In order to verify whether brain damage caused by chronic oxidative stress induces the impairment of cognitive function, the ability of learning and memory was assessed using the water maze and the eight-arm radial maze tasks. Young rats showed significantly greater learning ability before the stress than the old and vitamin E-deficient rats. At five days after subjection to oxidative stress, the memory function of the young declined toward the level of that in the aged rats maintained under normal condition. This phenomenon is supported by the findings that the delayed-type apoptosis appeared in the CA1 region of the hippocampus of the young at five to seven days after the stress. Vitamin E supplementation to the young accelerated significantly their learning functions before the stress and prevented the deficit of memory caused by the stress. When rats were subjected to stress, thiobarbituric acid-reactive substance (TBARS), lipid hydroperoxides, and protein carbonyls were significantly increased in synaptic plasma membranes. It was found that zeta-potential of the synaptic membrane surface was remarkably decreased. These phenomena were also observed in the aged and vitamin E-deficient rats maintained under normal condition. These results suggest that oxidative damage to the rat synapse in the cerebral cortex and hippocampus during aging may contribute to the deficit of cognitive functions.
In order to elucidate the oxidative damage in rat brain caused by oxidative stress, regional changes in the levels of lipid peroxidation products and antioxidative defense systems in cerebral cortex and hippocampus, and in their synapses, which modulate learning and memory functions in the brain, were studied. When rats were subjected to hyperoxia as an oxidative stress, thiobarbituric acid reactive substance (TBARS) in the regions studied increased more than in normal rats by approximately 35%. The values in oxygen-unexposed vitamin E-deficient rats were also higher than in normal rats. It was found that the TBARS contents in synaptosomes isolated from both regions were remarkably higher than in the organs. These results imply that synapses are more susceptible to oxidative stress than the organ itself. This tendency was also observed in the content of conjugated diene. In response to oxidative stress, the status of the antioxidant defense system in each region, i.e. the concentration of vitamin E, and the activities of superoxide dismutase, catalase and glutathione peroxidase, decreased remarkably. On the other hand, in oxygen-unexposed vitamin E-deficient rats, the activities of these enzymes each region tended to increase, except for catalase activity. These results suggest that in response to the oxidative stress, the antioxidant defense systems may be consumed to prevent oxidative damage, and then, may be supplied through the antioxidant network.
Summary Influence of oxidative stress on fusion of pre-synaptic plasma membranes with phosphatidylcholine (PC) liposomes as a model of synaptic vesicle was investigated. The inhibitory effect of vitamin E on the decline in the fusion caused by oxidative stress was also assessed. Rats subjected to hyperoxia as oxidative stress showed significant increases in the levels of lipid hydroperoxides and protein carbonyl moieties in pre-synaptic plasma membranes in the brain. The potential of pre-synaptic membrane surface was decreased markedly. When synaptosomes were incubated with PC liposomes labeled by either rhodamine B or calcein as a fluorescence probe, or 12-doxyl stearic acid as an ESR spin trapping agent, translocation of each probe into oxidatively damaged pre-synaptic membranes was decreased significantly. Fatty acid composition analysis in pre-synaptic membranes obtained from normal rats revealed a marked increase in linoleic acid and a moderate decrease in docosahexaenoic content after the incubation with liposomes. However, rats subjected to hyperoxia did not show marked changes in these fatty acid contents in their pre-synaptic membranes after the incubation. Such changes caused by hyperoxia were inhibited by vitamin E treatment of rats. These results suggest that oxidative damage of pre-synaptic membranes caused by oxidative stress lowers the lipid-mixing for the membrane fusion. The results of this study imply that vitamin E prevents the deficit in neurotransmission at nerve terminals due to the decline in fusion between pre-synaptic membrane and synaptic vesicles caused by oxidative membrane damage. Key Words vitamin E, neurotransmission, synaptic membrane fusion, oxidative damage, lipid-mixing Neurodegenerative diseases such as senile dementia including Alzheimer's disease have been characterized by progressive deterioration of cognitive function ( 1 ). Previous studies on brain aging revealed the high level of oxidative damage in the brain during normal aging, as well as in dementia ( 2 -4 ). Dementia is considered to be an acceleration of normal aging in affected brain regions which undergo progressive damage from reactive oxygen species (ROS) ( 5 ). It is, therefore, reasonable to assume that the deficit in neurotransmission is caused by oxidative damage to nerve terminals through chronic oxidative stress experienced over a long time, resulting in a cognitive dysfunction. In terms of neurodegeneration, the amount of oxidative damage to synapses in the brain regions, which modulate cognitive and motor functions, seems to depend on the protection afforded by several antioxidants ( 6 ). Accordingly, it seems that long-term vitamin E supplementation may prevent the oxidative damage of the nervous system during aging. In fact, a previous report revealed that long-term high-dose supplementation of vitamin E to aged individuals provides significant enhancement in cognitive function ( 7 ). A clinical trial on vitamin E supplementation in patients with moderately severe Alzheimer's disease showed delays in ...
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