Your search keyword '"Stephen W. Ragsdale"' showing total 238 results

1. Oxygen and Conformation Dependent Protein Oxidation and Aggregation by Porphyrins in Hepatocytes and Light-Exposed CellsSummary

Author

Dhiman Maitra, Eric L. Carter, Rani Richardson, Laure Rittié, Venkatesha Basrur, Haoming Zhang, Alexey I. Nesvizhskii, Yoichi Osawa, Matthew W. Wolf, Stephen W. Ragsdale, Nicolai Lehnert, Harald Herrmann, and M. Bishr Omary

Subjects

Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Background & Aims: Porphyrias are caused by porphyrin accumulation resulting from defects in the heme biosynthetic pathway that typically lead to photosensitivity and possible end-stage liver disease with an increased risk of hepatocellular carcinoma. Our aims were to study the mechanism of porphyrin-induced cell damage and protein aggregation, including liver injury, where light exposure is absent. Methods: Porphyria was induced in vivo in mice using 3,5-diethoxycarbonyl-1,4-dihydrocollidine or in vitro by exposing human liver Huh7 cells and keratinocytes, or their lysates, to protoporphyrin-IX, other porphyrins, or to δ-aminolevulinic acid plus deferoxamine. The livers, cultured cells, or porphyrin exposed purified proteins were analyzed for protein aggregation and oxidation using immunoblotting, mass spectrometry, and electron paramagnetic resonance spectroscopy. Consequences on cell-cycle progression were assessed. Results: Porphyrin-mediated protein aggregation required porphyrin-photosensitized singlet oxygen and porphyrin carboxylate side-chain deprotonation, and occurred with site-selective native protein methionine oxidation. Noncovalent interaction of protoporphyrin-IX with oxidized proteins led to protein aggregation that was reversed by incubation with acidified n-butanol or high-salt buffer. Phototoxicity and the ensuing proteotoxicity, mimicking porphyria photosensitivity conditions, were validated in cultured keratinocytes. Protoporphyrin-IX inhibited proteasome function by aggregating several proteasomal subunits, and caused cell growth arrest and aggregation of key cell proliferation proteins. Light-independent synergy of protein aggregation was observed when porphyrin was applied together with glucose oxidase as a secondary peroxide source. Conclusions: Photo-excitable porphyrins with deprotonated carboxylates mediate protein aggregation. Porphyrin-mediated proteotoxicity in the absence of light, as in the liver, requires porphyrin accumulation coupled with a second tissue oxidative injury. These findings provide a potential mechanism for internal organ damage and photosensitivity in porphyrias. Keywords: Porphyria, Oxidative Stress, Amino Acid Oxidation, Phototoxicity

Published

2019

2. Heme delivery to heme oxygenase-2 involves glyceraldehyde-3-phosphate dehydrogenase

Author

Yue Dai, Angela S. Fleischhacker, Liu Liu, Sara Fayad, Amanda L. Gunawan, Dennis J. Stuehr, and Stephen W. Ragsdale

Subjects

HEK293 Cells, Heme Oxygenase (Decyclizing), Clinical Biochemistry, Humans, Glyceraldehyde-3-Phosphate Dehydrogenases, Heme, Molecular Biology, Biochemistry, Article

Abstract

Heme regulatory motifs (HRMs) are found in a variety of proteins with diverse biological functions. In heme oxygenase-2 (HO2), heme binds to the HRMs and is readily transferred to the catalytic site in the core of the protein. To further define this heme transfer mechanism, we evaluated the ability of GAPDH, a known heme chaperone, to transfer heme to the HRMs and/or the catalytic core of HO2. Our results indicate GAPDH and HO2 form a complex in vitro. We have followed heme insertion at both sites by fluorescence quenching in HEK293 cells with HO2 reporter constructs. Upon mutation of residues essential for heme binding at each site in our reporter construct, we found that HO2 binds heme at the core and the HRMs in live cells and that heme delivery to HO2 is dependent on the presence of GAPDH that is competent for heme binding. In sum, GAPDH is involved in heme delivery to HO2 but, surprisingly, not to a specific site on HO2. Our results thus emphasize the importance of heme binding to both the core and the HRMs and the interplay of HO2 with the heme pool via GAPDH to maintain cellular heme homeostasis.

Published

2022

3. Regulation of protein function and degradation by heme, heme responsive motifs, and CO

Author

Liu Liu, Anindita Sarkar, Angela S. Fleischhacker, and Stephen W. Ragsdale

Subjects

Cell signaling, Hemeprotein, biology, Heme binding, Receptors, Cytoplasmic and Nuclear, Heme, Biochemistry, Cofactor, Article, Heme oxygenase, Repressor Proteins, chemistry.chemical_compound, Protein structure, chemistry, Nuclear receptor, biology.protein, Humans, Molecular Biology, Oxidation-Reduction, Protein Binding

Abstract

Heme is an essential biomolecule and cofactor involved in a myriad of biological processes. In this review, we focus on how heme binding to heme regulatory motifs (HRMs), catalytic sites, and gas signaling molecules as well as how changes in the heme redox state regulate protein structure, function, and degradation. We also relate these heme-dependent changes to the affected metabolic processes. We center our discussion on two HRM-containing proteins: human heme oxygenase-2, a protein that binds and degrades heme (releasing Fe(2+) and CO) in its catalytic core and binds Fe(3+)-heme at HRMs located within an unstructured region of the enzyme, and the transcriptional regulator Rev-erbβ, a protein that binds Fe(3+)-heme at an HRM and is involved in CO sensing. We will discuss these and other proteins as they relate to cellular heme composition, homeostasis, and trafficking. In addition, we will discuss the HRM-containing family of proteins and how the stability and activity of these proteins are regulated in a dependent manner through the HRMs. Then, after reviewing CO-mediated protein regulation of heme proteins, we turn our attention to the involvement of heme, HRMs, and CO in circadian rhythms. In sum, we stress the importance of understanding the various roles of heme and the distribution of the different heme pools as they relate to the heme redox state, CO, and heme binding affinities.

Published

2023

4. Efficient, Light-Driven Reduction of CO(2) to CO by a Carbon Monoxide Dehydrogenase–CdSe/CdS Nanorod Photosystem

Author

David W. White, Daniel Esckilsen, Seung Kyu Lee, Stephen W. Ragsdale, and R. Brian Dyer

Subjects

Carbon Monoxide, Nanotubes, Multienzyme Complexes, Cadmium Compounds, General Materials Science, Physical and Theoretical Chemistry, Carbon Dioxide, Selenium Compounds, Aldehyde Oxidoreductases, Article

Abstract

The solar conversion of CO(2) to low carbon fuels has been heralded as a potential solution to combat the rise in greenhouse gas emissions. Here we report the first light-driven activation of [NiFe] CODH II from Carboxydothermus hydrogenoformans for the reduction of CO(2) to CO. To accomplish this, a hybrid photosystem composed of CODH II and CdSe/CdS dot-in-rod nanocrystals was developed. By incorporating a low-potential redox mediator to assist electron transfer, quantum yields up to 19% and turnover frequencies of 9 s(−1) were achieved. These results represent a new standard in efficient CO(2) reduction by an enzyme-based photocatalytic systems. Furthermore, successful photoactivation of CODH II allows for future exploration into the enzyme’s not fully understood mechanism.

Published

2022

5. XFEL serial crystallography reveals the room temperature structure of methyl-coenzyme M reductase

Author

Christopher J. Ohmer, Medhanjali Dasgupta, Anjali Patwardhan, Isabel Bogacz, Corey Kaminsky, Margaret D. Doyle, Percival Yang-Ting Chen, Stephen M. Keable, Hiroki Makita, Philipp S. Simon, Ramzi Massad, Thomas Fransson, Ruchira Chatterjee, Asmit Bhowmick, Daniel W. Paley, Nigel W. Moriarty, Aaron S. Brewster, Leland B. Gee, Roberto Alonso-Mori, Frank Moss, Franklin D. Fuller, Alexander Batyuk, Nicholas K. Sauter, Uwe Bergmann, Catherine L. Drennan, Vittal K. Yachandra, Junko Yano, Jan F. Kern, and Stephen W. Ragsdale

Subjects

Crystallography, X-ray Free-Electron Laser, Methanogens, Lasers, X-ray Diffraction, Temperature, Crystallography, X-Ray, Biochemistry, Article, X-ray Emission Spectroscopy, Inorganic Chemistry, Nickel, Theoretical and Computational Chemistry, X-Ray, Serial femtosecond crystallography, Inorganic & Nuclear Chemistry, Oxidoreductases, Other Chemical Sciences, Methane, Oxidation-Reduction

Abstract

Methyl-Coenzyme M Reductase (MCR) catalyzes the biosynthesis of methane in methanogenic archaea, using a catalytic Ni-centered Cofactor F430 in its active site. It also catalyzes the reverse reaction, that is, the anaerobic activation and oxidation, including the cleavage of the C–H bond in methane. Because methanogenesis is the major source of methane on earth, understanding the reaction mechanism of this enzyme can have massive implications in global energy balances. While recent publications have proposed a radical-based catalytic mechanism as well as novel sulfonate-based binding modes of MCR for its native substrates, the structure of the active state of MCR, as well as a complete characterization of the reaction, remain elusive. Previous attempts to structurally characterize the active MCR-Ni(I) state have been unsuccessful due to oxidation of the redox- sensitive catalytic Ni center. Further, while many cryo structures of the inactive Ni(II)-enzyme in various substrates-bound forms have been published, no room temperature structures have been reported, and the structure and mechanism of MCR under physiologically relevant conditions is not known. In this study, we report the first room temperature structure of the MCRred1-silent Ni(II) form using an X-ray Free-Electron Laser (XFEL), with simultaneous X-ray Emission Spectroscopy (XES) and X-ray Diffraction (XRD) data collection. In celebration of the seminal contributions of inorganic chemist Dick Holm to our understanding of nickel-based catalysis, we are honored to announce our findings in this special issue dedicated to this remarkable pioneer of bioinorganic chemistry.

Published

2022

6. Heme oxygenase-2 is post-translationally regulated by heme occupancy in the catalytic site

Author

Liu Liu, Arti B. Dumbrepatil, Angela S. Fleischhacker, Stephen W. Ragsdale, and E. Neil G. Marsh

Subjects

0301 basic medicine, Proteasome Endopeptidase Complex, Heme binding, Heme, Protein degradation, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Chaperone-mediated autophagy, Catalytic Domain, Lysosome, Enzyme Stability, medicine, Humans, Molecular Biology, Biliverdin, 030102 biochemistry & molecular biology, Cell Biology, Cell biology, Heme oxygenase, HEK293 Cells, 030104 developmental biology, medicine.anatomical_structure, Proteasome, chemistry, Protein Synthesis and Degradation, Heme Oxygenase (Decyclizing), Proteolysis, Heme Oxygenase-1

Abstract

Heme oxygenase-2 (HO2) and -1 (HO1) catalyze heme degradation to biliverdin, CO, and iron, forming an essential link in the heme metabolism network. Tight regulation of the cellular levels and catalytic activities of HO1 and HO2 is important for maintaining heme homeostasis. HO1 expression is transcriptionally regulated; however, HO2 expression is constitutive. How the cellular levels and activity of HO2 are regulated remains unclear. Here, we elucidate the mechanism of post-translational regulation of cellular HO2 levels by heme. We find that, under heme-deficient conditions, HO2 is destabilized and targeted for degradation, suggesting that heme plays a direct role in HO2 regulation. HO2 has three heme binding sites: one at its catalytic site and the others at its two heme regulatory motifs (HRMs). We report that, in contrast to other HRM-containing proteins, the cellular protein level and degradation rate of HO2 are independent of heme binding to the HRMs. Rather, under heme deficiency, loss of heme binding to the catalytic site destabilizes HO2. Consistently, an HO2 catalytic site variant that is unable to bind heme exhibits a constant low protein level and an enhanced protein degradation rate compared with the WT HO2. Finally, HO2 is degraded by the lysosome through chaperone-mediated autophagy, distinct from other HRM-containing proteins and HO1, which are degraded by the proteasome. These results reveal a novel aspect of HO2 regulation and deepen our understanding of HO2's role in maintaining heme homeostasis, paving the way for future investigation into HO2's pathophysiological role in heme deficiency response.

