NO AND MITOCHONDRIAL RESPIRATION

Nitric oxide (NO) plays an important role as an inter- and intra-cellular messenger, acting in the cardiovascular system, in the nervous system and as a component of the immune system ¹. NO is a diatomic free radical which is a gas at room temperature, making it highly diffusible within the vasculature. One of its major targets is the soluble guanylyl cyclase (sGC). The binding of NO to Fe²⁺ in the haem group of sGC activates the enzyme and increases the concentration of cGMP (guanosine 3', 5'-cyclic monophosphate). The NO/cGMP signalling pathway has been demonstrated to be important in many biological systems including blood pressure regulation, platelet aggregability, smooth muscle relaxation and peripheral and central neurotransmission.

Recent work has shown that NO, in the nanomolar concentration range that activates sGC, can also bind to cytochrome c oxidase (complex IV) and inhibit it in a manner that is reversible and in competition with oxygen ^{2, 3}. Cytochrome c oxidase is the terminal enzyme of the mitochondrial respiratory chain and is responsible for 90% of cellular oxygen consumption in mammals. The enzyme catalyses the oxidation of cytochrome c²⁺ to cytochrome c³⁺ and the reduction of oxygen to water, which is coupled to the pumping of protons across the inner mitochondrial membrane. Because NO competes with oxygen at the cytochrome c oxidase, increases in NO concentration can prevent the enzyme from using any available oxygen, thus causing a kind of "metabolic hypoxia" ⁴.

Such "metabolic hypoxia" has profound biological consequences, particularly with regard to the regulation of the hypoxia-inducible factor (HIF)-1. HIF-1 is a transcription factor that plays a major role in the response of tissues to low partial pressures of oxygen, by upregulating genes such as those involved in glycolysis and angiogenesis ⁵. At normal oxygen concentrations HIF-1 is regulated in an oxygen-dependent manner by a family of prolyl hydroxylases that prevent stabilisation of HIF-1 its subsequent dimerisation with HIF-1 and the consequent activation of target genes. At low oxygen concentrations (1-3%) prolyl hydroxylase activity is inhibited, and HIF-1 accumulates, resulting in the activation of target gene expression. However, if cells maintained at 1-3% oxygen are exposed to low concentrations of NO, stabilisation of HIF-1 is prevented ⁶. We have shown that, in hypoxic conditions, NO and other inhibitors of mitochondrial respiration can cause redistribution of oxygen away from the electron transport chain towards non-respiratory oxygen-dependent targets such as prolyl hydroxylases ⁷. Since more than 70 genes (including those involved in erythropoiesis, angiogenesis and glycolysis) are known to be regulated at the transcriptional level by HIF-1 ⁵, NO-mediated inhibition of respiration may profoundly modify the signalling consequences of hypoxia.

NO AND THE ENDOPLASMIC RETICULUM STRESS RESPONSE

Until recently, the main function of mitochondria was considered to be the production of energy; however mitochondria can also play an important role in intracellular signalling, for example by coupling calcium signalling with the endoplasmic reticulum (ER) ^{8, 9, 10}. Studies using genetically targeted Ca²⁺-selective probes (such as the bioluminescent protein aequorin) or fluorescent dyes (such as rhod-2) have provided a direct and unambiguous readout of mitochondrial Ca²⁺ changes in living cells following receptor stimulation. Recently we found that in NO-generating cells there is a disruption in the respiratory chain and a decreased respiration rate that is accompanied by a mitochondrial Ca²⁺ flux ¹¹. These findings are in agreement with previous reports showing that exogenous NO ¹² and peroxynitrite ^{13, 14} can result in the release of Ca²⁺ from mitochondria. Interestingly, Nowicky and Duchen reported changes in [Ca²⁺]_i and membrane currents when mitochondrial respiration in dissociated rat hippocampal neurons was impaired by inhibition of cytochrome c oxidase using cyanide, or by hypoxia ¹⁵. It is possible that disrupting electron transfer at cytochrome c oxidase may result in ionic readjustment and modulation of the Ca²⁺ flux between the mitochondria and the ER. We found that this NO-mediated change in Ca²⁺ flux is sufficient to activate the Ca²⁺-dependent protease (site-1 protease, S1P) involved in a regulated intermembrane proteolysis (RIP) pathway. S1P, in association with the site-2 protease located in the Golgi apparatus, cleaves the ER stress-regulated transmembrane transcription factor p90 ATF6. The resulting soluble transcription factor p50 ATF6 is then free to translocate to the nucleus where it subsequently activates ER stress-responsive genes, such as glucose regulated protein 78 (Grp78) ¹¹.

Grp78 is a Ca²⁺-binding chaperone protein with cytoprotective properties. It can be up-regulated by hypoxic conditions and by glucose starvation. Grp78 associates transiently with nascent proteins, facilitating their translocation into the ER and aiding in their folding and transport through the ER. Grp78 appears to be a master switch of the unfolded protein response (UPR) and ER stress. We found that the NO-mediated up-regulation of Grp78 provides significant cytoprotection against toxic agents including thapsigargin (a selective ER Ca²⁺-ATPase inhibitor). This cytoprotection is abolished following treatment with cyclosporin A (CsA), which prevents mitochondrial Ca²⁺ efflux, and BAPTA-AM, an intracellular chelator. The NO-mediated ER stress response is diminished in rho⁰ cells that are devoid of mitochondrial DNA. Therefore, our work has shown that NO signals, via mitochondrial respiration, to the ER stress response with consequences for cell survival or death ¹¹.

Apart from Grp78, a number of other genes have been shown to be regulated by the Ca²⁺-dependent serine protease S1P. These include genes for growth factors, transcription factors and viral glycoproteins that are involved in neurological, cardiovascular and immunological systems. Our findings suggest that the NO-mediated Ca²⁺ signalling pathway may well be important in their regulation.

CONCLUSION

The coupling of mitochondrial signalling and the ER is an emerging area of interest, and a common apoptosis pathway has recently been described in BAX and BAK regulation in which the ER and mitochondria are coupled via Ca^{2+ 16}. It will be important to explore further how the NO-mediated ER signalling we have described interacts with BAX and BAK pathways to regulate mitochondria-mediated apoptosis.

References

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