The effects of aging on hippocampal and cortical projections of the forebrain cholinergic system

Pre- and post-synaptic cholinergic dysfunction in aged rodent brain regions: new findings and an interpretative review

Age-related impairment of dynamic aspects of central cholinergic neurotransmission has been indicated by many studies of aged rodents, but the regional distribution of cholinergic deficits and the relative contribution of presynaptic hypofunction and reduced acetylcholine release, loss of synaptic integrity or loss of muscarinic receptors remains unclear. This study therefore compared choline acetyltransferase activity (as a structural marker) and sodium-dependent high affinity choline uptake (which reflects both ongoing cholinergic neuronal activity and structural integrity) in the hippocampus, cortex and straitum of male C57BL mice at 3-4, 10-12 or 28-32 months of age. To evaluate the relationship of changes in muscarinic receptors to presynaptic alterations, binding of the antagonist 3H-quinuclidinyl benzilate was compared in membranes prepared from each of these brain regions. High affinity choline uptake was significantly reduced in all three brain regions by 28-32 months of age. This trend was already evident by 10-12 months of age, especially in hippocampus and cortex. By contrast, choline acetyltransferase activity was unchanged in striatum and actually increased in hippocampus and cortex of aged mice. Muscarinic binding was reduced significantly only in striatum and this effect was significant by 10-12 months of age. This decrease in antagonist binding was accompanied by a small but significant reduction in the relative proportion of high affinity agonist sites as defined by carbachol displacement. The impairment of high affinity choline uptake in the absence of a parallel reduction of choline acetyltransferase activity suggests a decline of ongoing cholinergic activity rather than loss of terminal integrity as the basis of presynaptic deficits in aging. This functional decline may be exacerbated by reduction of muscarinic receptors in striatum. Despite considerable literature support for the hypothesis that cholinergic mechanisms are impaired with age, several controversies leave important issues unresolved. Therefore, the present results are discussed in the context of a critical review with emphasis on dynamic properties of presynaptic function which require analysis in experimental animal models. The impact of normal aging on brain cholinergic systems is distinguished from the neurodegenerative changes in Alzheimer disease in that presynaptic function is compromised with a relative preservation of the integrity of innervation.(ABSTRACT TRUNCATED AT 400 WORDS)

Region selective increase in activities of CNS cholinergic marker enzymes during learning of memory tasks in aged rats

The effects of learning memory tasks on activities of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE) in the frontal cortex (FC), hippocampus (HC) and cerebellum of aged rat brains were studied in comparison with those of young adult rats. Aged rats were significantly inferior than young adult rats in both active avoidance (two-way shuttle box) and water-filled multiple T-maze learning. ChAT activity in the FC of aged rats was significantly increased after 5 days of training in an active-avoidance learning task. ChAT activity in the HC of aged rats was also significantly increased after 6 days of training in a water-filled multiple T-maze. These changes did not occur in young adult rats after either 2 or 5 days of active avoidance training, or in aged rats after 10 days of training, both of which were after the maximum level of learning of active avoidance task had been attained. AChE activity was significantly lower in the FC and HC of nontrained aged rats when compared with that of nontrained young adult rats. The reduced activity of AChE in both brain regions of nontrained aged rats rose to almost the same level as that in young adult rats in nontrained and trained states in an active avoidance task. From these findings, it is hypothesized that the task-dependent elevation in the activities of the central nervous system (CNS) cholinergic marker enzymes in trained aged rats may be compensatory changes to keep a relevant level of neurotransmission in the face of specific motor and/or cognitive insults.

Age-related loss of galanin-immunoreactive cells in the rat septal area

We have examined the distribution of galanin-like immunoreactive (LI) cell bodies in the medial septal nucleus (MS) and the nucleus of the diagonal band of Broca (nDBB) of young (3 months) and aged (25-30 months) rats, and assessed their respective contribution to the septohippocampal pathway. Immunohistochemical techniques were used alone or combined with the retrograde transport of a protein-gold complex injected into the dorsal hippocampus. In both groups, galanin-LI cells were observed in the MS and the nDBB. In aged rats, a significant decrease in both the staining intensity and the number of galanin-LI perikarya throughout the MS-nDBB complex was observed. Some immunoreactive cells appeared shrunken. The reduction in cell number ranged from 30 to 85%. There was also a decrease in the proportion of septohippocampal neurons containing galanin in aged rats (13% vs 20% in young animals) which however did not reach statistical significance. These results suggest that galanin-positive cells in the medial septal area undergo alterations with aging in the rat.

