Jean-Christophe Cassel

Serotonergic modulation of cholinergic function in the central nervous system: Cognitive implications

Accumulating evidence suggests that serotonin may modulate cholinergic function in several regions of the mammalian brain and that these serotonergic/cholinergic interactions influence cognition. The first part of this review is an overview of histological, electrophysiological and pharmacological (in vitro, in vivo) data indicating that, in several brain regions (e.g., hippocampus, cortex and striatum), there are neuroanatomical substrates for a serotonergic/cholinergic interaction, and that alterations in serotonergic activity may induce functional changes in cholinergic neurons. In the second part, the review focuses on experimental approaches showing or suggesting that central cholinergic and serotonergic mechanisms are cooperating in the regulation of cognitive functions. These arguments are based on lesion, intracerebral grafting and pharmacological techniques. It is concluded that not all mnesic perturbations induced by concurrent manipulations of the serotonergic and cholinergic systems can be attributed to a serotonergic modification of the cholinergic system. The cognitive faculties of an organism arise from interactions among several neurotransmitter systems within brain structures such as, for instance, the hippocampus or the cortex, but also from influences on memory of other general functions that may involve cerebral substrates different from those classically related to mnesic functions (e.g., attention, arousal, sensory accuracy, etc.).

Cognitive Performances and Locomotor Activity Following Dentate Granule Cell Damage in Rats: Role of Lesion Extent and Type of Memory Tested ☆

Intradentate injection of colchicine is one of the techniques used to destroy granule cells. This study compared the behavioral effects of various amounts of colchicine (1.0, 3.0, and 6.0 microg; Col 1, Col 3, and Col 6, respectively) injected into the dentate gyrus of adult Long-Evans male rats. Starting 10 days after lesion surgery, behavioral testing assessed home-cage and open-field locomotion, alternation in a T-maze, water-maze, and radial-maze learning according to protocols placing emphasis on reference, and working memory. All of these tasks are sensitive to hippocampal disruption. Histological verifications showed that the extent of the lesions depends on the dose of colchicine (index of dentate gyrus shrinkage: -33% in Col 1, -54% in Col 3, and -67% in Col 6 rats). Colchicine dose-dependently increased nocturnal home cage activity (an effect found 10 days but not 5 months after surgery), but had no significant effect on open-field locomotion or T-maze alternation. A dose-dependent reference memory impairment was found during the acquisition of spatial navigation in the water maze; Col 3 and Col 6 rats were more impaired than Col 1 rats. During the probe trial (platform removed), control rats spent a longer distance swimming over the platform area than all rats with colchicine lesions. In the working memory version of the test, all rats with colchicine lesions showed significant deficits. The deficits were larger in Col 3 and Col 6 rats compared to Col 1 rats. The lesions had no effect on swimming speed. In the radial-maze test, there was also a dose-dependent working memory impairment. However, reference memory was disrupted in a manner that did not differ among the three groups of lesioned rats. Our data are in line with the view that the dentate gyrus plays an important role in the acquisition of new information and is an integral neural substrate for spatial reference and spatial working memory. They also suggest that damage to granule cells might have more pronounced effects on reference than on working memory in the radial maze. Finally, they demonstrate that part of the variability in the conclusions from previous experiments concerning the role of granule cells in cognitive processes, particularly in spatial learning and memory, may be due to the type of tests used and/or the extent of the damage produced.

Spatial memory consolidation is associated with induction of several lysine-acetyltransferase (histone acetyltransferase) expression levels and H2B/H4 acetylation-dependent transcriptional events in the rat hippocampus.

Numerous genetic studies have shown that the CREB-binding protein (CBP) is an essential component of long-term memory formation, through its histone acetyltransferase (HAT) function. E1A-binding protein p300 and p300/CBP-associated factor (PCAF) have also recently been involved in memory formation. By contrast, only a few studies have reported on acetylation modifications during memory formation, and it remains unclear as to how the system is regulated during this dynamic phase. We investigated acetylation-dependent events and the expression profiles of these HATs during a hippocampus-dependent task taxing spatial reference memory in the Morris water maze. We found a specific increase in H2B and H4 acetylation in the rat dorsal hippocampus, while spatial memory was being consolidated. This increase correlated with the degree of specific acetylated histones enrichment on some memory/plasticity-related gene promoters. Overall, a global increase in HAT activity was measured during this memory consolidation phase, together with a global increase of CBP, p300, and PCAF expression. Interestingly, these regulations were altered in a model of hippocampal denervation disrupting spatial memory consolidation, making it impossible for the hippocampus to recruit the CBP pathway (CBP regulation and acetylated-H2B-dependent transcription). CBP has long been thought to be present in limited concentrations in the cells. These results show, for the first time, that CBP, p300, and PCAF are dynamically modulated during the establishment of a spatial memory and are likely to contribute to the induction of a specific epigenetic tagging of the genome for hippocampus-dependent (spatial) memory consolidation. These findings suggest the use of HAT-activating molecules in new therapeutic strategies of pathological aging, Alzheimers disease, and other neurodegenerative disorders.

