Time gradient for post-test vulnerability to scopolamine-induced amnesia following the initial acquisition session of a spatial reference memory task in mice

Murine genetic variance in muscarinic cholinergic receptor antagonism of acquisition and expression of sucrose-conditioned flavor preferences in three inbred mouse strains

Conditioned flavor preferences (CFP) are elicited by sucrose relative to saccharin in inbred mice with both the robustness of the preferences and sensitivity to pharmacological receptor antagonists sensitive to genetic variance. Dopamine, opioid and N-methyl-d-aspartate receptor antagonists differentially interfere with the acquisition (learning) and expression (maintenance) of sucrose-CFP in BALB/c and SWR inbred mice. Further, the muscarinic cholinergic receptor antagonist, scopolamine (SCOP) more potently reduces both sucrose and saccharin intake in BALB/c and C57BL/6 relative to SWR inbred mice. The present study examined whether SCOP altered the expression and acquisition of sucrose-CFP in BALB/c, C57BL/6 and SWR mice. In expression experiments, food-restricted mice alternately consumed a flavored (CS+, e.g., cherry, 5 sessions) 16% sucrose solution and a differently-flavored (CS-, e.g., grape, 5 sessions) 0.05% saccharin solution. Two-bottle CS choice tests with the two flavors mixed in 0.2% saccharin solutions occurred following vehicle or SCOP at doses of 1 or 5 mg/kg. SCOP significantly reduced the magnitude of the expression of sucrose-CFP in BALB/c, but not either C57BL/6 or SWR mice. In acquisition experiments, separate groups of BALB/c, C57BL/6 and SWR mice were treated prior to acquisition training sessions with vehicle or 2.5 or 5 mg/kg SCOP doses that was followed by six two-bottle CS choice tests without injections. SCOP dose-dependently reduced (1 mg/kg) and eliminated (2.5 mg/kg) the acquisition of sucrose-CFP in BALB/c mice, and reduced the magnitude of acquisition of sucrose-CFP in SWR mice. In contrast, neither SCOP dose affected the acquisition of sucrose-CFP in C57BL/6 mice. Thus, muscarinic cholinergic receptor signaling is essential for the learning of sucrose-CFP in BALB/c mice, to a lesser degree in SWR mice, but not in C57BL/6 mice. Murine genetic variance differentially modulates muscarinic cholinergic receptor control of sweet intake per se relative to learned conditioned flavor preferences of sweets.

Muscarinic receptor blockade in ventral hippocampus and prelimbic cortex impairs memory for socially transmitted food preference

Acetylcholine is involved in learning and memory and, particularly, in olfactory tasks, but reports on its specific role in consolidation processes are somewhat controversial. The present experiment sought to determine the effects of blocking muscarinic cholinergic receptors in the ventral hippocampus (vHPC) and the prelimbic cortex (PLC) on the consolidation of social transmission of food preference, an odor-guided relational task that depends on such brain areas. Adult male Wistar rats were bilaterally infused with scopolamine (20 microg/site) immediately after social training and showed impairment, relative to vehicle-injected controls, in the expression of the task measured 24 h after learning. Results indicated that scopolamine in the PLC completely abolished memory, suggesting that muscarinic transmission in this cortical region is crucial for consolidation of recent socially acquired information. Muscarinic receptors in the vHPC contribute in some way to task consolidation, as the rats injected with scopolamine in the vHPC showed significantly lower trained food preference than control rats, but higher than both chance level and that of the PLC-injected rats. Behavioral measures such as social interaction, motivation to eat, neophobia, or exploration did not differ between rats infused with scopolamine or vehicle. Such data suggest a possible differential role of muscarinic receptors in the PLC and the vHPC in the initial consolidation of a naturalistic form of nonspatial relational memory.

Characteristics of object location memory in mice: Behavioral and pharmacological studies

An object location test (OLT) has been developed to test spatial memory in rats. The test is based on the spontaneous tendency of rodents, previously exposed to two identical objects, to later explore one of the objects--replaced in a novel location--for a longer time than they explore the non-displaced object. In this study, we established the OLT in mice and investigated its characteristics with behavioral and pharmacological analysis. Mice discriminated the object in the novel location when the test trial was conducted < or =2 h after the acquisition trial. The cognitive ability was influenced neither by a change in the arrangement of the objects in the experimental apparatus, nor by change in the entry position of the mice. Object location memory was disrupted with change in the relative position of the objects to extra-field cues, or under conditions of deprivation of extra-field cues, suggesting that discrimination of the displaced object reflects spatial memory. A muscarinic cholinergic receptor antagonist (scopolamine, 1 mg/kg) impaired object location memory, while an acetylcholine esterase inhibitor (donepezil, 3 mg/kg) increased ability to maintain object location memory. In addition, aged mice showed poorer cognitive performance than young mice on the OLT. These findings indicate that the OLT can be used to assess spatial memory in mice, as well as in rats. The object location memory in mice was sensitive to pharmacological manipulation with cholinergic agents and to aging and could be used to identify agents affecting spatial memory.

