Differential deficits in the Morris water maze following cytotoxic lesions of the anterior thalamus and fornix transection

Rats with complete fornix lesions or cytotoxic lesions placed in the anterior thalamic region were trained on an allocentric spatial memory test (the Morris water maze). While both lesions led to impairments in locating the hidden platform in this test of reference memory, the thalamic lesions led to a significantly greater deficit than that observed after fornix transection as measured by a number of performance indices. The lesions also led to different patterns of swim behaviour in the pool. The severity of the thalamic lesion deficit was associated with anterior thalamic nuclei damage but not with damage to the nucleus medialis dorsalis. Both the fornix and the thalamic lesions also severely impaired T-maze alternation. In contrast, neither set of lesions appeared to affect the recognition of small or large objects. While the study provides further evidence of a close functional relationship between the hippocampus and the anterior thalamic nuclei, it also shows that disconnection of the fornical inputs to the anterior thalamic nuclei does not provide a full explanation of the thalamic deficit.     

The effects of lesions to the anterior thalamic nuclei on object-place associations in rats

Rats with lesions of the anterior nuclei of the thalamus were trained postoperatively on two spatial conditional associative learning tasks. In the first task, the rats were required to choose one or the other of two objects depending on the location in which they were found. In the second task, the animals learned to turn left or right depending on which one of two visual cues was presented. A third experiment examined the effects of damage to the anterior thalamic nuclei on the eight-arm radial maze, a spatial working memory task. Damage of the anterior thalamic nuclei impaired performance on the radial maze task and the conditional task requiring associations between objects and their location. By contrast, rats with anterior thalamic lesions were able to acquire, at a rate comparable with that of operated control animals, the conditional task requiring associations between objects and body turns. These findings suggest that lesions to the anterior thalamic nuclei result in a general impairment in learning about allocentric spatial information without disrupting the learning of egocentric spatial information.     

The conjoint importance of the hippocampus and anterior thalamic nuclei for allocentric spatial learning: evidence from a disconnection study in the rat

A disconnection procedure was used to test whether the hippocampus and anterior thalamic nuclei form functional components of the same spatial memory system. Unilateral excitotoxic lesions were placed in the anterior thalamic (AT) nuclei and hippocampus (HPC) in either the same (AT-HPC Ipsi group) or contralateral (AT-HPC Contra group) hemispheres of rats. The behavioral effects of these combined lesions were compared in several spatial memory tasks sensitive to bilateral hippocampal lesions. In all of the tasks tested, T-maze alternation, radial arm maze, and Morris water maze, those animals with lesions placed in the contralateral hemispheres were more impaired than those animals with lesions in the same hemisphere. These results provide direct support for the notion that the performance of tasks that require spatial memory rely on the operation of the anterior thalamus and hippocampus within an integrated neural network.     

Differentiated participation of thalamocortical subnetworks in slow/spindle waves and desynchronization

During sleep, the electroencephalogram exhibits synchronized slow waves that desynchronize when animals awaken [desynchronized states (DSs)]. During slow-wave states, the membrane potentials of cortical neurons oscillate between discrete depolarized states ("Up states") and periods of hyperpolarization ("Down states"). To determine the role of corticothalamic loops in generating Up/Down oscillations in rats, we recorded unit activities of layer 5 (L5) corticothalamic (CTh) cells in the frontal cortex, neurons in the thalamic reticular nucleus, and basal ganglia- and cerebellum-linked thalamic relay nuclei, while simultaneously monitoring the local cortical field potential to identify slow-wave/spindle oscillations and desynchronization. We found that (1) some basal ganglia-linked and reticular thalamic cells fire preferentially near the beginning of Up states; (2) thalamic cells fire more selectively at a given Up-state phase than do CTh cells; (3) CTh and thalamic cells exhibit different action potential timings within spindle cycles; and (4) neurons exhibit different firing characteristics when comparing their activity during Up states and DSs. These data demonstrate that cortico-thalamo-cortical subnetworks are temporally differentiated during slow and spindle oscillations, that the basal ganglia-linked thalamic nuclei are closely related with Up-state initiation, and that Up states and DSs are distinguished as different depolarization states of neurons within the network.     

