Early events of target deprivation/axotomy‐induced neuronal apoptosis <i>in vivo</i>: oxidative stress, DNA damage, p53 phosphorylation and subcellular redistribution of death proteins

Martin, Lee J.; Price, Anne C.; McClendon, Karen B.; Al-Abdulla, Nael A.; Subramaniam, Jamuna R.; Wong, Philip C.; Liu, Zhiping

doi:10.1046/j.1471-4159.2003.01659.x

Cited by 66 publications

(83 citation statements)

References 62 publications

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“…When deprived of trophic support or after stimulation of death receptors, motor neurons die by apoptosis, which is dependent on de novo synthesis of neuronal NOS, nitric oxide production, and peroxynitrite formation (Estévez et al, 1998a(Estévez et al, , 2000Martin et al, 1999Martin et al, , 2003Martin et al, , 2005. Herein we propose a model to explain the differential vulnerability of motor neurons after trophic factor deprivation.…”

Section: Discussionmentioning

confidence: 98%

Arginase 1 Regulation of Nitric Oxide Production Is Key to Survival of Trophic Factor-Deprived Motor Neurons

et al. 2006

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When deprived of trophic factors, the majority of cultured motor neurons undergo nitric oxide-dependent apoptosis. However, for reasons that have remained unclear, 30 -50% of the motor neurons survive for several days without trophic factors. Here we hypothesize that the resistance of this motor neuron subpopulation to trophic factor deprivation can be attributed to diminished nitric oxide production resulting from the activity of the arginine-degrading enzyme arginase. When incubated with nor-N G -hydroxy-nor-L-arginine (NOHA), the normally resistant trophic factor-deprived motor neurons showed a drop in survival rates, whereas trophic factor-treated neurons did not. NOHA-induced motor neuron death was inhibited by blocking nitric oxide synthesis and the scavenging of superoxide and peroxynitrite, suggesting that peroxynitrite mediates NOHA toxicity. When we transfected arginase 1 into motor neurons to see whether it alone could abrogate trophic factor deprivation-induced death, we found that its forced expression did indeed do so. The protection afforded by arginase 1 expression is reversed when cells are incubated with NOHA or with low concentrations of nitric oxide. These results reveal that arginase acts as a central regulator of trophic factor-deprived motor neuron survival by suppressing nitric oxide production and the consequent peroxynitrite toxicity. They also suggest that the resistance of motor neuron subpopulations to trophic factor deprivation may result from increased arginase activity.

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Section: Discussionmentioning

confidence: 98%

Arginase 1 Regulation of Nitric Oxide Production Is Key to Survival of Trophic Factor-Deprived Motor Neurons

et al. 2006

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“…29 A large percentage of CNS pathologies present acute focal brain lesions and their consequences have been studied in various animal models. 21,40,41 The HCb model is well established, in which neuronal degeneration can be analyzed remotely from the primary site of damage, where effects of the primary lesion can confound the study of degeneration. These remote phenomena can be used to exploit therapeutic approaches, because they are active long after the primary damage has subsided and influence postlesion impairments.…”

Section: Discussionmentioning

confidence: 99%

Stimulation of autophagy by rapamycin protects neurons from remote degeneration after acute focal brain damage

et al. 2012

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Keywords: neurodegeneration, neuronal death, acute brain damage, rapamycin, neuroprotectionAbbreviations: ANOVA, analysis of variance; APs, autophagosomes; Becn1, beclin 1; CNS, central nervous system; Cyt-c, cytochrome-c; CQ, chloroquine; GFP, green fluorescent protein; HCb, hemicerebellectomy; IO, inferior olive; LC3, microtubule-associated protein 1 light chain 3; mTOR, mammalian target of rapamycin; NeuN, neuron specific nuclear protein; NSS, neurological severity score; Pn, pontine nuclei; Rap, rapamycin; Sal, saline Autophagy is the evolutionarily conserved degradation and recycling of cellular constituents. In mammals, autophagy is implicated in the pathogenesis of many neurodegenerative diseases. However, its involvement in acute brain damage is unknown. This study addresses the function of autophagy in neurodegeneration that has been induced by acute focal cerebellar lesions. We provide morphological, ultrastructural, and biochemical evidence that lesions in a cerebellar hemisphere activate autophagy in axotomized precerebellar neurons. Through time course analyses of the apoptotic cascade, we determined mitochondrial dysfunction to be the early trigger of degeneration. Further, the stimulation of autophagy by rapamycin and the employment of mice with impaired autophagic responses allowed us to demonstrate that autophagy protects from damage promoting functional recovery. These findings have therapeutic significance, demonstrating the potential of pro-autophagy treatments for acute brain pathologies, such as stroke and brain trauma.

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“…The pathophysiological mechanisms of secondary injury are complex and include inflammation, production of ROS/ RNS, increased intracellular calcium and lipid peroxidation [41,42]. The breakdown of the blood-brain-barrier and a neuroinflammatory response after brain injury also contribute to neuronal death [43,44]. Oxidative stress and peroxidation of PUFA damage neuronal membranes, leading to the generation of 4-HNE and acrolein, which in turn can damage proteins.…”

Section: Discussionmentioning

confidence: 99%

Oxidative stress and modification of synaptic proteins in hippocampus after traumatic brain injury

Ansari

Roberts

Scheff

2008

Free Radical Biology and Medicine

272

220

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Oxidative stress, an imbalance between oxidants and antioxidants, contributes to the pathogenesis of traumatic brain injury (TBI). Oxidative neurodegeneration is a key mediator of exacerbated morphological responses and deficits in behavioral recoveries. The present study assessed early hippocampal sequential imbalance to possibly enhance antioxidant therapy. Young adult male Sprague-Dawley rats were subjected to a unilateral moderate cortical contusion. At various times post TBI, animals were killed and the hippocampus analyzed for antioxidants (GSH, GSSG, glutathione peroxidase, glutathione reductase, glutathione-S-transferase, glucose-6-phosphate dehydrogenase, superoxide dismutase and catalase), and oxidants (acrolein,, protein carbonyl [PC] and 3-nitrotyrosine. Synaptic markers (synapsin-I, post synaptic density-95 [PSD-95], synapse associated protein-97 [SAP-97], growth associated protein-43 were also analyzed. All values were compared to sham operated animals. Significant time-dependent changes in antioxidants were observed as early as 3 h post trauma and paralleled increases in oxidants (4-HNE, acrolein and PC) with peak values obtained at 24-48 h. Time dependent changes in synaptic proteins (synapsin-I, PSD-95 and SAP-97) occurred well after levels of oxidants peaked. These results indicate that depletion of antioxidant systems following trauma could adversely affect synaptic function and plasticity. Early onset of oxidative stress suggests that the initial therapeutic window following TBI appears to be relatively short and it may be necessary to stagger selective types of anti-oxidant therapy to target specific oxidative components.

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Early events of target deprivation/axotomy‐induced neuronal apoptosis in vivo: oxidative stress, DNA damage, p53 phosphorylation and subcellular redistribution of death proteins

Cited by 66 publications

References 62 publications

Arginase 1 Regulation of Nitric Oxide Production Is Key to Survival of Trophic Factor-Deprived Motor Neurons

Arginase 1 Regulation of Nitric Oxide Production Is Key to Survival of Trophic Factor-Deprived Motor Neurons

Stimulation of autophagy by rapamycin protects neurons from remote degeneration after acute focal brain damage

Oxidative stress and modification of synaptic proteins in hippocampus after traumatic brain injury

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