Role of central cholinergic receptor sub-types in spatial working memory: a five-arm maze task in mice provides evidence for a functional role of nicotinic receptors in mediating trace access processes

A delayed-matching spatial working memory protocol in a 5-arm maze was used to test the hypothesis of differential roles for central nicotinic and muscarinic cholinergic receptors in mediating task performance. In experiment 1, using a within subjects-repeated design, groups of C57Bl/6 mice, previously trained to criterion with a 4 h retention interval separating presentation and test phases, received i.p. injections of either saline, scopolamine (0.8 mg/kg), mecamylamine (8.0 mg/kg), or the combination of scopolamine and mecamylamine before re-testing. Injections were given either, a) 15 min pre-presentation or, b) 30 s, c) 15 min, d) 3 h 45 min post-presentation in order to differentially affect the acquisition, trace maintenance and recall phases. Significant decreases in correct responses were observed for each drug treatment but the effects were a function of the time of treatment. Results of condition d), (i.e.15 min before retention test) confirm previous reports of severe disruption by each antagonist and their combination on retention. However, conditions a-c) show a constant disruption by scopolamine, increasing disruption by mecamylamine, whereas the combined treatment was without effect. Although the data show that central nicotinic and muscarinic antagonists both modulate working memory performance, they indicate first, that scopolamine-induced "amnesia" results, not from selective post-synaptic M1 muscarinic blockade but from indirect over-activation of nicotinic receptors. Second, the observation of high levels of retention although nicotinic and muscarinic receptors had undergone combined blockade during a large part of the retention interval is incompatible with the concept that test-induced activation of central cholinergic neurones mediates memory trace maintenance. Finally, taken with data from experiment 2, using a short (20 min) treatment-to-test interval, we conclude that central nicotinic receptors play a key role in attentional processes enabling working memory trace access during retrieval.

Differential roles for nicotinic and muscarinic cholinergic receptors in sustained visuo-spatial attention? A study using a 5-arm maze protocol in mice

A 5-arm maze was used to measure sustained visuo-spatial attention in C57Bl/6 mice and test the hypothesis of differential functional roles for central nicotinic and muscarinic receptors in mediating task performance. Mice were first trained to acquire the basic visual discrimination task in which, on each trial, one randomly chosen arm among the five open arms was baited and remained lit until an arm-choice was made. Mice were then submitted to attentional testing in which trials using light signals of 2, 1 or 0.5 s were intermixed to evaluate the decrement in correct responses as a function of the decrease in light signal duration and thus, to construct a reference curve for the attentional performance of C57Bl/6 mice. Mice were then divided into four groups and received, in rotation, over four pharmacological sessions according to a Latin-square design, i.p. injections of either mecamylamine (4.0 mg/kg), scopolamine (0.8 mg/kg), the combination of mecamylamine and scopolamine or saline, 20 min before re-testing. Injection of cholinergic antagonists produced decreases in percentage of correct responses, which were systematically associated with significant increases in choice latencies. Mecamylamine produced slight disruption, whereas scopolamine and the combined treatment both produced severe disruption. In conclusion, whereas both nicotinic and muscarinic cholinergic antagonists disrupt performance in the attentional task, the increase in response latencies entails that correct responding becomes more dependent on the working memory processes and thus compromises conclusions as to a selective disruption of attention.

Retrograde amnesia after hippocampal damage: recent vs. remote memories in two tasks

We review evidence from experiments conducted in our laboratory on retrograde amnesia in rats with damage to the hippocampal formation. In a new experiment reported here, we show that N-methyl-D-aspartate (NMDA)-induced hippocampal damage produced retrograde amnesia for both hidden platform and two-choice visible platform discriminations in the Morris water task. For both problems there was a significant trend for longer training-surgery intervals to be associated with worse retention performance. Little support is offered by our work for the concept that there is a process involving hippocampal-dependent consolidation of memories in extrahippocampal permanent storage sites. Long-term memory consolidation may take place within the hippocampus. The hippocampus may be involved permanently in storage and/or retrieval of a variety of relational and nonrelational memories if it was intact at the time of learning, even involving information which is definitely not affected in anterograde amnesia after hippocampal damage.

