Your search keyword '"Shepard EM"' showing total 30 results

1. Role of ammonia-lyases in the synthesis of the dithiomethylamine ligand during [FeFe]-hydrogenase maturation.

Author

Pagnier A, Balci B, Shepard EM, Yang H, Drena A, Holliday GL, Hoffman BM, Broderick WE, and Broderick JB

Subjects

Ammonia-Lyases metabolism, Ammonia-Lyases genetics, Ligands, Bacterial Proteins metabolism, Bacterial Proteins genetics, Electron Spin Resonance Spectroscopy, Operon, Methylamines metabolism, Hydrogenase metabolism, Hydrogenase genetics, Iron-Sulfur Proteins metabolism, Iron-Sulfur Proteins genetics

Abstract

The generation of an active [FeFe]-hydrogenase requires the synthesis of a complex metal center, the H-cluster, by three dedicated maturases: the radical S-adenosyl-l-methionine (SAM) enzymes HydE and HydG, and the GTPase HydF. A key step of [FeFe]-hydrogenase maturation is the synthesis of the dithiomethylamine (DTMA) bridging ligand, a process recently shown to involve the aminomethyl-lipoyl-H-protein from the glycine cleavage system, whose methylamine group originates from serine and ammonium. Here we use functional assays together with electron paramagnetic resonance and electron-nuclear double resonance spectroscopies to show that serine or aspartate together with their respective ammonia-lyase enzymes can provide the nitrogen for DTMA biosynthesis during in vitro [FeFe]-hydrogenase maturation. We also report bioinformatic analysis of the hyd operon, revealing a strong association with genes encoding ammonia-lyases, suggesting important biochemical and metabolic connections. Together, our results provide evidence that ammonia-lyases play an important role in [FeFe]-hydrogenase maturation by delivering the ammonium required for dithiomethylamine ligand synthesis., Competing Interests: Conflicts of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. Impact of mineral and non-mineral sources of iron and sulfur on the metalloproteome of Methanosarcina barkeri .

Author

Larson J, Tokmina-Lukaszewska M, Payne D, Spietz RL, Fausset H, Alam MG, Brekke BK, Pauley J, Hasenoehrl EJ, Shepard EM, Boyd ES, and Bothner B

Subjects

Archaeal Proteins metabolism, Archaeal Proteins genetics, Minerals metabolism, Proteomics, Sulfur metabolism, Iron metabolism, Methanosarcina barkeri metabolism, Methanosarcina barkeri growth & development, Metalloproteins metabolism, Sulfides metabolism

Abstract

Methanogens often inhabit sulfidic environments that favor the precipitation of transition metals such as iron (Fe) as metal sulfides, including mackinawite (FeS) and pyrite (FeS 2 ). These metal sulfides have historically been considered biologically unavailable. Nonetheless, methanogens are commonly cultivated with sulfide (HS - ) as a sulfur source, a condition that would be expected to favor metal precipitation and thus limit metal availability. Recent studies have shown that methanogens can access Fe and sulfur (S) from FeS and FeS 2 to sustain growth. As such, medium supplied with FeS 2 should lead to higher availability of transition metals when compared to medium supplied with HS - . Here, we examined how transition metal availability under sulfidic (i.e., cells provided with HS - as sole S source) versus non-sulfidic (cells provided with FeS 2 as sole S source) conditions impact the metalloproteome of Methanosarcina barkeri Fusaro. To achieve this, we employed size exclusion chromatography coupled with inductively coupled plasma mass spectrometry and shotgun proteomics. Significant changes were observed in the composition and abundance of iron, cobalt, nickel, zinc, and molybdenum proteins. Among the differences were alterations in the stoichiometry and abundance of multisubunit protein complexes involved in methanogenesis and electron transport chains. Our data suggest that M. barkeri utilizes the minimal iron-sulfur cluster complex and canonical cysteine biosynthesis proteins when grown on FeS 2 but uses the canonical Suf pathway in conjunction with the tRNA-Sep cysteine pathway for iron-sulfur cluster and cysteine biosynthesis under sulfidic growth conditions.IMPORTANCEProteins that catalyze biochemical reactions often require transition metals that can have a high affinity for sulfur, another required element for life. Thus, the availability of metals and sulfur are intertwined and can have large impacts on an organismismal biochemistry. Methanogens often occupy anoxic, sulfide-rich (euxinic) environments that favor the precipitation of transition metals as metal sulfides, thereby creating presumed metal limitation. Recently, several methanogens have been shown to acquire iron and sulfur from pyrite, an abundant iron-sulfide mineral that was traditionally considered to be unavailable to biology. The work presented here provides new insights into the distribution of metalloproteins, and metal uptake of Methanosarcina barkeri Fusaro grown under euxinic or pyritic growth conditions. Thorough characterizations of this methanogen under different metal and sulfur conditions increase our understanding of the influence of metal availability on methanogens, and presumably other anaerobes, that inhabit euxinic environments., Competing Interests: The authors declare no conflict of interest.