Published

2020

7. 13C Electron Nuclear Double Resonance Spectroscopy Shows Acetyl-CoA Synthase Binds Two Substrate CO in Multiple Binding Modes and Reveals the Importance of a CO-Binding 'Alcove'

Author

Seth Wiley, Stephen W. Ragsdale, Brian M. Hoffman, and C. D. James

Subjects

Stereochemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Spectral line, Article, Catalysis, law.invention, chemistry.chemical_compound, Colloid and Surface Chemistry, law, Electron paramagnetic resonance, Conformational isomerism, Alanine, Electron nuclear double resonance, ATP synthase, biology, Chemistry, Carbon fixation, Acetyl-CoA, Substrate (chemistry), General Chemistry, 0104 chemical sciences, Crystallography, Electron nuclear double resonance spectroscopy, biology.protein, NIP, CO binding

Abstract

EPR and Electron Nuclear Double Resonance spectroscopies here characterize CO binding to the active-site A cluster of wild-type (WT) Acetyl-CoA Synthase (ACS) and two variants, F229W and F229A. The A-cluster binds CO to a proximal Ni (Nip) that bridges a [4Fe-4S] cluster and distal Nid. An alcove seen in the ACS crystal-structure near the A-cluster, defined by hydrophobic residues including F229, forms a cage surrounding a Xe mimic of CO and is suggested to ‘cradle’ this CO. Previously, we only knew WT ACS bound a single CO in the Ared-CO intermediate, here seen as forming Nip(I)-CO with CO on-axis of the dz2odd-electron orbital (g⊥>g‖∼2). The two-dimensional field-frequency pattern of 2K-35 GHz13C-ENDOR spectra collected across the Ared-CO EPR envelope now reveals a second CO bound in the dz2orbital’s equatorial plane. This WT A-cluster conformer dominates the nearly-conservative F229W variant, but13C-ENDOR reveals a minority “A” conformation with (g‖>g⊥∼2) characteristic of a ‘cloverleaf’ (eg. dx2-y2) odd-electron orbital, and with Nipbinding two, apparently ‘in-plane’ CO. Disruption of the alcove through introduction of the smaller alanine residue in the F229A variant diminishes conversion to Ni(I) ∼tenfold and introduces extensive cluster flexibility.13C-ENDOR shows the F229A cluster is mostly (60%) in the “A” conformation, but with ∼20% each of the WT conformer and an “O” state in which dz2Nip(I) (g⊥>g‖∼2) surprisingly lacks CO. This paper thus demonstrates the importance of an intact alcove in forming and stabilizing the Ni(I)-CO intermediate in the Wood-Ljungdahl pathway of anaerobic CO and CO2fixation.

Published

2020

8. Structure determination of the HgcAB complex using metagenome sequence data: insights into microbial mercury methylation

Author

Kaiyuan Zheng, Katherine W. Rush, Alexander Johs, Georgios A. Pavlopoulos, Nikos C. Kyrpides, Brian C. Sanders, Mircea Podar, Sergey Ovchinnikov, Jerry M. Parks, Connor J. Cooper, and Stephen W. Ragsdale

Subjects

Models, Molecular, Methyltransferase, Protein Conformation, Medicine (miscellaneous), medicine.disease_cause, Methylation, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Corrinoid, Bacterial Proteins, Protein Domains, Models, Metalloproteins, medicine, Desulfovibrio desulfuricans, Escherichia coli, lcsh:QH301-705.5, Ferredoxin, Phylogeny, 030304 developmental biology, Ultraviolet, 0303 health sciences, biology, Environmental microbiology, Molecular, Mercury, biology.organism_classification, Transmembrane domain, chemistry, Biochemistry, lcsh:Biology (General), Spectrophotometry, Multiprotein Complexes, Protein structure predictions, Corrinoids, Metagenome, Spectrophotometry, Ultraviolet, General Agricultural and Biological Sciences, 030217 neurology & neurosurgery, Binding domain, Archaea

Abstract

Bacteria and archaea possessing the hgcAB gene pair methylate inorganic mercury (Hg) to form highly toxic methylmercury. HgcA consists of a corrinoid binding domain and a transmembrane domain, and HgcB is a dicluster ferredoxin. However, their detailed structure and function have not been thoroughly characterized. We modeled the HgcAB complex by combining metagenome sequence data mining, coevolution analysis, and Rosetta structure calculations. In addition, we overexpressed HgcA and HgcB in Escherichia coli, confirmed spectroscopically that they bind cobalamin and [4Fe-4S] clusters, respectively, and incorporated these cofactors into the structural model. Surprisingly, the two domains of HgcA do not interact with each other, but HgcB forms extensive contacts with both domains. The model suggests that conserved cysteines in HgcB are involved in shuttling HgII, methylmercury, or both. These findings refine our understanding of the mechanism of Hg methylation and expand the known repertoire of corrinoid methyltransferases in nature., Connor J. Cooper et al. expressed HgcA and HgcB in Escherichia coli and modeled the structure of the HgcAB complex by combining metagenome sequence data, coevolution analysis, and ab initio structure calculations. This study provides insights into the biochemical mechanism of mercury (Hg) methylation.

Published

2020

9. Heme oxygenase-2 (HO-2) binds and buffers labile heme, which is largely oxidized, in human embryonic kidney cells

Author

Angela S. Fleischhacker, Amit R. Reddi, Stephen W. Ragsdale, Courtney M. Moore, Iqbal Hamza, David A. Hanna, Liu Liu, and Xiaojing Yuan

Subjects

Heme oxygenase, chemistry.chemical_compound, Oxygenase, Biliverdin, chemistry, Biochemistry, Bilirubin, Mutant, HEK 293 cells, Heme, Carbon monoxide

Abstract

Heme oxygenases (HO) detoxify heme by oxidatively degrading it into carbon monoxide, iron, and biliverdin, which is reduced to bilirubin and excreted. Humans express two isoforms: inducible HO-1, which is up-regulated in response to various stressors, including excess heme, and constitutive HO-2. While much is known about the regulation and physiological function of HO-1, comparatively little is known about the role of HO-2 in regulating heme homeostasis. The biochemical necessity for expressing constitutive HO-2 is largely dependent on whether heme is sufficiently abundant and accessible as a substrate under conditions in which HO-1 is not induced. By measuring labile heme, total heme, and bilirubin in human embryonic kidney HEK293 cells with silenced or over-expressed HO-2, and various HO-2 mutant alleles, we found that endogenous heme is too limiting to support HO-2 catalyzed heme degradation. Rather, we discovered that a novel role for HO-2 is to bind and buffer labile heme. Taken together, in the absence of excess heme, we propose that HO-2 regulates heme homeostasis by acting as a heme buffering factor in control of heme bioavailability. When heme is in excess, HO-1 is induced and both HO-2 and HO-1 can provide protection from heme toxicity by enzymatically degrading it. Our results explain why catalytically inactive mutants of HO-2 are cytoprotective against oxidative stress. Moreover, the change in bioavailable heme due to HO-2 overexpression, which selectively binds ferric over ferrous heme, is consistent with the labile heme pool being oxidized, thereby providing new insights into heme trafficking and signaling.

Published

2021

10. Dynamic and structural differences between heme oxygenase-1 and -2 are due to differences in their C-terminal regions

Author

Thomas E. Wales, John R. Engen, Donald F. Becker, Angela S. Fleischhacker, Stephen W. Ragsdale, and Brent A. Kochert

Subjects

0301 basic medicine, Gene isoform, Conformational change, Heme binding, Amino Acid Motifs, Heme, Molecular Dynamics Simulation, Biochemistry, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, Protein Domains, Humans, Molecular Biology, 030102 biochemistry & molecular biology, biology, Protein dynamics, Deuterium Exchange Measurement, Cell Biology, Heme oxygenase, 030104 developmental biology, Membrane protein, chemistry, Protein Structure and Folding, Heme Oxygenase (Decyclizing), Biophysics, biology.protein, Protein Multimerization, Heme Oxygenase-1

Abstract

Heme oxygenase (HO) catalyzes heme degradation, a process crucial for regulating cellular levels of this vital, but cytotoxic, cofactor. Two HO isoforms, HO1 and HO2, exhibit similar catalytic mechanisms and efficiencies. They also share catalytic core structures, including the heme-binding site. Outside their catalytic cores are two regions unique to HO2: a 20-amino acid-long N-terminal extension and a C-terminal domain containing two heme regulatory motifs (HRMs) that bind heme independently of the core. Both HO isoforms contain a C-terminal hydrophobic membrane anchor; however, their sequences diverge. Here, using hydrogen-deuterium exchange MS, size-exclusion chromatography, and sedimentation velocity, we investigated how these divergent regions impact the dynamics and structure of the apo and heme-bound forms of HO1 and HO2. Our results reveal that heme binding to the catalytic cores of HO1 and HO2 causes similar dynamic and structural changes in regions (proximal, distal, and A6 helices) within and linked to the heme pocket. We observed that full-length HO2 is more dynamic than truncated forms lacking the membrane-anchoring region, despite sharing the same steady-state activity and heme-binding properties. In contrast, the membrane anchor of HO1 did not influence its dynamics. Furthermore, although residues within the HRM domain facilitated HO2 dimerization, neither the HRM region nor the N-terminal extension appeared to affect HO2 dynamics. In summary, our results highlight significant dynamic and structural differences between HO2 and HO1 and indicate that their dissimilar C-terminal regions play a major role in controlling the structural dynamics of these two proteins.

Published

2019

11. Oxygen and Conformation Dependent Protein Oxidation and Aggregation by Porphyrins in Hepatocytes and Light-Exposed CellsSummary

Author

Nicolai Lehnert, Dhiman Maitra, Stephen W. Ragsdale, Laure Rittié, M. Bishr Omary, Alexey I. Nesvizhskii, Haoming Zhang, Matthew W. Wolf, Harald Herrmann, Venkatesha Basrur, Rani Richardson, Yoichi Osawa, and Eric L. Carter

Subjects

0301 basic medicine, Male, Protein Conformation, Protoporphyrins, BCA, Bicinchoninic acid, Protein aggregation, Protein oxidation, chemistry.chemical_compound, Mice, 0302 clinical medicine, Met, methionine, RPN1, 26S proteasome regulatory subunit RPN1, polycyclic compounds, Heme, Original Research, DFO, deferoxamine, DMA, dimethylacetamide, IF, intermediate filament, Photosensitizing Agents, Chemistry, Liver Neoplasms, Gastroenterology, K, keratin, DDC, 3,5-diethoxycarbonyl-1,4-dihydrocollidine, EPR, electron paramagnetic resonance spectroscopy, Liver, ALA, δ-aminolevulinic acid, Zn-PP, zinc protoporphyrin-IX, 030211 gastroenterology & hepatology, Phototoxicity, 1O2, singlet oxygen, Copro, coproporphyrin, PP-IX, protoporphyrin-IX, SDS, sodium dodecyl sulfate, Carcinoma, Hepatocellular, Porphyrins, O2-, superoxide, PP-Dim, protoporphyrin-IX dimethyl ester, PBS, phosphate-buffered saline, HMW, high molecular weight, Deferoxamine, Uro, uroporphyrin, Cell Line, ER, endoplasmic reticulum, 03 medical and health sciences, Porphyrias, Protein Aggregates, GOX, glucose oxidase, ROS, reactive oxygen species, medicine, Animals, Humans, Photosensitivity Disorders, NP-40, Nonidet P-40, lcsh:RC799-869, Cell damage, PAGE, polyacrylamide gel electrophoresis, Hepatology, Porphyria, TMPD, N, N, N′, N′-tetramethyl-p-phenylenediamine, Aminolevulinic Acid, medicine.disease, Porphyrin, POBN, α-(4-pyridyl-1-oxide)-N-tert-butylnitrone, Mice, Inbred C57BL, Oxygen, Oxidative Stress, 030104 developmental biology, Proteotoxicity, MS, mass spectrometry, Biophysics, Hepatocytes, lcsh:Diseases of the digestive system. Gastroenterology, Amino Acid Oxidation

Abstract

Background & Aims Porphyrias are caused by porphyrin accumulation resulting from defects in the heme biosynthetic pathway that typically lead to photosensitivity and possible end-stage liver disease with an increased risk of hepatocellular carcinoma. Our aims were to study the mechanism of porphyrin-induced cell damage and protein aggregation, including liver injury, where light exposure is absent. Methods Porphyria was induced in vivo in mice using 3,5-diethoxycarbonyl-1,4-dihydrocollidine or in vitro by exposing human liver Huh7 cells and keratinocytes, or their lysates, to protoporphyrin-IX, other porphyrins, or to δ-aminolevulinic acid plus deferoxamine. The livers, cultured cells, or porphyrin exposed purified proteins were analyzed for protein aggregation and oxidation using immunoblotting, mass spectrometry, and electron paramagnetic resonance spectroscopy. Consequences on cell-cycle progression were assessed. Results Porphyrin-mediated protein aggregation required porphyrin-photosensitized singlet oxygen and porphyrin carboxylate side-chain deprotonation, and occurred with site-selective native protein methionine oxidation. Noncovalent interaction of protoporphyrin-IX with oxidized proteins led to protein aggregation that was reversed by incubation with acidified n-butanol or high-salt buffer. Phototoxicity and the ensuing proteotoxicity, mimicking porphyria photosensitivity conditions, were validated in cultured keratinocytes. Protoporphyrin-IX inhibited proteasome function by aggregating several proteasomal subunits, and caused cell growth arrest and aggregation of key cell proliferation proteins. Light-independent synergy of protein aggregation was observed when porphyrin was applied together with glucose oxidase as a secondary peroxide source. Conclusions Photo-excitable porphyrins with deprotonated carboxylates mediate protein aggregation. Porphyrin-mediated proteotoxicity in the absence of light, as in the liver, requires porphyrin accumulation coupled with a second tissue oxidative injury. These findings provide a potential mechanism for internal organ damage and photosensitivity in porphyrias., Graphical abstract

