A distal ligand mutes the interaction of hydrogen sulfide with human neuroglobin

Ruetz, Markus; Kumutima, Jacques; Lewis, B. A.; Filipović, Miloš R.; Lehnert, Nicolai; Stemmler, Timothy L.; Banerjee, Ruma

doi:10.1074/jbc.m116.770370

Cited by 52 publications

(38 citation statements)

References 63 publications

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“…Although scavengers have many inherent problems (specificity, selectivity, delivery issues, and, unless they are catalytic, the fact they are consumed in the reactions and typically require large concentrations/ doses), in theory, this approach may also be of some merit for further exploration. However, the current state-of-the-art of H 2 S scavengers is in an embryonic stage; although heme-containing proteins (e.g., hemoglobin, myoglobin, neuroglobin) are known to scavenge H 2 S (Brunyanszki et al, 2015;Bostelaar et al, 2016;Ruetz et al, 2017;Vitvitsky et al, 2017), they also scavenge many other reactive species including nitric oxide.…”

Section: Alternative Means To Decrease Biologic H 2 S Levelsmentioning

confidence: 99%

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H₂S Levels: H₂S Donors and H₂S Biosynthesis Inhibitors

2017

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Over the last decade, hydrogen sulfide (HS) has emerged as an important endogenous gasotransmitter in mammalian cells and tissues. Similar to the previously characterized gasotransmitters nitric oxide and carbon monoxide, HS is produced by various enzymatic reactions and regulates a host of physiologic and pathophysiological processes in various cells and tissues. HS levels are decreased in a number of conditions (e.g., diabetes mellitus, ischemia, and aging) and are increased in other states (e.g., inflammation, critical illness, and cancer). Over the last decades, multiple approaches have been identified for the therapeutic exploitation of HS, either based on HS donation or inhibition of HS biosynthesis. HS donation can be achieved through the inhalation of HS gas and/or the parenteral or enteral administration of so-called fast-releasing HS donors (salts of HS such as NaHS and NaS) or slow-releasing HS donors (GYY4137 being the prototypical compound used in hundreds of studies in vitro and in vivo). Recent work also identifies various donors with regulated HS release profiles, including oxidant-triggered donors, pH-dependent donors, esterase-activated donors, and organelle-targeted (e.g., mitochondrial) compounds. There are also approaches where existing, clinically approved drugs of various classes (e.g., nonsteroidal anti-inflammatories) are coupled with HS-donating groups (the most advanced compound in clinical trials is ATB-346, an HS-donating derivative of the non-steroidal anti-inflammatory compound naproxen). For pharmacological inhibition of HS synthesis, there are now several small molecule compounds targeting each of the three HS-producing enzymes cystathionine--synthase (CBS), cystathionine--lyase, and 3-mercaptopyruvate sulfurtransferase. Although many of these compounds have their limitations (potency, selectivity), these molecules, especially in combination with genetic approaches, can be instrumental for the delineation of the biologic processes involving endogenous HS production. Moreover, some of these compounds (e.g., cell-permeable prodrugs of the CBS inhibitor aminooxyacetate, or benserazide, a potentially repurposable CBS inhibitor) may serve as starting points for future clinical translation. The present article overviews the currently known HS donors and HS biosynthesis inhibitors, delineates their mode of action, and offers examples for their biologic effects and potential therapeutic utility.

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Section: Alternative Means To Decrease Biologic H 2 S Levelsmentioning

confidence: 99%

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H₂S Levels: H₂S Donors and H₂S Biosynthesis Inhibitors

2017

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“…A). Previously reported EPR spectroscopic data demonstrates that human Ngb shows high‐spin ferric signals as well as low‐spin ones because of dissociation of distal histidine from the iron atom in the presence of disulfide bond between Cys46 and Cys55 . Unlike human Ngb, the EPR spectrum of WT Kgb did not show any sign of high‐spin signals, implying that the two axial ligands in Kgb are tightly bound to the iron atom.…”

Section: Discussionmentioning

confidence: 87%

“…However, while gaseous ligands are bound at the distal position through a heme sliding mechanism in Ngb and a distal histidine flipping mechanism in Cgb , it is unlikely that Kgb is responsible for binding gaseous ligands. Although dissociation of distal histidine from iron in Ngb is supported by the formation of a disulfide bond between Cys46 and Cys55 , such pair forming disulfide bond is absent in Kgb. Therefore, if Kgb reacts with oxygen species, it will likely undergo an outer‐sphere mechanism in which a heme–O 2 complex is not formed , while human Ngb reacts by forming a heme–O 2 complex to scavenge superoxide .…”

Section: Discussionmentioning

confidence: 99%

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Crystal structure of Kumaglobin: a hexacoordinated heme protein from an anhydrobiotic tardigrade, Ramazzottius varieornatus

2018

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Tardigrades, also known as water bears, can survive extreme conditions. For example, tardigrades have high tolerance to extreme desiccation because they can enter an anhydrobiotic state, in which they show no or nearly undetectable metabolic processes. Proteins from anhydrobiotic tardigrades with low homology to known proteins from other organisms are new potential targets for structural genomics. Here, we present spectroscopic and structural characterization of an unprecedented globin protein (Kumaglobin: Kgb) found in an anhydrobiotic tardigrade. Spectroscopy reveals that Kgb contains hexacoordinated low‐spin heme, which is not capable of binding to hydrogen sulfide (H2S) unlike other globin proteins, such as neuroglobin. Interestingly however, when distal histidine is replaced with alanine, H2S is capable of binding to heme, implying that the distal histidine of Kgb binds tightly to heme. The overall structure of Kgb at 1.5 Å resolution shows high resemblance to well‐characterized eukaryotic globin proteins, such as myoglobin and cytoglobin. However, the heme coordination geometry in Kgb is unique because the distal histidinyl ligand is located at the 11th position of helix E while it is found at 7th position on helix E in many known globin proteins. The unusual conformation of distal histidine in Kgb is stabilized by a hydrogen bond with the carbonyl O atom of A103. Furthermore, bulky residues exist around the heme cofactor, resulting in a ruffling conformation of the porphyrin ring. Based on our study, Kgb is thought to be involved in electron transfer or enzymatic reactions rather than transporting or storing ligands. Database Structural data are available in the Protein Data Bank under the accession numbers http://www.rcsb.org/pdb/search/structidSearch.do?structureId=5ZIQ (Kgb4‐SR) and http://www.rcsb.org/pdb/results/results.do?tabtoshow=Unreleased&qrid=D1773C9B (Kgb7‐house).

