Cerebral ischemic preconditioning induces lasting effects on CA1 neuronal survival, prevents memory impairments but not ischemia-induced hyperactivity

In ischemic preconditioning, prior exposure to a short 3-min global ischemia provides substantial protection against the deleterious effects of a subsequent prolonged ischemic insult in rats. The objective of the present study was to determine if the neuronal protection induced by ischemic preconditioning influence functional recovery following a 6-min ischemic insult in rats. Animals received either sham-operation, a 3-min ischemia, a preconditioning 3-min global ischemia followed 3 days later by a 6-min global ischemia or a single 6-min global ischemia. Open field habituation, memory performance in the 8-arm radial maze and object recognition were assessed at different intervals following ischemia. Our findings revealed that preconditioning reversed ischemia-induced spatial memory deficits in the 8-arm radial maze, as suggested by significant reduction of working memory errors in preconditioned as compared to ischemic animals. Preconditioning also attenuated ischemia-induced object recognition deficits at short-term intervals. Nonetheless, preconditioning failed to alter ischemia-induced hyperactivity as demonstrated by enhanced behavioral activity in the open field in both preconditioned and ischemic animals compared to 3-min ischemic and sham-operated rats. CA1 cell counts revealed significant neuronal sparing in preconditioned animals that was observed 6-month following reperfusion. Together, these findings suggest that neuronal survival in preconditioned rats is associated with significant improvements of hippocampal-dependent memory functions and, further support that ischemia-induced hyperactivity may not solely depend on selective neuronal damage to hippocampal neurons.     

Changes in neuropeptide Y immunoreactivity in the arcuate nucleus during and after food restriction in lactating rats

Previous studies have demonstrated that food restriction during lactation extends the length of lactational infertility in rats. In order to determine whether Neuropeptide Y (NPY) plays a role in the increased length of lactational infertility seen in food-restricted rats, NPY immunoreactivity in the arcuate nucleus of lactating rats that were ad lib fed or food restricted from Day 8 to 14 postpartum was compared. Food-restricted rats showed higher numbers of NPY-stained cells at the end of the food-restriction period (Day 15 postpartum) than did ad lib-fed rats at the same stage of lactation. This difference persisted until Day 25 postpartum although all animals were fed ad libitum from Day 15 onwards. Switching litters between ad lib-fed and food-restricted females from Day 15 until Day 20 postpartum did not eliminate the difference in NPY immunoreactivity between the two diet conditions. Given that food restriction during lactation leads to a prolonged suppression of LH release that also persists after refeeding and is not affected by the nutritional status of the litter, these data are consistent with a role for NPY in the prolonged suppression of reproductive function seen in food restricted lactating rats.     

Anterior thalamic lesions reduce spine density in both hippocampal CA1 and retrosplenial cortex,but enrichment rescues CA1 spines only

Injury to the anterior thalamic nuclei (ATN) may affect both hippocampus and retrosplenial cortex thus explaining some parallels between diencephalic and medial temporal lobe amnesias. We found that standard‐housed rats with ATN lesions, compared with standard‐housed controls, showed reduced spine density in hippocampal CA1 neurons (basal dendrites, ?11.2%; apical dendrites, ?9.6%) and in retrospenial granular b cortex (Rgb) neurons (apical dendrites, ?20.1%) together with spatial memory deficits on cross maze and radial‐arm maze tasks. Additional rats with ATN lesions were also shown to display a severe deficit on spatial working memory in the cross‐maze, but subsequent enriched housing ameliorated their performance on both this task and the radial‐arm maze. These enriched rats with ATN lesions also showed recovery of both basal and apical CA1 spine density to levels comparable to that of the standard‐housed controls, but no recovery of Rgb spine density. Inspection of spine types in the CA1 neurons showed that ATN lesions reduced the density of thin spines and mushroom spines, but not stubby spines; while enrichment promoted recovery of thin spines. Comparison with enriched rats that received pseudo‐training, which provided comparable task‐related experience, but no explicit spatial memory training, suggested that basal CA1 spine density in particular was associated with spatial learning and memory performance. Distal pathology in terms of reduced integrity of hippocampal and retrosplenial microstructure provides clear support for the influence of the ATN lesions on the extended hippocampal system. The reversal by postoperative enrichment of this deficit in the hippocampus but not the retrosplenial cortex may indicate region‐specific mechanisms of recovery after ATN injury. © 2014 Wiley Periodicals, Inc.     