Published

2019

12. Nickel-Sulfonate Mode of Substrate Binding for Forward and Reverse Reactions of Methyl-SCoM Reductase Suggest a Radical Mechanism Involving Long Range Electron Transfer

Author

Simone Raugei, Bojana Ginovska, Stephen W. Ragsdale, Anjali Patwardhan, and Ritimukta Sarangi

Subjects

Electron transfer, Cofactor F430, chemistry.chemical_compound, Crystallography, chemistry, Coenzyme B, Anaerobic oxidation of methane, Hexacoordinate, Methyl radical, Hydrogen atom abstraction, Homolysis

Abstract

Methyl-coenzyme M reductase (MCR) catalyzes both synthesis and anaerobic oxidation of methane (AOM). Its catalytic site contains Ni at the core of Cofactor F430. The Ni ion, in its low-valent Ni(I) state lights the fuse leading to homolysis of the C-S bond of methyl-coenzyme M (methyl-SCoM) to generate a methyl radical, which abstracts a hydrogen atom from Coenzyme B (HSCoB) to generate methane and the mixed disulfide CoMSSCoB. Direct reversal of this reaction activates methane to initiate anaerobic methane oxidation. Based on crystal structures, which reveal a Ni-thiol interaction between Ni(II)-MCR and inhibitor CoMSH, a Ni(I)-thioether complex with substrate methyl-SCoM has been transposed to canonical MCR mechanisms. Similarly, a Ni(I)-disulfide with CoMSSCoB is proposed for the reverse reaction. However, this Ni(I)-sulfur interaction poses a conundrum for the proposed hydrogen atom abstraction reaction because the >6 Å distance between the thiol group of SCoB and the thiol of SCoM observed in the structures appears too long for such a reaction. Spectroscopic, kinetic, structural and computational studies described here establish that both methyl-SCoM and CoMSSCoB bind to the active Ni(I) state of MCR through their sulfonate groups, forming a hexacoordinate Ni(I)-N/O complex, not Ni(I)-S. These studies rule out direct Ni(I)-sulfur interactions in both substrate-bound states. As a solution to the mechanistic conundrum, we propose that both forward and reverse MCR reactions emanate through long-range electron transfer from Ni(I)-sulfonate complexes with methyl-SCoM or CoMSSCoB, respectively.

Published

2021

13. Ferric heme as a CO/NO sensor in the nuclear receptor Rev-Erbß by coupling gas binding to electron transfer

Author

Jill B. Harland, Anindita Sarkar, Stephen W. Ragsdale, Eric L. Carter, Nicolai Lehnert, and Amy L. Speelman

Subjects

inorganic chemicals, 0301 basic medicine, Models, Molecular, Protein Conformation, alpha-Helical, Heme binding, Iron, Recombinant Fusion Proteins, Repressor, Gene Expression, Receptors, Cytoplasmic and Nuclear, Electrons, Heme, Nitric Oxide, Redox, Models, Biological, law.invention, Electron Transport, 03 medical and health sciences, Electron transfer, chemistry.chemical_compound, law, Escherichia coli, Humans, Protein Interaction Domains and Motifs, Electron paramagnetic resonance, Nuclear receptor co-repressor 1, Carbon Monoxide, Multidisciplinary, Binding Sites, 030102 biochemistry & molecular biology, Chemistry, Electron Spin Resonance Spectroscopy, Biological Transport, Circadian Rhythm, Repressor Proteins, 030104 developmental biology, Nuclear receptor, Physical Sciences, Biophysics, Protein Conformation, beta-Strand, Oxidation-Reduction, Protein Binding

Abstract

Rev-Erbβ is a nuclear receptor that couples circadian rhythm, metabolism, and inflammation. Heme binding to the protein modulates its function as a repressor, its stability, its ability to bind other proteins, and its activity in gas sensing. Rev-Erbβ binds Fe(3+)-heme more tightly than Fe(2+)-heme, suggesting its activities may be regulated by the heme redox state. Yet, this critical role of heme redox chemistry in defining the protein’s resting state and function is unknown. We demonstrate by electrochemical and whole-cell electron paramagnetic resonance experiments that Rev-Erbβ exists in the Fe(3+) form within the cell allowing the protein to be heme replete even at low concentrations of labile heme in the nucleus. However, being in the Fe(3+) redox state contradicts Rev-Erb’s known function as a gas sensor, which dogma asserts must be Fe(2+). This paper explains why the resting Fe(3+) state is congruent both with heme binding and cellular gas sensing. We show that the binding of CO/NO elicits a striking increase in the redox potential of the Fe(3+)/Fe(2+) couple, characteristic of an EC mechanism in which the unfavorable Electrochemical reduction of heme is coupled to the highly favorable Chemical reaction of gas binding, making the reduction spontaneous. Thus, Fe(3+)-Rev-Erbβ remains heme-loaded, crucial for its repressor activity, and undergoes reduction when diatomic gases are present. This work has broad implications for proteins in which ligand-triggered redox changes cause conformational changes influencing its function or interprotein interactions (e.g., between NCoR1 and Rev-Erbβ). This study opens up the possibility of CO/NO-mediated regulation of the circadian rhythm through redox changes in Rev-Erbβ.

Published

2021

14. Biological Carbon Fixation by an Organometallic Pathway: Evidence Supporting the Paramagnetic Mechanism of the Nickel-Iron-Sulfur Acetyl-CoA Synthase

Author

Stephen W. Ragsdale

Subjects

chemistry.chemical_compound, Paramagnetism, Nickel, ATP synthase, biology, Stereochemistry, Chemistry, Acetyl-CoA, Carbon fixation, biology.protein, chemistry.chemical_element, Sulfur, Mechanism (sociology)

Published

2021

15. Heme oxygenase-2 (HO-2) binds and buffers labile ferric heme in human embryonic kidney cells

Author

David A. Hanna, Courtney M. Moore, Liu Liu, Xiaojing Yuan, Iramofu M. Dominic, Angela S. Fleischhacker, Iqbal Hamza, Stephen W. Ragsdale, and Amit R. Reddi

Subjects

HEK293 Cells, Iron, Biliverdine, Heme Oxygenase (Decyclizing), Humans, Heme, Cell Biology, Kidney, Molecular Biology, Biochemistry, Heme Oxygenase-1

Abstract

Heme oxygenases (HOs) detoxify heme by oxidatively degrading it into carbon monoxide, iron, and biliverdin, which is reduced to bilirubin and excreted. Humans express two isoforms of HO: the inducible HO-1, which is upregulated in response to excess heme and other stressors, and the constitutive HO-2. Much is known about the regulation and physiological function of HO-1, whereas comparatively little is known about the role of HO-2 in regulating heme homeostasis. The biochemical necessity for expressing constitutive HO-2 is dependent on whether heme is sufficiently abundant and accessible as a substrate under conditions in which HO-1 is not induced. By measuring labile heme, total heme, and bilirubin in human embryonic kidney HEK293 cells with silenced or overexpressed HO-2, as well as various HO-2 mutant alleles, we found that endogenous heme is too limiting a substrate to observe HO-2-dependent heme degradation. Rather, we discovered a novel role for HO-2 in the binding and buffering of heme. Taken together, in the absence of excess heme, we propose that HO-2 regulates heme homeostasis by acting as a heme buffering factor that controls heme bioavailability. When heme is in excess, HO-1 is induced, and both HO-2 and HO-1 can provide protection from heme toxicity via enzymatic degradation. Our results explain why catalytically inactive mutants of HO-2 are cytoprotective against oxidative stress. Moreover, the change in bioavailable heme due to HO-2 overexpression, which selectively binds ferric over ferrous heme, is consistent with labile heme being oxidized, thereby providing new insights into heme trafficking and signaling.

Published

2022

16. Not a 'they' but a 'we': The microbiome helps promote our well-being

Author

Stephen W. Ragsdale

Subjects

one carbon metabolism, FDR, false discovery rate, QA, quaternary amine, microbiome, THF, tetrahydrofolate, folate, enzyme catalysis, Biochemistry, Methylamines, Carnitine, energy metabolism, L-carnitine, γ-butyrobetaine, Humans, acetogenesis, cobalamin, Molecular Biology, TMAO, TMA N-oxide, TMA, trimethylamine, ATCC, American Type Culture Collection, Eubacterium, Microbiota, microbiology, bacterial metabolism, Oxides, Methyltransferases, Editors' Pick, Cell Biology, Gastrointestinal Microbiome, Betaine, Vitamin B 12, Research Article

Abstract

The production of trimethylamine (TMA) from quaternary amines such as l-carnitine or γ-butyrobetaine (4-(trimethylammonio)butanoate) by gut microbial enzymes has been linked to heart disease. This has led to interest in enzymes of the gut microbiome that might ameliorate net TMA production, such as members of the MttB superfamily of proteins, which can demethylate TMA (e.g., MttB) or l-carnitine (e.g., MtcB). Here, we show that the human gut acetogen Eubacterium limosum demethylates γ-butyrobetaine and produces MtyB, a previously uncharacterized MttB superfamily member catalyzing the demethylation of γ-butyrobetaine. Proteomic analyses of E. limosum grown on either γ-butyrobetaine or dl-lactate were employed to identify candidate proteins underlying catabolic demethylation of the growth substrate. Three proteins were significantly elevated in abundance in γ-butyrobetaine-grown cells: MtyB, MtqC (a corrinoid-binding protein), and MtqA (a corrinoid:tetrahydrofolate methyltransferase). Together, these proteins act as a γ-butyrobetaine:tetrahydrofolate methyltransferase system, forming a key intermediate of acetogenesis. Recombinant MtyB acts as a γ-butyrobetaine:MtqC methyltransferase but cannot methylate free cobalamin cofactor. MtyB is very similar to MtcB, the carnitine methyltransferase, but neither was detectable in cells grown on carnitine nor was detectable in cells grown with γ-butyrobetaine. Both quaternary amines are substrates for either enzyme, but kinetic analysis revealed that, in comparison to MtcB, MtyB has a lower apparent Km for γ-butyrobetaine and higher apparent Vmax, providing a rationale for MtyB abundance in γ-butyrobetaine-grown cells. As TMA is readily produced from γ-butyrobetaine, organisms with MtyB-like proteins may provide a means to lower levels of TMA and proatherogenic TMA-N-oxide via precursor competition.

Published

2022

17. Ferric Heme as a CO/NO Sensor in the Nuclear Receptor Reverbβ by Coupling Gas binding to Electron Transfer

Author

Jill B. Harland, Amy L. Speelman, Nicolai Lehnert, Stephen W. Ragsdale, Anindita Sarkar, and Eric L. Carter

Subjects

Electron transfer, chemistry.chemical_compound, Hemeprotein, Heme binding, chemistry, law, Biophysics, Repressor, Electron paramagnetic resonance, Redox, Heme, Nuclear receptor co-repressor 1, law.invention

Abstract

Rev-Erbβ is a nuclear receptor that couples circadian rhythm, metabolism, and inflammation.1-7Heme binding to the protein modulates its function as a repressor, its stability, its ability to bind other proteins, and its activity in gas sensing.8-11Rev-Erbβ binds Fe3+-heme tighter than Fe2+-heme, suggesting its activities may be regulated by the heme redox state.9Yet, this critical role of heme redox chemistry in defining the protein’s resting state and function is unknown. We demonstrate by electrochemical and whole-cell electron paramagnetic resonance experiments that Rev-Erbβ exists in the Fe3+form within the cell essentially allowing the protein to be heme-replete even at low concentrations of labile heme in the nucleus. However, being in the Fe3+redox state contradicts Rev-Erb’s known function as a gas sensor, which dogma asserts must be a Fe2+protein This paper explains why the resting Fe3+-state is congruent both with heme-binding and cellular gas sensing. We show that the binding of CO/NO elicits a striking increase in the redox potential of the Fe3+/Fe2+couple, characteristic of an EC mechanism in which the unfavorableElectrochemical reduction of heme is coupled to the highly favorableChemical reaction of gas binding, making the reduction spontaneous. Thus, Fe3+-Rev-Erbβ remains heme-loaded, crucial for its repressor activity, and only undergoes reduction when diatomic gases are present. This work has broad implications for hemoproteins where ligand-triggered redox changes cause conformational changes influencing protein’s function or inter-protein interactions, like NCoR1 for Rev-Erbβ. This study opens up the possibility of CO/NO-mediated regulation of the circadian rhythm through redox changes in Rev-Erbβ.

