Nitric oxide, mitochondria and neurological disease.

Damage to the mitochondrial electron transport chain has been suggested to be an important factor in the pathogenesis of a range of neurological disorders, such as Parkinson's disease, Alzheimer's disease, multiple sclerosis, stroke and amyotrophic lateral sclerosis. There is also a growing body of evidence to implicate excessive or inappropriate generation of nitric oxide (NO) in these disorders. It is now well documented that NO and its toxic metabolite, peroxynitrite (ONOO-), can inhibit components of the mitochondrial respiratory chain leading, if damage is severe enough, to a cellular energy deficiency state. Within the brain, the susceptibility of different brain cell types to NO and ONOO- exposure may be dependent on factors such as the intracellular reduced glutathione (GSH) concentration and an ability to increase glycolytic flux in the face of mitochondrial damage. Thus neurones, in contrast to astrocytes, appear particularly vulnerable to the action of these molecules. Following cytokine exposure, astrocytes can increase NO generation, due to de novo synthesis of the inducible form of nitric oxide synthase (NOS). Whilst the NO/ONOO- so formed may not affect astrocyte survival, these molecules may diffuse out to cause mitochondrial damage, and possibly cell death, to other cells, such as neurones, in close proximity. Evidence is now available to support this scenario for neurological disorders, such as multiple sclerosis. In other conditions, such as ischaemia, increased availability of glutamate may lead to an activation of a calcium-dependent nitric oxide synthase associated with neurones. Such increased/inappropriate NO formation may contribute to energy depletion and neuronal cell death. The evidence available for NO/ONOO--mediated mitochondrial damage in various neurological disorders is considered and potential therapeutic strategies are proposed.

Comparison of mitochondrial respiratory chain enzyme activities in rodent astrocytes and neurones and a human astrocytoma cell line.

This study has found that mitochondrial NADH-CoQ1 reductase (complex I) activity is significantly lower in C57 mice astrocytes compared with Wistar and Sprague-Dawley rat astrocytes, and a human astrocytoma cell line. In addition, complex I activity is 4-fold greater in Sprague-Dawley neurones when compared to Wistar or C57 neurones. These findings have important implications for mitochondrial studies involving rodent or human cell line systems, and in particular, indicate the importance of choosing an appropriate model when investigating the mitochondrial respiratory chain.

Astrocyte-derived nitric oxide causes both reversible and irreversible damage to the neuronal mitochondrial respiratory chain.

Cytokine-stimulated astrocytes produce nitric oxide (NO), which, along with its metabolite peroxynitrite (ONOO(-)), can inhibit components of the mitochondrial respiratory chain. We used astrocytes as a source of NO/ONOO(-) and monitored the effects on neurons in coculture. We previously demonstrated that astrocytic NO/ONOO(-) causes significant damage to the activities of complexes II/III and IV of neighbouring neurons after a 24-h coculture. Under these conditions, no neuronal death was observed. Using polytetrafluoroethane filters, which are permeable to gases such as NO but impermeable to NO derivatives, we have now demonstrated that astrocyte-derived NO is responsible for the damage observed in our coculture system. Expanding on these observations, we have now shown that 24 h after removal of NO-producing astrocytes, neurons exhibit complete recovery of complex II/III and IV activities. Furthermore, extending the period of exposure of neurons to NO-producing astrocytes does not cause further damage to the neuronal mitochondrial respiratory chain. However, whereas the activity of complex II/III recovers with time, the damage to complex IV caused by a 48-h coculture with NO-producing astrocytes is irreversible. Therefore, it appears that neurons can recover from short-term damage to mitochondrial complex II/III and IV, whereas exposure to astrocytic-derived NO for longer periods causes permanent damage to neuronal complex IV.

Pretreatment of astrocytes with interferon-alpha/beta prevents neuronal mitochondrial respiratory chain damage.

