treatment produced strong amnesia in animals tested 1 and 3 days post-training but normal retention in animals tested 7 and 10 days after learning. The amnesia abruptly reappeared at 14 days after which time it remained stable. The marked similarity of the scopolamine retention curve to changes in the strength of memory of discrimination learning in undertrained rats reported by Deutsch suggested that scopolamine resulted in the storage of a weak memory of the avoidance response. To explore this idea further we trained mice to a criterion (4/5) which would result in a weak avoidance response and tested different groups 1, 3, 10, 14, and 28 days following learning. Results showed that strength of the memory of avoidance learning increased up to 10 days and then decreased abruptly at 14 days thus replicating the general shape of the retention curve produced by injecting scopolamine following strong training. These data suggest that scopolamine disrupts processes essential for the formation of durable memories.

Alleviation of scopolamine amnesia by different retrieval enhancing treatments

Mice were trained in a one-way active avoidance task to a criterion of 9/10 avoidances. Immediately following training they were injected with scopolamine hydrochloride (1 mg/kg SC) or with saline. Retention was assessed 3 days after training by 5 test trials on which the UCS was not present. Thirty min prior to the test, groups were injected with different doses of arecoline, d-amphetamine sulphate or with saline. Other scopolamine-treated mice were exposed to the CS or the UCS 24 hr prior to the test. The scopolamine-induced amnesia was attenuated by both 0.5 and 1.0 mg/kg arecoline and by 2.0 mg/kg d-amphetamine. Retention was also improved by exposure to the CS and the UCS. These data show that scopolamine amnesia can be alleviated by treatments which activate retrieval processes.

Attenuation of forgetting by pharmacological stimulation of aminergic neurotransmitter systems

Mice were trained in one-way active avoidance to a criterion of 3/4 avoidances and tested under extinction conditions one week later when substantial forgetting had occurred. Thirty min prior to testing animals were injected with either saline or different doses of drugs which activate the noradrenergic (phenylephrine, salbutamol, clonidine) dopaminergic (L-dopa(Sinemet) transdihydrolisuride, apomorphine) and serotonergic (fluoxetine, 5-methoxy DMT) neurotransmitter systems. Results showed that all agents alleviated forgetting in a dose dependent fashion. Untrained mice treated with the most effective dose of representative drugs from each class did not exhibit avoidance behavior at testing indicating that the improved performance of trained animals was probably not the result of increased activity or other non-memorial effects of the drugs. It was concluded that pharmacological agents which stimulate monoamine systems may improve memory retrieval by activating a non-specific neural system which controls arousal, attention and motor readiness.

Amphetamine enhances retrieval following diverse sources of forgetting

The generality of amphetamine-induced retrieval enhancement was investigated by determining whether pretest administration could alleviate different types of forgetting. Thirsty mice were punished for licking a water tube following a period of free drinking. Forgetting of the conditioned drink suppression was induced in different groups of animals by; protein synthesis inhibition, cholinergic receptor blockade, inhibition of norepinephrine synthesis, stimulation of serotonin receptors, electroconvulsive shock, a 2.5 month training to test interval and the use of senescent animals with an endogenous memory defect. Thirty min prior to testing mice were injected with either saline or with 2 mg/kg d-amphetamine sulphate. Results showed that amphetamine produced a highly significant improvement in remembering in all of the forgetting treatment groups. It is concluded that amphetamine can alleviate forgetting caused by widely diverse etiologies probably by activating a nonspecific general retrieval system.

Reversal learning in senescent rats

The ability of old (24 months) and young (3 months) male rats to reverse a previously acquired discrimination was compared in 5 experiments. The old rats did not need more trials to learn a position habit in a T-maze to obtain water reward, but required more trials to reverse the position habit. The old rats showed a similar deficit in a second, but not in subsequent reversals of the position habit. In a second experiment, old rats were slower in learning to operate one of two levers in an operant chamber to obtain food reward on a CRF schedule, but by the session prior to reaching criterion for acquisition they showed response rates similar to the young animals. When the rats were required to operate the alternative lever to obtain reward, the young rats emitted 70% of their responses during the first reversal session on the newly-correct lever, but the old rats only 35%. Nevertheless, the groups were similar in the number of sessions required to reach a criterion of 95% of responses on the correct lever. In 3 subsequent reversals, old and young rats did not differ nor were there differences in the number of responses in 4 extinction sessions in the rats which had received reversal training. In experiment 3 with old and young rats which had received only acquisition training, old rats emitted fewer responses than young animals during extinction. From these experiments it was hypothesized that the apparent difficulty of old rats in learning a reversal task was due to the low probability of their emitting spontaneously a novel or previously unrewarded response, and not to a difficulty in forming a new association. This hypothesis was tested in two further experiments in which rats were required to learn a brightness discrimination in a T-maze. Old and young rats which had learned and reversed position habits in the T-maze in experiment 1, did not differ in either acquisition or reversal of the brightness discrimination, suggesting that old rats do not differ from young animals in reversal tasks when the motor response requirements for the task are already within the animals' behavioural repertoire. Consistent with this hypothesis, naive old rats were slower than young rats in acquiring a similar brightness discrimination but did not differ in the reversal task.