Stress impairs performance in spatial water maze learning tasks

The water maze task has been developed to test spatial learning abilities in rats or mice, and is widely used. Though it has been reported before that numerous cognitive abilities are of importance for learning this task, poor performance is usually interpreted as an impairment of spatial memory formation. Previous investigations that tried to correlate long-term potentiation (LTP) of synaptic transmission with spatial learning abilities in rats reported that injection of drugs or specific gene deletions which blocked the expression of LTP correlated with learning impairments of spatial tasks in a water maze. Recent studies, however, have shown that pretraining enables these animals to learn such spatial tasks even though LTP was still found to be blocked. I investigated to what degree altered fear condition and stress perception could account for the impaired spatial learning when no pretraining is given. In a fear habituation task, unhandled rats preferred a dark over a well lit chamber more than handled animals did, but unhandled rats favoured the lit chamber more in an active avoidance task. They also performed poorly in a spatial water maze task compared with handled rats. Rats pretrained in a radial arm maze performed better in a water maze than non-pretrained rats. No difference between groups was found in a non-spatial water maze task. On the other hand, when pretrained in a water maze, rats performed only marginally better in a radial arm maze compared to non-pretrained animals. Since animals have to be handled to learn a radial arm maze, the difference in this task was not due to stress but most probably due to getting accustomed to the room dimensions prior to learning the spatial task. The results suggest that impaired learning of spatial tasks in the water maze can be due to increased stress and decreased fear conditioning without actually affecting spatial learning abilities. These results question the interpretations of the results of some previously published results of spatial water maze tasks.     

Forebrain ischemia induces selective behavioral impairments associated with hippocampal injury in rats

Two groups of rats were tested on a variety of motor and cognitive tasks after either 10 minutes of two-vessel occlusion forebrain ischemia (n = 8) or sham operative procedures (n = 6). Histological injury was absent in the sham-operated group. In the ischemic group, hippocampal injury was restricted to field CA1, while damage in the neocortex and caudoputamen was sparse. Motor tests performed on postoperative days 18 and 28 revealed no significant differences between the ischemic and sham-operated groups. Retention performance of a radial maze discrimination task was impaired, with a significant but transient increase in both working and reference memory errors. Passive avoidance acquisition and retention were not significantly affected, although conclusions concerning the utility of this task must be reserved because of variability in the behavior of the sham-operated rats. Morris maze spatial navigation (place learning) and open-field activity were insensitive to treatment group. These functional results are consistent with the observed histological injury and what is known about hippocampal injury and behavior, and they provide further guidance for the development of neurological assays appropriate for discriminating outcome from forebrain ischemia in rats.     

Ventromedial Nuclei of the Hypothalamus are Involved in the Phase Advance of Temperature and Activity Rhythms in Food-Restricted Rats Fed During Daytime

Daily rhythms are synchronized to the light-dark cycle (LD) via a circadian clock located in the suprachiasmatic nuclei. A timed caloric restriction phase advances daily rhythms of body temperature and wheel-running activity in rats kept under LD. Because lesions of the ventromedial hypothalamic nuclei (VMH) prevent the fasting-induced changes in the day-night pattern of activity, it was hypothesized that the VMH might participate in the caloric restriction-induced phase changes. To test this hypothesis, rats with electrolytic or ibotenic acid lesions of VMH and control rats were fed 2 h after lights on 50% of ad lib food intake. During the preceding fed state, rats with electrolytic lesions of VMH displayed a less marked day-night difference in locomotor activity and a phase-advanced acrophase of temperature rhythm (2 h) compared to those of sham-operated rats. These effects were not found in fed rats with ibotenic lesions of VMH, suggesting that these effects of electrolytic lesions were due to disruption of undetermined fibers of passage. In response to a timed caloric restriction, the nocturnal peak of temperature rhythm was phase advanced by 7 h in sham-operated rats. Their day-night pattern of activity was also phase advanced towards the time of feeding. In both groups of food-restricted VMH-lesioned rats, the acrophase of temperature rhythm plateaued 3 h later than in sham-operated group. The phase advance of body temperature was, therefore, reduced to 4 h by ibotenic lesions of VMH and to 2 h by electrolytic lesions. Except for a feeding-associated component of activity expressed in control and VMH-lesioned rats, no significant change in day-night pattern of activity was detected in VMH-lesioned rats, either by electrolytic or ibotenic lesions. These results indicate that neuronal damage of the VMH limits the phase-advancing properties of a timed caloric restriction on the daily rhythms of temperature and locomotor activity.     

