The noble gas xenon provides protection and trophic stimulation to midbrain dopamine neurons

Lavaur, Jérémie; Nogue, Déborah Le; Lemaire, Marc; Pype, J L; Farjot, Géraldine; Hirsch, Étienne C.; Michel, Patrick P.

doi:10.1111/jnc.14041

Cited by 36 publications

(45 citation statements)

References 68 publications

(89 reference statements)

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“…The effects of DA and SKF are only partially mimicked with the cAMP-elevating agent FK nigra DA neurons in PD may not simply result from an increased excitatory drive from subthalamic glutamatergic neurons as suggested before (Lavaur et al, 2017;Wallace et al, 2007) but also from a local rise of the neurotransmitter. **p < .01 and ****p < .0001 vs. controls.…”

Section: Aggregated But Not Monomeric Forms Of αS Stimulate Glutamamentioning

confidence: 95%

“…Here, we wished to evaluate the pro-inflammatory potential of amyloid fibrils of αS, using glutamate release as an activation marker of these cells. Our specific interest for this marker comes from the fact that glutamate has the potential to generate low-level excitotoxic insults (Lavaur et al, 2017) that may aggravate neurodegeneration in PD (Ambrosi et al, 2014). Using a model system of purified microglial cell cultures, we established that amyloid fibrils of αS had the capacity to stimulate FIGURE 5 Dopamine prevents glutamate release induced by αSa in microglial cells through D 1 receptor activation.…”

Section: Aggregated But Not Monomeric Forms Of αS Stimulate Glutamamentioning

confidence: 99%

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Microglial glutamate release evoked by α‐synuclein aggregates is prevented by dopamine

Pereira

Acuña

Hamadat

et al. 2018

Glia

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When activated, microglial cells have the potential not only to secrete typical proinflammatory mediators but also to release the neurotransmitter glutamate in amounts that may promote excitotoxicity. Here, we wished to determine the potential of the Parkinson's disease (PD) protein α‐Synuclein (αS) to stimulate glutamate release using cultures of purified microglial cells. We established that glutamate release was robustly increased when microglial cultures were treated with fibrillary aggregates of αS but not with the native monomeric protein. Promotion of microglial glutamate release by αS aggregates (αSa) required concomitant engagement of TLR2 and P2X7 receptors. Downstream to cell surface receptors, the release process was mediated by activation of a signaling cascade sequentially involving phosphoinositide 3‐kinase (PI3K) and NADPH oxidase, a superoxide‐producing enzyme. Inhibition of the Xc‐ antiporter, a plasma membrane exchange system that imports extracellular l‐cystine and exports intracellular glutamate, prevented the release of glutamate induced by αSa, indicating that system Xc‐ was the final effector element in the release process downstream to NADPH oxidase activation. Of interest, the stimulation of glutamate release by αSa was abrogated by dopamine through an antioxidant effect requiring D1 dopamine receptor activation and PI3K inhibition. Altogether, present data suggest that the activation of microglial cells by αSa may possibly result in a toxic build‐up of extracellular glutamate contributing to excitotoxic stress in PD. The deficit in dopamine that characterizes this disorder may further aggravate this process in a vicious circle mechanism.

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Section: Aggregated But Not Monomeric Forms Of αS Stimulate Glutamamentioning

confidence: 95%

Section: Aggregated But Not Monomeric Forms Of αS Stimulate Glutamamentioning

confidence: 99%

Microglial glutamate release evoked by α‐synuclein aggregates is prevented by dopamine

Pereira

Acuña

Hamadat

et al. 2018

Glia

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“…We reported previously that xenon promotes neuronal rescue not only against acute ischemic insults as initially demonstrated, but also in experimental situations where neurodegeneration is more slowly progressing (Lavaur et al 2016a, b). In particular, xenon was found to protect dopamine (DA) neurons in a culture setting where these neurons undergo sustained, low-level excitotoxicity mediated by glutamate (Lavaur et al 2017), i.e., experimental conditions that model Parkinson disease (PD) neurodegeneration (Nafia et al 2008). Indeed, an excessive excitatory drive from subthalamic nucleus glutamatergic neurons is thought to contribute to the vulnerability of substantia nigra DA neurons in this disorder (Wallace et al 2007;Ambrosi et al 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Specifically, this slow excitotoxic process was mimicked by treating midbrain dopaminergic cultures with l-transpyrrolidine-2,4-dicarboxylate (PDC), a synthetic analog of glutamate that operates as a transportable inhibitor of inward glutamate transport (Blitzblau et al 1996;Grewer et al 2014). In such paradigm, DA neurons were protected when 75% nitrogen contained in the control atmosphere was substituted with 75% xenon (Lavaur et al 2017) but we did not explore the neuroprotective potential of lower concentrations of xenon in this setting. Furthermore, even if we reported previously that argon was inactive against DA cell death induced by PDC, we have no information about the effects of other noble gases in the same experimental context.…”

