Thousands of hippocampal neurons are born in adulthood, suggesting that new cells could be important for hippocampal function. To determine whether hippocampus-dependent learning affects adult-generated neurons, we examined the fate of new cells labeled with the thymidine analog bromodeoxyuridine following specific behavioral tasks. Here we report that the number of adult-generated neurons doubles in the rat dentate gyrus in response to training on associative learning tasks that require the hippocampus. In contrast, training on associative learning tasks that do not require the hippocampus did not alter the number of new cells. These findings indicate that adult-generated hippocampal neurons are specifically affected by, and potentially involved in, associative memory formation.
The vertebrate brain continues to produce new neurons throughout life. In the rat hippocampus, several thousand are produced each day, many of which die within weeks. Associative learning can enhance their survival; however, until now it was unknown whether new neurons are involved in memory formation. Here we show that a substantial reduction in the number of newly generated neurons in the adult rat impairs hippocampal-dependent trace conditioning, a task in which an animal must associate stimuli that are separated in time. A similar reduction did not affect learning when the same stimuli are not separated in time, a task that is hippocampal-independent. The reduction in neurogenesis did not induce death of mature hippocampal neurons or permanently alter neurophysiological properties of the CA1 region, such as long-term potentiation. Moreover, recovery of cell production was associated with the ability to acquire trace memories. These results indicate that newly generated neurons in the adult are not only affected by the formation of a hippocampal-dependent memory, but also participate in it.
Exposure to an acute stressful experience facilitates classical conditioning in male rats but impairs conditioning in female rats (T. J. Shors, C. Lewczyk, M. Paczynski, P. R. Mathew, & J. Pickett, 1998; G. E. Wood & T. J. Shors, 1998). The authors report that these effects extend to performance on the hippocampal-dependent task of trace conditioning. The stress-induced impairment of conditioning in females was evident immediately, 24 hr and 48 hr after stress, depending on the stage of estrus. Moreover, the effect could be reactivated days later by reexposure to the stressful context. Corticosterone levels correlated with overall performance in males but not in females. Unlike the effect seen in males, adrenalectomy did not prevent the stress-induced effect on conditioning in females. These data indicate that exposure to the same experience can have opposite effects on learning in males versus females and that these opposing effects are mediated by differing hormonal systems.
Exposure to acute stressful experience can enhance the later ability to acquire new memories about associations between stimuli. This enhanced learning is observed during classical eyeblink conditioning of both hippocampal-dependent and -independent learning. It can be induced within minutes of the stressful event and persists for days. Here we examined the role of the major stress hormones glucocorticoids in the enhancement of learning after stress. In the first two experiments, it was determined that adrenalectomy (ADX), with and without replacement of basal levels of corticosterone, prevented the stress-induced enhancement of trace conditioning, a task that is dependent on the hippocampus for acquisition. In a third experiment, demedullation, which removes the adrenal medulla but leaves the adrenal cortex and corticosterone levels intact, did not affect the enhancement of learning after stress. In a fourth experiment, ADX prevented the stress-induced enhancement of delay conditioning, a hippocampal-independent task. In a final experiment, it was determined that one injection of stress levels of corticosterone enhanced new learning within minutes but not new learning 24 h later. Together these results suggest that endogenous glucocorticoids are necessary and sufficient for transiently enhancing acquisition of new associative memories and necessary but insufficient for persistently enhancing their acquisition after exposure to an acute stressful experience.
Exposure to a brief, stressful event is reported to facilitate classical eyeblink conditioning in the male rat (Rattus norvegicus) by use of a delay paradigm in which the conditioned stimulus (CS) and unconditioned stimulus (US) overlap and coterminate. This study examined the effects of stress on trace conditioning, a task in which the CS and US were separated by 500 ms. Experiment 1 showed that exposure to brief (1 s), low-intensity (1 mA) tailshocks facilitated acquisition 24 hr later. Experiment 2 showed that stressor exposure did not affect retention or extinction of trace conditioning in rats that were stressed after acquisition. Experiment 3 showed that exposure to the same stressor opposed acquisition of inhibitory conditioning. These results suggest that exposure to a stressful event persistently facilitates acquisition of trace conditioning and enhances a bias toward acquiring positive versus negative associations.
Clinical and animal studies indicate that hyperthermia during or after traumatic brain injury (TBI) is associated with poor outcome. Alcohol intoxication, a complicating risk factor in many cases of head injury, has been found to both worsen or attenuate posttraumatic neural damage and outcome. The purpose of the present study was to determine whether chronic ethanol consumption would affect TBI-induced hyperthermia and deficits in spatial learning. TBI was produced by cortical contusion injury in adult male rats. We first characterized the TBI-induced febrile response using probes implanted intraperitoneally (ip) or intracerebroventricularly for continuous biotelemetric recording of core body and brain temperatures and locomotor activity. In another experiment, rats, implanted with ip probes, were fed a liquid diet containing ethanol (5% w/v, 35% ethanol-derived calories); control rats were pair-fed the isocaloric liquid diet (P-P). At 14 days after commencement of diet feeding, TBI or sham surgery was performed, and the ethanol-fed rats were divided into two groups: half were transferred to the isocaloric diet (E-P) and the other half remained on the ethanol-containing diet (E-E). TBI produced a significant febrile response in all rats, that persisted for at least 6 days in the E-P and P-P groups but lasted for only 2 days in the E-E group. When tested at 3-4 weeks after TBI, E-E rats required significantly fewer trials than E-P rats to reach criterion in the Morris water maze. In sum, continuous consumption of ethanol before and after TBI attenuated TBI-induced hyperthermia and deficits in spatial learning. Whereas the results suggest that this ethanol regimen may be neuroprotective, a causal relationship between the two outcomes remains to be determined.
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