Effect of donepezil on reversal learning in a touch screen-based operant task.

Impairments in reversal learning, which are commonly observed in patients with psychiatric disorders, remain difficult to treat. There is still a debate over the beneficial effects of cholinergic enhancers on improving behavioural flexibility. The objective of this study was to investigate the effect of an acetylcholinesterase inhibitor, donepezil, on the performance of a rodent Probabilistic Reversal Learning task. Lister-Hooded rats were trained to retrieve food rewards by discriminating two computer-generated stimuli in an automated touch screen-based operant task. When a steady performance was achieved, the stimulus-reward rule was reversed. Each rat was given a 30-min training session daily for 24 days and donepezil was administered 30 min before each training session. Systemic treatment with donepezil had no effect on trial accuracy of the two-stimulus discrimination training. However, the donepezil group showed enhanced performance in the reversal learning. Our result showed that treatment with donepezil significantly enhanced Probabilistic Reversal Learning performance in healthy animals. On the basis of this finding, the inhibition of the central acetylcholinesterase would seem to be a potential therapeutic approach to treat behavioural inflexibility.

Procognitive 5-HT6 antagonists in the rat forced swimming test: potential therapeutic utility in mood disorders associated with Alzheimer's disease.

AIMS: 5-HT(6) receptor subtype is predominantly expressed in the brain, and preclinical evidence suggests its potential role in the cognitive function. Brain microdialysis studies demonstrated that 5-HT(6) antagonists enhance not only cholinergic but also monoaminergic neurotransmission, a property that may differentiate from acetylcholine esterase (AChE) inhibitors such as donepezil. In this study we compared the antidepressant-like effects of 5-HT(6) antagonists with donepezil to determine whether their different effects on monoamines are behaviorally relevant. MAIN METHODS: Selective 5-HT(6) antagonists (SB-399885 and SB-271046) and donepezil were evaluated in the rat forced swimming test since this is known to identify drugs such as antidepressants which can increase brain monoamine levels. Binding assay was undertaken by using [(125)I]SB-258585 to measure brain 5-HT(6) receptor occupancy. KEY FINDINGS: Systemic administration of SB-399885 (3 and 10 mg/kg, i.p.) and SB-271046 (10 and 30 mg/kg, i.p.) produced a significant reduction of immobility time in the rat forced swimming test with a similar profile in terms of 5-HT(6) receptor occupancy (62 and 96% for 3 and 10 mg/kg SB-399885 respectively; 56 and 84% for 10 and 30 mg/kg SB-271046 respectively). In contrast, donepezil (0.5 and 1 mg/kg i.p.) did not show any effects in this model. SIGNIFICANCE: These data suggest that 5-HT(6) antagonists, at doses corresponding to those occupy central 5-HT(6) receptors, could have an antidepressive effect in humans. This may differentiate 5-HT(6) antagonists from AChE inhibitors with respect to the mood control in the symptomatic treatment of Alzheimer's disease.

Working memory deficits in retinoid X receptor gamma-deficient mice.

Retinoid signaling has been recently shown to be required for mnemonic functions in rodents. To dissect the behavioral and molecular mechanisms involved in this requirement, we have analyzed the spatial and recognition working memory in mice carrying null mutations of retinoid receptors RARbeta and RXRgamma. Double mutants appeared deficient in spatial working memory as tested in spontaneous alternation in the Y-maze and delayed nonmatch to place (DNMTP) test in the T-maze. These mutant mice did acquire, however, spatial place reference or right/left discrimination tasks in the T-maze set-up, indicating that basic sensorimotor functions, spatial orientation, and motivational factors are unlikely to account for deficits in working memory-sensitive tasks. Double-mutant mice were also deficient in novel object recognition at intermediate, but not short delays. RXRgamma appeared to be the functionally predominant receptor in modulation of the working memory, as RXRgamma, but not RARbeta single null mutant mice exhibited deficits similar to those observed in the double mutants. The mechanism of this modulation is potentially related to functions of RXRgamma in frontal and perirhinal cortex, structures in which we detected RXRgamma expression and which are functionally implicated in working memory processes.

Cognitive aging: recapturing the excitation of youth?

The electrical excitability of cortical neurons changes significantly during normal ageing. A recent study found that targeted deletion of a gene encoding a potassium channel-modifier subunit can restore to aged mice, not only normal neuronal firing, but also normal learning and synaptic plasticity.

Neocortical long-term potentiation and experience-dependent synaptic plasticity require alpha-calcium/calmodulin-dependent protein kinase II autophosphorylation.