Spatial memory, habituation, and reactions to spatial and nonspatial changes in rats with selective lesions of the hippocampus, the entorhinal cortex or the subiculum

Various spatial memory deficits have been described in rats with damage to the hippocampal formation (including the subiculum and the entorhinal cortex) and particularly in rats with selective lesions of the hippocampus proper. So far, the involvement of the entorhinal cortex in spatial memory is still controversial and the role of the subiculum is poorly documented. The aim of the present study was to compare the behavioural effects of selective lesions of the hippocampus, the entorhinal cortex or the subiculum in (a) a water-maze task using testing procedures sensitive to the disruption of reference or working memory and (b) in an object exploration task designed to evaluate habituation and subsequently reactions to changes of the spatial layout of objects (spatial change) or to the substitution of a familiar object by a new one (nonspatial change). Our results showed several similarities between the behavioural consequences of damage to each of the three structures. A few differences were also noted. Hippocampal rats were impaired in all spatial tasks, but they reacted like controls to a nonspatial change. The rats sustaining lesions of the entorhinal cortex or the subiculum were not impaired in the reference-memory procedure of the water-maze task and showed a deficit in reacting to a nonspatial change. Overall, our results confirm the central role of the hippocampus in spatial memory and also suggest a role for the entorhinal cortex and the subiculum in processing spatial informations. In addition, they indicate that the entorhinal cortex and the subiculum may have a hippocampal-independent role in memory.

Immunohistochemical and neurochemical correlates of learning deficits in aged rats

This study examined whether cholinergic and monoaminergic dysfunctions in the brain could be related to spatial learning capabilities in 26-month-old, as compared to three-month-old, Long-Evans female rats. Performances were evaluated in the water maze task and used to constitute subgroups with a cluster analysis statistical procedure. In the first experiment (histological approach), the first cluster contained young rats and aged unimpaired rats, the second one aged rats with moderate impairment and the third one aged rats with severe impairment. Aged rats showed a reduced number of choline acetyltransferase- and p75(NTR)-positive neurons in the nucleus basalis magnocellularis, and choline acetyltransferase-positive neurons in the striatum. In the second experiment (neurochemical approach), the three clusters comprised young rats, aged rats with moderate impairment and aged rats with severe impairment. Alterations related to aging consisted of reduced concentration of acetylcholine, norepinephrine and serotonin in the striatum, serotonin in the occipital cortex, dopamine and norepinephrine in the dorsal hippocampus, and norepinephrine in the ventral hippocampus. In the first experiment, there were significant correlations between water maze performance and the number of; (i) choline acetyltransferase- and p75(NTR)-positive neurons in the nucleus basalis magnocellularis; (ii) choline acetyltransferase-positive neurons in the striatum and; (iii) p75(NTR)-positive neurons in the medial septum. In the second experiment, water maze performance was correlated with the concentration of; (i) acetylcholine and serotonin in the striatum; (ii) serotonin and norepinephrine in the dorsal hippocampus; (iii) norepinephrine in the frontoparietal cortex and; (iv) with other functional markers such as the 5-hydroxyindoleacetic acid/serotonin ratio in the striatum, 3,4-dihydroxyphenylacetic acid/dopamine ratio in the dorsal hippocampus, 5-hydroxyindoleacetic acid/serotonin and homovanillic acid/dopamine ratios in the frontoparietal cortex, and 3,4-dihydroxyphenylacetic acid/dopamine ratio in the occipital cortex. The results indicate that cognitive deficits related to aging might involve concomitant alterations of various neurochemical systems in several brain regions such as the striatum, the hippocampus or the cortex. It also seems that these alterations occur in a complex way which, in addition to the loss of cholinergic neurons in the basal forebrain, affects dopaminergic, noradrenergic and serotonergic processes.

Combined lesions of cholinergic and serotonergic neurons in the rat brain using 192 IgG-saporin and 5,7-dihydroxytryptamine: neurochemical and behavioural characterization.

