3pku Citations

Pressure-response analysis of anesthetic gases xenon and nitrous oxide on urate oxidase: a crystallographic study.

Marassio G, Prangé T, David HN, Santos JS, Gabison L, Delcroix N, Abraini JH, Colloc'h N
FASEB J 25 2266-75 (2011)
Related entries: 3pjk, 3pk3, 3pk4, 3pk5, 3pk6, 3pk8, 3pkf, 3pkg, 3pkh, 3pkk, 3pkl, 3pks, 3pkt, 3ple, 3plg, 3plh, 3pli, 3plj, 3plm

Cited: 20 times
EuropePMC logo PMID: 21421845

Abstract

The remarkably safe anesthetics xenon (Xe) and, to lesser extent, nitrous oxide (N(2)O) possess neuroprotective properties in preclinical studies. To investigate the mechanisms of pharmacological action of these gases, which are still poorly known, we performed both crystallography under a large range of gas pressure and biochemical studies on urate oxidase, a prototype of globular gas-binding proteins whose activity is modulated by inert gases. We show that Xe and N(2)O bind to, compete for, and expand the volume of a hydrophobic cavity located just behind the active site of urate oxidase and further inhibit urate oxidase enzymatic activity. By demonstrating a significant relationship between the binding and biochemical effects of Xe and N(2)O, given alone or in combination, these data from structure to function highlight the mechanisms by which chemically and metabolically inert gases can alter protein function and produce their pharmacological effects. Interestingly, the effects of a Xe:N(2)O equimolar mixture were found to be equivalent to those of Xe alone, thereby suggesting that gas mixtures containing Xe and N(2)O could be an alternative and efficient neuroprotective strategy to Xe alone, whose widespread clinical use is limited due to the cost of production and availability of this gas.

Reviews citing this publication (2)

  1. High-pressure macromolecular crystallography and NMR: status, achievements and prospects. Fourme R, Girard E, Akasaka K. Curr Opin Struct Biol 22 636-642 (2012)
  2. Are Protein Cavities and Pockets Commonly Used by Redox Active Signalling Molecules? Hancock JT. Plants (Basel) 12 2594 (2023)

Articles citing this publication (18)

  1. Tunnels modulate ligand flux in a heme nitric oxide/oxygen binding (H-NOX) domain. Winter MB, Herzik MA, Kuriyan J, Marletta MA. Proc Natl Acad Sci U S A 108 E881-9 (2011)
  2. Microbial diversity and adaptation to high hydrostatic pressure in deep-sea hydrothermal vents prokaryotes. Jebbar M, Franzetti B, Girard E, Oger P. Extremophiles 19 721-740 (2015)
  3. Structural Basis for Xenon Inhibition in a Cationic Pentameric Ligand-Gated Ion Channel. Sauguet L, Fourati Z, Prangé T, Delarue M, Colloc'h N. PLoS One 11 e0149795 (2016)
  4. Prothrombolytic action of normobaric oxygen given alone or in combination with recombinant tissue-plasminogen activator in a rat model of thromboembolic stroke. David HN, Haelewyn B, Degoulet M, Colomb DG, Risso JJ, Abraini JH. J Appl Physiol (1985) 112 2068-2076 (2012)
  5. Functional relevance of the internal hydrophobic cavity of urate oxidase. Colloc'h N, Prangé T. FEBS Lett 588 1715-1719 (2014)
  6. Interactions between nitrous oxide and tissue plasminogen activator in a rat model of thromboembolic stroke. Haelewyn B, David HN, Colloc'h N, Colomb DG, Risso JJ, Abraini JH. Anesthesiology 115 1044-1053 (2011)
  7. Crystallographic studies with xenon and nitrous oxide provide evidence for protein-dependent processes in the mechanisms of general anesthesia. Abraini JH, Marassio G, David HN, Vallone B, Prangé T, Colloc'h N. Anesthesiology 121 1018-1027 (2014)
  8. Paramagnetic Shifts and Guest Exchange Kinetics in ConFe4-n Metal-Organic Capsules. Du K, Zemerov SD, Carroll PJ, Dmochowski IJ. Inorg Chem 59 12758-12767 (2020)
  9. Mechanism of action of nitrogen pressure in controlling striatal dopamine level of freely moving rats is changed by recurrent exposures to nitrogen narcosis. Lavoute C, Weiss M, Risso JJ, Rostain JC. Neurochem Res 37 655-664 (2012)
  10. Xenon for tunnelling analysis of the efflux pump component OprN. Ntsogo Enguéné YV, Phan G, Garnier C, Ducruix A, Prangé T, Broutin I. PLoS One 12 e0184045 (2017)
  11. Xenon-Protein Interactions: Characterization by X-Ray Crystallography and Hyper-CEST NMR. Roose BW, Zemerov SD, Dmochowski IJ. Methods Enzymol 602 249-272 (2018)
  12. Modelling of noble anaesthetic gases and high hydrostatic pressure effects in lipid bilayers. Moskovitz Y, Yang H. Soft Matter 11 2125-2138 (2015)
  13. Argon blocks the expression of locomotor sensitization to amphetamine through antagonism at the vesicular monoamine transporter-2 and mu-opioid receptor in the nucleus accumbens. David HN, Dhilly M, Degoulet M, Poisnel G, Meckler C, Vallée N, Blatteau JÉ, Risso JJ, Lemaire M, Debruyne D, Abraini JH. Transl Psychiatry 5 e594 (2015)
  14. Mapping Hydrophobic Tunnels and Cavities in Neuroglobin with Noble Gas under Pressure. Colloc'h N, Carpentier P, Montemiglio LC, Vallone B, Prangé T. Biophys J 113 2199-2206 (2017)
  15. Revisiting the Effects of Xenon on Urate Oxidase and Tissue Plasminogen Activator: No Evidence for Inhibition by Noble Gases. Cahill J, Ruffing AM. Front Mol Biosci 7 574477 (2020)
  16. Selective pressure modulation of synaptic voltage-dependent calcium channels-involvement in HPNS mechanism. Aviner B, Gradwohl G, Bliznyuk A, Grossman Y. J Cell Mol Med 20 1872-1888 (2016)
  17. Xenon Blocks Neuronal Injury Associated with Decompression. Blatteau JE, David HN, Vallée N, Meckler C, Demaistre S, Lambrechts K, Risso JJ, Abraini JH. Sci Rep 5 15093 (2015)
  18. Water chreodes and the mechanisms of ligand diffusion, general anesthesia, and sleep. Kier LB. Biochem Res Int 2011 396560 (2011)


Quick links