Experience-dependent plasticity can be induced in the barrel cortex by removing all but one whisker, leading to potentiation of the neuronal response to the spared whisker. To determine whether this form of potentiation depends on synaptic plasticity, we studied long-term potentiation (LTP) and sensory-evoked potentials in the barrel cortex of alpha-calcium/calmodulin-dependent protein kinase II (alphaCaMKII)T286A mutant mice. We studied three different forms of LTP induction: theta-burst stimulation, spike pairing, and postsynaptic depolarization paired with low-frequency presynaptic stimulation. None of these protocols produced LTP in alphaCaMKIIT286A mutant mice, although all three were successful in wild-type mice. To study synaptic plasticity in vivo, we measured sensory-evoked potentials in the barrel cortex and found that single-whisker experience selectively potentiated synaptic responses evoked by sensory stimulation of the spared whisker in wild types but not in alphaCaMKIIT286A mice. These results demonstrate that alphaCaMKII autophosphorylation is required for synaptic plasticity in the neocortex, whether induced by a variety of LTP induction paradigms or by manipulation of sensory experience, thereby strengthening the case that the two forms of plasticity are related.

Synaptic plasticity in the amygdala: comparisons with hippocampus.

Long-term potentiation (LTP) is a widely studied form of synaptic plasticity, and a considerable amount of evidence indicates that it could be involved in learning and memory. Intensive investigation of this phenomenon in the hippocampus has yielded tremendous insight into the workings of synapses in the mammalian central nervous system, but important questions remain to be answered. The most important of these are: (1) whether LTP is the basis of learning and memory, and (2) how similar are the induction, maintenance, and expression mechanisms in the rest of the brain to those in the hippocampus. Because the most important strategy for linking LTP to learning involves disrupting the mechanisms of LTP and examining the consequences on behavior, it is likely that the first question cannot be answered until the second has been addressed. Recent evidence indicates that although the general processes have much in common, significant differences exist among forebrain structures, including the hippocampus, basolateral amygdala, and ventral striatum. It is clear that the roles of receptors and calcium channels, kinases, and transcription factors vary within these structures, reflecting the different functions of these brain regions.

Deletion of the mental retardation gene Gdi1 impairs associative memory and alters social behavior in mice.

Non-specific mental retardation (NSMR) is a common human disorder characterized by mental handicap as the only clinical symptom. Among the recently identified MR genes is GDI1, which encodes alpha Gdi, one of the proteins controlling the activity of the small GTPases of the Rab family in vesicle fusion and intracellular trafficking. We report the cognitive and behavioral characterization of mice carrying a deletion of Gdi1. The Gdi1-deficient mice are fertile and anatomically normal. They appear normal also in many tasks to assess spatial and episodic memory and emotional behavior. Gdi1-deficient mice are impaired in tasks requiring formation of short-term temporal associations, suggesting a defect in short-term memory. In addition, they show lowered aggression and altered social behavior. In mice, as in humans, lack of Gdi1 spares most central nervous system functions and preferentially impairs only a few forebrain functions required to form temporal associations. The general similarity to human mental retardation is striking, and suggests that the Gdi1 mutants may provide insights into the human defect and into the molecular mechanisms important for development of cognitive functions.

Giving drugs to knockout mice: can they do that?

The past ten years have seen an explosion in the number of genetically modified mice created to aid understanding of the basic mechanisms of learning and memory. There are still significant problems associated with this useful technique, mostly involving the lack of temporal or spatial control over the genetic 'lesion'. By combining the application of drugs that are sub-threshold in wild-type mice with heterozygosity for gene mutations that do not produce effects alone, it is now possible to avoid many of the problems of both the genetic and the pharmacological approaches.

Knockout of ERK1 MAP kinase enhances synaptic plasticity in the striatum and facilitates striatal-mediated learning and memory.

Extracellular signal-regulated kinases (ERK1 and 2) are synaptic signaling components necessary for several forms of learning. In mice lacking ERK1, we observe a dramatic enhancement of striatum-dependent long-term memory, which correlates with a facilitation of long-term potentiation in the nucleus accumbens. At the cellular level, we find that ablation of ERK1 results in a stimulus-dependent increase of ERK2 signaling, likely due to its enhanced interaction with the upstream kinase MEK. Consistently, such activity change is responsible for the hypersensitivity of ERK1 mutant mice to the rewarding properties of morphine. Our results reveal an unexpected complexity of ERK-dependent signaling in the brain and a critical regulatory role for ERK1 in the long-term adaptive changes underlying striatum-dependent behavioral plasticity and drug addiction.