This study assessed behavioural and neurochemical effects of i.c.v. injections of both the cholinergic toxin 192 IgG‐saporin (2 μg) and the serotonergic toxin 5,7‐dihydroxytryptamine (5,7‐DHT; 150 μg) in Long–Evans female rats. Dependent behavioural variables were locomotor activity, forced T‐maze alternation, beam walking, Morris water‐maze (working and reference memory) and radial‐maze performances. After killing by microwave irradiation, the concentrations of acetylcholine, monoamines and 5‐hydroxyindoleacetic acid (5‐HIAA) were measured in the hippocampus, frontoparietal cortex and striatum. 192 IgG‐saporin reduced the concentration of acetylcholine by ∼ 40% in the frontoparietal cortex and hippocampus, but had no effect in the striatum. 5,7‐DHT lesions reduced the concentration of serotonin by 60% in the frontoparietal cortex and 80% in the hippocampus and striatum. Noradrenaline was unchanged in all structures except the ventral hippocampus where it was slightly increased in rats given 192 IgG‐saporin. Cholinergic lesions induced severe motor deficits but had no other effect. Serotonergic lesions produced diurnal and nocturnal hyperactivity but had no other effect. Rats with combined lesions were more active than those with only serotonergic lesions, showed motor dysfunctions similar to those found in rats with cholinergic lesions alone, and exhibited impaired performances in the T‐maze alternation test, the water‐maze working memory test and the radial‐maze. Taken together and although cholinergic lesions were not maximal, these data show that 192 IgG‐saporin and 5,7‐DHT lesions can be combined to selectively damage cholinergic and serotonergic neurons, and confirm that cholinergic–serotonergic interactions play an important role in some aspects of memory, particularly in spatial working memory.

A double dissociation between serial reaction time and radial maze performance in rats subjected to 192 IgG-saporin lesions of the nucleus basalis and/or the septal region.

The cholinergic basal forebrain has been implicated in aspects of cognitive function including memory and attention, but the precise contribution of its major components, the basalocortical and the septohippocampal systems, remains unclear. Rats were subjected to lesions of either the nucleus basalis magnocellularis (Basalis), the medial septum/vertical limb of the diagonal band of Broca (Septum), or both nuclei (Basalis + Septum), using the selective cholinotoxin 192 IgG‐saporin. Cognitive performance was evaluated in tasks taxing attention (the five‐choice serial reaction time task, 5‐CSRTT) and spatial working memory (radial arm maze, RAM). Nucleus basalis lesions disrupted performance of the 5‐CSRTT, as demonstrated by decreased choice accuracy, increased incidence of missed trials, increased latencies to respond correctly, and a disrupted pattern of response control. Combined lesions of the Basalis and Septum resulted in qualitatively similar deficits to Basalis lesions alone, although interestingly, these rats were unimpaired on measures of response speed, and showed weaker deficits on accuracy and omissions. Decreasing the attentional load by lengthening stimulus duration reversed some of the deficits in Basalis and Basalis + Septum rats, suggesting an attentional deficit rather than motivation or motor perturbations. Performance in rats with septal lesions was only affected when task difficulty was increased. In the RAM an opposing pattern of effects was observed, with Septum and Basalis + Septum rats showing dramatic impairments, and Basalis rats performing normally. Taken together, these data provide clear evidence for a functional dissociation between septohippocampal and basalocortical cholinergic systems in aspects of cognitive function.

Graft-induced behavioral recovery from subcallosal septohippocampal damage in rats depends on maturity stage of donor tissue

Long-Evans female rats sustained electrolytic lesions of the fimbria and the dorsal fornix and, 10-14 days later, received intrahippocampal suspension grafts of septal-diagonal band tissue from either 14-day-old (Group S14, n = 8) or 16-day-old fetuses (Group S16, n = 10), or of parietal cortex from 16-day-old fetuses (Group Cx, n = 10). Sham-operated (Group S, n = 10) and lesion-only (Group Fifo, n = 21) rats served as non-grafted controls. Spontaneous alternation was assessed in a T-maze at three weeks and two months post-grafting. Home cage and open field activity as well as radial maze learning were assessed from two months post-grafting onwards. Fimbria-fornix lesions induced lasting hyperactivity in both the open field and the home cage, impaired radial maze learning and transiently reduced spontaneous alternation rates. Neither type of graft significantly affected home cage activity. Septal-diagonal band grafts improved open field habituation (within trial decline of ambulatory activity) and radial maze learning; the former was observed only in S16 rats, whereas the latter was observed only in S14 rats. Acetylcholinesterase histochemistry revealed an initial lesion-induced depletion of hippocampal acetylcholinesterase (eight days post-surgery) which was no longer observed at the end of the experiment. Acetylcholinesterase positivity was similar in S14 and S16 grafts, which also contained many choline acetyltransferase-positive neurons. Cortical grafts were found to be almost devoid of acetylcholinesterase positivity and no well-stained choline acetyltransferase-positive neurons could be identified. Septal-diagonal band grafts from 14-day-old fetuses and cortical grafts contained more parvalbumin-positive neurons than septal-diagonal band grafts provided by 16-day-old fetuses. These results suggest that grafts rich in cholinergic neurons may promote behavioral recovery from fimbria-fornix lesion-induced deficits. However, such a recovery may concern different behavioral deficits as a function of the age of the implanted tissue, suggesting that the maturity stage of the donor may critically influence the functional expression in the lesioned recipient. Also, such a recovery does not appear to be related solely to cholinergic hippocampal (re)innervation and might depend on the presence, not only of cholinergic neurons, but also of non-cholinergic neuronal populations, such as parvalbumin-positive (probably GABAergic) neurons.