Role of the anterodorsal and anteroventral nuclei of the thalamus in spatial memory in the rat

This study tests the hypothesis that the anterior thalamic nuclei play a significant role in spatial learning and memory. Adult, male Sprague-Dawley rats with bilateral ibotenic acid lesions of the anterior thalamus were tested for 5 days in a repeated acquisition water maze task. Compared with Controls, rats with nearly complete lesions of both anterodorsal (AD) and anteroventral (AV) thalamic nuclei (AD/AV) were only mildly impaired in their spatial learning and memory. Larger lesions that extended into the anteromedial (AM) thalamic nucleus (AD/AV+) caused a more severe impairment and complete lesions of all three anterior nuclei (AD/AV/AM) resulted in even greater impairment that extended to all aspects of the task. In probe trials, only the Control animals had a preference for the correct quadrant. Approximately one-half of the rats were tested for a second week to determine if the impaired groups would benefit from further training. AD/AV/AM rats showed little improvement, but the other groups all improved significantly in all aspects of the task except the probe trial. Together, these data indicate that the anterior thalamic nuclei contribute to spatial learning and memory, but neither AV nor AD independently plays a dominant role.     

Anterior Thalamic Inputs Are Required for Subiculum Spatial Coding,with Associated Consequences for Hippocampal Spatial Memory

Just as hippocampal lesions are principally responsible for “temporal lobe” amnesia, lesions affecting the anterior thalamic nuclei seem principally responsible for a similar loss of memory, “diencephalic” amnesia. Compared with the former, the causes of diencephalic amnesia have remained elusive. A potential clue comes from how the two sites are interconnected, as within the hippocampal formation, only the subiculum has direct, reciprocal connections with the anterior thalamic nuclei. We found that both permanent and reversible anterior thalamic nuclei lesions in male rats cause a cessation of subicular spatial signaling, reduce spatial memory performance to chance, but leave hippocampal CA1 place cells largely unaffected. We suggest that a core element of diencephalic amnesia stems from the information loss in hippocampal output regions following anterior thalamic pathology.SIGNIFICANCE STATEMENT At present, we know little about interactions between temporal lobe and diencephalic memory systems. Here, we focused on the subiculum, as the sole hippocampal formation region directly interconnected with the anterior thalamic nuclei. We combined reversible and permanent lesions of the anterior thalamic nuclei, electrophysiological recordings of the subiculum, and behavioral analyses. Our results were striking and clear: following permanent thalamic lesions, the diverse spatial signals normally found in the subiculum (including place cells, grid cells, and head-direction cells) all disappeared. Anterior thalamic lesions had no discernible impact on hippocampal CA1 place fields. Thus, spatial firing activity within the subiculum requires anterior thalamic function, as does successful spatial memory performance. Our findings provide a key missing part of the much bigger puzzle concerning why anterior thalamic damage is so catastrophic for spatial memory in rodents and episodic memory in humans.     

The role of the fornix/fimbria and some related subcortical structures in place learning and memory

Place learning and memory were assessed in rats with selective damage to the fornix/fimbria or to subcortical structures which have a major connection with the hippocampal formation via the fornix/fimbria. Navigation to a hidden or visible platform in a fixed location was studied in the Morris water task in rats who were preoperatively trained in the task or who were preoperatively naive. All rats learned to navigate accurately to a visible platform. Only complete transection of the fornix/fimbria abolished both acquisition and retention of navigation to a hidden platform. Severe impairment of postoperative acquisition was produced by bilateral damage to the medial nucleus accumbens or bilateral damage to the anterior thalamic area. Nucleus accumbens or anterior thalamic damage produced little effect on retention of preoperatively acquired place navigation. Damage to medial septum or mammillary complex produced modest impairments evident only in postoperative acquisition.     