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“…Alternatively or additionally, increased H 2 S could stimulate its oxidation by heme proteins. We have shown that globins like hemoglobin, myoglobin and neuroglobin catalyze oxidation of H 2 S to thiosulfate (26)(27)(28)(29).…”

Section: Discussionmentioning

confidence: 99%

Mechanism-based inhibition of human persulfide dioxygenase by γ-glutamyl-homocysteinyl-glycine

Kabil

Motl

Strack

et al. 2018

Journal of Biological Chemistry

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Hydrogen sulfide (H 2 S) is a signaling molecule with many beneficial effects. However, its cellular concentration is strictly regulated to avoid toxicity. Persulfide dioxygenase (PDO or ETHE1) is a mononuclear non-heme ironcontaining protein in the sulfide oxidation pathway catalyzing the conversion of glutathione persulfide (GSSH) to sulfite and glutathione. PDO mutations result in the autosomal recessive disorder, ethylmalonic encephalopathy (EE). Here, we developed γ-glutamyl-homocysteinyl-glycine (GHcySH) in which the cysteinyl moiety in glutathione is substituted with homocysteine, as a mechanismbased PDO inhibitor. Human PDO used GHcySH as an alternate substrate and converted it to GHcy-SO 2 H, mimicking GS-SO 2 H, the putative oxygenated intermediate formed with the natural substrate. Since GHcy-SO 2 H contains a C-S bond rather than an S-S bond in GS-SO 2 H, it failed to undergo the final hydrolysis step in the catalytic cycle, leading to PDO inhibition. We also characterized the biochemical penalties incurred by the L55P, T136A, C161Y and R163W mutations reported in EE patients. The variants displayed lower iron content (1.4-to 11-fold) and lower thermal stability (1.2-to 1.7-fold) than wild-type PDO. They also exhibited varying degrees of catalytic impairment; the k cat /K m values for R163W, L55P and C161Y PDOs were 18-, 42-and 65-fold lower, respectively and the T136A variant was most affected with a 200-fold lower k cat /K m . Like wild-type enzyme, these variants were inhibited by GHcySH. This study provides the first characterization of an intermediate in the PDO-catalyzed reaction and reports on deficits associated with EE-linked mutations that are distal from the active site.Ethylmalonic encephalopathy (EE) 1 is an autosomal recessive disorder that is associated with pathological effects in the brain, gastrointestinal tract and peripheral vessels (1-3). It results in acrocyanosis, petechiae, hemorrhagic diarrhea, developmental delay and progressive neurological failure leading to necrotic lesions in the deep gray matter of the brain. Patients with EE usually succumb to the disease within the first decade of life (4). The clinical profile of EE includes elevated ethylmalonic acid in urine, C4 and C5 acrylcarnitines in blood and a deficiency of cytochrome c oxidase in brain and muscle (5). EE is caused by mutations in the ethe1 gene that encodes persulfide dioxygenase (PDO or ETHE1). Over 20 mutations have been described in the ethe1 gene, of which a subset represents missense mutations (3,4,6).PDO is a mitochondrial matrix protein that participates in the mitochondrial sulfide oxidation pathway, which converts H 2 S to the end products, thiosulfate and sulfate (7,8). In addition to PDO, the other enzymes involved in the mitochondrial sulfur oxidation pathway are sulfide quinone oxidoreductase (9), rhodanese (10), and sulfite oxidase (11). PDO catalyzes the second step in the pathway, i.e. the oxidation of glutathione persulfide (GSSH) to sulfite (Eq. 1) (12). Sulfite is either oxidized b...

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A distal ligand mutes the interaction of hydrogen sulfide with human neuroglobin

Cited by 52 publications

References 63 publications

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H₂S Levels: H₂S Donors and H₂S Biosynthesis Inhibitors

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H₂S Levels: H₂S Donors and H₂S Biosynthesis Inhibitors

Crystal structure of Kumaglobin: a hexacoordinated heme protein from an anhydrobiotic tardigrade, Ramazzottius varieornatus

Mechanism-based inhibition of human persulfide dioxygenase by γ-glutamyl-homocysteinyl-glycine

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A distal ligand mutes the interaction of hydrogen sulfide with human neuroglobin

Cited by 52 publications

References 63 publications

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H2S Levels: H2S Donors and H2S Biosynthesis Inhibitors

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H2S Levels: H2S Donors and H2S Biosynthesis Inhibitors

Crystal structure of Kumaglobin: a hexacoordinated heme protein from an anhydrobiotic tardigrade, Ramazzottius varieornatus

Mechanism-based inhibition of human persulfide dioxygenase by γ-glutamyl-homocysteinyl-glycine

Contact Info

Product

Resources

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International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H₂S Levels: H₂S Donors and H₂S Biosynthesis Inhibitors

International Union of Basic and Clinical Pharmacology. CII: Pharmacological Modulation of H₂S Levels: H₂S Donors and H₂S Biosynthesis Inhibitors