Published

2020

18. Absence of heme at the catalytic site of heme oxygenase-2 triggers its lysosomal degradation

Author

Angela S. Fleischhacker, Stephen W. Ragsdale, Arti B. Dumbrepatil, Liu Liu, and E. Neil G. Marsh

Subjects

Heme oxygenase, chemistry.chemical_compound, Biliverdin, medicine.anatomical_structure, Heme binding, Proteasome, Chemistry, Lysosome, Autophagy, medicine, Protein degradation, Heme, Cell biology

Abstract

Heme oxygenase-2 (HO2) and −1 (HO1) catalyze heme degradation to biliverdin, CO, and iron, forming an essential link in the heme metabolism network. Tight regulation of the cellular levels and catalytic activities of HO1 and HO2 is important for maintaining heme homeostasis. While transcriptional control of HO1 expression has been well-studied, how the cellular levels and activity of HO2 are regulated remains unclear. Here, the mechanism of post-translational regulation of cellular HO2 level by heme is elucidated. Under heme deficient conditions, HO2 is destabilized and targeted for degradation. In HO2, three heme binding sites are potential targets of heme-dependent regulation: one at its catalytic site; the others at its two heme regulatory motifs (HRMs). We report that, in contrast to other HRM-containing proteins, the cellular protein level and degradation rate of HO2 are independent of heme binding to the HRMs. Rather, under heme deficiency, loss of heme binding to the catalytic site destabilizes HO2. Consistently, a HO2 catalytic site variant that is unable to bind heme exhibits a constant low protein level and an enhanced protein degradation rate compared to the wild-type HO2. However, cellular heme overload does not affect HO2 stability. Finally, HO2 is degraded by the lysosome through chaperone-mediated autophagy, distinct from other HRM-containing proteins and HO1, which are degraded by the proteasome. These results reveal a novel aspect of HO2 regulation and deepen our understanding of HO2’s role in maintaining heme homeostasis, paving the way for future investigation into HO2’s pathophysiological role in heme deficiency response.

Published

2020

19. Negative-Stain Electron Microscopy Reveals Dramatic Structural Rearrangements in Ni-Fe-S-Dependent Carbon Monoxide Dehydrogenase/Acetyl-CoA Synthase

Author

Catherine L. Drennan, Edward J. Brignole, Elizabeth C. Wittenborn, Samuel Thompson, Mehmet Can, Stephen W. Ragsdale, and Steven E. Cohen

Subjects

Stereochemistry, Iron, Molecular Dynamics Simulation, Article, 03 medical and health sciences, chemistry.chemical_compound, Corrinoid, Bacterial Proteins, Protein Domains, Structural Biology, Moorella thermoacetica, Multienzyme Complexes, Nickel, Moorella, Molecular Biology, 030304 developmental biology, 0303 health sciences, biology, ATP synthase, 030302 biochemistry & molecular biology, Acetyl-CoA, Methylation, biology.organism_classification, Negative stain, Aldehyde Oxidoreductases, chemistry, Acetogenesis, biology.protein, Sulfur, Carbon monoxide dehydrogenase

Abstract

The nickel-iron-sulfur-containing A-cluster of acetyl-CoA synthase (ACS) assembles acetyl-CoA from carbon monoxide (CO), a methyl group (CH(3)(+)), and coenzyme A (CoA). To accomplish this feat, ACS must bind CoA and interact with two other proteins that contribute the CO and CH(3)(+), respectively: carbon monoxide dehydrogenase (CODH) and corrinoid iron-sulfur protein (CFeSP). Previous structural data show that in the model acetogen Moorella thermoacetica, domain 1 of ACS binds to CODH such that a 70-Å-long internal channel is created that allows for CO to travel from CODH to the A-cluster. The A-cluster is largely buried and is inaccessible to CFeSP for methylation. Here we use electron microscopy to capture multiple snapshots of ACS that reveal previously uncharacterized domain motion, forming extended and hyperextended structural states. In these structural states, the A-cluster is accessible for methylation by CFeSP.

Published

2020

20. The heme-regulatory motifs of heme oxygenase-2 contribute to the transfer of heme to the catalytic site for degradation

Author

Angela S. Fleischhacker, Stephen W. Ragsdale, Thomas E. Wales, Liu Liu, John R. Engen, Amanda L. Gunawan, Brent A. Kochert, and Maelyn C. Borowy

Subjects

0301 basic medicine, Conformational change, Heme binding, Stereochemistry, Iron, Hydrogen Deuterium Exchange-Mass Spectrometry, Heme, Molecular Dynamics Simulation, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Catalytic Domain, Metalloprotein, Humans, Editors' Picks, Binding site, Molecular Biology, chemistry.chemical_classification, Biliverdin, 030102 biochemistry & molecular biology, biology, Active site, Cell Biology, Heme oxygenase, 030104 developmental biology, chemistry, Heme Oxygenase (Decyclizing), biology.protein

Abstract

Heme-regulatory motifs (HRMs) are present in many proteins that are involved in diverse biological functions. The C-terminal tail region of human heme oxygenase-2 (HO2) contains two HRMs whose cysteine residues form a disulfide bond; when reduced, these cysteines are available to bind Fe(3+)-heme. Heme binding to the HRMs occurs independently of the HO2 catalytic active site in the core of the protein, where heme binds with high affinity and is degraded to biliverdin. Here, we describe the reversible, protein-mediated transfer of heme between the HRMs and the HO2 core. Using hydrogen-deuterium exchange (HDX)-MS to monitor the dynamics of HO2 with and without Fe(3+)-heme bound to the HRMs and to the core, we detected conformational changes in the catalytic core only in one state of the catalytic cycle—when Fe(3+)-heme is bound to the HRMs and the core is in the apo state. These conformational changes were consistent with transfer of heme between binding sites. Indeed, we observed that HRM-bound Fe(3+)-heme is transferred to the apo-core either upon independent expression of the core and of a construct spanning the HRM-containing tail or after a single turnover of heme at the core. Moreover, we observed transfer of heme from the core to the HRMs and equilibration of heme between the core and HRMs. We therefore propose an Fe(3+)-heme transfer model in which HRM-bound heme is readily transferred to the catalytic site for degradation to facilitate turnover but can also equilibrate between the sites to maintain heme homeostasis.

Published

2020

21. Crystallographic Characterization of the Carbonylated A-Cluster in Carbon Monoxide Dehydrogenase/Acetyl-CoA Synthase

Author

Catherine L. Drennan, Elizabeth C. Wittenborn, Rachel A Hendrickson, Steven E. Cohen, Mehmet Can, and Stephen W. Ragsdale

Subjects

Letter, Stereochemistry, CODH, 010402 general chemistry, 01 natural sciences, carbon monoxide, Catalysis, chemistry.chemical_compound, acetogenesis, Phosphofructokinase 2, X-ray crystallography, metalloenzymes, biology, ATP synthase, 010405 organic chemistry, Acetyl-CoA, General Chemistry, ACS, 0104 chemical sciences, Wood−Ljungdahl, chemistry, Acetogenesis, Carbon dioxide, biology.protein, acetyl coenzyme A, Carbon monoxide dehydrogenase, Carbon monoxide

Abstract

Copyright © 2020 American Chemical Society. The Wood-Ljungdahl pathway allows for autotrophic bacterial growth on carbon dioxide, with the last step in acetyl-CoA synthesis catalyzed by the bifunctional enzyme carbon monoxide dehydrogenase/acetyl-CoA synthase (CODH/ACS). ACS uses a complex Ni-Fe-S metallocluster termed the A-cluster to assemble acetyl-CoA from carbon monoxide, a methyl moiety and coenzyme A. Here, we report the crystal structure of CODH/ACS from Moorella thermoacetica with substrate carbon monoxide bound at the A-cluster, a state previously uncharacterized by crystallography. Direct structural characterization of this state highlights the role of second sphere residues and conformational dynamics in acetyl-CoA assembly, the biological equivalent of the Monsanto process.

Published

2020

22. Binding site for coenzyme A revealed in the structure of pyruvate:ferredoxin oxidoreductase from Moorella thermoacetica

Author

Catherine L. Drennan, Stephen W. Ragsdale, Mehmet Can, Percival Yang-Ting Chen, and Heather Aman

Subjects

0301 basic medicine, Pyruvate decarboxylation, Pyruvate Synthase, Stereochemistry, Coenzyme A, Crystallography, X-Ray, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Moorella thermoacetica, Oxidoreductase, Moorella, Pyruvic Acid, Binding site, Ferredoxin, chemistry.chemical_classification, Binding Sites, Multidisciplinary, 030102 biochemistry & molecular biology, biology, Chemistry, Active site, Biological Sciences, Carbon Dioxide, biology.organism_classification, Kinetics, 030104 developmental biology, biology.protein, Ferredoxins

Abstract

Pyruvate:ferredoxin oxidoreductase (PFOR) is a microbial enzyme that uses thiamine pyrophosphate (TPP), three [4Fe-4S] clusters, and coenzyme A (CoA) in the reversible oxidation of pyruvate to generate acetyl-CoA and carbon dioxide. The two electrons that are generated as a result of pyruvate decarboxylation are used in the reduction of low potential ferredoxins, which provide reducing equivalents for central metabolism, including the Wood–Ljungdahl pathway. PFOR is a member of the 2-oxoacid:ferredoxin oxidoreductase (OFOR) superfamily, which plays major roles in both microbial redox reactions and carbon dioxide fixation. Here, we present a set of crystallographic snapshots of the best-studied member of this superfamily, the PFOR from Moorella thermoacetica ( Mt PFOR). These snapshots include the native structure, those of lactyl-TPP and acetyl-TPP reaction intermediates, and the first of an OFOR with CoA bound. These structural data reveal the binding site of CoA as domain III, the function of which in OFORs was previously unknown, and establish sequence motifs for CoA binding in the OFOR superfamily. Mt PFOR structures further show that domain III undergoes a conformational change upon CoA binding that seals off the active site and positions the thiolate of CoA directly adjacent to the TPP cofactor. These structural findings provide a molecular basis for the experimental observation that CoA binding accelerates catalysis by 10 5 -fold.

Published

2018

23. The heme-regulatory motif of nuclear receptor Rev-erbβ is a key mediator of heme and redox signaling in circadian rhythm maintenance and metabolism

Author

Yanil Ramirez, Stephen W. Ragsdale, and Eric L. Carter

Subjects

0301 basic medicine, Heme binding, Iron, Amino Acid Motifs, Receptors, Cytoplasmic and Nuclear, Heme, Ligand Binding Protein, Biology, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Protein Domains, Nuclear Receptor Co-Repressor 1, Molecular Biology, Transcription factor, Nuclear receptor co-repressor 1, Isothermal titration calorimetry, Cell Biology, Circadian Rhythm, Repressor Proteins, Kinetics, Metabolism, 030104 developmental biology, Nuclear receptor, chemistry, Biophysics, Spectrophotometry, Ultraviolet, Oxidation-Reduction, Protein Binding, Signal Transduction, Cysteine

Abstract

Rev-erbβ is a heme-responsive transcription factor that regulates genes involved in circadian rhythm maintenance and metabolism, effectively bridging these critical cellular processes. Heme binding to Rev-erbβ indirectly facilitates its interaction with the nuclear receptor co-repressor (NCoR1), resulting in repression of Rev-erbβ target genes. Fe3+-heme binds in a 6-coordinate complex with axial His and Cys ligands, the latter provided by a heme-regulatory motif (HRM). Rev-erbβ was thought to be a heme sensor based on a weak Kd value for the Rev-erbβ·heme complex of 2 μm determined with isothermal titration calorimetry. However, our group demonstrated with UV-visible difference titrations that the Kd value is in the low nanomolar range, and the Fe3+-heme off-rate is on the order of 10−6 s−1 making Rev-erbβ ineffective as a sensor of Fe3+-heme. In this study, we dissected the kinetics of heme binding to Rev-erbβ and provided a Kd for Fe3+-heme of ∼0.1 nm. Loss of the HRM axial thiolate via redox processes, including oxidation to a disulfide with a neighboring cysteine or dissociation upon reduction of Fe3+- to Fe2+-heme, decreased binding affinity by >20-fold. Furthermore, as measured in a co-immunoprecipitation assay, substitution of the His or Cys heme ligands in Rev-erbβ was accompanied by a significant loss of NCoR1 binding. These results demonstrate the importance of the Rev-erbβ HRM in regulating interactions with heme and NCoR1 and advance our understanding of how signaling through HRMs affects the major cellular processes of circadian rhythm maintenance and metabolism.