Contribution of the anterior thalamic nuclei to conditional learning in rats

The anterior thalamic region is intimately linked anatomically and functionally with the hippocampus, which is critical for various forms of spatial learning. Rats with lesions to the anterior thalamic nuclei and a control group were trained on a visual-spatial conditional associative learning task in which they had to learn to go to one of two locations depending on the particular visual cue presented on each trial; the rats approached the cues from different directions. The animals were subsequently tested on a spatial working memory task, the eight-arm radial maze. Performance on both these tasks had previously been shown to be impaired by hippocampal lesions. Rats with anterior thalamic damage were able to acquire the conditional associative task at a rate comparable to that of the control animals, but were impaired on the radial maze task. The finding of a dissociation between the effects of lesions of the anterior thalamic nuclei on two different classes of behavior known to be associated with hippocampal function suggest that while different neural stations within the extended hippocampal circuit may all play a role in spatial learning, the role of each of these regions in such learning may be more selective than previously considered.     

The origin of projections from the posterior cingulate and retrosplenial cortices to the anterior,medial dorsal and laterodorsal thalamic nuclei of macaque monkeys

Interactions between the posterior cingulate cortex (areas 23 and 31) and the retrosplenial cortex (areas 29 and 30) with the anterior, laterodorsal and dorsal medial thalamic nuclei are thought to support various aspects of cognition, including memory and spatial processing. To detail these interactions better, the present study used retrograde tracers to reveal the origins of the corticothalamic projections in two closely related monkey species (Macaca mulatta, Macaca fascicularis). The medial dorsal thalamic nucleus received only light cortical inputs, which predominantly arose from area 23. Efferents to the anterior medial thalamic nucleus also arose principally from area 23, but these projections proved more numerous than those to the medial dorsal nucleus and also involved additional inputs from areas 29 and 30. The anterior ventral and laterodorsal thalamic nuclei had similar sources of inputs from the posterior cingulate and retrosplenial cortices. For both nuclei, the densest projections arose from areas 29 and 30, with numbers of thalamic inputs often decreasing when going dorsal from area 23a to 23c and to area 31. In all cases, the corticothalamic projections almost always arose from the deepest cortical layer. The different profiles of inputs to the anterior medial and anterior ventral thalamic nuclei reinforce other anatomical and electrophysiological findings suggesting that these adjacent thalamic nuclei serve different, but complementary, functions supporting memory. While the lack of retrosplenial connections singled out the medial dorsal nucleus, the very similar connection patterns shown by the anterior ventral and laterodorsal nuclei point to common roles in cognition.     

Individual variation in the propensity to attribute incentive salience to an appetitive cue predicts the propensity to attribute motivational salience to an aversive cue

It has been proposed that animals that attribute high levels of incentive salience to reward-related cues may be especially vulnerable to addiction. Individual variation has also been observed in the motivational value attributed to aversive cues, which may confer vulnerability to anxiety disorders such as post-traumatic stress disorder (PTSD). There may be a core behavioral trait that contributes to individual variation in the motivational value assigned to predictive cues regardless of emotional valence. To test this hypothesis, we used a Pavlovian conditioned approach procedure to classify rats based on whether they learned to approach and interact with a cue predicting food reward (sign-trackers) or learned upon cue presentation to go to the location of impending food delivery (goal-trackers), and then examined Pavlovian fear conditioning in the same animals. It has recently been proposed that sign-trackers are more vulnerable to substance abuse because they attribute greater incentive motivational value to drug cues. Here we show that sign-trackers also have a tendency to be more fearful of discrete cues that predict footshock. In addition, we found that goal-trackers exhibited greater contextual fear when placed back into the original fear-conditioning context in the absence of temporally discrete cues. These results suggest that there may be a subset of individuals who tend to attribute high levels of motivational salience to predictive cues regardless of emotional valence, which may predispose them to a number of psychiatric comorbidities including PTSD and substance abuse. Other individuals use contexts to appropriately modify their reactions to such salient stimuli.     

