Enhancement of choline acetyltransferase activity in coculture of rat septal and hippocampal neurons

We report that choline acetyltransferase (ChAT) activity and neuronal survival were enhanced in rat septal neurons cocultured with hippocampal neurons. The enhancement of ChAT activity also occurred as a result of the addition of hippocampal conditioned medium (HpCM). When septal neurons from embryonic day 17 (E17) rats were cocultured with hippocampal neurons, ChAT activity was increased 2-fold compared with homogeneous culture of septal neurons. By contrast, no increase in ChAT activity was observed in coculture of septal and neocortical neurons. Treatment with HpCM obtained from cultured E19 rat hippocampal neurons enhanced the ChAT activity of E17 rat septal neurons. The enhancement of ChAT activity caused by coculture with hippocampal neurons and that caused by the addition of HpCM were not blocked by the addition of anti-nerve growth factor (NGF) antibody, suggesting that NGF, which is known to increase the ChAT activity of septal neurons both in vivo and in vitro, did not participate in the increase of ChAT activity. These findings indicate that possible target-derived neurotrophic factor(s), other than NGF, from hippocampal neurons enhance(s) the ChAT activity of septal neurons.     

血管性痴呆小鼠海马胆碱乙酰转移酶mRNA表达特征及石杉碱甲的影响

目的观测石杉碱甲对血管性痴呆小鼠海马神经元胆碱乙酰转移酶(ChAT)原位杂交的影响,进一步研究其在血管性痴呆发病中的作用及石杉碱甲对其影响的机制。方法双侧颈总动脉线结,反复缺血-再灌注法制备模型,药物组用石杉碱甲溶液灌胃,跳台试验和水迷宫试验观测其行为学改变,采用原位杂交技术观测小鼠海马神经元ChAT mRNA的表达变化。结果石杉碱甲组小鼠学习、记忆成绩优于模型组(P<0.01),其海马ChATmRNA表达也明显增高(P<0.01)。结论石杉碱甲改善血管性痴呆小鼠学习、记忆成绩与其恢复海马低水平的ChAT mRNA有关。     

Enhancement of spatial learning in F344 rats by physical activity and related learning-associated alterations in hippocampal and cortical cholinergic functioning.

The effects of physical activity on spatial memory performance and associated cholinergic function were examined in F344 rats. Cholinergic analysis included resting and depolarization-induced activation of high-affinity choline uptake and muscarinic receptor binding in the hippocampus, parietal cortex and frontal cortex. Rats that were physically trained, using chronic treadmill running, demonstrated significantly enhanced performance on the spatial learning task, both in second trial latency and first and second trial proximity ratio scores (P less than 0.002). Concomitant with enhanced behavioral performance were neurochemical changes of a reduction in hippocampal high-affinity choline uptake, an upregulation of muscarinic receptor density, and an increase in high-affinity choline uptake 24 h after spatial memory testing (P less than 0.05). Spatial memory tested rats demonstrated enhanced depolarization-induced activation of high-affinity choline uptake (P less than 0.001). Rats that were yoked for swim time to spatial memory tested rats did not show any spatial learning-induced alterations in high affinity choline uptake. These spatial learning- and physical activity-induced cholinergic alterations were observed only in the hippocampus, not in the parietal or frontal cortex. These data indicate that the chronic running-induced alterations in hippocampal high-affinity choline uptake and upregulation of muscarinic receptor density, in combination with enhancement of high-affinity choline uptake related to spatial learning, may contribute to the enhanced spatial learning performance of chronic-run rats.     

Amygdala kindling-induced seizures selectively impair spatial memory. 2. Effects on hippocampal neuronal and glial muscarinic acetylcholine receptor.