Age differences in within-session habituation of exploratory behavior: effects of stimulus complexity

The effects of age on the habituation of exploratory behavior of 8-month- and 28-month-old male C57BL/NNia mice were examined under three different stimulus complexity conditions. Increases in the degree of stimulus complexity resulted in an attenuation of between-session habituation and an initial disruption of within-session habituation by 8-month-old mice. Although increases in stimulus complexity also resulted in an increase in the overall level of exploration by aged mice, stimulus complexity was not found to have a systematic effect on between- or within-session habituation by aged mice. No between-session habituation was observed in aged mice under any of the stimulus complexity conditions. Further, aged mice exhibited significant within-session increases, rather than decreases, in exploration under each stimulus complexity condition. This disruption of within-session habituation in aged mice was found to persist over four daily test sessions. In view of the specific patterns of exploration by aged mice, the disruption of within-session habituation was attributed to age-related differences in reactivity to the arousal-inducing properties of novel stimuli.

Recovery of memory following forgetting induced by depletion of biogenic amines

Following depletion of biogenic amines by reserpine, mice were trained to avoid one compartment of a shuttle box by employing the procedures of Pavlovian fear conditioning. Retention was tested one week later using both an active and a passive measure. A robust amnesia was apparent in reserpine-treated animals on both retention measures. Treatment with the mixed dopamine-serotonin agonist lisuride 30 min prior to the test alleviated the memory loss. Since improved retention in the drug treated mice was indexed by increased response latencies in the passive test and decreased latencies in the active test it is unlikely that the improvement in performance was the result of non-specific effects on activity. The results are consistent with the hypothesis that lisuride treatment before testing facilitates retrieval processes.

Facilitation of memory retrieval by centrally administered catecholamine stimulating agents

Amnesia for inhibitory avoidance learning induced in mice by a post-training injection of the protein synthesis inhibitor anisomycin was alleviated in a dose-dependent fashion by introcerebroventricular injections of D-amphetamine (20 micrograms), dopamine (10, 25 and 50 micrograms) and the dopamine agonist lisuride (0.5 and 1.0 micrograms), given 5 min before the retention test. Animals which received avoidance training in a different apparatus did not show increased test latencies following drug treatment thus eliminating non-specific behavioral suppression as an explanation for the findings. Neither norepinephrine nor the norepinephrine agonist clonidine was able to reverse the amnesia. These findings indicate that central dopamine systems may play a role in the retrieval of inhibitory avoidance learning.

Brain cyclic AMP and memory in mice

A phosphodiesterase inhibitor 4-(3-cyclopentyloxy-4-methoxyphenyl)-2-pyrrolidone (Rolipram, 10 mg/kg IP) administered immediately, but not 3 hr post-training, reversed an amnesia for an inhibitory avoidance response induced by the protein synthesis inhibitor anisomycin. Immediate post-training administration of Rolipram also enhanced retention for a weakly learned avoidance response. Unshocked animals did not show increased test latencies thus ruling out conditioned aversion as an explanation for the enhanced avoidance. Mice treated with Rolipram (10 mg/kg after training showed elevated cyclic AMP but not cyclic GMP in frontal cortex, thalamus, and hypothalamus. These results support the suggestion that cyclic AMP may play a role in memory processes.

Effects of cycloheximide, a protein synthesis inhibitor, on mouse brain catecholamine biochemistry

Cycloheximide (CXM), a protein synthesis inhibitor, has been shown to result in a marked inhibition of central catecholamine (CA) synthetic mechanisms at doses that cause amnesia in animals. Unlike other inhibitors of CA synthesis no significant depletion of whole brain NE or DA concentrations was observed 0.75, 1, 2, 3, 4, 6, 17, or 24 hours after administration of CXM (120 mg/kg) to C57BL/6J mice. In order to investigate the underlying basis of maintenance of CA levels in face of CA synthesis inhibition, the effects of CXM on in vitro release of 3H-NE was studied in mouse hypothalamic slices. CXM, in a dose related manner, significantly inhibited the potassium stimulated release of NE from hypothalamic slices. Anisomycin, another protein synthesis inhibitor, similarly inhibited NE release. These studies further document the effects of protein synthesis inhibitors on CA mechanisms and suggest that disruption of CA biochemistry may play a role in the amnesia observed after administration of protein synthesis inhibitors.

Characteristics of retrograde amnesia following reactivation of memory in mice

Amnesia for approach-avoidance learning was induced in mice by injecting the protein synthesis inhibitor anisomycin (ANI) immediately, 1, or 2 hours, but not 3 hours after training. A robust amnesia could be demonstrated if ANI was administered 3 hours after training, immediately following a 60 second exposure to the training apparatus or to a structurally similar environment. The temporal gradient of effectiveness of amnesia production by ANI was significantly steeper following reactivation treatment than it was following initial training. In addition, while amnesia produced by the conventional procedure remained stable for 6 days, the amnesia induced following reactivation treatment spontaneously recovered 4 days after training. These findings are discussed in terms of their relevance to interpretations of retrograde amnesia studies.