The role of the laterodorsal nucleus of the thalamus in spatial learning and memory in the rat

The anterior thalamic nuclei appear to play an important role in learning and memory. Connectionally and structurally, the lateral dorsal nucleus is similar to the anterior nuclei. This study tested the hypothesis that the laterodorsal thalamic nucleus (LD) also contributes to these functions. Adult Sprague-Dawley rats received bilateral ibotenic acid lesions of LD, and 2 weeks later the rats were tested in a repeated acquisition water maze task. The control groups displayed a short final escape latency and showed a preference for the correct quadrant in the probe trial. Rats with a lesion restricted to LD (LDL) were mildly impaired in the task, but rats with lesions that destroyed LD and also significantly (50%) damaged the adjacent anterior thalamic nuclei (LDL+) were severely impaired, displaying no improvement in performing the spatial task. In a second experiment, training in the same paradigm for 2 weeks resulted in improved final performance by LDL and control rats but not by LDL+ rats. These findings support the hypothesis that together with the anterior thalamic nuclei, LD plays a role in spatial learning and memory.     

Both fornix and anterior thalamic, but not mammillary, lesions disrupt delayed non-matching-to-position memory in rats.

Rats with radiofrequency lesions of the fimbria/fornix, or neurotoxic lesions of the mammillary bodies or the anterior thalamic nuclei were tested on their ability to perform a delayed non-matching-to-position task that had been learnt before surgery. In this task rats had to respond to a sample lever in an operant chamber and, after a variable delay (during which they were required to respond at the magazine tray), press the other lever when both were presented. Extensive mammillary body lesions had no effect on performance. In contrast, lesions in either the anterior thalamic nuclei or the fimbria/fornix produced marked deficits, the pattern of these deficits being consistent with a mnemonic impairment. It is argued that the anterior thalamic nuclei represent an important hippocampal output for spatial problems, but that the mammillary bodies are only necessary for certain types of mnemonic task.     

Parallel but separate inputs from limbic cortices to the mammillary bodies and anterior thalamic nuclei in the rat

The proposal that separate populations of subicular cells provide the direct hippocampal projections to the mammillary bodies and anterior thalamic nuclei was tested by placing two different fluorescent tracers in these two sites. In spite of varying the injection locations within the mammillary bodies and within the three principal anterior thalamic nuclei and the lateral dorsal thalamic nucleus, the overall pattern of results remained consistent. Neurons projecting to the thalamus were localized to the deepest cell populations within the subiculum while neurons projecting to the mammillary bodies consisted of more superficially placed pyramidal cells within the subiculum. Even when these two cell populations become more intermingled, e.g., in parts of the intermediate subiculum, almost no individual cells were found to project to both diencephalic targets. In adjacent limbic areas, i.e., the retrosplenial cortex, postsubiculum, and entorhinal cortex, populations of cells that project to the anterior thalamic nuclei and mammillary bodies were completely segregated. This segregated pattern included afferents to those nuclei comprising the head‐direction system. The sole exception was a handful of double‐labeled cells, mainly confined to the ventral subiculum, that were only found after pairs of injections in the anteromedial thalamic nucleus and mammillary bodies. The projections to the anterior thalamic nuclei also had a septal‐temporal gradient with relatively fewer cells projecting from the ventral (temporal) subiculum. These limbic projections to the mammillary bodies and anterior thalamus comprise a circuit that is vital for memory, within which the two major components could convey parallel, independent information. J. Comp. Neurol. 518:2334–2354, 2010. © 2010 Wiley‐Liss, Inc.     