Excessive nitric oxide/peroxynitrite generation has been implicated in the pathogenesis of multiple sclerosis, and the demonstration of increased astrocytic nitric oxide synthase activity in the postmortem brain of multiple sclerosis patients supports this hypothesis. Interferon-beta is used for the treatment of multiple sclerosis, but currently little is known regarding its mode of action. Exposure of astrocytes in culture to interferon-gamma plus lipopolysaccharide results in stimulation of nitric oxide release. Using a coculture system, we have been able to use astrocytes as a source of nitric oxide/peroxynitrite in an attempt to "model" the effects of raised cytokine levels observed in multiple sclerosis and to monitor the effect on neurones. Our results indicate that stimulation of astrocytic nitric oxide synthase activity causes significant damage to the mitochondrial activities of complexes II/III and IV of neighbouring neurones. This damage was prevented by a nitric oxide synthase inhibitor, suggesting that the damage was nitric oxide-mediated. Furthermore, interferon-alpha/beta also prevented this damage. In view of these results, we suggest that a possible mechanism of action of interferon-beta in the treatment of multiple sclerosis is that it prevents astrocytic nitric oxide production, thereby limiting damage to neighbouring cells, such as neurones.

Pretreatment of astrocytes with interferon-alpha/beta impairs interferon-gamma induction of nitric oxide synthase.

Excessive nitric oxide/peroxynitrite generation has been implicated in the pathogenesis of multiple sclerosis, and the demonstration of increased astrocytic nitric oxide synthase activity in the postmortem brain of multiple sclerosis patients supports this hypothesis. Exposure of astrocytes, in primary culture, to interferon-gamma results in stimulation of nitric oxide synthase activity and increased nitric oxide release. In contrast to interferon-gamma, interferon-alpha/beta had a minimal effect on astrocytic nitric oxide formation. Furthermore, pretreatment of astrocytes with interferon-alpha/beta inhibited (approximately 65%) stimulation by interferon-gamma of nitric oxide synthase activity and nitric oxide release. Treatment with interferon-alpha/beta at a concentration as low as 10 U/ml caused inhibition of mitochondrial cytochrome c oxidase. Furthermore, the damage to cytochrome c oxidase was prevented by the putative interferon-alpha/beta receptor antagonist oxyphenylbutazone. In view of these observations, our current hypothesis is that the mitochondrial damage caused by exposure to interferon-alpha/beta may impair the ability of astrocytes to induce nitric oxide synthase activity on subsequent interferon-gamma exposure. These results may have implications for our understanding of the mechanisms responsible for the therapeutic effects of interferon-alpha/beta preparations in multiple sclerosis.

Nitric oxide-dependent damage to neuronal mitochondria involves the NMDA receptor.

Cytokine-stimulated astrocytes produce nitric oxide, which can inhibit components of the mitochondrial respiratory chain. We have previously demonstrated that prolonged exposure (48 h) to rat astrocytic nitric oxide damages complexes II--III and IV of neighbouring rat neurons in coculture, resulting in neuronal death. Expanding on these observations, we have now shown that the NMDA receptor antagonist, MK-801, prevents this damage, suggesting involvement of glutamate. We postulate that astrocyte-derived nitric oxide stimulates release of neuronal glutamate. Indeed we demonstrate that neurons incubated with nitric oxide-generating astrocytes display enhanced glutamate release. Furthermore, direct exposure to the nitric oxide donor, DETA-NONOate resulted in a loss of activity of all the neuronal mitochondrial complexes, which was again prevented by MK-801. Thus, nitric oxide, generated by both cytokine-stimulated astrocytes and by a nitric oxide donor, causes activation of the NMDA receptor leading to damage to the neuronal mitochondrial respiratory chain. Glutamate exposure is known to damage the neuronal mitochondrial respiratory chain via neuronal nitric oxide synthase. Therefore, we propose that astrocyte-derived nitric oxide is capable of eliciting neuronal glutamate release, which in turn activates the neuronal NMDA receptor and stimulates further formation of reactive nitrogen species via neuronal nitric oxide synthases, leading to mitochondrial damage and neuronal death. Our findings support the hypothesis that glutamate, reactive nitrogen species and mitochondrial dysfunction may have a role in the neurodegenerative process.