Over the last decades, studies from our laboratory and other groups using animal models have shown that iron overload, resulting in iron accumulation in the brain, produces significant cognitive deficits. Iron accumulation in the hippocampus and the basal ganglia has been related to impairments in spatial memory, aversive memory, and recognition memory in rodents. These results are corroborated by studies showing that the administration of iron chelators attenuates cognitive deficits in a variety of animal models of cognitive dysfunction, including aging and Alzheimer's disease models. Remarkably, recent human studies using magnetic resonance image techniques have also shown a consistent correlation between cognitive dysfunction and iron deposition, mostly in the hippocampus, cortical areas, and basal ganglia. These findings may have relevant implications in the light of the knowledge that iron accumulates in brain regions of patients suffering from neurodegenerative diseases. A better understanding of the functional consequences of iron dysregulation in aging and neurological diseases may help to identify novel targets for treating memory problems that afflict a growing aging population.
Alterations of brain iron levels have been observed in a number of neurodegenerative disorders. We have previously demonstrated that iron overload in the neonatal period results in severe and persistent memory deficits in the adulthood. Protein degradation mediated by the ubiquitin-proteasome system (UPS) plays a central regulatory role in several cellular processes. Impairment of the UPS has been implicated in the pathogenesis of neurodegenerative disorders. Here, we examined the effects of iron exposure in the neonatal period (12th-14th day of postnatal life) on the expression of proteasome β-1, β-2, and β-5 subunits, and ubiquitinated proteins in brains of 15-day-old rats, to evaluate the immediate effect of the treatment, and in adulthood to assess long-lasting effects. Two different memory types, emotionally motivated conditioning and object recognition were assessed in adult animals. We found that iron administered in the neonatal period impairs both emotionally motivated and recognition memory. Polyubiquitinated protein levels were increased in the hippocampus, but not in the cortex, of adult animals treated with iron. Gene expression of subunits β1 and β5 was affected by age, being higher in the early stages of development in the hippocampus, accompanied by an age-related increase in polyubiquitinated protein levels in adults. In the cortex, gene expression of the three proteasome subunits was significantly higher in adulthood than in the neonatal period. These findings suggest that expression of proteasome subunits and activity are age-dependently regulated. Iron exposure in the neonatal period produces long-lasting harmful effects on the UPS functioning, which may be related with iron-induced memory impairment.
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