Over-expression of mutant copper, zinc superoxide dismutase (SOD) in mice induces ALS and has become the most widely used model of neurodegeneration. However, no pharmaceutical agent in twenty years has extended lifespan by more than a few weeks. The Copper-Chaperone-for-SOD (CCS) protein completes the maturation of SOD by inserting copper, but paradoxically human CCS causes mice co-expressing mutant SOD to die within two weeks of birth. Hypothesizing that co-expression of CCS created copper deficiency in spinal cord, we treated these pups with the PET-imaging agent CuATSM, which is known to deliver copper into the CNS within minutes. CuATSM prevented the early mortality of CCSxSOD mice, while markedly increasing Cu,Zn SOD protein in their ventral spinal cord. Remarkably, continued treatment with CuATSM extended the survival of these mice by an average of 18 months. When CuATSM treatment was stopped, these mice developed ALS-related symptoms and died within three months. Restoring CuATSM treatment could rescue these mice after they became symptomatic, providing a means to start and stop disease progression. All ALS patients also express human CCS, raising the hope that familial SOD ALS patients could respond to CuATSM treatment similarly to the CCSxSOD mice.
Oxidative stress is a widely recognized cause of cell death associated with neurodegeneration, inflammation, and aging. Tyrosine nitration in these conditions has been reported extensively, but whether tyrosine nitration is a marker or plays a role in the cell-death processes was unknown. Here, we show that nitration of a single tyrosine residue on a small proportion of 90-kDa heat-shock protein (Hsp90), is sufficient to induce motor neuron death by the P2X7 receptor-dependent activation of the Fas pathway. Nitrotyrosine at position 33 or 56 stimulates a toxic gain of function that turns Hsp90 into a toxic protein. Using an antibody that recognizes the nitrated Hsp90, we found immunoreactivity in motor neurons of patients with amyotrophic lateral sclerosis, in an animal model of amyotrophic lateral sclerosis, and after experimental spinal cord injury. Our findings reveal that cell death can be triggered by nitration of a single protein and highlight nitrated Hsp90 as a potential target for the development of effective therapies for a large number of pathologies.apoptosis | peroxynitrite | PC12 cells
The transduction of cellular signals occurs through the modification of target molecules. Most of these modifications are transitory, thus the signal transduction pathways can be tightly regulated. Reactive nitrogen species are a group of compounds with different properties and reactivity. Some reactive nitrogen species are highly reactive and their interaction with macromolecules can lead to permanent modifications, which suggested they were lacking the specificity needed to participate in cell signaling events. However, the perception of reactive nitrogen species as oxidizers of macromolecules leading to general oxidative damage has recently evolved. The concept of redox signaling is now well established for a number of reactive oxygen and nitrogen species. In this context, the post-translational modifications introduced by reactive nitrogen species can be very specific and are active participants in signal transduction pathways. This review addresses the role of these oxidative modifications in the regulation of cell signaling events.
Although transcriptional effects of thyroid hormones have substantial influence on oxidative metabolism, how thyroid sets basal metabolic rate remains obscure. Compartmental localization of nitric-oxide synthases is important for nitric oxide signaling. We therefore examined liver neuronal nitric-oxide synthase-␣ (nNOS) subcellular distribution as a putative mechanism for thyroid effects on rat metabolic rate. At low 3,3 ,5-triiodo-L-thyronine levels, nNOS mRNA increased by 3-fold, protein expression by one-fold, and nNOS was selectively translocated to mitochondria without changes in other isoforms. In contrast, under thyroid hormone administration, mRNA level did not change and nNOS remained predominantly localized in cytosol. In hypothyroidism, nNOS translocation resulted in enhanced mitochondrial nitric-oxide synthase activity with low O 2 uptake. In this context, NO utilization increased active O 2 species and peroxynitrite yields and tyrosine nitration of complex I proteins that reduced complex activity. Hypothyroidism was also associated to high phospho-p38 mitogenactivated protein kinase and decreased phospho-extracellular signal-regulated kinase 1/2 and cyclin D1 levels. Similarly to thyroid hormones, but without changing thyroid status, nitric-oxide synthase inhibitor N -nitro-L-arginine methyl ester increased basal metabolic rate, prevented mitochondrial nitration and complex I derangement, and turned mitogen-activated protein kinase signaling and cyclin D1 expression back to control pattern. We surmise that nNOS spatial confinement in mitochondria is a significant downstream effector of thyroid hormone and hypothyroid phenotype.Hypothyroidism is a prevalent disorder associated to low oxygen utilization and low tissue proliferation rate (1). In addition to non-genomic effects (2), thyroid hormones influence transcription of a number of nuclear and mitochondrial-encoded respiratory genes (3). Although direct or transcriptional effects have considerable impact on oxidative metabolism and hemodynamic function, much is still unknown about how thyroid hormones set the metabolic rate of the body (4); consonant with slowness of transcriptional mechanisms, treatment of hypothyroidism may require weeks of hormone administration to normalize the altered functions (5). In the last decade, the effects of nitric oxide (NO) 2 expanded from the vascular system to the intracellular milieu. In this context, subcellular localization of nitric oxide-synthases (NOS) with effector molecules is an important regulatory mechanism for NO signaling (6, 7). Accordingly, we are interested in the traffic of a posttranslationally modified variant of neuronal nitric-oxide synthase-␣ (nNOS) to mitochondria (formerly named mitochondrial nitric-oxide synthase or mtNOS), which vectorially directs NO to the matrix compartment (8, 9). mtNOS could be low in adult rodents, but a modulated increase has been associated to thyroid status (10), release of cytochrome c (11), mitochondrial protein nitration (12), liver and brain development (13,...