Section: Introductionmentioning

confidence: 99%

Neuroprotection of dopamine neurons by xenon against low-level excitotoxic insults is not reproduced by other noble gases

et al. 2019

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Using midbrain cultures, we previously demonstrated that the noble gas xenon is robustly protective for dopamine (DA) neurons exposed to l-trans-pyrrolidine-2,4-dicarboxylate (PDC), an inhibitor of glutamate uptake used to generate sustained, low-level excitotoxic insults. DA cell rescue was observed in conditions where the control atmosphere for cell culture was substituted with a gas mix, comprising the same amount of oxygen (20%) and carbon dioxide (5%) but 75% of xenon instead of nitrogen. In the present study, we first aimed to determine whether DA cell rescue against PDC remains detectable when concentrations of xenon are progressively reduced in the cell culture atmosphere. Besides, we also sought to compare the effect of xenon to that of other noble gases, including helium, neon and krypton. Our results show that the protective effect of xenon for DA neurons was concentration-dependent with an IC 50 estimated at about 44%. We also established that none of the other noble gases tested in this study protected DA neurons from PDC-mediated insults. Xenon's effectiveness was most probably due to its unique capacity to block NMDA glutamate receptors. Besides, mathematical modeling of gas diffusion in the culture medium revealed that the concentration reached by xenon at the cell layer level is the highest of all noble gases when neurodegeneration is underway. Altogether, our data suggest that xenon may be of potential therapeutic value in Parkinson disease, a chronic neurodegenerative condition where DA neurons appear vulnerable to slow excitotoxicity.

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“…Heavier noble gases exhibit valuable properties in clinical and experimental settings—almost ideal anesthesia, neuroprotection, and analgesic qualities—and show beneficial effects on memory and addiction. They provide neuroprotection in in vitro and in vivo models of neurodegenerative conditions, potentially alleviating long‐term sequelae of stroke or other ischemic accidents . They exhibit little toxicity and wash out quickly, leading to rapid recovery.…”

Section: Introductionmentioning

confidence: 99%

Decoding the Rich Biological Properties of Noble Gases: How Well Can We Predict Noble Gas Binding to Diverse Proteins?

et al. 2018

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The chemically inert noble gases display a surprisingly rich spectrum of useful biological properties. Relatively little is known about the molecular mechanisms behind these effects. It is clearly not feasible to conduct large numbers of pharmacological experiments on noble gases to identify activity. Computational studies of the binding of noble gases and proteins can address this paucity of information and provide insight into mechanisms of action. We used bespoke computational grid calculations to predict the positions of energy minima in the interactions of noble gases with diverse proteins. The method was validated by quantifying how well simulations could predict binding positions in 131 diverse protein X-ray structures containing 399 Xe and Kr atoms. We found excellent agreement between calculated and experimental binding positions of noble gases. 94 % of all crystallographic xenon atoms were within 1 Xe van der Waals (vdW) diameter of a predicted binding site, and 97 % lay within 2 vdW diameters. 100 % of crystallographic krypton atoms were within 1 Kr vdW diameter of a predicted binding site. We showed the feasibility of large-scale computational screening of all ≈60 000 unique structures in the Protein Data Bank. This will elucidate biochemical mechanisms by which these novel 'atomic drugs' elicit their valuable biochemical properties and identify new medical uses.

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The noble gas xenon provides protection and trophic stimulation to midbrain dopamine neurons

Cited by 36 publications

References 68 publications

Microglial glutamate release evoked by α‐synuclein aggregates is prevented by dopamine

Microglial glutamate release evoked by α‐synuclein aggregates is prevented by dopamine

Neuroprotection of dopamine neurons by xenon against low-level excitotoxic insults is not reproduced by other noble gases

Decoding the Rich Biological Properties of Noble Gases: How Well Can We Predict Noble Gas Binding to Diverse Proteins?

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