Alleviation of anisomycin-induced amnesia by pre-test treatment with lysine- vasopressin

Amnesia in mice for a passive avoidance response induced by anisomycin injection immediately after training was reversed by 40 micrograms of lysine-vasopressin given one hour before testing. Control groups receiving non-contingent shock instead of training were used to demonstrate that the effects of vasopressin were due to memory of shock received in a particular place, rather than non-specific suppression of locomotion. The effects of vasopressin on retention were not mimicked by either pentylenetetrazol or epinephrine suggesting that the enhanced latencies were probably not the result of increases in fear or arousal. These data support the hypothesis that the retrieval of memory can be facilitated by vasopressin. The possibility of a relationship between the effects of vasopressin and those of catecholamine manipulations on memory is discussed.

Reversal of anisomycin-induced amnesia by the ergot derivative hydergine

The ergot alkaloid Hydergine was tested for its ability to reverse an amnesia for approach-avoidance training. Thirsty mice were trained to drink in a test chamber and then punished with brief electric shocks for drinking. Those mice injected with the protein-synthesis inhibitor anisomycin immediately after training were amnesic for the shock when tested 48 h later. Pre-test injection of 10.0 or 1.0 mg/kg of Hydergine effectively reversed the amnesia while 0.1 mg/kg was ineffective. Non-contingent shock control groups ruled out the possibility that the effect was due to non-specific effects of the drug or training stimuli.

Clonidine reverses the amnesia induced by dopamine beta hydroxylase inhibition

The role of noradrenergic (NE) mechanisms in amnesia induced by the dopamine-beta-hydroxylase (DBH) inhibitor, diethyldithiocarbamate (DEDTC) was examined by studying the antiamnestic characteristics of the alpha-NE receptor stimulator clonidine. DEDTC (250 mg/kg) administered 3 hr prior to training to C57BL/6J mice resulted in marked deficits when retention of a multiple trial food motivated spatial discrimination task was measured 24 hr after learning. Investigation of the temporal aspects of recovery indicated that the agonist was an effective antiamnestic agent when administered 0, 1, 3, 21 and 23 hr after training. No recovery was observed when the drug was administered 6 and 18 hr posttraining. A dose response study of the effectiveness of clonidine administered 1 hr prior to testing indicated recovery of memory at doses ranging from 10-500 microgram/kg. The clonidine induced recovery was not a result of general performance facilitation, but specific to the memory tested. In addition, the clonidine effect was pharmacologically specific to its actions on NE receptors, as recovery was blocked by pre-treatment with the alpha-NE antagonist, phentolamine. No recovery from DEDTC induced amnesia was seen with post-training or pre-test injection of d-amphetamine.

Reversal of cycloheximide-induced amnesia by adrenergic receptor stimulation

Amnesia for a multiple trial appetitive spatial dicrimination habit induced by the protein synthesis inhibitor cycloheximide (CXM) was reversed by peripheral injections of both alpha (clonidine) and beta (isoproterenol) norepinephrine receptor stimulators. Stimulation of dopamine receptors with piribedil and acetylcholine receptors with pilocarpine was ineffective in reversing amnesia. The clonidine-induced recovery was blocked by phentolamine and the isoproterenol recovery by propranolol. Examination of the temporal parameters of clonidine-induced recovery indicated that the amnesia was prevented if the agonist was injected either before training and CXM treatment, up to 1 hr after training and up to 3 hr prior to testing. Clonidine also alleviated amnesia induced by another protein synthesis inhibitor anisomycin, for a shock motivated brightness discrimination habit. These data suggest that the transient amnesia induced by CXM may be a consequence of disruption of adrenergic mechanisms and more specifically that norepinephrine may play an important role in memory retrieval.

Some characteristics of amnesia induced by FLA-63 an inhibitor of dopamine beta hydroxylase

The amnesic effects of FLA-63, a potent dopamine-beta-hydroxylase (DBH) inhibitor, were investigated in a food motivated spatial discrimination task. Groups of C57BL/6J mice were injected with either 5 mg/kg, 15 mg/kg, 25 mg/kg, 35 mg/kg or physiological saline 4 hr prior to training. Amnesia was observed 24 hr following training at all dose levels except 5 mg/kh. The performance deficit was specific to memory of the discrimination and not the result of state-dependency. Training conditions which produce an increase in habit strength prevented the amnestic effects of FLS-63. Spontaneous recovery of memory occurred 48 hr following drug administration. Recovery from amnesia was also induced by injections of a monoamine oxidase inhibitor, pargyline, administered 2 hr prior to the retention test. These data suggest that amnesia induced by norpinephrine (NE) depletion is the result of impairment of mechanisms necessary for memory retrieval.