Published

2024

3. A shift between mineral and nonmineral sources of iron and sulfur causes proteome-wide changes in Methanosarcina barkeri .

Author

Fausset H, Spietz RL, Cox S, Cooper G, Spurzem S, Tokmina-Lukaszewska M, DuBois J, Broderick JB, Shepard EM, Boyd ES, and Bothner B

Subjects

Iron metabolism, Minerals metabolism, Sulfur metabolism, Ferrous Compounds metabolism, Methanosarcina barkeri genetics, Methanosarcina barkeri metabolism, Proteome metabolism

Abstract

Iron (Fe) and sulfur (S) are required elements for life, and changes in their availability can limit the ecological distribution and function of microorganisms. In anoxic environments, soluble Fe typically exists as ferrous iron [Fe(II)] and S as sulfide (HS - ). These species exhibit a strong affinity that ultimately drives the formation of sedimentary pyrite (FeS 2 ). Recently, paradigm-shifting studies indicate that Fe and S in FeS 2 can be made bioavailable by methanogens through a reductive dissolution process. However, the impact of the utilization of FeS 2 , as opposed to canonical Fe and S sources, on the phenotype of cells is not fully understood. Here, shotgun proteomics was utilized to measure changes in the phenotype of Methanosarcina barkeri MS grown with FeS 2 , Fe(II)/HS - , or Fe(II)/cysteine. Shotgun proteomics tracked 1,019 proteins overall, with 307 observed to change between growth conditions. Functional characterization and pathway analyses revealed these changes to be systemic and largely tangential to Fe/S metabolism. As a final step, the proteomics data were viewed with respect to previously collected transcriptomics data to deepen the analysis. Presented here is evidence that M. barkeri adopts distinct phenotypes to exploit specific sources of Fe and S in its environment. This is supported by observed protein abundance changes across broad categories of cellular biology. DNA adjacent metabolism, central carbon metabolism methanogenesis, metal trafficking, quorum sensing, and porphyrin biosynthesis pathways are all features in the phenotypic differentiation. Differences in trace metal availability attributed to complexation with HS - , either as a component of the growth medium [Fe(II)/HS - ] or generated through reduction of FeS 2 , were likely a major factor underpinning these phenotypic differences.IMPORTANCEThe methanogenic archaeon Methanosarcina barkeri holds great potential for industrial bio-mining and energy generation technologies. Much of the biochemistry of this microbe is poorly understood, and its characterization will provide a glimpse into biological processes that evolved close to life's origin. The discovery of its ability to extract iron and sulfur from bulk, solid-phase minerals shifted a longstanding paradigm that these elements were inaccessible to biological systems. The full elucidation of this process has the potential to help scientists and engineers extract valuable metals from low-grade ore and mine waste generating energy in the form of methane while doing so., Competing Interests: The authors declare no conflict of interest.

Published

2024

4. Semisynthetic maturation of [FeFe]-hydrogenase using [Fe 2 (μ-SH) 2 (CN) 2 (CO) 4 ] 2- : key roles for HydF and GTP.

Author

Balci B, O'Neill RD, Shepard EM, Pagnier A, Marlott A, Mock MT, Broderick WE, and Broderick JB

Subjects

Electron Spin Resonance Spectroscopy, Guanosine Triphosphate, Hydrogenase metabolism, Iron-Sulfur Proteins

Abstract

Here we describe maturation of the [FeFe]-hydrogenase from its [4Fe-4S]-bound precursor state by using the synthetic complex [Fe 2 (μ-SH) 2 (CN) 2 (CO) 4 ] 2- together with HydF and components of the glycine cleavage system, but in the absence of the maturases HydE and HydG. This semisynthetic and fully-defined maturation provides new insights into the nature of H-cluster biosynthesis.

Published

2023

5. [FeFe]-Hydrogenase In Vitro Maturation.

Author

Pagnier A, Balci B, Shepard EM, Broderick WE, and Broderick JB

Subjects

Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

The [FeFe]-hydrogenase H-cluster is a complex organometallic cofactor whose assembly and installation requires three dedicated accessory proteins referred to as HydE, HydF, and HydG. The roles of these maturases and the precise mechanisms by which they synthesize and insert the H-cluster are not fully understood. This Minireview will focus on new insights into the [FeFe]-hydrogenase maturation process that have been provided by in vitro approaches in which the biosynthetic pathway has been partially or fully reconstructed using semisynthetic and enzyme-based approaches. Specifically, the application of these in vitro, semisynthetic, and fully defined approaches has shed light on the roles of individual maturation enzymes, the nature of H-cluster assembly intermediates, the molecular precursors of H-cluster ligands, and the sequence of steps involved in [FeFe]-hydrogenase maturation., (© 2022 Wiley-VCH GmbH.)