The muscarinic acetylcholine receptor is linked via hydrolysis of phosphoinositides to the protein kinase C pathway. In a preceding paper (Beldhuis, H. J. A., H. G. J. Everts, E. A. Vander Zee, P. G. M. Luiten, and B. Bohus (1992) Amygdala kindling-induced seizures selectively impair spatial memory. 1. Behavioral characteristics and effects on hippocampal neuronal protein kinase C isoforms. Hippocampus 2:397-410), the role of different isoforms of protein kinase C in neurobiological processes associated with plasticity was studied using both a spatial learning paradigm and amygdala kindling in the rat. This study extended the findings on protein kinase C activity to the level of the muscarinic acetylcholine receptor. Rats were trained in a spatial learning paradigm and kindled simultaneously in the amygdala to develop generalized motor convulsions. Control rats were trained only in the spatial learning paradigm to acquire stable working and reference memory performance. Alteration in the expression of the muscarinic acetylcholine receptor was investigated using a monoclonal antibody to muscarinic acetylcholine receptor proteins. Trained control rats that were exposed repeatedly to the spatial learning paradigm showed an increase in immunoreactivity for the muscarinic acetylcholine receptor located in the same hippocampal regions in which the protein kinase C activity was increased. In fully kindled rats, however, this increase located in principal neurons was absent, whereas expression of muscarinic acetylcholine receptor proteins was increased in hippocampal astrocytes. Moreover, fully kindled rats showed an impairment in reference memory performance as compared to trained control rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Choline and acetylcholine metabolism in slice cultures of the newborn rat septum

The incorporation of [3H]choline into acetylcholine and other choline-containing compounds was investigated in slice cultures of the septal area of newborn rats. At choline concentrations in the range of the high affinity transport mechanism (0.1-1 microM) most of the labeled choline was incorporated into phosphorylcholine, followed by lipids, acetylcholine and the free choline pool. Hemicholinium-3 (1-10 microM) lead to a marked decrease of acetylcholine synthesis, whereas choline accumulation or phosphorylcholine synthesis were not decreased. Both basal and K+-induced release of acetylcholine were Ca2+ dependent. The efflux of choline was not stimulated by high K+. When choline was absent from the incubation medium, the slices were able to liberate significant amounts of the [3H]choline previously incorporated into phospholipids, and were also able to synthesize some acetylcholine. In choline-free medium, acetylcholine synthesis was greatly enhanced by depolarization. During the period in culture, there was a decrease of the incorporation rate of [3H]choline into phosphorylcholine and an increase of the incorporation rate into acetylcholine. The tissue structure was well preserved after several weeks in culture. After staining for acetylcholinesterase, the cholinergic neurons in the cultures showed a similar morphology to that seen in situ. The main conclusions of the present study are: cholinergic neurons in slice cultures develop and behave in a manner which is very similar to their in situ counterparts; the main divergence from previous studies of choline metabolism in tissue culture is the substantial incorporation rate of choline into acetylcholine at choline concentrations in the range of the high affinity uptake mechanism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Physical activity effects on hippocampal and parietal cortical cholinergic function and spatial learning in F344 rats

In the present investigation, the effects of physical activity on hippocampal cholinergic function, parietal cortical cholinergic function, and spatial memory were examined in F344 rats. Single bouts of physical activity elevated hippocampal and cortical high affinity choline uptake, whereas chronic physical activity significantly reduced only hippocampal high affinity choline uptake (HACU) and elevated muscarinic (QNB) receptor density. Three weeks prior to the end of the 14-week chronic treadmill running protocol, a group of chronic-run rats and their non-run controls were tested on a stringent version of Whishaw's place learning-set task. Chronic-run rats exhibited enhanced performance on the spatial task by significantly reduced second trial latencies and elevated first and second trial proximity ratio scores. Chronic-run spatial memory tested rats also showed enhanced hippocampal HACU and muscarinic receptor binding. These data indicate that chronic physical activity improves spatial learning performance. This improvement may be due, in part, to a chronic running-induced enhancement of hippocampal cholinergic functioning.     