Mitochondria are specialized organelles that control energy metabolism and also activate a multiplicity of pathways that modulate cell proliferation and mitochondrial biogenesis or, conversely, promote cell arrest and programmed cell death by a limited number of oxidative or nitrative reactions. Nitric oxide (NO) regulates oxygen uptake by reversible inhibition of cytochrome oxidase and the production of superoxide anion from the mitochondrial electron transfer chain. In this sense, NO produced by mtNOS will set the oxygen uptake level and contribute to oxidation-reduction reaction (redox)-dependent cell signaling. Modulation of translocation and activation of neuronal nitric oxide synthase (mtNOS activity) under different physiologic or pathologic conditions represents an adaptive response properly modulated to adjust mitochondria to different cell challenges.
When replete with zinc and copper, amyotrophic lateral sclerosis (ALS)-associated mutant SOD proteins can protect motor neurons in culture from trophic factor deprivation as efficiently as wild-type SOD. However, the removal of zinc from either mutant or wild-type SOD results in apoptosis of motor neurons through a copper-and peroxynitrite-dependent mechanism. It has also been shown that motor neurons isolated from transgenic mice expressing mutant SODs survive well in culture but undergo apoptosis when exposed to nitric oxide via a Fas-dependent mechanism. We combined these two parallel approaches for understanding SOD toxicity in ALS and found that zincdeficient SOD-induced motor neuron death required Fas activation, whereas the nitric oxide-dependent death of G93A SODexpressing motor neurons required copper and involved peroxynitrite formation. Surprisingly, motor neuron death doubled when Cu,Zn-SOD protein was either delivered intracellularly to G93A SOD-expressing motor neurons or co-delivered with zinc-deficient SOD to nontransgenic motor neurons. These results could be rationalized by biophysical data showing that heterodimer formation of Cu,Zn-SOD with zinc-deficient SOD prevented the monomerization and subsequent aggregation of zinc-deficient SOD under thiol-reducing conditions. ALS mutant SOD was also stabilized by mutating cysteine 111 to serine, which greatly increased the toxicity of zinc-deficient SOD. Thus, stabilization of ALS mutant SOD by two different approaches augmented its toxicity to motor neurons. Taken together, these results are consistent with copper-containing zinc-deficient SOD being the elusive "partially unfolded intermediate" responsible for the toxic gain of function conferred by ALS mutant SOD.Mutations to copper/zinc superoxide dismutase (SOD) 4 are the most common genetic cause of the familial form of amyotrophic lateral sclerosis (ALS) (1, 2). Although transgenic expression of these mutant SOD genes in mice and rats is sufficient to produce a progressive motor neuron disease that mimics human pathology (3), the toxic mechanisms remain obscure. Primary motor neuron cultures have proven to be a powerful model to elucidate the toxic gain of function conferred by ALS mutations to SOD and to determine the underlying cell death pathways. Motor neurons isolated from transgenic mice carrying ALS mutant SOD are fully viable in culture (4, 5) but undergo apoptosis after incubation with low, physiologically relevant concentrations of exogenous nitric oxide (50 -100 nM). This remains the most direct evidence that mutant SOD can become directly toxic to motor neurons but also demonstrates that expression of mutant SOD alone may not be sufficient to be toxic to motor neurons.The concentrations of nitric oxide used to induce death of ALS-SOD-expressing motor neurons were not injurious to motor neurons isolated from transgenic mice expressing wildtype SOD and are even trophic to nontransgenic motor neurons (6). Over the past decade, we have accumulated considerable evidence that the reacti...
Background: Heat shock protein 90 (Hsp90) is a pro-survival molecular chaperone that is nitrated only in pathological conditions. Results: Hsp90 nitrated on tyrosine 33 down-regulates mitochondrial activity. Conclusion: Differential nitration states of Hsp90 regulate distinct aspects of cellular metabolism. Significance: This is the first demonstration of a site-specific-nitrated protein regulating mitochondrial metabolism.
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