Persistent behavioral impairments and neuroinflammation following global ischemia in the rat

Cognitive deficits associated with cardiac arrest have been well documented; however, the corresponding deficits in animal models of global ischemia have not been comprehensively assessed, particularly after long‐term, clinically relevant survival times. We exposed male Sprague–Dawley rats to 10 min of bilateral carotid artery occlusion + systemic hypotension (40–45 mmHg) or sham surgery, and used histopathological assessments for short‐term survival animals (16 days) and both behavioral and histopathological assessments for long‐term survival animals (270 days). Analyses revealed significant long‐term deficits in ischemic animals’ learning, memory (T‐maze, radial arm maze), working memory (radial arm maze), and reference memory (Morris water maze, radial arm maze) abilities that were not associated with a general cognitive decline. Histological results showed significant increases in glial fibrillary acidic protein, neuron glia 2, OX‐42 and ED‐1 staining, as well as significant decreases in microtubule‐associated protein 2 staining and cornu ammonis area 1 (CA1) cell counts 16 days post‐ischemia. The pattern at 270 days was similar, but notably there was a persistent elevation of ED‐1 staining, suggesting recent cell death as well as significant atrophy of CA1. Whereas previous work has primarily reported transient changes in behavior after global ischemia, this study describes disturbances in several different functional domains following CA1 cell loss at clinically relevant survival times. Moreover, the histopathological outcome is suggestive of a spontaneous repopulation of CA1, but this was not sufficient to offset the behavioral impairments arising from the ischemic insult.     

A novel version of the 8-arm radial maze: effects of cerebral ischemia on learning and memory

A novel version of the 8-arm radial maze task was developed to quantify spatial learning and memory in rats subjected to transient cerebral ischemia (TCI) using the 4-VO model. This maze uses the rat's natural behavior of avoiding open, illuminated areas, and preference for a darkened, enclosed shelter. Ischemic rats were required to escape from the central area into the darkened goal box. Ischemia was induced before or after training to examine its influence on acquisition and retention of cognition, respectively. During the acquisition test, latency of ischemic rats to find the goal box, and working memory performance were significantly impaired (P < 0.005-0.001). The performance for retention of cognition was also disrupted by ischemia (P < 0.05-0.01). There was no correlation between the degree of CA1 pyramidal cell loss and behavioral deficits. The present data reveal that the aversive version of the 8-arm radial maze is sensitive to the cognitive effects of ischemia. Since it excludes the need for food deprivation or immersion of the animal in water, the method should provide a sensitive and more practical behavioral test with which to evaluate the effects of ischemic brain damage on cognition.     

Differential effects of tumor necrosis factor-alpha co-administered with amyloid beta-peptide (25-35) on memory function and hippocampal damage in rat

Effects of concurrent intracerebroventricular administration of amyloid-beta peptide 25-35 (Abeta(25-35)) and the proinflammatory cytokine tumor necrosis factor-alpha (TNFalpha) to rats were investigated. A battery of behavioral tests including radial arm maze, passive avoidance, elevated plus-maze and forced swim test as well as histological methods were used. A single administration of Abeta(25-35) induced delayed behavioral deficits manifested in reference and working memory disturbances in the radial maze task involving spatial memory. However, no effects of Abeta(25-35) on learning or retention in a passive avoidance test could be revealed. Abeta(25-35) appeared to decrease anxiety without affecting depression-like behavior in the rats. Abeta(25-35)-induced cognitive deficits could be related to the moderate neuronal cell loss found in the hippocampal CA1 field. Though administration of TNFalpha did not impair learning and memory of rats in the radial maze, it induced gross changes in their behavior during passive avoidance training. Though TNFalpha did not protect against Abeta(25-35)-induced neuronal cell loss in the CA1 field of hippocampus, co-administration of TNFalpha with Abeta(25-35) resulted in an improvement of reference memory impaired by the amyloid peptide, but not of working memory.     