Effects of raloxifene and estradiol on hippocampal acetylcholine release and spatial learning in the rat

The effects of raloxifene on acquisition of a delayed matching to position (DMP) T-maze task and on hippocampal acetylcholine release were evaluated and compared with estradiol, to determine whether raloxifene has estrogenic effects on cognitive performance and hippocampal cholinergic activity. Ovariectomized rats received continuous treatment with raloxifene (one of two doses), estradiol, or vehicle for 30 days, followed by behavioral training, and then in vivo microdialysis assessment of basal and potassium-stimulated acetylcholine release. The data show that estradiol significantly enhanced DMP acquisition, whereas raloxifene did not. In contrast, both estradiol and the higher dose of raloxifene significantly increased potassium-stimulated acetylcholine release in the hippocampus. These data suggest that, despite increasing evidence for estrogenic effects of raloxifene in brain, raloxifene does not mimic the effects of estrogen on cognitive performance as assessed by acquisition of a simple spatial memory task in ovariectomized rats.     

Chronic brain cytochrome oxidase inhibition selectively alters hippocampal cholinergic innervation and impairs memory: prevention by ladostigil

A 25-35% reduction of brain cytochrome oxidase (COx) activity found in Alzheimer's disease (AD) could contribute to neuronal dysfunction and cognitive impairment. The present study replicated the reduction in brain COx activity in rats by administering sodium azide (NaN(3)) for 4 weeks via Alzet minipumps at the rate of 1 mg/kg/h, and determined its effect on hippocampal cholinergic transmission, spatial and episodic memory. NaN(3) caused a selective reduction in choline acetyltransferase (ChAT) immunoreactivity in the diagonal band, a major source of cholinergic input to the hippocampus and cingulate cortex, without altering the number of cholinergic neurons. NaN(3) also induced a significant increase in vesicular acetylcholine transporter (VAChT)-immunoreactive varicosities, GAP-43 in the subgranular layer and of transferrin receptors (TfR) in the hilus of the dentate gyrus. These neurochemical changes were associated with impairment in spatial learning in the Morris water maze and in episodic memory in the object recognition test. Chronic treatment with ladostigil, a novel cholinesterase and monoamine oxidase inhibitor, prevented the decrease in ChAT in the diagonal band, the compensatory increase in synaptic plasticity and TfR and the memory deficits without restoring COx activity. Ladostigil had no significant effect on ChAT activity, synaptic plasticity or TfR in control rats. Ladostigil may have a beneficial effect on cognitive deficits in AD patients that have a reduction in cortical COx activity and cholinergic hypofunction.     

MKC-231, a choline uptake enhancer,ameliorates working memory deficits and decreased hippocampal acetylcholine induced by ethylcholine aziridinium ion in mice

Summary The effects of acute and chronic administration of MKC-231, a new choline uptake enhancer, and two other nootropic agents, linopiridine (Dup 996) and tetrahydroaminoacridine (THA) on working memory deficits and decreased hippocampal acetylcholine (ACh) content were studied in a delayed non-matching to sample task, using a T-maze, in ethylcholine aziridinium ion (AF64A)-treated mice. Treatment with AF64A (3.5 nmol, i.c.v.) produced memory deficits and decreased hippocampal ACh content. In acute behavioral experiments, MKC-231 and THA had no significant effect on AF64A-induced memory deficits at any doses tested (0.3, 1.0 and 3.0mg/kg), whereas Dup 996, at a dose of 1.0mg/kg, significantly improved memory deficits. In chronic experiments, MKC-231 improved memory deficit at all doses tested (0.3, 1.0, or 3.0mg/kg p.o., once daily for 11 days) and Dup 996 did so only at a dose of 3.0 mg/kg, whereas THA did not improve memory deficit at any doses tested. In acute neurochemical experiments, MKC-231 and THA did not reverse the AF64A-induced hippocampal ACh depletion. Dup 996, however, further decreased hippocampal ACh content compared to that in the AF64A-treated group. In chronic experiments, MKC-231 significantly reversed hippocampal ACh depletion at doses of 0.3 and 1.0mg/kg, whereas neither Dup 996 nor THA reversed hippocampal ACh depletion at any doses tested. These results indicate that MKC-231 improved the AF64A-induced working memory deficit and hippocampal ACh depletion, probably by recovering reduced high-affinity choline uptake and ACh release.     