Distinct, parallel pathways link the medial mammillary bodies to the anterior thalamus in macaque monkeys

Mammillary body neurons projecting to the thalamus were identified by injecting retrograde tracers into the medial thalamus of macaque monkeys. The source of the thalamic projections from the medial mammillary nucleus showed strikingly different patterns of organization depending on the site of the injection within the two anterior thalamic nuclei, anterior medialis and anterior ventralis. These data reveal at least two distinct modes by which the primate medial mammillary bodies can regulate anterior thalamic function. Projections to the thalamic nucleus anterior medialis arise mainly from the pars lateralis of the medial mammillary nucleus. A particularly dense source is the dorsal cap in the posterior half of the pars lateralis, a subregion that has not previously been distinguished. In contrast, neurons spread evenly across the medial mammillary nucleus gave rise to projections more laterally in the anterior thalamic nuclei. A third pattern of medial mammillary neurons appeared to provide the source of projections to the rostral midline thalamic nuclei. In contrast, the labeled cells in the lateral mammillary nucleus were evenly spread across that nucleus, irrespective of injection site. In addition to the established projection to anterior dorsalis, the lateral mammillary nucleus appears to project lightly to a number of other thalamic nuclei, including lateralis dorsalis, anterior medialis, anterior ventralis, and the rostral midline nuclei, e.g. nucleus reuniens. These anatomical findings not only reveal novel ways of grouping the neurons within the medial mammillary nucleus, but also indicate that the mammillothalamic connections support cognition in multiple ways.     

Egocentric conditional associative learning: effects of restricted lesions to the hippocampo-mammillo-thalamic pathway

Rats with lesions of the hippocampus, the mammillary region, the anterior thalamic nuclei, and normal control animals were trained on a conditional associative learning task in which they had to learn to make one of two motor responses (i.e., turn left or right), depending on which one of two visual cues was presented. Damage to the hippocampus severely impaired performance of this task. By contrast, rats with lesions of the mammillary region or the anterior thalamic nuclei were able to acquire the task at a rate comparable to that of the normal animals. These findings demonstrate that hippocampal lesions impair the ability to form arbitrary associations between visual cues and kinesthetic responses (body turns) and, furthermore, suggest that the hippocampus does not rely on input from its major subcortical targets for learning such visual-kinesthetic associations.     

Rats' processing of visual scenes: effects of lesions to fornix, anterior thalamus, mamillary nuclei or the retrohippocampal region

We analysed the effects of lesions of hippocampal-diencephalic projections -- fornix (FX) mamillary bodies (MB) and anterior thalamic nuclei (AT) -- and retrohippocampal (RH) lesions including entorhinal cortex and ventral subiculum, upon scene processing. All lesions except FX were neurotoxic. Rats learned to discriminate among computer-generated visual displays ("scenes") each comprising three different shapes ("objects"). The paradigm was constant-negative; one constant scene (unrewarded) appeared on every trial together with a trial-unique variable scene (rewarded). Four types of variable scene were intermingled: (1) unfamiliar objects in different positions from those of the constant (type O+P), (2) unfamiliar objects in same positions as in the constant (type O), (3) same objects as the constant in different positions (type P), (4) same objects and positions as the constant but recombined (type X). Group RH performed like controls while groups FX, AT and MB showed (surprisingly) enhanced performance on types X and O. One explanation is that normal rats attempt to process all objects in a scene concurrently, while hippocampal-projection lesions disrupt this tendency, producing a narrower attention, which paradoxically aids performance with some variable types. The results confirm that the entorhinal cortex has a different function from other components of the hippocampal system.     