Characterizing learning deficits and hippocampal neuron loss following transient global cerebral ischemia in rats

The 2-vessel-occlusion + hypotension (2VO + H) model of transient global cerebral ischemia results in neurodegeneration within the CA1 field of the hippocampus, but previous research has failed to demonstrate robust or reliable learning/memory deficits in rats subjected to this treatment. In the present study, sensitive behavioral protocols were developed in an effort to characterize the cognitive impairments following 2VO + H more precisely. Adult rats were exposed to 10 min of bilateral carotid occlusion with simultaneous hypotension. Following recovery, 2VO + H and control rats were subjected to a series of behavioral tests (locomotor activity, sensorimotor battery, water maze [cued, place, learning set], object recognition, and radial arm maze) over an extended recovery period followed by an assessment of neuronal loss in the dorsal hippocampus. The 2VO + H treatment was associated with long-lasting spatial learning deficits in the absence of other behavioral impairments and with neurodegeneration in dorsal hippocampal CA1. Water maze protocols that placed higher memory demands upon the rats (relatively "hard" vs. "easy") were more sensitive for detecting ischemia-induced deficits. We have shown that the use of appropriate behavioral tests (e.g., a relatively difficult place learning task) allowed for the observation of robust spatial learning deficits in a model previously shown to induce relatively subtle behavioral effects. Thus, the 2VO + H model induces both hippocampal neuronal loss and long-term learning deficits in rats, providing a potentially useful model for evaluating therapeutic efficacy.     

Dentate gyrus-selective colchicine lesion and disruption of performance in spatial tasks: difficulties in "place strategy" because of a lack of flexibility in the use of environmental cues?

The effects of intradentate colchicine injections on the performance of tasks requiring spatial working and reference memory are controversial. Multiple-site colchicine injections (7 microg/microl; via a drawn micropipette) throughout the dentate gyrus (DG) of rats (nine sites in each hemisphere, 0.06 microl at each site) selectively destroy about 90% of the DG granule cells, as revealed by quantitative stereological estimates; stereology also revealed minor neuronal losses in the CA4 (33%) and CA1 (23%) subfields, but lack of damage to the CA3 hippocampal subfield. Spatial reference and working memory were assessed in Morris' water maze; in the reference memory task, the rats were required to learn a single, fixed location for the platform over several days of training; in the working memory task, animals were required to learn a new platform location every day, in a matching-to-place procedure. Compared to sham-operated controls, lesioned rats showed significant disruption in acquisition of the reference memory water maze task; however, the data reveal that these rats did acquire relevant information about the task, probably based on guidance and orientation strategies. In a subsequent probe test, with the platform removed, lesioned rats showed disruption in precise indexes of spatial memory (e.g., driving search towards the surroundings of the former platform location), but not in less precise indexes of spatial location. Finally, the lesioned rats showed no improvement in the match-to-place procedure, suggesting that their working memory for places was disrupted. Thus, although capable of acquiring relevant information about the task, possibly through guidance and/or orientation strategies, DG-lesioned rats exhibit a marked difficulty in place strategies. This is particularly evident when these rats are required to deal with one-trial place learning in a familiar environment, such as in the working memory version of the water maze task, which requires flexibility in the use of previously acquired information.     

Neurobehavioral deficit due to ischemic brain damage limited to half of the CA1 sector of the hippocampus