Differential long-term effect of AF64A on [3H]ACh synthesis and release in rat hippocampal synaptosomes.

The activities of various presynaptic cholinergic parameters were determined in hippocampal synaptosomes of rats 29 weeks after intracerebroventricular injection of ethylcholine aziridinium (AF64A) (3 nmol/2 microliters/side) or vehicle (saline). Synaptosomes were preloaded with [3H]choline ([3H]Ch), treated with diisopropyl fluorophosphate to inhibit cholinesterase activity and then were assayed for their content of [3H]Ch and [3H]acetylcholine ([3H]ACh) and for their ability to synthesize and release [3H]ACh. In synaptosomes from AF64A-treated rats compared with synaptosomes from vehicle-treated rats we observed that: (i) specific uptake of [3H]Ch was reduced to 60% of control; (ii) residing [3H]ACh levels were 43% of control while residing [3H]Ch levels were 72% of control; (iii) basal and K(+)-induced [3H]ACh release were 77% and 73% of control, respectively; (iv) high K(+)-induced synthesis of [3H]ACh was only 9% of control; (v) but, choline acetyltransferase activity remained relatively high, being 80% of control. These results suggest that AF64A-induced cholinergic hypofunction is expressed by both loss of some cholinergic neurons and impairment in the functioning of the spared neurons.     

Hippocampal place cell dysfunction and the effects of muscarinic M1 receptor agonism in a rat model of Alzheimer's disease

Alzheimer's disease (AD) is a neurodegenerative disease that disproportionately impacts memory and the hippocampus. However, it is unclear how AD pathology influences the activity of surviving neurons in the hippocampus to contribute to the memory symptoms in AD. One well‐understood connection between spatial memory and neuronal activity in healthy brains is the activity of place cells, neurons in the hippocampus that fire preferentially in a specific location of a given environment (the place field of the place cell). In the present study, place cells were recorded from the hippocampus in a recently‐developed rat model of AD (Tg‐F344 AD) at an age (12–20 months) at which the AD rats showed marked spatial memory deficits. Place cells in the CA2 and CA3 pyramidal regions of the hippocampus in AD rats showed sharply reduced spatial fidelity relative to wild‐type (WT) rats. In contrast, spiking activity of place cells recorded in region CA1 in AD rats showed good spatial fidelity that was similar to CA1 place cells in WT rats. Oral administration of the M₁ muscarinic acetylcholine receptor agonist VU0364572 impacted place cell firing rates in CA1 and CA2/3 hippocampal regions, but did not improve the spatial fidelity of CA2/3 hippocampal place cells in AD rats. The results indicated that, to the extent the spatial memory impairment in AD rats was attributable to hippocampal dysfunction, the memory impairment was more attributable to dysfunction in hippocampal regions CA2 and CA3 rather than CA1.     

Memory-improving action of glucose: indirect evidence for a facilitation of hippocampal acetylcholine synthesis

The effect of a 3 g/kg glucose injection on the velocity of the sodium-dependent high-affinity choline uptake mechanism in the hippocampus was both measured in quiet control mice and in mice immediately after training in an operant bar pressing task. Glucose did not significantly change high-affinity choline uptake in resting animals. High-affinity choline uptake in the hippocampus was increased by training in the operant bar pressing task. Glucose significantly reduced the amplitude of the increase in high-affinity choline uptake observed in the trained animals. Similarly, a 3 g/kg glucose injection also attenuated the increase in high-affinity choline uptake observed in animals injected with 1 mg/kg scopolamine. Finally, a 3 g/kg glucose injection significantly attenuated the amnesia produced by a post-training 1 mg/kg scopolamine injection in mice trained for an operant bar pressing task. These results provide additional evidence for an action of glucose on hippocampal cholinergic activity under conditions of high acetylcholine demand. This action may be mediated via an increase in acetyl coenzyme A availability, one of the precursors of acetylcholine. This facilitative effect of glucose on hippocampal acetylcholine synthesis may constitute the physiological basis for its facilitative action on memory and its attenuation of scopolamine amnesia.     

