1. Age-related calcium changes, oxyradical damage, caspase activation and nuclear condensation in hippocampal neurons in response to glutamate and beta-amyloid
- Author
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Gregory J. Brewer, A. Lim, Nicole G. Capps, and John R. Torricelli
- Subjects
Aging ,medicine.medical_specialty ,Programmed cell death ,Neurotoxins ,Excitotoxicity ,Glutamic Acid ,chemistry.chemical_element ,Apoptosis ,Hippocampal formation ,Biology ,Calcium ,medicine.disease_cause ,Hippocampus ,Biochemistry ,Calcium in biology ,Endocrinology ,Internal medicine ,Genetics ,medicine ,Animals ,Molecular Biology ,Cells, Cultured ,Cell Nucleus ,Neurons ,Enzyme Precursors ,Amyloid beta-Peptides ,Caspase 3 ,Glutamate receptor ,Cell Biology ,Rats, Inbred F344 ,Rats ,medicine.anatomical_structure ,nervous system ,chemistry ,Caspases ,Neuron ,Reactive Oxygen Species - Abstract
Neuronal degeneration increases with age in response to stressors, but the sub-cellular mechanism is unknown, partly because of previous difficulty in studying aged neurons in isolation. We studied the mechanism of enhanced neuronal susceptibility to glutamate and beta-amyloid in terms of condensed nuclei and other upstream events in hippocampal neurons cultured from old rats (24 months) compared to middle-age (10 months) and embryonic rats. Treatment of neurons from old animals with beta-amyloid (or glutamate) produced condensed nuclei 1.5x (2x) more frequently than middle-age and 3x (4x) more frequently than embryonic neurons. In addition to age-related baseline levels of caspase activation, neurons from old animals showed a 50% greater increase in caspase activation compared to middle-age and embryonic neurons. In contrast to glutamate treatment, beta-amyloid caused oxyradical damage as protein carbonyls increased 2-fold higher for old neurons than middle-age and 10-fold higher than embryonic neurons. Contrary to expectations, steady-state calcium levels for adult neurons did not increase in response to beta-amyloid. Overall, these results suggest that aged neurons have an inherent increased susceptibility to beta-amyloid toxicity through an early action of oxyradicals followed by caspase activation and nuclear condensation, a common pathway of apoptosis. Age-related glutamate toxicity involves other steps that lead to nuclear condensation, but neuron responses to calcium influx appear more important to cell death than the amount of influx.
- Published
- 2005
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