It is well known that ischemia causes neuronal necrosis in selectively vulnerable sectors of the hippocampus. Since the hippocampus is involved in spatial navigation, learning, and memory, selective deficits in these areas may arise from ischemic brain damage. The objective of this study was to test whether a minimal ischemic insult, producing selective neuronal necrosis restricted to only a portion of the CA1 pyramidal cells of the hippocampus, could produce a detectable spatial navigation deficit. Male Wistar rats received 9 min of forebrain ischemia induced by carotid clamping and hypotension or sham operation with exposure of the carotid arteries. The rats were allowed to recover and were tested on a simple place task, a place learning-set task, and a pattern discrimination task in swimming pools paradigms. Subsequently, the rats were perfusion-fixed and their entire brains subjected to quantitative histopathologic analysis. Although both ischemic and sham-operated groups learned the simple place task, the learning-set task revealed defects in spatial navigation, reflected as increased errors and latency in the performance of the ischemic rats. In the subsequent pattern discrimination task, the ischemic group was superior to the control group, which perseverated by attempting to use a place strategy to solve the discrimination. Quantitative neuropathology revealed neuronal necrosis in the ischemia group limited to 50% of the CA1 zone of the hippocampus. Extrahippocampal damage consisted of rare cortical neuronal necrosis in 2 of 6 animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Impaired conditioned emotional response and object recognition are concomitant to neuronal damage in the amygdala and perirhinal cortex in middle-aged ischemic rats

The current study characterizes fear conditioning responses following global ischemia and evaluates neuronal damage affecting discrete extra-hippocampal areas susceptible to contribute to post ischemic emotional and memory impairments. Conditioned emotional response, Barnes Maze and object recognition tests were used to assess emotional, spatial and recognition memory, respectively. Behavioural testing was initiated in middle-aged animals (10-12 month old) 1 week following sham (n=16) or 4VO occlusion (n=18). Post-mortem cellular assessment was performed in the hippocampal CA1 layer, the perirhinal cortex and basolateral amygdala. Middle-aged ischemic animals showed impaired spatial memory in the initial three testing days in the Barnes Maze and deficit in recognition memory. Of interest, ischemic rats demonstrated a significant reduction of freezing and increased locomotion during the contextual fear testing period, suggesting reduced fear in these animals. Assessment of neuronal density 40 days following global ischemia revealed that CA1 neuronal injury was accompanied by 20-25% neuronal loss in the basolateral nucleus of the amygdala and perirhinal cortex in middle-aged ischemic compared to sham-operated animals. This study represents the first demonstration of altered conditioned fear responses following ischemia. Our findings also indicate a vulnerability of extra-hippocampal neurons to ischemic injury, possibly contributing to discrete emotional and/or memory impairments post ischemia.     

In vivo administration of corticotropin-releasing hormone at remote intervals following ischemia enhances CA1 neuronal survival and recovery of spatial memory impairments: a role for opioid receptors

The contribution of corticotropin-releasing hormone (CRH) in the modulation of ischemia-induced cell death in vivo remains unclear. We characterized the impact of pre-ischemic administration of CRH (0, 0.1, 1, 5 microg, i.c.v., 15 min prior to vessel occlusion) on neuronal damage following global ischemia in rats. The injection of 5 microg CRH led to a 37% increase in CA1 neuronal survival compared to vehicle-treated ischemic animals, while pre-treatment with alpha-helical CRH (9-41) abolished this neuronal protection. A second objective aimed to determine whether CRH protection is maintained over weeks when the peptide is administered at remote time intervals following ischemia. Compared to vehicle-treated ischemic animals, administration of CRH 8h following global ischemia led to a 61% increase in CA1 neuronal survival observed 30 days post-ischemia. Neuronal protection translated into significant improvement of ischemia-induced spatial memory deficits in the radial maze. Finally, our findings demonstrated that selective blockade of kappa- and delta-opioid receptors (using nor-binaltorphimine and naltrindole, respectively) prior to CRH administration significantly reduced CA1 neuronal protection. These findings represent the first demonstration of enhanced neuronal survival following in vivo CRH administration in a global model of ischemia in rats. They also support the idea that CRH-induced neuroprotection involves opioid receptors activation.     