Electroacupuncture in rats normalizes the diabetes‐induced alterations in the septo‐hippocampal cholinergic system

Diabetes induces early sufferance in the cholinergic septo‐hippocampal system, characterized by deficits in learning and memory, reduced hippocampal plasticity and abnormal pro‐nerve growth factor (proNGF) release from hippocampal cells, all linked to dysfunctions in the muscarinic cholinergic modulation of hippocampal physiology. These alterations are associated with dysregulation of several cholinergic markers, such as the NGF receptor system and the acetylcholine biosynthetic enzyme choline‐acetyl transferase (ChAT), in the medial septum and its target, the hippocampus. Controlled and repeated sensory stimulation by electroacupuncture has been proven effective in counteracting the consequences of diabetes on cholinergic system physiology in the brain. Here, we used a well‐established Type 1 diabetes model, obtained by injecting young adult male rats with streptozotocin, to induce sufferance in the septo‐hippocampal system. We then evaluated the effects of a 3‐week treatment with low‐frequency electroacupuncture on: (a) the expression and protein distribution of proNGF in the hippocampus, (b) the tissue distribution and content of NGF receptors in the medial septum, (c) the neuronal cholinergic and glial phenotype in the septo‐hippocampal circuitry. Twice‐a‐week treatment with low‐frequency electroacupuncture normalized, in both hippocampus and medial septum, the ratio between the neurotrophic NGF and its neurotoxic counterpart, the precursor proNGF. Electroacupuncture regulated the balance between the two major proNGF variants (proNGF‐A and proNGF‐B) at both gene expression and protein synthesis levels. In addition, electroacupuncture recovered to basal level the pro‐neurotrophic NGF receptor tropomyosin receptor kinase‐A content, down‐regulated in medial septum cholinergic neurons by diabetes. Electroacupuncture also regulated ChAT content in medial septum neurons and its anterograde transport toward the hippocampus. Our data indicate that repeated sensory stimulation can positively affect brain circuits involved in learning and memory, reverting early impairment induced by diabetes development. Electroacupuncture could exert its effects on the septo‐hippocampal cholinergic neurotransmission in diabetic rats, not only by rescuing the hippocampal muscarinic responsivity, as previously described, but also normalizing acetylcholine biosynthesis and NGF metabolism in the hippocampus.     

Cannabinoid-induced working memory impairment is reversed by a second generation cholinesterase inhibitor in rats

Cannabinoids which impair rat working memory appear to inhibit hippocampal extracellular acetylcholine (Ach) release and reduce choline uptake through an interaction with CB1 cannabinoid receptors. Here we report that CP 55,940, a potent bicyclic synthetic cannabinoid analog, dose-dependently impaired rat performance, when given i.p. 20 min before an eight-arm radial maze test. The selective CB1 cannabinoid receptor antagonist SR 141716A, given i.p. 20 min earlier, significantly reduced the memory deficit Pretreatment with eptastigmine, a second generation cholinesterase inhibitor, given orally 100 min before the cannabinoid agonist, relieved the memory impairment without affecting CP 55,940-induced behavioural alterations such as reduced spontaneous motor activity, analgesia and hind limb splaying. These data suggest that cannabinoid-induced working memory impairment is mediated through a central cholinergic blockade.     

Pregnenolone sulfate increases hippocampal acetylcholine release and spatial recognition

