Neuronal Glutathione Content and Antioxidant Capacity can be Normalized In Situ by N-acetyl Cysteine Concentrations Attained in Human Cerebrospinal Fluid

Reyes, Reno C.; Cittolin-Santos, Giordano Fabricio; Kim, Jieun; Won, Seok Joon; Brennan-Minnella, Angela M.; Katz, Maya; Glass, Graham A.; Swanson, Raymond A.

doi:10.1007/s13311-015-0404-4

Cited by 34 publications

(39 citation statements)

References 39 publications

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“…51 As we plan to try to avoid these enormous challenges in moving our studies of NAC forward for ICH, we will need to develop a good biomarker for NAC's therapeutic effect in humans. Almost all studies chose doses of NAC that are safe, but without clear elucidation of the dose required to induce a therapeutic effect.…”

Section: Discussionmentioning

confidence: 99%

“…Cerebrospinal fluid measurements could improve fidelity of glutathione measurements, but a threshold level of increase of glutathione has yet to be elucidated in any paradigm. 51 As we plan to try to avoid these enormous challenges in moving our studies of NAC forward for ICH, we will need to develop a good biomarker for NAC's therapeutic effect in humans. Given the ability of PGE 2 to synergize with NAC in mice to induce functional recovery, it is our hypothesis that understanding precisely how this combination is effective will provide the best chances of neuroprotection with the widest therapeutic window in humans, once a good biomarker for NAC efficacy (possibly an ALOX5 metabolite) is identified.…”

Section: Discussionmentioning

confidence: 99%

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N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E₂ to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

Karuppagounder

Alin

Chen

et al. 2018

Annals of Neurology

226

167

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Objectives N‐acetylcysteine (NAC) is a clinically approved thiol‐containing redox modulatory compound currently in trials for many neurological and psychiatric disorders. Although generically labeled as an “antioxidant,” poor understanding of its site(s) of action is a barrier to its use in neurological practice. Here, we examined the efficacy and mechanism of action of NAC in rodent models of hemorrhagic stroke. Methods Hemin was used to model ferroptosis and hemorrhagic stroke in cultured neurons. Striatal infusion of collagenase was used to model intracerebral hemorrhage (ICH) in mice and rats. Chemical biology, targeted lipidomics, arachidonate 5‐lipoxygenase (ALOX5) knockout mice, and viral‐gene transfer were used to gain insight into the pharmacological targets and mechanism of action of NAC. Results NAC prevented hemin‐induced ferroptosis by neutralizing toxic lipids generated by arachidonate‐dependent ALOX5 activity. NAC efficacy required increases in glutathione and is correlated with suppression of reactive lipids by glutathione‐dependent enzymes such as glutathione S ‐transferase. Accordingly, its protective effects were mimicked by chemical or molecular lipid peroxidation inhibitors. NAC delivered postinjury reduced neuronal death and improved functional recovery at least 7 days following ICH in mice and can synergize with clinically approved prostaglandin E 2 (PGE 2 ). Interpretation NAC is a promising, protective therapy for ICH, which acted to inhibit toxic arachidonic acid products of nuclear ALOX5 that synergized with exogenously delivered protective PGE 2 in vitro and in vivo. The findings provide novel insight into a target for NAC, beyond the generic characterization as an antioxidant, resulting in neuroprotection and offer a feasible combinatorial strategy to optimize efficacy and safety in dosing of NAC for treatment of neurological disorders involving ferroptosis such as ICH. Ann Neurol 2018;84:854–872

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E₂ to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

Karuppagounder

Alin

Chen

et al. 2018

Annals of Neurology

226

167

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“…Yet, any increased glutamate extrusion caused by stimulation of system

x_{c}^{-}

by NAC was clearly insufficient to inhibit LTP at either 1 or 12 h after injection on its own. Interestingly, the relative ability of NAC to increase intracellular GSH and extracellular glutamate concentrations is state‐dependent (Baker et al, ; Choy et al, ; Kupchik et al, ; Reyes et al, ). An alternative or additional explanation for the delayed beneficial action of NAC is that it may trigger a gradual increase in the expression of amino acid transporters that mediate glutamate uptake, and thereby promote the clearance of excess glutamate from the extracellular space.…”

Section: Discussionmentioning

confidence: 99%

“…NAC has been found to increase GSH synthesis in brain both directly and indirectly (Holmay et al, 2013;Zhou et al, 2015). Although the extent of blood brain barrier permeability of NAC is somewhat controversial, available evidence indicates that the levels in CSF increase rapidly and transiently, peaking 20 min after acute injection (Reyes et al, 2016), consistent with NAC's short elimination half-life (30 min in mice, Zhou et al, 2015). In contrast, NAC has been found to elicit a more gradual increase in brain GSH synthesis, reaching a plateau within 3-6 h after acute administration (Holmay et al, 2013;Zhou et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