Behavioral deficits after intrahippocampal fetal septal grafts in rats with selective fimbria-fornix lesions

SummaryFetal septal transplants have been shown to promote behavioral recovery in young adult rats with aspiration fimbria-fornix lesions, rats with septal lesions and in intact aged rats. The present study examined the behavioral impact of intrahippocampal septal cell suspension transplants (T) in young female rats that had received, 10 days earlier, either medial fimbria lesions (Group FI.T), dorsal (subcallosal) fornix lesions (Group FO.T) or these two lesions together (Group FIFO.T). Relative to rats with lesions only (groups FI, FO and FIFO), grafted rats, irrespective of lesion locus, displayed unexpected impairments in (i) a serial alternation learning task, 5 weeks and 6 months after transplantation, and (ii) in a radial maze, 7 months after transplantation. In the first alternation test, Group FIFO showed impaired performance relative to Groups FI, FO and the sham-operated controls (Group S). In the second alternation test, Groups FO.T and FO showed impaired performance relative to Groups FI.T and FI, and only the performance of Group FI did not differ from that of Group S. In the radial maze, Groups FI, FO and FIFO all showed impaired performance relative to Group S. By contrast, there were no deleterious effects of lesions or of grafts in the acquisition and retention of a step-through passive avoidance task, 10 weeks after transplantation. Our findings on the effects of selective fimbria-fornix lesions did not confirm the report that rats with FI lesions but not those with FO lesions are unable to learn a serial alternation task, nor the report that FO lesions impair passive avoidance retention. Acetylcholinesterase (AChE) histochemistry revealed that grafts were present but graft-derived innervation of the host hippocampus varied from extensive to almost non-existent in all transplant groups. AChE-positivity in the dorsal hippocampus (DH) was not related to behavioral performance. However, the grafts often grew to a considerable size within the host brain and in many rats, especially those in Group FI.T, produced moderate to extreme damage of the host DH. There was a significant positive correlation between errors in the radial maze and graft-induced DH damage but no relationship between errors and graft size. The results indicate that, after partial lesions of the fimbria-fornix, intrahippocampal septal grafts survive well but are likely to damage recipient structures and result in behavioral impairments.

Tuning acetylation levels with HAT activators: therapeutic strategy in neurodegenerative diseases.

Neurodegenerative diseases, such as polyglutamine-related diseases, amyotrophic lateral sclerosis, and Alzheimers disease are accompanied by transcriptional dysfunctions, leading to neuronal death. It is becoming more evident that the chromatin acetylation status is impaired during the lifetime of neurons, by a common mechanism related to the loss of function of histone acetyltransferase (HAT) activity. Notably, the HAT termed cAMP response element binding protein (CREB)-binding protein (CBP) was shown to display neuroprotective functions. Several other HATs have now been shown to participate in basic but vital neuronal functions. In addition, there is increasing evidence of several HATs (including CBP), as essential regulators of neuronal plasticity and memory formation processes. In order to counteract neuronal loss and/or memory deficits in neurodegenerative diseases, the current therapeutic strategies involve the use of small molecules antagonizing histone deacetylase (HDAC) activity (i.e. HDAC inhibitors). Although this strategy lacks specificity, some of these molecules display promising therapeutic properties. With the rapidly evolving literature on HATs and their respective functions in neuronal survival and memory formation, it seems essential to envisage direct stimulation of the acetyltransferase function as a new therapeutic tool in neurodegenerative diseases. In this review, we will highlight the present understanding and the future prospects of such therapeutic approach.