Published

2017

24. Properties of Intermediates in the Catalytic Cycle of Oxalate Oxidoreductase and Its Suicide Inactivation by Pyruvate

Author

Mehmet Can, Elizabeth Pierce, Steven O. Mansoorabadi, Stephen W. Ragsdale, and George H. Reed

Subjects

0301 basic medicine, Stereochemistry, Decarboxylation, Coenzyme A, Biochemistry, Catalysis, Article, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, Oxidoreductase, Pyruvic Acid, Ferredoxin, chemistry.chemical_classification, Oxalates, 030102 biochemistry & molecular biology, biology, Chemistry, Electron Spin Resonance Spectroscopy, Metabolic intermediate, 030104 developmental biology, Catalytic cycle, biology.protein, Spectrophotometry, Ultraviolet, Oxidoreductases, Thiamine pyrophosphate

Abstract

Oxalate:ferredoxin oxidoreductase (OOR) is an unusual member of the thiamine pyrophosphate (TPP)-dependent 2-oxoacid:ferredoxin oxidoreductase (OFOR) family in that it catalyzes the coenzyme A (CoA)-independent conversion of oxalate into 2 equivalents of carbon dioxide. This reaction is surprising because binding of CoA to the acyl-TPP intermediate of other OFORs results in formation of a CoA ester, and in the case of pyruvate:ferredoxin oxidoreductase (PFOR), CoA binding generates the central metabolic intermediate acetyl-CoA and promotes a 105-fold acceleration of the rate of electron transfer. Here we describe kinetic, spectroscopic, and computational results to show that CoA has no effect on catalysis by OOR and describe the chemical rationale for why this cofactor is unnecessary in this enzymatic transformation. Our results demonstrate that, like PFOR, OOR binds pyruvate and catalyzes decarboxylation to form the same hydroxyethylidine–TPP (HE–TPP) intermediate and one-electron transfer to generate the HE–TPP radical. However, in OOR, this intermediate remains stranded at the active site as a covalent inhibitor. These and other results indicate that, like other OFOR family members, OOR generates an oxalate-derived adduct with TPP (oxalyl-TPP) that undergoes decarboxylation and one-electron transfer to form a radical intermediate remaining bound to TPP (dihydroxymethylidene–TPP). However, unlike in PFOR, where CoA binding drives formation of the product, in OOR, proton transfer and a conformational change in the “switch loop” alter the redox potential of the radical intermediate sufficiently to promote the transfer of an electron into the iron–sulfur cluster network, leading directly to a second decarboxylation and completing the catalytic cycle.

Published

2017

25. X-ray Absorption Spectroscopy Reveals an Organometallic Ni–C Bond in the CO-Treated Form of Acetyl-CoA Synthase

Author

Logan J. Giles, Ritimukta Sarangi, Mehmet Can, and Stephen W. Ragsdale

Subjects

Models, Molecular, 0301 basic medicine, Absorption spectroscopy, Stereochemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, 03 medical and health sciences, chemistry.chemical_compound, Nickel, Catalytic Domain, Coenzyme A Ligases, Organometallic Compounds, Group 2 organometallic chemistry, Carbon Monoxide, X-ray absorption spectroscopy, biology, Chemistry, Acetyl-CoA, Active site, 0104 chemical sciences, X-Ray Absorption Spectroscopy, 030104 developmental biology, biology.protein, Quantum Theory, Density functional theory, Absorption (chemistry), Oxidation-Reduction, Carbon monoxide

Abstract

Acetyl-CoA synthase (ACS) is a key enzyme in the Wood–Ljungdahl pathway of anaerobic CO2 fixation, which has long been proposed to operate by a novel mechanism involving a series of protein-bound organometallic (Ni–CO, methyl–Ni, and acetyl–Ni) intermediates. Here we report the first direct structural evidence of the proposed metal–carbon bond. We describe the preparation of the highly active metal-replete enzyme and near-quantitative generation of the kinetically competent carbonylated intermediate. This advance has allowed a combination of Ni and Fe K-edge X-ray absorption spectroscopy and extended X-ray absorption fine structure experiments along with density functional theory calculations. The data reveal that CO binds to the proximal Ni of the six-metal metallocenter at the active site and undergoes dramatic structural and electronic perturbation in forming this organometallic Ni–CO intermediate. This direct identification of a Ni–carbon bond in the catalytically competent CO-bound form of the A cluster of ACS provides definitive experimental structural evidence supporting the proposed organometallic mechanism of anaerobic acetyl-CoA synthesis.

Published

2017

26. Protonation of the Hydroperoxo Intermediate of Cytochrome P450 2B4 Is Slower in the Presence of Cytochrome P450 Reductase Than in the Presence of Cytochrome b5

Author

R. David Britt, Sang Choul Im, Ryan C. Kunz, Lucy Waskell, Jarett Wilcoxen, Joseph E. Darty, Stephen W. Ragsdale, and Naw May Pearl

Subjects

0301 basic medicine, Electrons, Protonation, Reductase, Photochemistry, Models, Biological, Biochemistry, Redox, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Cytochrome b5, medicine, Animals, Cytochrome P450 Family 2, Heme, NADPH-Ferrihemoprotein Reductase, 030102 biochemistry & molecular biology, biology, Electron Spin Resonance Spectroscopy, Cytochrome P450 reductase, Cytochrome P450, NAD, Kinetics, Cytochromes b5, chemistry, Biocatalysis, biology.protein, Ferric, Aryl Hydrocarbon Hydroxylases, Hydrogenation, Rabbits, Protons, Oxidation-Reduction, Protein Binding, medicine.drug

Abstract

Microsomal cytochromes P450 (P450) require two electrons and two protons for the oxidation of substrates. Although the two electrons can be provided by cytochrome P450 reductase, the second electron can also be donated by cytochrome b5 (b5). The steady-state activity of P450 2B4 is increased up to 10-fold by b5. To improve our understanding of the molecular basis of the stimulatory effect of b5 and to test the hypothesis that b5 stimulates catalysis by more rapid protonation of the anionic ferric hydroperoxo heme intermediate of P450 (Fe3+OOH)− and subsequent formation of the active oxidizing species (Fe+4═O POR•+), we have freeze-quenched the reaction mixture during a single turnover following reduction of oxyferrous P450 2B4 by each of its redox partners, b5 and P450 reductase. The electron paramagnetic resonance spectra of the freeze-quenched reaction mixtures lacked evidence of a hydroperoxo intermediate when b5 was the reductant presumably because hydroperoxo protonation and catalysis occurred within...

Published

2016

27. Exploring Hydrogenotrophic Methanogenesis: a Genome Scale Metabolic Reconstruction of Methanococcus maripaludis

Author

Nathan D. Price, Juan Zhang, Thomas J. Lie, Matthew A. Richards, John A. Leigh, and Stephen W. Ragsdale

Subjects

0301 basic medicine, Methanococcus, Chemoautotrophic Growth, Methanogenesis, Archaeal Proteins, 030106 microbiology, Genome scale, Metabolic network, Computational biology, Microbiology, Metabolic engineering, 03 medical and health sciences, Genome, Archaeal, Molecular Biology, biology, Ecology, Methanococcus maripaludis, Articles, biology.organism_classification, Methanogen, 030104 developmental biology, Methane, Metabolic Networks and Pathways, Hydrogen

Abstract

Hydrogenotrophic methanogenesis occurs in multiple environments, ranging from the intestinal tracts of animals to anaerobic sediments and hot springs. Energy conservation in hydrogenotrophic methanogens was long a mystery; only within the last decade was it reported that net energy conservation for growth depends on electron bifurcation. In this work, we focus on Methanococcus maripaludis , a well-studied hydrogenotrophic marine methanogen. To better understand hydrogenotrophic methanogenesis and compare it with methylotrophic methanogenesis that utilizes oxidative phosphorylation rather than electron bifurcation, we have built iMR539, a genome scale metabolic reconstruction that accounts for 539 of the 1,722 protein-coding genes of M. maripaludis strain S2. Our reconstructed metabolic network uses recent literature to not only represent the central electron bifurcation reaction but also incorporate vital biosynthesis and assimilation pathways, including unique cofactor and coenzyme syntheses. We show that our model accurately predicts experimental growth and gene knockout data, with 93% accuracy and a Matthews correlation coefficient of 0.78. Furthermore, we use our metabolic network reconstruction to probe the implications of electron bifurcation by showing its essentiality, as well as investigating the infeasibility of aceticlastic methanogenesis in the network. Additionally, we demonstrate a method of applying thermodynamic constraints to a metabolic model to quickly estimate overall free-energy changes between what comes in and out of the cell. Finally, we describe a novel reconstruction-specific computational toolbox we created to improve usability. Together, our results provide a computational network for exploring hydrogenotrophic methanogenesis and confirm the importance of electron bifurcation in this process. IMPORTANCE Understanding and applying hydrogenotrophic methanogenesis is a promising avenue for developing new bioenergy technologies around methane gas. Although a significant portion of biological methane is generated through this environmentally ubiquitous pathway, existing methanogen models portray the more traditional energy conservation mechanisms that are found in other methanogens. We have constructed a genome scale metabolic network of Methanococcus maripaludis that explicitly accounts for all major reactions involved in hydrogenotrophic methanogenesis. Our reconstruction demonstrates the importance of electron bifurcation in central metabolism, providing both a window into hydrogenotrophic methanogenesis and a hypothesis-generating platform to fuel metabolic engineering efforts.

Published

2016

28. Fast and Selective Photoreduction of CO

Author

Liyun, Zhang, Mehmet, Can, Stephen W, Ragsdale, and Fraser A, Armstrong

Subjects

Article

Abstract

Selective, visible-light-driven conversion of CO(2) to CO with a turnover frequency of 20 s(−1) under visible light irradiation at 25 °C is catalyzed by an aqueous colloidal system comprising a pseudoternary complex formed among carbon monoxide dehydrogenase (CODH), silver nanoclusters stabilized by polymethacrylic acid (AgNCs-PMAA), and TiO(2) nanoparticles. The photocatalytic assembly, which is stable over several hours and for at least 250000 turnovers of the enzyme’s active site, was investigated by separate electrochemical (dark) and fluorescence measurements to establish specific connectivities among the components. The data show (a) that a coating of AgNCs-PMAA on TiO(2) greatly enhances its ability as an electrode for CODH- based electrocatalysis of CO(2) reduction and (b) that the individual Ag nanoclusters interact directly and dynamically with the enzyme surface, most likely at exposed cysteine thiols. The results lead to a model for photocatalysis in which the AgNCs act as photosensitizers, CODH captures the excited electrons for catalysis, and TiO(2) mediates hole transfer from the AgNC valence band to sacrificial electron donors. The results greatly increase the benchmark for reversible CO(2) reduction under ambient conditions and demonstrate that, with such efficient catalysts, the limiting factor is the supply of photogenerated electrons.

Published

2019

29. Production and properties of enzymes that activate and produce carbon monoxide

Author

Rodney L. Burton, Mehmet Can, Daniel Esckilsen, Seth Wiley, and Stephen W. Ragsdale

Subjects

0301 basic medicine, Hydrogenase, Coenzyme A, 030106 microbiology, Article, 03 medical and health sciences, chemistry.chemical_compound, Bacteria, Anaerobic, Multienzyme Complexes, Coenzyme A Ligases, Carbon Monoxide, biology, Chemistry, Carbon fixation, Acetyl-CoA, Carbon Dioxide, biology.organism_classification, Aldehyde Oxidoreductases, Archaea, 030104 developmental biology, Biochemistry, biology.protein, Anaerobic bacteria, Oxidation-Reduction, Syngas, Carbon monoxide dehydrogenase

Abstract

The chapter focuses on the methods involved in producing and characterizing two key nickel–iron–sulfur enzymes in the Wood–Ljungdahl pathway (WLP) of anaerobic conversion of carbon dioxide fixation into acetyl-CoA: carbon monoxide dehydrogenase (CODH) and acetyl-CoA synthase (ACS). The WLP is used for biosynthesis of cell material and energy conservation by anaerobic bacteria and archaea, and it is central to several industrial biotechnology processes aimed at using syngas and waste gases for the production of fuels and chemicals. The pathway can run in reverse to allow organisms, e. g., methanogens and sulfate reducers, to grow on acetate. The CODH and ACS intertwine to form a tenacious CODH/ACS complex that converts CO(2), a methyl group, and coenzyme A into acetyl-CoA. CODH also behaves as a modular unit that can function as an independent homodimer. Besides coupling to ACS, CODH can interact with hydrogenases to couple CO oxidation to H(2) formation. These enzymes have been purified and characterized from several microbes.