Opposite in vivo effects of agents that stimulate or inhibit the glutamate/cysteine exchanger system on the inhibition of hippocampal LTP by Aß

et al. 2016

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Aggregated amyloid ß-protein (Aß) is pathognomonic of Alzheimer's disease and certain assemblies of Aß are synaptotoxic. Excess glutamate or diminished glutathione reserve are both implicated in mediating or modulating Aß-induced disruption of synaptic plasticity. The system xc- antiporter promotes Na -independent exchange of cystine with glutamate thereby providing a major source of extracellular glutamate and intracellular glutathione concentrations. Here we probed the ability of two drugs with opposite effects on system xc-, the inhibitor sulfasalazine and facilitator N-acetylcysteine, to modulate the ability of Aß1-42 to inhibit long-term potentiation (LTP) in the CA1 area of the anaesthetized rat. Whereas acute systemic treatment with sulfasalazine lowered the threshold for Aß to interfere with synaptic plasticity, N-acetylcysteine prevented the inhibition of LTP by Aß alone or in combination with sulfasalazine. Moreover acute N-acetylcysteine also prevented the inhibition of LTP by TNFα, a putative mediator of Aß actions, and repeated systemic N-acetylcysteine treatment for 7 days reversed the delayed deleterious effect of Aß on LTP. Since both of these drugs are widely used clinically, further evaluation of their potential beneficial and deleterious actions in early Alzheimer's disease seems warranted. © 2016 Wiley Periodicals, Inc.

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“…2A). The H 2 O 2 -induced c-Abl activation was suppressed by N-acetyl-cysteine (NAC), a thiol agent previously shown to support neuronal glutathione synthesis 28,31 and to have salutary effects in animal models of PD 28,32,33 . We next evaluated the effect of redox stress on c-Abl activation in vivo, using EAAC1 -/mice.…”

Section: Oxidative Stress Alone Is Sufficient To Activate C-abl In Cumentioning

confidence: 99%

Disrupting pathogenic interactions between α-synuclein, c-Abl, and redox stress

Ghosh

Won

Fong

et al. 2019

Preprint

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Objective: Redox stress, c-Abl activation, and α -synuclein aggregates each independently contribute to neurodegeneration in Parkinson's disease. Interactions between these factors may underlie convergent and feed-forward mechanisms of disease progression. Methods:α -synuclein aggregate formation was induced in neuronal cultures and mouse substantia nigra by exposure to pre-formed human α -synuclein fibrils or by AAV-mediated over-expression of α -synuclein. Aggregate formation, c-Abl activation, redox stress, and neurodegeneration were evaluated by immunohistochemistry and Western blots, and mouse motor function was evaluated using the rota-rod and pole tests. To suppress redox stress, cultures and mice were treated with N-acetyl cysteine, a thiol repletion agent that supports neuronal glutathione metabolism. Results: In primary neuron cultures, the formation of α -synuclein aggregates led to redox stress and c-Abl activation. Redox stress alone, in the absence of α -synuclein aggregates, was also sufficient to induced c-Abl activation. N-acetyl cysteine suppressed redox stress, and likewise suppressed both c-Abl activation and α -synuclein aggregation. A similar pattern was observed in the two mouse models of Parkinson's disease. In both models, α synuclein aggregates in the substantia nigra were accompanied by redox stress, c-Abl activation, dopaminergic neurodegeneration and motor impairment, all of which were attenuated in mice treated with oral N-acetyl cysteine.Interpretation: These results indicate that α -synuclein aggregates induce c-Abl activation by a redox stress mechanism. c-Abl in turn promotes α -synuclein aggregation, and this potentially feed-forward process can be blocked by N-acetyl cysteine. The findings thus add mechanistic support for N-acetyl cysteine as a therapeutic for Parkinson's disease.

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Neuronal Glutathione Content and Antioxidant Capacity can be Normalized In Situ by N-acetyl Cysteine Concentrations Attained in Human Cerebrospinal Fluid

Cited by 34 publications

References 39 publications

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E₂ to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E₂ to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

Opposite in vivo effects of agents that stimulate or inhibit the glutamate/cysteine exchanger system on the inhibition of hippocampal LTP by Aß

Disrupting pathogenic interactions between α-synuclein, c-Abl, and redox stress

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Neuronal Glutathione Content and Antioxidant Capacity can be Normalized In Situ by N-acetyl Cysteine Concentrations Attained in Human Cerebrospinal Fluid

Cited by 34 publications

References 39 publications

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E2 to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E2 to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

Opposite in vivo effects of agents that stimulate or inhibit the glutamate/cysteine exchanger system on the inhibition of hippocampal LTP by Aß

Disrupting pathogenic interactions between α-synuclein, c-Abl, and redox stress

Contact Info

Product

Resources

About

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E₂ to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice

N‐acetylcysteine targets 5 lipoxygenase‐derived, toxic lipids and can synergize with prostaglandin E₂ to inhibit ferroptosis and improve outcomes following hemorrhagic stroke in mice