The pregnenolone sulfate is a neurosteroid with promnesic properties. Recently, a correlation between endogenous levels of pregnenolone sulfate in the hippocampus and performance in a spatial memory task has been reported in aged rats. Cholinergic transmission is known to modulate memory processes and to be altered with age. In the present experiment we investigated the effect of increasing doses of pregnenolone sulfate on hippocampal acetylcholine release. Our results show that intracerebroventricular administrations of this neurosteroid induced a dose-dependent increase in acetylcholine release. Administration of 12 and 48 nmol of pregnenolone sulfate induced a short lasting (20 min) enhancement of acetylcholine output with a maximum around 120% over baseline and the administration of 96 and 192 nmol doses induced a long-lasting (80 min) increase that peaked around 300% over baseline. In a second experiment we have observed that the 12 nmol dose enhanced spatial memory performance, whereas the 192 nmol dose was inefficient. These results are consistent with previous work suggesting that, a modest increase in acetylcholine release facilitates memory processes, while elevation beyond an optimal level is ineffective. Nevertheless, neurosteroids may be of value for reinforcing depressed cholinergic transmission in certain age-related memory disorders.     

Changes in Cholinergic Neurons and Failure in Learning Function After Microsphere Embolism-Induced Cerebral Ischemia

Central cholinergic neurons play an important role in learning and memory functions. The present study was undertaken to elucidate the pathological changes in learning function and acetylcholine metabolism of the cerebral cortex and hippocampus, following microsphere embolism in rats. Microspheres (48

Full-size image

) were injected into the right internal carotid artery of the rats. Learning function was determined using a passive avoidance task on the seventh day after the embolism. In the biochemical study, acetylcholine and choline contents, and choline acetyltransferase activity were measured in the cerebral cortex and hippocampus. Cortical acetylcholinesterase-containing fibers were quantitatively estimated in the embolized rat. Passive avoidance was impaired in the microsphere-embolized rat. Microsphere embolism decreased the acetylcholine concentration and choline acetyltransferase activity in the cerebral cortex and hippocampus. In the histochemical study, the length of cortical acetylcholinesterase-containing fibers was decreased, but cell density was unchanged in the ipsilateral hemisphere of the microsphere-embolized rat. The results suggest that microsphere embolism induces severe damage to cholinergic neurons, which may be related to the impairment of learning function in the ischemic brain.     

Experimental immune-mediated damage of septal cholinergic neurons

Degeneration of cholinergic neurons in the medial septum and the diagonal band of Broca is a frequent neuropathological feature of Alzheimer's disease. To determine whether an immune process can injure these basal forebrain cholinergic neurons, we serially immunized guinea pigs with septal cholinergic hybrid cells (SN-56). Following immunization, a relatively selective damage of septal cholinergic neurons, reduction in septal choline acetyltransferase (ChAT) activity and decrease in acetylcholine release in hippocampus were detected. Serum IgG from guinea pigs immunized with SN-56 cells and stereotactically injected into the medial septal region of rats produced a loss of ChAT activity in the medial septum, frontal cortex and hippocampus, together with impairment of learning and long term spatial memory. These data suggest that relatively selective damage to septal cholinergic neurons can be caused by an immune-mediated process in experimental animals.     

Intrahippocampal amyloid-β (1-40) injections injure medial septal neurons in rats

Alzheimer's disease (AD) is a devastating disorder that leads to memory loss and dementia. Neurodegeneration of cholinergic neurons in the septum and other basal forebrain areas is evident in early stages of AD. Glutamatergic neurons are also affected early in AD. In these stages, amyloid-β-peptide (Aβ) plaques are present in the hippocampus and other cortices but not in the basal forebrain, which includes the septum. We postulate that early deposition of hippocampal Aβ damages the axon terminals of cholinergic and glutamatergic septo-hippocampal neurons, leading to their degeneration. To determine the mechanisms underlying septal degeneration, fibrillar Aβ1-40 was injected into the Cornu Ammonis (CA1) hippocampal region of rats. Controls were injected with reverse peptide Aβ40-1. A 16% reduction in NeuN+ cells was observed around the injection sites when compared to controls (p < 0.05) one week after injections. Stereology was used to estimate the number of choline acetyl transferase (ChAT), glutamate and glutamic acid decarboxylase 67 (GAD67) immunoreactive septal neurons. Medial septal ChAT and glutamate immunoreactive neurons were reduced 38% and 26%, respectively by hippocampal injections of Aβ1-40 peptide in relation to controls. In contrast, the number of GAD67 inmunoreactive neurons was not significantly reduced. Apoptotic cells were detected in the medial septal region of Aβ1-40 treated animals but not in controls. These results indicate that limited Aβ-induced hippocampal lesions lead to an overall damage of vulnerable septal neuronal populations, most likely by Aβ interaction with septo-hippocampal axon terminals. Thus, axon terminals constitute an important target for novel therapeutics dedicated to control Aβ-induced toxicity.     