Published

2018

30. The radical mechanism of biological methane synthesis by methyl-coenzyme M reductase

Author

Stephen W. Ragsdale, Dayle M. A. Smith, Dariusz A. Sliwa, Nicolai Lehnert, Matthew W. Wolf, Thanyaporn Wongnate, Bojana Ginovska, and Simone Raugei

Subjects

0301 basic medicine, Methanobacteriaceae, Methanogenesis, Stereochemistry, Molecular Dynamics Simulation, Reductase, 010402 general chemistry, 01 natural sciences, Article, Methane, Catalysis, 03 medical and health sciences, chemistry.chemical_compound, Nickel, Catalytic Domain, chemistry.chemical_classification, Multidisciplinary, Spectrum Analysis, Temperature, Methyl radical, Hydrogen Bonding, 0104 chemical sciences, Enzyme Activation, Kinetics, 030104 developmental biology, Enzyme, chemistry, Anaerobic oxidation of methane, Biocatalysis, Density functional theory, Oxidoreductases, Oxidation-Reduction

Abstract

Methyl-coenzyme M reductase, the rate-limiting enzyme in methanogenesis and anaerobic methane oxidation, is responsible for the biological production of more than 1 billion tons of methane per year. The mechanism of methane synthesis is thought to involve either methyl-nickel(III) or methyl radical/Ni(II)-thiolate intermediates. We employed transient kinetic, spectroscopic, and computational approaches to study the reaction between the active Ni(I) enzyme and substrates. Consistent with the methyl radical-based mechanism, there was no evidence for a methyl-Ni(III) species; furthermore, magnetic circular dichroism spectroscopy identified the Ni(II)-thiolate intermediate. Temperature-dependent transient kinetics also closely matched density functional theory predictions of the methyl radical mechanism. Identifying the key intermediate in methanogenesis provides fundamental insights to develop better catalysts for producing and activating an important fuel and potent greenhouse gas.

Published

2016

31. High Affinity Heme Binding to a Heme Regulatory Motif on the Nuclear Receptor Rev-erbβ Leads to Its Degradation and Indirectly Regulates Its Interaction with Nuclear Receptor Corepressor

Author

Nirupama Gupta, Stephen W. Ragsdale, and Eric L. Carter

Subjects

0301 basic medicine, Heme binding, Amino Acid Motifs, Receptors, Cytoplasmic and Nuclear, Repressor, Heme, Biology, Ligands, Transfection, Biochemistry, Mass Spectrometry, Protein–protein interaction, 03 medical and health sciences, chemistry.chemical_compound, Protein Interaction Mapping, Humans, Nuclear Receptor Co-Repressor 1, Gene Regulation, Protein–DNA interaction, Cycloheximide, Promoter Regions, Genetic, Molecular Biology, Nuclear receptor co-repressor 1, Inflammation, Ions, Myoglobin, Ubiquitin, Cell Biology, Circadian Rhythm, Cell biology, Repressor Proteins, HEK293 Cells, 030104 developmental biology, Gene Expression Regulation, Nuclear receptor, chemistry, Metals, Apoproteins, Protein Processing, Post-Translational, Corepressor, Protein Binding

Abstract

Rev-erbα and Rev-erbβ are heme-binding nuclear receptors (NR) that repress the transcription of genes involved in regulating metabolism, inflammation, and the circadian clock. Previous gene expression and co-immunoprecipitation studies led to a model in which heme binding to Rev-erbα recruits nuclear receptor corepressor 1 (NCoR1) into an active repressor complex. However, in contradiction, biochemical and crystallographic studies have shown that heme decreases the affinity of the ligand-binding domain of Rev-erb NRs for NCoR1 peptides. One explanation for this discrepancy is that the ligand-binding domain and NCoR1 peptides used for in vitro studies cannot replicate the key features of the full-length proteins used in cellular studies. However, the combined in vitro and cellular results described here demonstrate that heme does not directly promote interactions between full-length Rev-erbβ (FLRev-erbβ) and an NCoR1 construct encompassing all three NR interaction domains. NCoR1 tightly binds both apo- and heme-replete FLRev-erbβ·DNA complexes; furthermore, heme, at high concentrations, destabilizes the FLRev-erbβ·NCoR1 complex. The interaction between FLRev-erbβ and NCoR1 as well as Rev-erbβ repression at the Bmal1 promoter appear to be modulated by another cellular factor(s), at least one of which is related to the ubiquitin-proteasome pathway. Our studies suggest that heme is involved in regulating the degradation of Rev-erbβ in a manner consistent with its role in circadian rhythm maintenance. Finally, the very slow rate constant (10(-6) s(-1)) of heme dissociation from Rev-erbβ rules out a prior proposal that Rev-erbβ acts as an intracellular heme sensor.

Published

2016

32. One-carbon chemistry of oxalate oxidoreductase captured by X-ray crystallography

Author

Percival Yang-Ting Chen, Marcus I. Gibson, Aileen C. Johnson, Catherine L. Drennan, Stephen W. Ragsdale, Mehmet Can, and Elizabeth Pierce

Subjects

Models, Molecular, 0301 basic medicine, Inorganic chemistry, Reaction intermediate, Crystallography, X-Ray, Oxalate, 03 medical and health sciences, chemistry.chemical_compound, Oxidoreductase, Catalytic Domain, Moorella, Side chain, Molecule, chemistry.chemical_classification, Oxalates, Multidisciplinary, 030102 biochemistry & molecular biology, biology, Active site, Biological Sciences, Carbon, Protein Structure, Tertiary, Crystallography, chemistry, Covalent bond, Acetogenesis, Solvents, biology.protein, Oxidoreductases, Oxidation-Reduction

Abstract

Thiamine pyrophosphate (TPP)-dependent oxalate oxidoreductase (OOR) metabolizes oxalate, generating two molecules of CO2 and two low-potential electrons, thus providing both the carbon and reducing equivalents for operation of the Wood-Ljungdahl pathway of acetogenesis. Here we present structures of OOR in which two different reaction intermediate bound states have been trapped: the covalent adducts between TPP and oxalate and between TPP and CO2. These structures, along with the previously determined structure of substrate-free OOR, allow us to visualize how active site rearrangements can drive catalysis. Our results suggest that OOR operates via a bait-and-switch mechanism, attracting substrate into the active site through the presence of positively charged and polar residues, and then altering the electrostatic environment through loop and side chain movements to drive catalysis. This simple but elegant mechanism explains how oxalate, a molecule that humans and most animals cannot break down, can be used for growth by acetogenic bacteria.

Published

2015

33. Fast and selective photoreduction of CO2 to CO Catalyzed by a complex of carbon monoxide dehydrogenase, TiO2, and Ag nanoclusters

Author

Stephen W. Ragsdale, Mehmet Can, Liyun Zhang, and Fraser A. Armstrong

Subjects

Aqueous solution, biology, Chemistry, Visible light irradiation, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, Photochemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Nanoclusters, Artificial photosynthesis, Colloid, biology.protein, 0210 nano-technology, Carbon monoxide dehydrogenase

Abstract

Selective, visible-light-driven conversion of CO2 to CO with a turnover frequency of 20 s–1 under visible light irradiation at 25 °C is catalyzed by an aqueous colloidal system comprising a pseudoternary complex formed among carbon monoxide dehydrogenase (CODH), silver nanoclusters stabilized by polymethacrylic acid (AgNCs-PMAA), and TiO2 nanoparticles. The photocatalytic assembly, which is stable over several hours and for at least 250000 turnovers of the enzyme’s active site, was investigated by separate electrochemical (dark) and fluorescence measurements to establish specific connectivities among the components. The data show (a) that a coating of AgNCs-PMAA on TiO2 greatly enhances its ability as an electrode for CODH-based electrocatalysis of CO2 reduction and (b) that the individual Ag nanoclusters interact directly and dynamically with the enzyme surface, most likely at exposed cysteine thiols. The results lead to a model for photocatalysis in which the AgNCs act as photosensitizers, CODH captures the excited electrons for catalysis, and TiO2 mediates hole transfer from the AgNC valence band to sacrificial electron donors. The results greatly increase the benchmark for reversible CO2 reduction under ambient conditions and demonstrate that, with such efficient catalysts, the limiting factor is the supply of photogenerated electrons.

Published

2018

34. Elusive microbe that consumes ethane found under the sea

Author

Stephen W. Ragsdale

Subjects

0301 basic medicine, chemistry.chemical_classification, Multidisciplinary, 010504 meteorology & atmospheric sciences, Sulfide, biology, Microorganism, chemistry.chemical_element, biology.organism_classification, 01 natural sciences, Oxygen, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Environmental chemistry, Sulfate, 0105 earth and related environmental sciences, Archaea

Abstract

A microorganism that consumes ethane in the absence of environmental oxygen has been discovered. In the depths of the sea, this microbe, which oxidizes ethane, partners with another that reduces sulfate to sulfide. Ethanivorous archaea identified.

Published

2019

35. Spectroscopic Studies Reveal That the Heme Regulatory Motifs of Heme Oxygenase-2 Are Dynamically Disordered and Exhibit Redox-Dependent Interaction with Heme

Author

Angela S. Fleischhacker, Erik R. P. Zuiderweg, Ajay Sharma, Ireena Bagai, Ritimukta Sarangi, Stephen W. Ragsdale, and Brian M. Hoffman

Subjects

chemistry.chemical_classification, Biliverdin, Sequence Homology, Amino Acid, Heme binding, biology, Stereochemistry, Spectrum Analysis, Molecular Sequence Data, Heme, Biochemistry, Redox, Article, Cofactor, Heme oxygenase, chemistry.chemical_compound, Enzyme, chemistry, Heme Oxygenase (Decyclizing), Helix, biology.protein, Amino Acid Sequence, Oxidation-Reduction

Abstract

Heme oxygenase (HO) catalyzes a key step in heme homeostasis: the O2- and NADPH-cytochrome P450 reductase-dependent conversion of heme to biliverdin, Fe, and CO through a process in which the heme participates both as a prosthetic group and as a substrate. Mammals contain two isoforms of this enzyme, HO2 and HO1, which share the same α-helical fold forming the catalytic core and heme binding site, as well as a membrane spanning helix at their C-termini. However, unlike HO1, HO2 has an additional 30-residue N-terminus as well as two cysteine-proline sequences near the C-terminus that reside in heme regulatory motifs (HRMs). While the role of the additional N-terminal residues of HO2 is not yet understood, the HRMs have been proposed to reversibly form a thiol/disulfide redox switch that modulates the affinity of HO2 for ferric heme as a function of cellular redox poise. To further define the roles of the N- and C-terminal regions unique to HO2, we used multiple spectroscopic techniques to characterize these regions of the human HO2. Nuclear magnetic resonance spectroscopic experiments with HO2 demonstrate that, when the HRMs are in the oxidized state (HO2(O)), both the extra N-terminal and the C-terminal HRM-containing regions are disordered. However, protein NMR experiments illustrate that, under reducing conditions, the C-terminal region gains some structure as the Cys residues in the HRMs undergo reduction (HO2(R)) and, in experiments employing a diamagnetic protoporphyrin, suggest a redox-dependent interaction between the core and the HRM domains. Further, electron nuclear double resonance and X-ray absorption spectroscopic studies demonstrate that, upon reduction of the HRMs to the sulfhydryl form, a cysteine residue from the HRM region ligates to a ferric heme. Taken together with EPR measurements, which show the appearance of a new low-spin heme signal in reduced HO2, it appears that a cysteine residue(s) in the HRMs directly interacts with a second bound heme.

Published

2015

36. The Reaction Mechanism of Methyl-Coenzyme M Reductase

Author

Stephen W. Ragsdale and Thanyaporn Wongnate

Subjects

Reaction mechanism, biology, Stereochemistry, Chemistry, Cell Biology, Reaction intermediate, Reductase, biology.organism_classification, Biochemistry, Chemical reaction, Reaction rate constant, Methanothermobacter marburgensis, Enzyme kinetics, Molecular Biology, Ternary complex, hormones, hormone substitutes, and hormone antagonists

Abstract

Methyl-coenzyme M reductase (MCR) is a nickel tetrahydrocorphinoid (coenzyme F430) containing enzyme involved in the biological synthesis and anaerobic oxidation of methane. MCR catalyzes the conversion of methyl-2-mercaptoethanesulfonate (methyl-SCoM) and N-7-mercaptoheptanoylthreonine phosphate (CoB7SH) to CH4 and the mixed disulfide CoBS-SCoM. In this study, the reaction of MCR from Methanothermobacter marburgensis, with its native substrates was investigated using static binding, chemical quench, and stopped-flow techniques. Rate constants were measured for each step in this strictly ordered ternary complex catalytic mechanism. Surprisingly, in the absence of the other substrate, MCR can bind either substrate; however, only one binary complex (MCR·methyl-SCoM) is productive whereas the other (MCR·CoB7SH) is inhibitory. Moreover, the kinetic data demonstrate that binding of methyl-SCoM to the inhibitory MCR·CoB7SH complex is highly disfavored (Kd = 56 mM). However, binding of CoB7SH to the productive MCR·methyl-SCoM complex to form the active ternary complex (CoB7SH·MCR(Ni(I))·CH3SCoM) is highly favored (Kd = 79 μM). Only then can the chemical reaction occur (kobs = 20 s(-1) at 25 °C), leading to rapid formation and dissociation of CH4 leaving the binary product complex (MCR(Ni(II))·CoB7S(-)·SCoM), which undergoes electron transfer to regenerate Ni(I) and the final product CoBS-SCoM. This first rapid kinetics study of MCR with its natural substrates describes how an enzyme can enforce a strictly ordered ternary complex mechanism and serves as a template for identification of the reaction intermediates.