Thalamocortical tract between anterior thalamic nuclei and cingulate gyrus in the human brain: diffusion tensor tractography study

Most portions of the Papez circuit have been identified by diffusion tensor tractography (DTT). However, no DTT study on the proportion of the Papez circuit between the anterior thalamic nuclei and cingulate gyrus has been reported. We attempted to reconstruct the thalamocortical tract between the anterior thalamic nuclei and cingulate gyrus using DTT. All the reconstructed thalamocortical tracts originated from the anterior thalamic nuclei, ascended through the genu of the internal capsule, the anterior limb of the internal capsule, and the white matter around the anterior horn of the lateral ventricle in the anterior and lateral direction, and then terminated at the anterior cingulate gyrus. In terms of FA, MD, and tract volume, no significant differences were observed between hemispheres (p?>?0.05). We reconstructed the thalamocortical tract between the anterior thalamic nucleus and cingulate gyrus in the human brain using DTT. We believe that the methodology and results of this study will be helpful to researchers investigating the Papez circuit.     

Lesions of mediodorsal thalamus and anterior thalamic nuclei produce dissociable effects on instrumental conditioning in rats

Two experiments examined the effects of bilateral excitotoxic lesions of either the mediodorsal (MD) or anterior (ANT) thalamic nuclei on instrumental acquisition and performance, sensitivity to changes in the value of the instrumental outcome, and sensitivity to changes in the instrumental contingency. Rats were food deprived and trained to press two levers, each earning a unique food outcome (pellets or sucrose). All rats acquired the instrumental response although ANT lesions appear slightly to increase and MD lesions slightly to suppress instrumental performance. After training, specific satiety-induced devaluation of one of the two instrumental outcomes produced a selective reduction in responding on the lever that in training had earned the now devalued outcome but only in the SHAM and ANT groups. In contrast, MD animals failed to show evidence of a selective devaluation effect when tested in extinction. Additionally, SHAM and ANT animals selectively decreased responding when one action-outcome contingency was degraded, whereas MD animals reduced responding nonselectively on the two levers. Subsequent tests established that an inability to discriminate between either the two actions or the two outcomes cannot account for the lack of selective responding observed in the MD animals. Together these data suggest that MD lesions produce a profound deficit in the ability of rats to utilize specific action-outcome associations and appear to render rats relatively insensitive to the causal consequences of their instrumental actions. In contrast, far from producing a deficit, ANT lesioned rats were as sensitive to the effects of these behavioural manipulations as the sham lesioned controls.     

Organization of projections from the anterior pole of the nucleus reticularis thalami (NRT) to subdivisions of the motor thalamus: light and electron microscopic studies in the rhesus monkey.

Projections to the motor-related thalamic nuclei from the anterior pole of the reticular thalamic nucleus (NRT) were studied after injections of biotinylated dextran amine and wheat germ agglutinin conjugated horseradish peroxidase at light and electron microscopic levels, respectively. Each injection resulted in anterograde labeling in the three subdivisions of the ventral anterior nucleus (pars parvicellularis, VApc; pars densicellularis, VAdc; and pars magnocellularis, VAmc) and in the ventral lateral nucleus (VL). NRT fibers had beaded shapes and coursed in a posterior direction giving rise to relatively diffuse terminal plexuses. The average size of the beads (0.7 microm2) and their density per 100 microm of fiber length (23.7-25.7) were similar between the nuclei studied. At the electron microscopic level, anterogradely labeled boutons displayed positive immunoreactivity for gamma-aminobutyric acid (GABA), contained pleomorphic synaptic vesicles, and formed relatively long (approximately 0.4 microm) symmetric synaptic contacts. Usually, a single terminal formed synapses on more than one postsynaptic structure. Synaptic contacts were on projection and local circuit neurons and targeted mainly their distal dendrites. In the VAmc, synapses on local circuit neurons composed 48% of the total sample, in the VAdc/VApc and in the VL the proportion was higher, 65% and 62%, respectively. The results suggest that the input from the anterior pole of the monkey reticular nucleus to the motor-related thalamic nuclei is organized differently from what is known on the organization of connections of NRT with sensory thalamic nuclei in other species in that the terminal fields of individual fibers are diffuse rather than focal and that at least 50% of synapses are established on GABAergic local circuit neurons.