Septal alpha-noradrenergic antagonism in vivo blocks the testing-induced activation of septo-hippocampal cholinergic neurones and produces a concomitant deficit in working memory performance of mice

In order to test the hypothesis that alpha-noradrenergic receptors in the septum 1) play an important functional role in the mediation of trans-synaptic control of the neurones of the cholinergic septo-hippocampal pathway and 2) produce resultant modulation of working memory performance, we have investigated the effects in vivo of the acute intraseptal injection of an alpha-antagonist, phenoxybenzamine, in mice. Neurochemical analysis was performed using measures of the kinetics of sodium-dependent high-affinity choline uptake in samples of hippocampus from injected mice and their relevant controls in both quiet conditions and immediately following selective working memory testing in an 8-arm radial maze. Results show that whereas the injection of phenoxybenzamine produces no significant alteration of the activity of the cholinergic septo-hippocampal neurones in quiet conditions, the pretrial (20 min) administration of this drug almost totally abolished the usually observed increase in hippocampal cholinergic activity induced by testing. This inhibition of cholinergic activation was associated with a parallel working memory deficit. The results provide further direct support for the hypothesis that septal noradrenergic afferents via alpha-receptors mediate a phasic and net excitatory trans-synaptic influence on the cholinergic septo-hippocampal pathway during working memory testing and thereby significantly contribute to the modulation of the level of working memory performance.

Intracellular storage and evoked release of acetylcholine from postnatal rat basal forebrain cholinergic neurons in culture with nerve growth factor

Cholinergic neurons from the septum area, the vertical limb of the diagonal band of Broca, and the nucleus basalis of Meynert of postnatal 13-day-old rats were cultured with or without nerve growth factor (NGF) conditions. Total choline acetyltransferase (ChAT) activities, acetylcholine (ACh) contents, and survival numbers of cholinergic neurons in culture from each of three distinct regions were increased by NGF treatment, but little difference was found in cellular ChAT activities and ACh contents obtained in cultures with or without NGF. The result shows that NGF promotes the survival of cholinergic neurons from 13-day-old rats. Furthermore, the release of ACh from cultured neurons was investigated. The cells cultured with NGF showed a larger increase of the high K+-evoked ACh release than those cultured without NGF. However, NGF had no effect on spontaneous release. This suggests that NGF could regenerate and sustain the stimulation-evoked release mechanisms of ACh in cultured cholinergic neurons from postnatal rats.

Characterization of a 3H-arginine8-vasopressin binding site in the cingulate gyrus of the rat pup

Autoradiographic analysis of 1, 8, 16 and 26-day-old rat brains showed 3H-arginine8-vasopressin (3H-AVP) binding to the cingulate gyrus-dorsal hippocampus (CG) only in the 8-day-old rat brain. Saturation analysis of CG membranes prepared from pups (7-10 days) and adults (90 days) revealed a small but significant increase in binding site concentration in adults compared to pups. However, the Kd of the 3H-AVP binding site increased significantly with age. The Kd of 3H-AVP binding to pup CG membranes was 0.9 +/- 0.1 nM, while the adult CG was 5.7 +/- 1.0 nM. The pharmacological specificity of 3H-AVP binding sites in the pup and adult CG was similar, but differed markedly from the profile observed in adult septal membranes. The primary specificity difference between the pup CG and septum was the reduced potency of certain V1 receptor antagonists. In competition experiments the CG binding site showed a reduced affinity for the V1 antagonist, [d(CH2)5, Tyr(Me)]AVP. This reduced affinity for the V1 antagonist was also documented autoradiographically using 3H-[d(CH2)5, Tyr(Me)]AVP. The data suggest that the 3H-AVP binding site expressed in the pup CG is not identical to the V1 type receptor present in the periphery and brain of the adult rat.

Loss of NGF receptor immunoreactivity in basal forebrain neurons of aged rats: correlation with spatial memory impairment

Nerve growth factor (NGF) has recently been implicated as a trophic agent in the survival and maintenance of basal forebrain cholinergic neurons. To test the hypothesis that NGF may play a role in the age-related decline of cerebral cholinergic function and loss of cognitive ability, we investigated the possible correlation between the loss of basal forebrain neurons that stain for NGF receptor, and impairment of spatial reference memory performance in aged rats. Our results suggest that NGF receptor-positive basal forebrain neurons undergo marked cell atrophy and loss of neuropil staining in aged rats exhibiting impaired spatial learning and memory performance. Conversely, numerous, densely immunoreactive perikarya and a profuse neuritic plexus within the basal forebrain nuclei was consistently observed in behaviorally intact rats. Overall, the mean number of NGF receptor-positive basal forebrain neurons both in the nucleus of the diagonal band and nucleus basalis correlated with retention of the spatial task (r = 0.84 and r = 0.67, respectively; P less than 0.01). Our results support the view that progressive failure of retrograde trophic support due to the age-related loss of NGF receptors may promote degenerative changes in basal forebrain cholinergic neurons, and contribute to deterioration of cognitive ability in senescence.