A critical review of chronic stress effects on spatial learning and memory

The purpose of this review is to evaluate the effects of chronic stress on hippocampal-dependent function, based primarily upon studies using young, adult male rodents and spatial navigation tasks. Despite this restriction, variability amongst the findings was evident and how or even whether chronic stress influenced spatial ability depended upon the type of task, the dependent variable measured and how the task was implemented, the type and duration of the stressors, housing conditions of the animals that include accessibility to food and cage mates, and duration from the end of the stress to the start of behavioral assessment. Nonetheless, patterns emerged as follows: For spatial memory, chronic stress impairs spatial reference memory and has transient effects on spatial working memory. For spatial learning, however, chronic stress effects appear to be task-specific: chronic stress impairs spatial learning on appetitively motivated tasks, such as the radial arm maze or holeboard, tasks that evoke relatively mild to low arousal components from fear. But under testing conditions that evoke moderate to strong arousal components from fear, such as during radial arm water maze testing, chronic stress appears to have minimal impairing effects or may even facilitate spatial learning. Chronic stress clearly impacts nearly every brain region and thus, how chronic stress alters hippocampal spatial ability likely depends upon the engagement of other brain structures during behavioral training and testing.     

Restricted feeding facilitates time-place learning in adult rats

Many species can acquire time-of-day discrimination when tested in food reinforced place learning tasks. It is believed that this type of learning is dependent upon the ability of animals to consult their internal circadian pacemakers entrained by various environmental zeitgebers, such as light-dark cycles and scheduled restricted feeding. In the present study, we examined, (1) whether rats can acquire time-of-day discrimination in an aversively motivated water maze task wherein an escape platform is located in one position in the morning and in another position in the afternoon; (2) whether time-of-day cues provided by the light- and feeding-entrainable pacemakers may have divergent impacts upon the ability of rats to learn this task. Two groups of rats, both maintained on 12-h light:12-h dark cycle, were used; in one group, animals had free access to food, whereas in the other, they were subjected to a restricted feeding protocol (60% of food consumed by rats fed ad libitum, once daily). Despite the heightened difficulty of the task, food-restricted rats were apparently able to acquire associations between two different platform positions and two different times of day, as indicated by the fact that the percentage of discrimination errors in this group declined progressively, as a function of training, and stabilized at the level of 22+/-9%. In contrast, rats that were fed ad libitum, even after extensive training, failed to perform the task above level of chance. These data indicate that time-place learning is a universal, reward-nonspecific, cognitive phenomenon. They furthermore suggest that the ability of animals to integrate spatial and temporal information can be dependent on the access to timing stimuli provided by the feeding-entrainable circadian system.     

Elevations of endogenous kynurenic acid produce spatial working memory deficits

Kynurenic acid (KYNA) is a tryptophan metabolite that is synthesized and released by astrocytes and acts as a competitive antagonist of the glycine site of N-methyl-D-aspartate receptors at high concentrations and as a noncompetitive antagonist of the alpha7-nicotinic acetylcholine receptor at low concentrations. The discovery of increased cortical KYNA levels in schizophrenia prompted the hypothesis that elevated KYNA concentration may underlie the working memory dysfunction observed in this population that has been attributed to altered glutamatergic and/or cholinergic transmission. The present study investigated the effect of elevated endogenous KYNA on spatial working memory function in rats. Increased KYNA levels were achieved with intraperitoneal administration of kynurenine (100 mg/kg), the precursor of KYNA synthesis. Rats were treated with either kynurenine or a vehicle solution prior to testing in a radial arm maze task at various delays. Elevations of endogenous KYNA resulted in increased errors in the radial arm maze. In separate experiments, assessment of locomotor activity in an open field and latency to retrieve food reward from one of the maze arms ruled out the possibility that deficits in the maze were attributable to altered locomotor activity or motivation to consume food. These results provide evidence that increased KYNA levels produce spatial working memory deficits and are among the first to demonstrate the influence of glia-derived molecules on cognitive function. The implications for psychopathological conditions such as schizophrenia are discussed.     

Early rearing environment and dorsal hippocampal ibotenic acid lesions: long-term influences on spatial learning and alternation in the rat

