Abstract

Hydrogen sulfide is a critical signaling molecule, but high concentrations cause cellular toxicity. A four-enzyme pathway in the mitochondrion detoxifies H2S by converting it to thiosulfate and sulfate. Recent studies have shown that globins like hemoglobin and myoglobin can also oxidize H2S to thiosulfate and hydropolysulfides. Neuroglobin, a globin enriched in the brain, was reported to bind H2S tightly and was postulated to play a role in modulating neuronal sensitivity to H2S in conditions such as stroke. However, the H2S reactivity of the coordinately saturated heme in neuroglobin is expected a priori to be substantially lower than that of the 5-coordinate hemes present in myoglobin and hemoglobin. To resolve this discrepancy, we explored the role of the distal histidine residue in muting the reactivity of human neuroglobin toward H2S. Ferric neuroglobin is slowly reduced by H2S and catalyzes its inefficient oxidative conversion to thiosulfate. Mutation of the distal His64 residue to alanine promotes rapid binding of H2S and its efficient conversion to oxidized products. X-ray absorption, EPR, and resonance Raman spectroscopy highlight the chemically different reaction options influenced by the distal histidine ligand. This study provides mechanistic insights into how the distal heme ligand in neuroglobin caps its reactivity toward H2S and identifies by cryo-mass spectrometry a range of sulfide oxidation products with 2-6 catenated sulfur atoms with or without oxygen insertion, which accumulate in the absence of the His64 ligand.

Highlights

  • Hydrogen sulfide is a critical signaling molecule, but high concentrations cause cellular toxicity

  • We explored the role of the distal histidine residue in muting the reactivity of human neuroglobin toward H2S

  • This study provides mechanistic insights into how the distal heme ligand in neuroglobin caps its reactivity toward H2S and identifies by cryo-mass spectrometry a range of sulfide oxidation products with 2– 6 catenated sulfur atoms with or without oxygen insertion, which accumulate in the absence of the His64 ligand

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Summary

The abbreviations used are

FeII-Ngb, ferrous neuroglobin; FeIII-Ngb, ferric neuroglobin; Cys-SSH, cysteine persulfide; ESI, electrospray ionization; MWCO, molecular weight cut-off; XAS, X-ray absorption spectroscopy; EXAFS, extended X-ray absorption fine structure; XANES, X-ray absorption near edge structure; CSE, cystathionine ␥-lyase. Very low levels of mRNA (and protein) encoding sulfide quinone oxidoreductase are found in brain [33] These observations raise questions about the mechanism by which H2S is oxidized in the brain and the possible involvement of hemeproteins such as neuroglobin in catalyzing H2S oxidation via a noncanonical pathway. Replacement of the distal histidine ligand by alanine greatly accelerates sulfide oxidation by neuroglobin and supports its oxidation to thiosulfate and to a wide range of catenated sulfur products

Results
Discussion
Experimental procedures

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