Age-related decline of acetylcholine release evoked by depolarizing stimulation

Release of endogenous acetylcholine (ACh) from the dorsal hippocampus in response to depolarizing stimulation with high-K+ infusion was examined in young and aged rats using the method of in vivo dialysis. ACh content in the dialysate was determined by high-performance liquid chromatography-electrochemical detection (HPCC-ECD). During the high-K+ stimulation, the concentration of ACh in the dialysate only slightly increased in aged rats in contrast with young rats where the ACh content during stimulation increased about 2-fold of the basal level. These results showed that ACh release evoked by depolarizing stimulation declined through aging in the hippocampus.

Elevated dynorphin in the hippocampal formation of aged rats: relation to cognitive impairment on a spatial learning task

Radioimmunoassay revealed increased dynorphin A(1-8)-like immunoreactivity [dynA(1-8)LI] in the aged rat brain. Among a number of brain regions examined, an age-related dynA(1-8)LI elevation was found only in the hippocampal formation and frontal cortex. Moreover, the increase in dynA(1-8)LI in the aged hippocampus was associated with a decline in spatial learning ability: dynA(1-8)LI distinguished aged rats that were behaviorally impaired from aged cohorts that learned the spatial task as rapidly as younger animals. Northern blot hybridization using a 32P-labeled complementary RNA probe encoding rat prodynorphin indicated that the abundance of prodynorphin mRNA was also significantly increased in the hippocampal formation of aged rats with identified spatial learning impairments.

Neuronal membrane depolarization and the control of cholinergic muscarinic receptors: selective effect on different neuronal cell types

1. The possibility that a long-lasting neuronal activation regulates the expression of muscarinic cholinergic receptors was studied with three cultured neuronal cell lines. 2. Continuous depolarization of a subclone of the neuroblastoma-glioma NG108-15 hybrid cells with potassium chloride increased by 45-75% the number of cholinergic muscarinic receptors, monitored with 3H-QNB, whereas a short incubation with KCl for 10 min or 6 hr had no effect. 3. The calcium channel blocker verapamil increased the effect of KCl. 4. Two cell lines, named SC9 and WC5, that originate from the rat brain, also bind 3H-QNB. They were therefore used to test whether the effect of chronic depolarization is universal. Depolarized SC9 and WC5 cells, in the presence or absence of verapamil, did not show an increased 3H-QNB binding. 5. Muscarinic receptors of both SC9 and WC5 cells have a higher affinity to pirenzepine than the M-3 receptor subtype of the neuroblastoma-glioma cells, suggesting therefore that the two rat brain cell lines possess M-1 or M-2 receptors. 6. The physiological significance of this differential role of depolarization on the expression of different muscarinic receptors is discussed in the context of their postreceptor second messengers.

Age-related impairment in complex maze learning in rats: relationship to neophobia and cholinergic antagonism

Scopolamine was utilized to assess cholinergic muscarinic blockade on the performance of young (3 months) and aged (23 months) male F-344 rats in a 14-unit T-maze task. Prior to training, a portion of each age group received a gustatory neophobia test (percent consumption of a novel sucrose solution) to assess involvement of norepinephrine systems implicated in age-related impairments of rats in other memory tasks. All rats were pretrained in one-way active avoidance (1.0 mA) on 3 consecutive days. Rats meeting criterion (8/10 avoidances on last day) began maze training the next day consisting of 10 trials on 2 consecutive days. The task required the rat to negotiate each of 5 maze segments within 10 sec to avoid scrambled footshock (1.0 mA). Rats received an intraperitoneal injection of either scopolamine hydrochloride (0.5 mg/kg or 0.75 mg/kg) or saline vehicle 30 min prior to maze testing. Consistent with past reports, aged rats were more neophobic (i.e., consumed less sucrose) than were young rats, but the degree of neophobia was not significantly correlated with maze error performance in either age group. Also consistent with previous studies, aged rats were significantly impaired, compared to young counterparts, in all maze performance measures including errors, alternation errors, runtime, and shock frequency and duration. Significant scopolamine-induced deficits were observed in both age groups, but only in errors and alternation strategy. No age by drug interaction was manifested in any performance measure indicating that scopolamine impaired learning of young and aged rats equivalently.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of concurrent manipulations of cholinergic and noradrenergic function on learning and retention in mice