Differential participation of the NBM in the acquisition and retrieval of conditioned taste aversion and Morris water maze

Deficits in both learning and memory after lesions of the cholinergic basal forebrain, in particular the nucleus basalis magnocellularis (NBM), have been widely reported. However, the participation of the cholinergic system in either acquisition or retrieval of memory process is still unclear. In this study, we tested the possibility that excitotoxic lesions of the NBM affect either acquisition or retrieval of two tasks. In the first experiment, animals were trained for two conditioned taste aversion tasks using different flavors, saccharine and saline. The acquisition of the first task was before NBM lesions (to test retrieval) and the acquisition of the second task was after the lesions (to test acquisition). Accordingly, in the first part of the second experiment, animals were trained in the Morris water maze (MWM), lesioned and finally tested. In the final part of this experiment, another set of animals was lesioned, then trained in the MWM and finally tested. All animals were able to retrieve conditioned taste aversion (CTA) and MWM when learned before NBM lesions; however, lesions disrupted the acquisition of CTA and MWM. The results suggest that the NBM and cholinergic system may play an important role in acquisition but not during retrieval of aversive memories.

Injections of tacrine and scopolamine into the nucleus accumbens: opposing effects of immediate vs delayed posttrial treatment on memory of an open field

Using the paradigm of habituation learning in the open field, we tested the effects of microinjections of the nonspecific acetylcholine-esterase inhibitor tacrine (0.1, 1.0, 10.0 micrograms), and the muscarinic receptor antagonist scopolamine (0.1, 1.0, 10.0 micrograms) into the core of the nucleus accumbens. When injected immediately after the first exposure to the open field (posttrial), tacrine dose-dependently enhanced habituation of rearing behavior during the test on the following day, indicating a facilitation of memory. In contrast, scopolamine impaired habituation of rearing behavior at the two lower doses, but not at the highest dose. When scopolamine or tacrine (10.0 micrograms) was injected with a delay of 5 h after the learning trial, both drugs impaired habituation of rearing on the following day. The effects on locomotor activity differed from those on rearing behavior. Here, habituation on Day 2 was observed only in those animals which had received posttrial injections of vehicle or 10 micrograms of tacrine on the day before, whereas in animals which had received the two lower doses of tacrine, locomotor activity on Day 2 was not significantly decreased. In animals with posttrial treatment of scopolamine, locomotor activity on Day 2 was even enhanced, especially with the lower doses. No such effects were observed when scopolamine or tacrine (10.0 micrograms each) was injected with a delay of 5 h after the learning trial. These results show that cholinergic manipulations aimed at the nucleus accumbens can have substantial effects in this posttrial memory paradigm, which depend on drug, dose, and time of injection, and the specific kind of behavioral measure analyzed. Among others, the findings are discussed with respect to the role of muscarinic and nicotinergic cholinergic mechanisms in the nucleus accumbens on cognitive functions. They may be relevant, for example, for understanding the psychopathology of Alzheimer's disease, since the nucleus accumbens is one of the sites where cholinergic neurons are lost in this neurodegenerative disease.

A structural basis for memory storage in mammals

It is proposed that altered dendrite length and de novo formation of new dendrite branches in cholinoceptive cells are responsible for long-term memory storage, a process enabled by the degradation of microtubule-associated protein-2. These memories are encoded as modality-specific associable representations. Accordingly, associable representations are confined to cytoarchitectonic modules of the cerebral cortex, hippocampus, and amygdala. The proposed sequence of events leading to long-term storage in cholinoceptive dendrites begins with changes in neuronal activity, then in neurotrophin release, followed by enhanced acetylcholine release, muscarinic response, calcium influx, degradation of microtubule-associated protein-2, and finally new dendrite structure. Hypothetically, each associable representation consists of altered dendrite segments from approximately 5000-15,000 cholinoceptive cells contained within one or a few module(s). Simultaneous restructuring during consolidation of long-term memory is hypothesized to result in a similar infrastructure among dendrite sets, facilitating co-activation of those dendrite sets by neurotransmitters such as acetylcholine, and conceivably enabling high energy interactions between those dendrites by phenomena such as quantum optical coherence. Based on the specific architecture proposed, it is estimated that the human telecephalon contains enough dendrites to encode 50 million associable representations in a lifetime, or put another way, to encode one new associable representation each minute. The implications that this proposal has regarding treatments for Alzheimer's disease are also discussed.