Published

2015

37. Biochemistry of Methyl-Coenzyme M Reductase

Author

Stephen W. Ragsdale, Bojana Ginovska, Thanyaporn Wongnate, and Simone Raugei

Subjects

biology, Methane monooxygenase, Coenzyme B, Methanogenesis, Atmospheric methane, Reductase, Methane, chemistry.chemical_compound, chemistry, Biochemistry, Anaerobic oxidation of methane, biology.protein, Organic chemistry, Methanol

Abstract

Methanogens are masters of CO2 reduction. They conserve energy by coupling H2 oxidation to the reduction of CO2 to CH4, the primary constituent of natural gas. They also generate methane by the reduction of acetic acid, methanol, methane thiol, and methylamines. Methanogens produce 109 tons of methane per year and are the major source of the earth’s atmospheric methane. Reverse methanogenesis or anaerobic methane oxidation, which is catalyzed by methanotrophic archaea living in consortia among bacteria that can act as an electron acceptor, is responsible for annual oxidation of 108 tons of methane to CO2. This chapter briefly describes the overall process of methanogenesis and then describes the enzymatic mechanism of the nickel enzyme, methyl-CoM reductase (MCR), the key enzyme in methane synthesis and oxidation. MCR catalyzes the formation of methane and the heterodisulfide (CoBSSCoM) from methyl-coenzyme M (methyl-CoM) and coenzyme B (HSCoB). Uncovering the mechanistic and molecular details of MCR catalysis is critical since methane is an abundant and important fuel and is the second (to CO2) most prevalent greenhouse gas.

Published

2017

38. Protein/Protein Interactions in the Mammalian Heme Degradation Pathway

Author

Erik R. P. Zuiderweg, Andrea Morris Spencer, Stephen W. Ragsdale, Ireena Bagai, and Donald F. Becker

Subjects

Biliverdin, biology, Bilirubin, Stereochemistry, education, Biliverdin reductase, Cytochrome P450 reductase, Cytochrome P450, Cell Biology, Biochemistry, Heme oxygenase, chemistry.chemical_compound, chemistry, biology.protein, Enzyme kinetics, Molecular Biology, Heme

Abstract

Heme oxygenase (HO) catalyzes the rate-limiting step in the O2-dependent degradation of heme to biliverdin, CO, and iron with electrons delivered from NADPH via cytochrome P450 reductase (CPR). Biliverdin reductase (BVR) then catalyzes conversion of biliverdin to bilirubin. We describe mutagenesis combined with kinetic, spectroscopic (fluorescence and NMR), surface plasmon resonance, cross-linking, gel filtration, and analytical ultracentrifugation studies aimed at evaluating interactions of HO-2 with CPR and BVR. Based on these results, we propose a model in which HO-2 and CPR form a dynamic ensemble of complex(es) that precede formation of the productive electron transfer complex. The 1H-15N TROSY NMR spectrum of HO-2 reveals specific residues, including Leu-201, near the heme face of HO-2 that are affected by the addition of CPR, implicating these residues at the HO/CPR interface. Alanine substitutions at HO-2 residues Leu-201 and Lys-169 cause a respective 3- and 22-fold increase in Km values for CPR, consistent with a role for these residues in CPR binding. Sedimentation velocity experiments confirm the transient nature of the HO-2·CPR complex (Kd = 15.1 μm). Our results also indicate that HO-2 and BVR form a very weak complex that is only captured by cross-linking. For example, under conditions where CPR affects the 1H-15N TROSY NMR spectrum of HO-2, BVR has no effect. Fluorescence quenching experiments also suggest that BVR binds HO-2 weakly, if at all, and that the previously reported high affinity of BVR for HO is artifactual, resulting from the effects of free heme (dissociated from HO) on BVR fluorescence.

Published

2014

39. Modulation of nuclear receptor function by cellular redox poise

Author

Stephen W. Ragsdale and Eric L. Carter

Subjects

Transcription, Genetic, Heme, Plasma protein binding, Ligands, medicine.disease_cause, Biochemistry, Redox, Article, Inorganic Chemistry, chemistry.chemical_compound, Nuclear Reactors, Transcription (biology), medicine, Humans, Disulfides, Sulfhydryl Compounds, Receptor, Transcription factor, humanities, Cell biology, chemistry, Nuclear receptor, Oxidation-Reduction, human activities, Oxidative stress, Protein Binding, Transcription Factors

Abstract

Nuclear receptors (NRs) are ligand-responsive transcription factors involved in diverse cellular processes ranging from metabolism to circadian rhythms. This review focuses on NRs that contain redox-active thiol groups, a common feature within the superfamily. We will begin by describing NRs, how they regulate various cellular processes and how binding ligands, corepressors and/or coactivators modulates their activity. We will then describe the general area of redox regulation, especially as it pertains to thiol-disulfide interconversion and the cellular systems that respond to and govern this redox equilibrium. Lastly, we will discuss specific examples of NRs whose activities are regulated by redox-active thiols. Glucocorticoid, estrogen, and the heme-responsive receptor, Rev-erb, will be described in the most detail as they exhibit archetypal redox regulatory mechanisms.

Published

2014

40. Microbiology: Deep-sea secrets of butane metabolism

Author

Stephen W, Ragsdale

Subjects

Oceans and Seas, Butanes, Seawater, Water Microbiology

Published

2016

41. An unlikely heme chaperone confirmed at last

Author

Angela S. Fleischhacker and Stephen W. Ragsdale

Subjects

0301 basic medicine, Cell, Dehydrogenase, Heme, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, medicine, Animals, Humans, Cytotoxicity, Molecular Biology, Glyceraldehyde 3-phosphate dehydrogenase, biology, Chemistry, Glyceraldehyde-3-Phosphate Dehydrogenases, Cell Biology, Heme transport, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Chaperone (protein), Editors' Picks Highlights, biology.protein, Intracellular, Molecular Chaperones, Protein Binding

Abstract

Labile heme, as opposed to heme that is tightly bound within proteins, is thought to require a chaperone to be trafficked within the cell due to its cytotoxicity, but the identity of this chaperone was not known. A new study reveals that an unlikely protein, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), is a heme chaperone that binds and transfers labile heme to downstream target proteins. These results provide a new framework for understanding heme homeostasis and raise intriguing questions regarding the intersection of heme transport, carbohydrate metabolism, and intracellular signaling.

Published

2018

42. Stealth reactions driving carbon fixation

Author

Stephen W. Ragsdale

Subjects

0301 basic medicine, Multidisciplinary, biology, Chemistry, Carbon fixation, Heterotroph, chemistry.chemical_element, Metabolism, Bacterial Physiological Phenomena, biology.organism_classification, Oxygen, Sulfur, Carbon Cycle, 03 medical and health sciences, 030104 developmental biology, Biochemistry, Autotroph, Carbon, Archaea

Abstract

Organisms live in an interconnected dynamic web in which they make, degrade, and interconvert compounds containing carbon, hydrogen, nitrogen, oxygen, phosphorus, and sulfur. The carbon cycle involves the oxidation of organic compounds to produce CO2 by heterotrophic organisms and the incorporation (“fixation”) of CO2 from the environment into living tissue by autotrophic organisms. Heterotrophic organisms (most animals) obtain the energy for life by conserving the energy obtained by oxidizing organic molecules to CO2 in the form of reducing equivalents (electrons) and adenosine triphosphate (ATP). Autotrophic plants, bacteria, and archaea fix CO2 by a process in which the energy of electrons and ATP is used to produce biomolecules, such as sugars, amino acids, and lipids, thereby replenishing these essential organic molecules in the ecosystem. Cumulatively, autotrophy occurs on the huge scale of 7 × 1016 g of carbon fixed annually ( 1 ). Six CO2 fixation pathways differing in their ATP requirements are known to exist. Fixing CO2 using the least ATP possible is key for anaerobes because their metabolism generates much less ATP than does growth on oxygen. The reductive tricarboxylic acid (rTCA) cycle is one of the most evolutionarily ancient and least ATP-demanding autotrophic pathways. On pages 563 and 559 of this issue, Mall et al. ( 2 ) and Nunoura et al. ( 3 ), respectively, uncover an unexpected ATP-conserving mechanism, and Pachiadaki et al. ( 4 ) report a surprising source of reducing equivalents in the rTCA cycle.

Published

2018

43. Investigations of Two Bidirectional Carbon Monoxide Dehydrogenases fromCarboxydothermus hydrogenoformansby Protein Film Electrochemistry

Author

Stephen W. Ragsdale, Fraser A. Armstrong, and Vincent Wang

Subjects

Stereochemistry, Carboxydothermus hydrogenoformans, Sulfides, Biochemistry, Isozyme, Article, chemistry.chemical_compound, Multienzyme Complexes, Catalytic Domain, Organic chemistry, Molecular Biology, Cyanates, Carbon Monoxide, Cyanides, biology, Organic Chemistry, Active site, Substrate (chemistry), Electrochemical Techniques, Carbon Dioxide, biology.organism_classification, Cyanate, Aldehyde Oxidoreductases, Kinetics, chemistry, Biocatalysis, biology.protein, Molecular Medicine, Cyclic voltammetry, Oxidation-Reduction, Thermoanaerobacterium, Carbon monoxide

Abstract

Carbon monoxide dehydrogenases (CODHs) catalyse the reversible conversion between CO and CO2. Several small molecules or ions are inhibitors and probes for different oxidation states of the unusual [Ni-4Fe-4S] cluster that forms the active site. The actions of these small probes on two enzymes-CODH ICh and CODH IICh-produced by Carboxydothermus hydrogenoformans have been studied by protein film voltammetry to compare their behaviour and to establish general characteristics. Whereas CODH ICh is, so far, the better studied of the two isozymes in terms of its electrocatalytic properties, it is CODH IICh that has been characterised by X-ray crystallography. The two isozymes, which share 58.3% sequence identity and 73.9% sequence similarity, show similar patterns of behaviour with regard to selective inhibition of CO2 reduction by CO (product) and cyanate, potent and selective inhibition of CO oxidation by cyanide, and the action of sulfide, which promotes oxidative inactivation of the enzyme. For both isozymes, rates of binding of substrate analogues CN- (for CO) and NCO- (for CO2) are orders of magnitude lower than turnover, a feature that is clearly revealed through hysteresis of cyclic voltammetry. Inhibition by CN- and CO is much stronger for CODH IICh than for CODH ICh, a property that has relevance for applying these enzymes as model catalysts in solar-driven CO2 reduction. © 2013 WILEY-VCH Verlag GmbH and Co. KGaA, Weinheim.

Published

2013

44. Frontiers, Opportunities, and Challenges in Biochemical and Chemical Catalysis of CO2 Fixation

Author

Andrew Bruce Bocarsly, Holger Dobbek, Rudolf K. Thauer, Robert H. Morris, Michel Dupuis, Archie R. Portis, Daniel L. DuBois, James G. Ferry, Grover L. Waldrop, Thomas B. Rauchfuss, Joost N. H. Reek, Cheryl A. Kerfeld, Etsuko Fujita, Paul J. A. Kenis, Russ Hille, John E. Bercaw, Stephen W. Ragsdale, Aaron M. Appel, Lance C. Seefeldt, Charles H. F. Peden, and Homogeneous and Supramolecular Catalysis (HIMS, FNWI)

Subjects

Natural resource economics, Ribulose-Bisphosphate Carboxylase, Cyanobacteria, Biochemistry, Sink (geography), Article, Catalysis, Multienzyme Complexes, Carbon-Nitrogen Ligases, Energy supply, geography, Carbon Monoxide, geography.geographical_feature_category, business.industry, Chemistry, Geothermal energy, Fossil fuel, Carbon fixation, Ocean acidification, General Chemistry, Carbon Dioxide, Aldehyde Oxidoreductases, Formate Dehydrogenases, Carbon, Biofuel, Metals, Biofuels, business, Energy source, Oxidation-Reduction

Abstract

Two major energy-related problems confront the world in the next 50 years. First, increased worldwide competition for gradually depleting fossil fuel reserves (derived from past photosynthesis) will lead to higher costs, both monetarily and politically. Second, atmospheric CO_2 levels are at their highest recorded level since records began. Further increases are predicted to produce large and uncontrollable impacts on the world climate. These projected impacts extend beyond climate to ocean acidification, because the ocean is a major sink for atmospheric CO2.1 Providing a future energy supply that is secure and CO_2-neutral will require switching to nonfossil energy sources such as wind, solar, nuclear, and geothermal energy and developing methods for transforming the energy produced by these new sources into forms that can be stored, transported, and used upon demand.