Interactions between the neuromodulators acetylcholine and norepinephrine (NE) have been reported in both developmental neural plasticity and learning and memory. In a test of the generality of this phenomenon, we assessed the amnestic effects of the muscarinic antagonist scopolamine in normal and NE-depleted mice. Pretraining administration of scopolamine impaired 24-h retention of inhibitory (passive) avoidance training (at doses of 0.1, 0.3 and 1.0 mg/kg) and the acquisition of place-training in a water maze (at a dose of 1.0 mg/kg). NE depletion resulting from systemic administration of DSP-4 did not affect performance on these tasks and did not significantly alter the effects of scopolamine. NE depletion did, however, impair the retention of place learning when mice were retested 16 days after initial training; and this impairment in the retest was additive with one observed in mice originally trained under scopolamine. Normal acquisition but rapid forgetting has also been reported in aged rodents, who display deterioration of the noradrenergic system. Thus, observation of a similar pattern of performance consequent to experimental NE depletion suggests a role for noradrenergic dysfunction in age-related memory decline.

Degenerative Changes in Forebrain Cholinergic Nuclei Correlate with Cognitive Impairments in Aged Rats

Degenerative changes in the forebrain cholinergic nuclei have been studied morphometrically in behaviourally characterized aged female Sprague-Dawley rats. In all regions analysed (medial septum, diagonal band of Broca, nucleus basalis, and striatum) the acetylcholinesterase-positive neurons were reduced in both size and number in the aged (24-months-old) rats as compared to the young (3-months-old) controls. The overall reduction in cell size amounted to between 20 and 30% and the overall reduction in cell number to between 27 and 45%. Impairment in learning and/or memory performance in the aged rats, as assessed in the Morris' water-maze task, was significantly correlated with both cholinergic cell size and cell number in the medial septum, and with cholinergic cell number in the diagonal band of Broca and in the striatum. In the nucleus basalis there was a trend in the same direction but it did not reach significance. In contrast to these degenerative changes in the cell body regions, no significant differences in cortical or hippocampal choline acetyltransferase activity were detected biochemically between the young and the aged rats, and the enzyme activity levels did not correlate with the degree of behavioural impairment in the aged rats. The present results provide evidence that all major forebrain cholinergic cell groups undergo degenerative changes with age in the rat, and that the most severe changes are found in those rats which display the most profound spatial learning impairments. Despite the severe changes at the cell body level, however, the choline acetyltransferase activity in the cortical projection areas are affected only to a minor degree, perhaps as a result of functional compensatory changes at the terminal level.

Local cerebral glucose utilization in the autoimmune New Zealand black (NZB) mouse

By means of the [14C]-2-deoxyglucose method the local cerebral glucose utilization (LCGU) was measured in 41 brain regions in autoimmune New Zealand Black (NZB) mice and in Carworth Farm Winkelmann (CFW) mice, which served as the control strain. At the age of 6 months, the mean LCGU of all measured areas and brain stem nuclei was 67.7 mumol glucose/(100 g x min) in the nonautoimmune CFW mice. These LCGU values are within the limits published by other observers. In contrast, in the aged-matched NZB mice the glucose use was markedly reduced, the mean LCGU of all measured areas being 37.7 mumol glucose/(100 g x min). These findings suggest that the immunological, morphological and behavioural abnormalities in the aged NZB mouse correlate with a reduced functional activity of the central nervous system, measured as reduced cerebral glucose utilization.

Local cerebral glucose utilization in the hippocampus of old rats

The local cerebral glucose utilization (LCGU) was measured in the different areas and layers of the Ammon's horn and dentate gyrus of young adult (3 to 4-month-old) rats, and of 27-month-old rats with proven cognitive deficits. The LCGU was determined by quantitative [14C]2-deoxyglucose autoradiography. Compared to young animals, in the old rats the LCGU was significantly reduced by 12% to 15% in the oriens layers of CA1 and CA2, the pyramidal layers of the CA sectors 1-3, the radiatum and lacunosum-molecular layers of CA2 and CA3 and in the lucidum layer of CA3. The LCGU values of all the other layers of the Ammon's horn and the dentate gyrus did not differ significantly between young and old rats. The pattern of the LCGU reduction found in the old rats roughly resembles changes found after fimbra-fornix lesions or systemic administration of scopolamine, suggesting a functionally important deficit in the cholinergic innervation of the old rats' hippocampi.