Learning impairment and cholinergic deafferentation after cortical nerve growth factor deprivation

Cholinergic basal forebrain (CBF ) neurons have been shown to respond in vivo to exogenous administration of NGF. Although neurotrophins and their receptors are widely expressed in the CNS, little data exist for the physiological significance of endogenous neurotrophin signaling in CNS neurons. To test directly whether cortically derived NGF is functionally required for the cholinergic functions mediated by the cerebral cortex, repeated injections of anti-NGF mAbs were locally applied into the insular cortex (IC) of rats. The biochemical results, using an in vivo microdialysis technique, showed a dramatic lack of extracellular release of acetylcholine after high potassium stimulation compared with controls. Furthermore, by using small injections of the neurotracer fluorogold, we found a corresponding disruption in the connectivity between the IC and the CBF. Behavioral experiments showed that the NGF antibodies applied into the IC produced a significant disruption on the acquisition of conditioned taste aversion and inhibitory avoidance learning. However, the same animals were able to recall the taste aversion when the conditioning trial was established before injections of NGF antibodies. Given these results, it seems that cortical cholinergic functions are actively dependent on locally derived NGF in the adult normal brain, and that the cholinergic activity from the CBF is not necessary for recalling aversive stimuli, but is necessary for the acquisition of aversively motivated conditionings.

Plus-maze retest profile in mice: importance of initial stages of trail 1 and response to post-trail cholinergic receptor blockade

Recent research has shown that a single undrugged prior experience of the elevated plus-maze produces significant behavioural changes upon 24-h retest in rats and mice. Typically, when reexposed to the maze, animals display an increased avoidance of the open arms and a corresponding preference for the enclosed sections of the apparatus. Using ethological analyses, the present series of experiments sought to further characterize this phenomenon in mice and to determine whether or not it involves cholinergic receptor mechanisms. Results confirmed that behaviour during Trial 2 is markedly different to that seen on initial exposure, and that such changes are independent of the duration of Trial 1 (2 vs. 5 min). Retest behavioural changes included reduced entry latencies, reduced open arm entries, less time on the open arms and centre platform, lower levels of exploratory head-dipping, and increased entries into and time spent in the closed arms. The importance to the retest phenomenon of the first few minutes of initial exposure was further suggested by min-by-min analyses of the behaviour of animals naive to the maze. Results showed that behaviour during the first min is characterized by high levels of risk assessment from the centre platform and relatively low, but equal, levels of open- and closed-arm exploration. From min 2 onwards, however, behaviour showed a marked change with increasing open arm/centre platform avoidance, increasing closed-arm preference, and decreasing levels of risk assessment and exploratory head-dipping. Thus, it would appear that this within-session aversive learning transfers between sessions to account for behavioural profiles on retest. Irrespective of the duration of Trial 1 (2 or 5 min), posttrial administration of the muscarinic antagonist, scopolamine (0.1-1.0 mg/kg), failed to significantly alter the behavioural changes seen between trials. Data are discussed in relation to the apparent sensitization of fear produced by plus-maze exposure, its possible relation to phobia acquisition, and the need for further research on underlying mechanisms.

Spatial working memory over long retention intervals: dependence on sustained cholinergic activation in the septohippocampal or nucleus basalis magnocellularis-cortical pathways?

Previous direct neurochemical studies of the temporal dynamics of cholinergic activation in the septohippocampal and nucleus basalis magnocellularis-cortical pathways at various stages during repeated testing of mice with selective spatial reference or working memory protocols [Durkin and Toumane (1992), Behav. Brain Res. 50, 43-52] showed that the post-test durations of cholinergic activation in each pathway varied as a function of the type of memory tested and the level of task mastery. Since (i) the hippocampal formation is considered to constitute a critical component of a temporary memory buffer, and (ii) working memory items are not thought to be submitted to consolidation and permanent storage, we postulated that the duration of testing-induced cholinergic activation in the septohippocampal pathway may govern the maintenance of the working memory trace over the retention interval. In order to test directly this hypothesis C57 B1/6 mice were extensively trained (one trial/day, 25-30 days) on an identical selective working memory task to attain high levels of retention (> 80% correct), but using either 5 min (Group 1), or 60 min (Group 2) retention intervals. At various times (30 s-75 min) following the initial acquisition phase of the test, cholinergic activity in the hippocampus and frontal cortex was quantified using measures of high-affinity choline uptake. Whereas cholinergic activation was observed in both pathways at 30 s post-acquisition and throughout the 5 min retention interval in Group 1, the situation in Group 2 is different, activation of the septohippocampal pathway being maintained for only 15 min, while activation in the nucleus basalis magnocellularis-cortical pathway is maintained for the totality of the 1 h retention interval. The nucleus basalis magnocellularis-cortical cholinergic pathway, in addition to its role in long-term reference memory storage processes may, thus, via an intervention in the temporal encoding of information, also subsume a complementary intermediate-term buffer storage role in working memory situations requiring retention intervals in excess of 15 min in mice. This secondary, "backup", function of the nucleus basalis magnocellularis-cortical pathway would thus liberate the septohippocampal complex from its primary active role in the temporary maintenance and/or accessibility of the working memory trace in these particular cases requiring long retention intervals.