5,7-Dihydroxytryptamine lesions enhance and serotonergic grafts normalize the evoked overflow of acetylcholine in rat hippocampal slices

Adult rats were subjected to intracerebroventricular injections of 5,7-dihydroxytryptamine (5,7-DHT; 150 micro g) and, 15 days later, to intrahippocampal grafts of fetal raphe cell suspensions. About 11 months later, we assessed baseline and electrically evoked release of tritium ([3H]) in hippocampal slices, preloaded with tritiated ([3H])choline or [3H]serotonin (5-HT), in the presence or absence of the 5-HT1B receptor agonist CP-93,129 and the 5-HT receptor antagonist methiothepine. HPLC determinations of monoamine concentrations were also performed. The lesions reduced the concentration of 5-HT (-90%) and the accumulation (-80%) as well as the evoked release (-90%) of [3H]5-HT. They also decreased the inhibitory effects of CP-93,129 on the evoked release of [3H]5-HT. Most interestingly, they facilitated the evoked release of [3H]acetylcholine (+20%). In slices from rats subjected to lesions and grafts, the responsiveness of the serotonergic autoreceptors (presumably located on the terminals of the grafted neurons) and the release of acetylcholine were close to normal. These results confirm that grafts rich in serotonergic neurons may partially compensate for the dramatic effects of 5,7-DHT lesions on serotonergic hippocampal functions. The lesion-induced reduction of the 5-HT1B autoreceptor-mediated inhibition of evoked 5-HT release may be an adaptation enhancing serotonergic transmission in the (few) remaining terminals. The facilitated release of acetylcholine is probably caused by a reduced serotonergic tone on the inhibitory 5-HT1B heteroreceptors of the cholinergic terminals. When related to data in the literature, this facilitation may be of particular interest in terms of transmitter-based strategies developed to tackle cognitive symptoms related to neurodegenerative diseases.     

Blockade of hippocampal M1 muscarinic receptors impairs working memory performance of rats

In order to clarify the roles of hippocampal M₁ and M₂ muscarinic receptors in working and reference memory performance of rats, the effects of intrahippocampal injections of selective antagonists at both receptors on this behavior were examined with a three-panel runway task. In the working memory task, the M₁ muscarinic receptor antagonist pirenzepine, injected bilaterally at 0.32 and 1.0 μg/side into the dorsal hippocampus, significantly increased the number of errors (attempts to pass through two incorrect panels of the three panel-gates at four choice points). This effect of intrahippocampal pirenzepine (1.0 μg/side) on working memory was attenuated by concurrent injection of 10 μg/side AF102B, the selective M₁ muscarinic receptor agonist. Intrahippocampal injection of the M₂ muscarinic receptor antagonist methoctramine at doses up to 1.0 μg/side had no significant effect on the number of working memory errors. Intrahippocampal methoctramine injection at 3.2 μg/side produced a significant increase in working memory errors, an effect that was reversed by concurrent injection of 10 μg/side AF102B. Concurrent injection of 0.32 μg/side methoctramine significantly reduced the increase in working memory errors induced by intrahippocampal pirenzepine (1.0 μg/side). In the reference memory task, neither pirenzepine nor methoctramine affected the number of errors when injected into the hippocampus at doses up to 1.0 and 3.2 μg/side, respectively. These results suggest that processes mediated by M₁ muscarinic receptors in the hippocampus are involved in working memory, but not in reference memory, and that blockade of hippocampal M₂ muscarinic receptors ameliorates working memory deficits produced by M₁ muscarinic blockade, possibly by increasing acetylcholine release.