Place cell rigidity correlates with impaired spatial learning in aged rats.

In humans and in animals, some aged individuals are severely impaired in learning and memory capacity whereas others perform as well as young adults. In the present study, the spatial memory capacity of young and aged rats was characterized by the Morris water maze task, and then firing patterns of hippocampal "place cells" were assessed as the animals explored a familiar environment and a geometrically-altered version of the environment. Spatial representations of hippocampal cells in young and memory-intact aged rats changed upon exposure to the altered environment. In contrast, spatial representations of many cells in aged, memory-impaired rats were unaffected by the environmental alteration. Furthermore, combining all groups, the extent to which spatial representations distinguished the familiar and altered environments predicted learning capacity in the water maze. These findings suggest that a major component of memory impairment in aging may be the failure of the hippocampus to encode subtle differences in contextual information that differ across multiple experiences, such as the sequence of training trials in the water maze.

Orbitofrontal cortex and representation of incentive value in associative learning.

Clinical evidence indicates that damage to ventromedial prefrontal cortex disrupts goal-directed actions that are guided by motivational and emotional factors. As a consequence, patients with such damage characteristically engage in maladaptive behaviors. Other research has shown that neurons in the corresponding orbital region of prefrontal cortex in laboratory animals encode information regarding the incentive properties of goals or expected events. The present study investigates the effect of neurotoxic orbitofrontal cortex (OFC) lesions in the rat on responses that are normally influenced by associations between a conditioned stimulus (CS) and the incentive value of reinforcement. Rats were first trained to associate a visual CS with delivery of food pellets to a food cup. As a consequence of learning, rats approached the food cup during the CS in anticipation of reinforcement. In a second training phase, injection of LiCl followed consumption of the food unconditioned stimulus (US) in the home cage, a procedure used to alter the incentive value of the US. Subsequently, rats were returned to the conditioning chamber, and their responding to the CS in the absence of the food US was tested. Lesions of OFC did not affect either the initial acquisition of a conditioned response to the light CS in the first training phase or taste aversion learning in the second training phase. In the test for devaluation, however, OFC rats exhibited no change in conditioned responding to the visual CS. This outcome contrasts with the behavior of control rats; after devaluation of the US a significant decrease occurred in approach to the food cup during presentation of the CS. The results reveal an inability of a cue to access representational information about the incentive value of associated reinforcement after OFC damage.

The role of an amygdalo-nigrostriatal pathway in associative learning.

The present study examined the role of an amygdalo-nigrostriatal pathway in associative learning. An asymmetrical lesion model was used to test whether a circuit from the amygdala central nucleus to the dorsolateral striatum, via the substantia nigra, is critical for mediating conditioned orienting responses. Rats with an asymmetrical lesion, consisting of neurotoxic removal of central nucleus neurons in one hemisphere and depletion of the dopamine innervation of the dorsolateral striatum in the contralateral hemisphere, failed to acquire conditioned orienting responses. In contrast, the asymmetrical lesion had no effect on spontaneous orienting or learning another response directed to the source of the food unconditioned stimulus in the same task. A second experiment tested the effect of reversible inactivation of the dorsolateral striatum contralateral to a neurotoxic central nucleus lesion on acquisition of the conditioned orienting response. Although inactivation did not affect spontaneous orienting, rats failed to acquire the conditioned orienting response during sessions in which inactivation occurred. Immediately after the inactivation procedure was terminated, however, a significant increase in orienting to the conditioned stimulus was evident. These data support the interpretation that the dorsolateral striatum provides a route for the expression of the conditioned orienting response but is not essential for acquisition of this learned behavior.

Selective immunolesions of hippocampal cholinergic input fail to impair spatial working memory.

The septo-hippocampal cholinergic pathway has traditionally been thought of as essential for spatial memory. Recent studies have demonstrated intact spatial learning following removal of this pathway with an immunotoxin selective for cholinergic neurons. In the present experiment, rats with selective removal of hippocampal cholinergic input were tested in a delayed nonmatching-to-position task in a water version of the radial arm maze. This allowed us to increase and parametrically vary the memory load compared with the standard Morris water maze (by varying the delay between the initial four choices and the final four choices) to determine if this would reveal a deficit in rats with lesions of septo-hippocampal cholinergic projections. Male Long-Evans rats were given injections of 192 IgG-saporin, a selective immunotoxin for cholinergic neurons, into the medial septum/vertical limb of the diagonal band (MS/VDB) to remove cholinergic projections to the hippocampus, or a control surgery. The rats were trained on the radial maze task following surgery. An escape platform was located at the end of each arm of the maze and was removed after an arm was utilized for escape. After initial training, a delay was interposed between the first four trials and the second four trials. Errors during the second four-trial component were scored in two categories: retroactive (reentering an arm chosen before the delay) and proactive (reentering an arm chosen after the delay). Retroactive errors increased as delay increased (from 60 s to 6 h) but were equivalent in control and MS/VDB-lesion groups. Proactive errors did not vary with delay and were also unaffected by the lesion. Radioenzymatic assays for choline acetyltransferase activity in the hippocampus of lesioned rats confirmed a significant loss of cholinergic input from the MS/VDB. These results indicate that normal spatial working memory is possible after substantial loss of septo-hippocampal cholinergic projections.