Cortical cholinergic fibers in aging and Alzheimer's disease: a morphometric study

A histochemical method for acetylcholinesterase was used to assess the regional density of acetylcholinesterase-rich (putatively cholinergic) axons in the cerebral cortex. A dense plexus of these fibers was observed in all cortical areas. The entorhinal, cingulate and inferotemporal regions were used for quantitative analysis. The paralimbic cortical areas (entorhinal and cingulate) contained a higher density of acetylcholinesterase-rich fibers than the association cortex of inferotemporal area TE. The more superficial layers in all three regions contained a denser net of these fibers than did the deep layers. Aging was accompanied by a modest loss in the density of acetylcholinesterase-positive fibers in the entorhinal and inferotemporal cortex but not in the cingulate area. In brains from patients with Alzheimer's disease, a dramatic loss of these fibers was observed in all three areas examined but the loss was relatively less pronounced in the cingulate area. The results demonstrate that the cholinergic innervation of the cerebral cortex in the human brain displays considerable regional and laminar variations. Regional variations were also observed in the alterations that the cortical cholinergic fibers displayed as a result of normal aging and Alzheimer's disease. The age-related reduction observed in the density of cholinergic fibers in the cerebral cortex was quite modest when compared with the dramatic loss in Alzheimer's disease.

Brain cholinergic enzymes and cortical EEG activity in young and old rats

1. Cholinergic enzymes (ChAT, AChE) in different areas of the brain and cortical electroencephalography (EEG) activity were investigated in young and old rats. 2. In old rats, ChAT activity was low in the striatum, but high in the amygdala. Compared to young rats, ChAT activity in old rats was unchanged in the frontal, parietal/occipital and entorhinal cortex as well as in the hypothalamus, midbrain, hippocampus and brain stem. 3. AChE activity in old rats was lower than in young animals in the parietal/occipital cortex, hippocampus, striatum and brainstem. In other areas of the brain AChE activity was unchanged. 4. In old rats the peak frequency (Fp) of cortical EEG activity (mobility-related) was significantly lower than in young animals, both frontally and occipitally. The power of 5-10 Hz frequency band was markedly lower than in young rats. During immobility, the power of the 1.5-3 Hz and 3-5 Hz bands was lower in the frontal cortex of old rats. The power of 3-5 Hz, 5-10 Hz and 10-20 Hz bands was lower in the occipital cortex of old rats. In all of the old rats, but not in any of the young ones, symmetric high voltage activity was observed in the frontal pole of the cortex. 5. These results suggest that the age-related decrease of higher frequencies of cortical EEG activity may be related to the decrease of AChE activity in the parietal/occipital cortex. This decrease in AChE may reflect degeneration of the cholinergic synapses.

Basal forebrain efferents to the medial dorsal thalamic nucleus in the rhesus monkey

Thalamic efferent connections of the basal forebrain (BF); medial septal nucleus (MS), vertical limb of the diagonal band (VDB), horizontal limb of the diagonal band (HDB), nucleus basalis (NB), and ventral pallidum (VP) were investigated in twelve rhesus monkeys. In five animals, injections of radioactively labeled amino acids were placed in the BF. In four animals, the injections involved different divisions of the NB, HDB, and the most ventral part of the VDB. In those four cases, labeled fibers in the medial forebrain bundle were observed traveling caudally towards the hypothalamus where some turned dorsally to enter the inferior thalamic peduncle. These fibers terminated in the ventral half of the magnocellular part of the medial dorsal thalamic nucleus (MDmc). In a fifth case, the amino acid injection involved most of the MS and the VDB. Labeled fibers traveled caudally from the injection site and entered the stria medullaris. These fibers then traveled caudally before turning ventrally to terminate in the dorsal half of MDmc. To determine which of the diverse neuronal types in the BF gives rise to these thalamic projections, in two monkeys injections of horseradish peroxidase (HRP) were placed into MDmc. Labeled neurons were observed throughout the full extent of the NB, the VDB, the MS, and part of the VP. In order to determine the extent of the cholinergic input to MDmc from the BF, one of the HRP cases was processed for the simultaneous visualization of HRP, and acetylcholinesterase (AChE), the hydrolytic enzyme for acetylcholine, and a second case was processed for simultaneous visualization of HRP, and choline acetyltransferase (ChAT), the synthetic enzyme for acetylcholine. We observed that 30-50% of the HRP-labeled neurons were putatively cholinergic. In order to determine if the NB projection to MD is a collateral of the NB projection to orbital frontal cortex, one fluorescent retrograde tracer was injected into the orbital frontal cortex and one into MD. This case showed that approximately 5% of the BF neurons that project to MDmc also project to the orbital frontal cortex. These results confirm a significant subcortical projection by which the cholinergic system of the basal forebrain may influence higher cortical functions through the thalamus.