Published

2013

45. Radical reactions of thiamin pyrophosphate in 2-oxoacid oxidoreductases

Author

Steven O. Mansoorabadi, Stephen W. Ragsdale, and George H. Reed

Subjects

Iron-Sulfur Proteins, Models, Molecular, Free Radicals, Pyruvate Synthase, Stereochemistry, Coenzyme A, Biophysics, Electrons, Photochemistry, Biochemistry, Redox, Article, Cofactor, Analytical Chemistry, Electron transfer, chemistry.chemical_compound, Bacterial Proteins, Molecular Biology, chemistry.chemical_classification, Pyruvate synthase, biology, Chemistry, Electron acceptor, Biocatalysis, biology.protein, Thiamine Pyrophosphate, Oxidation-Reduction, Radical SAM, Pyruvate decarboxylase

Abstract

Thiamin pyrophosphate (TPP) is essential in carbohydrate metabolism in all forms of life. TPP-dependent decarboxylation reactions of 2-oxo-acid substrates result in enamine adducts between the thiazolium moiety of the coenzyme and decarboxylated substrate. These central enamine intermediates experience different fates from protonation in pyruvate decarboxylase to oxidation by the 2-oxoacid dehydrogenase complexes, the pyruvate oxidases, and 2-oxoacid oxidoreductases. Virtually all of the TPP-dependent enzymes, including pyruvate decarboxylase, can be assayed by 1-electron redox reactions linked to ferricyanide. Oxidation of the enamines is thought to occur via a 2-electron process in the 2-oxoacid dehydrogenase complexes, wherein acyl group transfer is associated with reduction of the disulfide of the lipoamide moiety. However, discrete 1-electron steps occur in the oxidoreductases, where one or more [4Fe-4S] clusters mediate the electron transfer reactions to external electron acceptors. These radical intermediates can be detected in the absence of the acyl-group acceptor, coenzyme A (CoASH). The π-electron system of the thiazolium ring stabilizes the radical. The extensively delocalized character of the radical is evidenced by quantitative analysis of nuclear hyperfine splitting tensors as detected by electron paramagnetic resonance (EPR) spectroscopy and by electronic structure calculations. The second electron transfer step is markedly accelerated by the presence of CoASH. While details of the second electron transfer step and its facilitation by CoASH remain elusive, expected redox properties of potential intermediates limit possible scenarios. This article is part of a Special Issue entitled: Radical SAM enzymes and Radical Enzymology.

Published

2012

46. Targeting methanogenesis with a nitrooxypropanol bullet

Author

Stephen W. Ragsdale

Subjects

0301 basic medicine, Multidisciplinary, Natural resource economics, business.industry, 030106 microbiology, Global warming, Fossil fuel, Climate change, Methane, Renewable energy, Carbon cycle, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Greenhouse gas, Commentaries, Environmental science, business, Energy source

Abstract

There is no substitute for dramatic reductions in the emissions of CO2 and other greenhouse gases to mitigate the negative consequences of climate change and, concurrently, to reduce ocean acidification. Mitigation, although technologically feasible, has been difficult to achieve for political, economic, and social reasons that may persist well into the future.National Research Council (1)Climate change is a global problem with grave implications: environmental, social, economic, political and for the distribution of goods. It represents one of the principal challenges facing humanity in our day. … There is an urgent need to develop policies so that, in the next few years, the emission of carbon dioxide and other highly polluting gases can be drastically reduced, for example, substituting for fossil fuels and developing sources of renewable energy.Pope Francis (2) Our planet is sustained by a web of interconnected and interdependent cycles (Fig. 1). Methane, an important component of the global carbon cycle, is widely used as a fuel by humans and as a carbon and energy source by microbes. Although invisible to our eyes, methane casts a dark specter through its proficiency to trap infrared radiation from the sun. As greenhouse gases, methane and carbon dioxide are recognized to be the … [↵][1]1Email: sragsdal{at}umich.edu. [1]: #xref-corresp-1-1

Published

2016

47. Transient B12-Dependent Methyltransferase Complexes Revealed by Small-Angle X-ray Scattering

Author

Stephen W. Ragsdale, Nozomi Ando, Güneş Bender, Catherine L. Drennan, Yan Kung, and Mehmet Can

Subjects

Iron-Sulfur Proteins, Models, Molecular, Cooperativity, Crystal structure, Biochemistry, Article, Catalysis, Protein–protein interaction, 03 medical and health sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Corrinoid, X-Ray Diffraction, Scattering, Small Angle, 030304 developmental biology, 0303 health sciences, Small-angle X-ray scattering, 030302 biochemistry & molecular biology, Isothermal titration calorimetry, Methyltransferases, General Chemistry, Vitamin B 12, Crystallography, chemistry, X-ray crystallography, Corrinoids, Thermodynamics, Protein Binding, Methyl group

Abstract

In the Wood–Ljungdahl carbon fixation pathway, protein–protein interactions between methyltransferase (MeTr) and corrinoid iron–sulfur protein (CFeSP) are required for the transfer of a methyl group. While crystal structures have been determined for MeTr and CFeSP both free and in complex, solution structures have not been established. Here, we examine the transient interactions between MeTr and CFeSP in solution using anaerobic small-angle X-ray scattering (SAXS) and present a global analysis approach for the deconvolution of heterogeneous mixtures formed by weakly interacting proteins. We further support this SAXS analysis with complementary results obtained by anaerobic isothermal titration calorimetry. Our results indicate that solution conditions affect the cooperativity with which CFeSP binds to MeTr, resulting in two distinct CFeSP/MeTr complexes with differing oligomeric compositions, both of which are active. One assembly resembles the CFeSP/MeTr complex observed crystallographically with 2:1 protein stoichiometry, while the other best fits a 1:1 CFeSP/MeTr arrangement. These results demonstrate the value of SAXS in uncovering the rich solution behavior of transient protein interactions visualized by crystallography.

Published

2012

48. Visualizing molecular juggling within a B12-dependent methyltransferase complex

Author

Tzanko Doukov, Nozomi Ando, Catherine L. Drennan, Stephen W. Ragsdale, Javier Seravalli, Güneş Bender, Yan Kung, and Leah C. Blasiak

Subjects

Iron-Sulfur Proteins, Models, Molecular, Stereochemistry, Crystallography, X-Ray, 010402 general chemistry, Methylation, Models, Biological, 01 natural sciences, Article, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, Folic Acid, Corrinoid, Moorella thermoacetica, Moorella, Binding site, 030304 developmental biology, 0303 health sciences, Binding Sites, Multidisciplinary, biology, Chemistry, Methyltransferase complex, Methyltransferases, biology.organism_classification, Protein Structure, Tertiary, 0104 chemical sciences, Vitamin B 12, Biocatalysis, biology.protein, Corrinoids, Protein Multimerization, Methyl group

Abstract

The first three-dimensional description of all the protein modules required for the activation, protection and catalytic steps of B12-dependent methyl transfer. Vitamin B12 (cobalamin) and its derivatives are important cofactors in a broad range of biological processes, including methionine biosynthesis in humans and CO2 fixation in acetogenic bacteria. In this manuscript, the authors structurally and biochemically characterize a large vitamin-B12-containing protein complex — the corrinoid iron–sulphur protein and its methyltransferase — from the model acetogen Moorella thermoacetica. The structures obtained in this study represent the first three-dimensional description of all the protein modules required for the activation, protection and catalytic steps of B12-dependent methyltransfer. Derivatives of vitamin B12 are used in methyl group transfer in biological processes as diverse as methionine synthesis in humans and CO2 fixation in acetogenic bacteria1,2,3. This seemingly straightforward reaction requires large, multimodular enzyme complexes that adopt multiple conformations to alternately activate, protect and perform catalysis on the reactive B12 cofactor. Crystal structures determined thus far have provided structural information for only fragments of these complexes4,5,6,7,8,9,10,11,12, inspiring speculation about the overall protein assembly and conformational movements inherent to activity. Here we present X-ray crystal structures of a complete 220 kDa complex that contains all enzymes responsible for B12-dependent methyl transfer, namely the corrinoid iron–sulphur protein and its methyltransferase from the model acetogen Moorella thermoacetica. These structures provide the first three-dimensional depiction of all protein modules required for the activation, protection and catalytic steps of B12-dependent methyl transfer. In addition, the structures capture B12 at multiple locations between its ‘resting’ and catalytic positions, allowing visualization of the dramatic protein rearrangements that enable methyl transfer and identification of the trajectory for B12 movement within the large enzyme scaffold. The structures are also presented alongside in crystallo spectroscopic data, which confirm enzymatic activity within crystals and demonstrate the largest known conformational movements of proteins in a crystalline state. Taken together, this work provides a model for the molecular juggling that accompanies turnover and helps explain why such an elaborate protein framework is required for such a simple, yet biologically essential reaction.

Published

2012

49. Comparison of the Mechanisms of Heme Hydroxylation by Heme Oxygenases-1 and -2: Kinetic and Cryoreduction Studies

Author

Angela S. Fleischhacker, Stephen W. Ragsdale, Ireena Bagai, Brian M. Hoffman, and Roman Davydov

Subjects

0301 basic medicine, Oxygenase, Stereochemistry, Heme, 010402 general chemistry, Photochemistry, Hydroxylation, 01 natural sciences, Biochemistry, Redox, Article, law.invention, 03 medical and health sciences, chemistry.chemical_compound, law, Moiety, Humans, Electron paramagnetic resonance, Biliverdin, Electron Spin Resonance Spectroscopy, 0104 chemical sciences, Heme oxygenase, Cold Temperature, Oxygen, Kinetics, 030104 developmental biology, chemistry, Heme Oxygenase (Decyclizing), Oxidation-Reduction, Heme Oxygenase-1

Abstract

The two isoforms of human heme oxygenase (HO1 and HO2) catalyze oxidative degradation of heme to biliverdin, Fe, and CO. Unlike HO1, HO2 contains two C-terminal heme regulatory motifs (HRMs) centered at Cys265 and Cys282 that act as redox switches and, in their reduced dithiolate state, bind heme (Fleischhacker et al., Biochemistry , 2015 , 54 , 2693 - 2708 ). Here, we describe cryoreduction/annealing and electron paramagnetic resonance spectroscopic experiments to study the structural features of the oxyheme moiety in HO2 and to elucidate the initial steps in heme degradation. We conclude that the same mechanism of heme hydroxylation to α-meso-hydroxyheme is employed by both isoforms and that the HRMs do not affect the physicochemical properties of the oxy-Fe(II) and HOO-Fe(III) states of HO2. However, the absorption spectrum of oxy-Fe(II)-HO2 is slightly blue-shifted relative to that of HO1. Furthermore, heme hydroxylation proceeds three times more slowly, and the oxy-Fe(II) state is 100-fold less stable in HO2 than in HO1. These distinctions are attributed to slight structural variances in the two proteins, including differences in equilibrium between open versus closed conformations. Kinetic studies revealed that heme oxygenation by HO2 occurs solely at the catalytic core in that a variant of HO2 lacking the C-terminal HRM domain exhibits the same specific activity as one containing both the catalytic core and HRM domain; furthermore, a truncated variant containing only the HRM region binds but cannot oxidize heme. In summary, HO1 and HO2 share similar catalytic mechanisms, and the HRMs do not play a direct role in the HO2 catalytic cycle.

Published

2015

50. Thiol/Disulfide Redox Switches in the Regulation of Heme Binding to Proteins

Author

Stephen W. Ragsdale and Li Yi

Subjects

BK channel, Heme binding, Physiology, Clinical Biochemistry, Heme, Plasma protein binding, Models, Biological, Biochemistry, Redox, chemistry.chemical_compound, Disulfides, Molecular Biology, Ion channel, General Environmental Science, chemistry.chemical_classification, biology, Proteins, Cell Biology, Forum Review Articles, Non-innocent ligand, chemistry, biology.protein, Thiol, General Earth and Planetary Sciences, Oxidation-Reduction, Protein Binding

Abstract

This review focuses on thiol/disulfide redox switches that regulate heme binding to proteins and modulate their activities. The importance of redox switches in metabolic regulation and the general mechanism by which redox switches modulate activity are discussed. Methods are described to characterize heme-binding sites and to assess their physiological relevance. For thiol/disulfide interconversion to regulate activity of a system, the redox process must be reversible at the ambient redox potentials found within the cell; thus, methods (and their limitations) are discussed that can address the physiological relevance of a redox switch. We review recent results that define a mechanism for how thiol/disulfide redox switches that control heme binding can regulate the activities of an enzyme, heme oxygenase-2, and an ion channel, the BK potassium channel. The redox switches on these proteins are composed of different types of Cys-containing motifs that have opposite effects on heme affinity, yet have complementary effects on hypoxia sensing. Finally, a model is proposed to describe how the redox switches on heme oxygenase-2 and the BK channel form an interconnected system that is poised to sense oxygen levels in the bloodstream and to elicit the hypoxic response when oxygen levels drop below a threshold value. Antioxid. Redox Signal. 14, 1039–1047.

Published

2011