Behavioural responses in a set of spatial and cue tasks were assessed in adult rats that had been given ibotenic acid lesions of the dorsal hippocampus at weaning. The lesions or sham operations were immediately followed by one month of differential rearing, either in enriched, social or isolated housing environments. The differential rearing was followed by standard (social) housing conditions until behavioural testing began at 4 months of age. Compared to sham-operated rats, the rats with early cytotoxic lesions showed substantial impairments on learning and efficient strategy formation in radial arm maze, retention of a spatial location, but not of a cue-marked location, in a + maze and spontaneous alternation. Differential rearing had some long-term effects depending on the task. Sham-operated rats which had been housed in isolation used a pattern of strategies in the radial arm maze that resembled the pattern used by rats with lesions. Early enrichment, on the other hand, alleviated lesion deficits only in a spontaneous alternation task in a T-maze where the variety and salience of proximal cues were maximised. Enrichment increased lesion deficits in the radial maze task, where distal cues only could guide performance. The results suggest that the hippocampus may play an important role in the use of contextual information and that behavioural recovery after early hippocampal damage--limited to situations in which featural information is highly salient--may be permanently induced by rearing in environments, as in enriched ones, where rats can attend to and manipulate environmental cues.     

Chronic food restriction is associated with subtle dendritic alterations in granule cells of the rat hippocampal formation

The hippocampal formation undergoes significant morphological and functional changes after prolonged feeding with low-protein diets. In this study we tested whether prolonged food restriction causes deleterious alterations in this brain region as well. It was found that the total number of dentate granule cells and hippocampal CA3 and CA1 pyramidal neurons did not differ between controls and rats submitted to food restriction (40%) for 36 weeks. Likewise, no effects of this dietary regimen have been detected on the morphology of the dendritic trees of hippocampal pyramids, and on the total number of the mossy fiber-CA3 synapses. By contrast, the dendritic arborizations of granule cells were found to have a reduced number of segments in food-restricted rats. However, the spine density on the distal segments of their dendritic trees and the total number of axospinous synapses in the outer molecular layer of the dentate gyrus were increased in these animals. In addition, the total dendritic length of the granule cells and the overall surface area of the active zones of the synapses in the outer molecular layer were preserved, indicating that the capacity of dentate granule cells to process afferent stimuli is likely to be unaffected by this dietary treatment. Supporting this view are the results obtained in the water maze experiment which show that food-restricted rats exhibit unimpaired spatial abilities, which are known to be dependent on the entorhinal drive towards the hippocampal formation. These results show that, among hippocampal neurons, dentate granule cells are selectively vulnerable to food restriction. Nonetheless, the reorganization which takes place in their dendrites and synapses is capable of minimizing the functional impairments that were expected to occur following changes in the hippocampal neuronal circuitry induced by this type of dietary restriction.     

Spatial memory and choice behavior in the radial arm maze after fornix transection

In the radial arm maze task, it is well established that performance of rats with hippocampal damage is severely impaired on the place version, which relies heavily, if not exclusively, on spatial information. However, very little is known about the effects of hippocampal damage on actual choice behavior. To address this issue, sham-operated (SH) and fornix-transected (FX) rats were trained and tested on the place task in the eight-arm radial maze. The following measures were recorded: the frequency of re-entry errors, the number of choices separating repeated visits to the same arm, the latency to arm re-entry, the distribution and targets of microchoices defined as orientations toward an arm or entries in the proximal portion of an arm [Brown, M.F., 1992. Does a cognitive map guide choices in the radial arm maze? J. Exp. Psychol., Anim. Behav. Processes 18, 56-66]. These measures were used as indexes of performance, within-trial retroactive intrusion, memory trace decay and choice behavior, respectively. As generally observed in the literature, the frequency of errors was higher in rats of the FX group than in rats of the SH group; the impairment persisted even after the training criterion was reached. The analysis of latency to arm re-entry and of the number of choices separating re-entries suggested that this impairment was the result of faster memory decay rather than retroactive interference. Both FX and SH groups exhibited a systematic pattern of microchoices, but the frequency of microchoices was higher in FX lesioned rats than in SH controls. Moreover, in lesioned animals, relatively fewer of the initial microchoices were directed toward the baited arms during training-to-criterion. Some of the results provide support to the working memory theory [Olton, D.S., Becker, J.T., Handelmann, G.E., 1979. Hippocampus, space, and memory. Behav. Brain Sci. 2, 313-365], whereas others look more consistent with the cognitive map view [O'Keefe, J., Nadel, L., 1978. The Hippocampus as a Cognitive Map. Clarendon Press, Oxford]. The discussion suggests that both theories and a distinction between prospective and retrospective memory may be required to account for the function of the hippocampal formation in memory.