Published

2022

6. Proteomic Analysis of Methanococcus voltae Grown in the Presence of Mineral and Nonmineral Sources of Iron and Sulfur.

Author

Steward KF, Payne D, Kincannon W, Johnson C, Lensing M, Fausset H, Németh B, Shepard EM, Broderick WE, Broderick JB, Dubois J, and Bothner B

Subjects

Iron metabolism, Minerals metabolism, Proteomics, Sulfur metabolism, Iron-Sulfur Proteins metabolism, Methanococcus metabolism

Abstract

Iron sulfur (Fe-S) proteins are essential and ubiquitous across all domains of life, yet the mechanisms underpinning assimilation of iron (Fe) and sulfur (S) and biogenesis of Fe-S clusters are poorly understood. This is particularly true for anaerobic methanogenic archaea, which are known to employ more Fe-S proteins than other prokaryotes. Here, we utilized a deep proteomics analysis of Methanococcus voltae A3 cultured in the presence of either synthetic pyrite (FeS 2 ) or aqueous forms of ferrous iron and sulfide to elucidate physiological responses to growth on mineral or nonmineral sources of Fe and S. The liquid chromatography-mass spectrometry (LCMS) shotgun proteomics analysis included 77% of the predicted proteome. Through a comparative analysis of intra- and extracellular proteomes, candidate proteins associated with FeS 2 reductive dissolution, Fe and S acquisition, and the subsequent transport, trafficking, and storage of Fe and S were identified. The proteomic response shows a large and balanced change, suggesting that M. voltae makes physiological adjustments involving a range of biochemical processes based on the available nutrient source. Among the proteins differentially regulated were members of core methanogenesis, oxidoreductases, membrane proteins putatively involved in transport, Fe-S binding ferredoxin and radical S-adenosylmethionine proteins, ribosomal proteins, and intracellular proteins involved in Fe-S cluster assembly and storage. This work improves our understanding of ancient biogeochemical processes and can support efforts in biomining of minerals. IMPORTANCE Clusters of iron and sulfur are key components of the active sites of enzymes that facilitate microbial conversion of light or electrical energy into chemical bonds. The proteins responsible for transporting iron and sulfur into cells and assembling these elements into metal clusters are not well understood. Using a microorganism that has an unusually high demand for iron and sulfur, we conducted a global investigation of cellular proteins and how they change based on the mineral forms of iron and sulfur. Understanding this process will answer questions about life on early earth and has application in biomining and sustainable sources of energy.

Published

2022

7. [FeFe]-Hydrogenase: Defined Lysate-Free Maturation Reveals a Key Role for Lipoyl-H-Protein in DTMA Ligand Biosynthesis.

Author

Pagnier A, Balci B, Shepard EM, Yang H, Warui DM, Impano S, Booker SJ, Hoffman BM, Broderick WE, and Broderick JB

Subjects

Electron Spin Resonance Spectroscopy, Ligands, S-Adenosylmethionine, Hydrogenase metabolism, Iron-Sulfur Proteins

Abstract

Maturation of [FeFe]-hydrogenase (HydA) involves synthesis of a CO, CN - , and dithiomethylamine (DTMA)-coordinated 2Fe subcluster that is inserted into HydA to make the active hydrogenase. This process requires three maturation enzymes: the radical S-adenosyl-l-methionine (SAM) enzymes HydE and HydG, and the GTPase HydF. In vitro maturation with purified maturation enzymes has been possible only when clarified cell lysate was added, with the lysate presumably providing essential components for DTMA synthesis and delivery. Here we report maturation of [FeFe]-hydrogenase using a fully defined system that includes components of the glycine cleavage system (GCS), but no cell lysate. Our results reveal for the first time an essential role for the aminomethyl-lipoyl-H-protein of the GCS in hydrogenase maturation and the synthesis of the DTMA ligand of the H-cluster. In addition, we show that ammonia is the source of the bridgehead nitrogen of DTMA., (© 2022 Wiley-VCH GmbH.)

Published

2022

8. The B 12 -independent glycerol dehydratase activating enzyme from Clostridium butyricum cleaves SAM to produce 5'-deoxyadenosine and not 5'-deoxy-5'-(methylthio)adenosine.

Author

Walls WG, Moody JD, McDaniel EC, Villanueva M, Shepard EM, Broderick WE, and Broderick JB

Subjects

Vitamin B 12 chemistry, Bacterial Proteins chemistry, Clostridium butyricum enzymology, Deoxyadenosines chemistry, Hydro-Lyases chemistry, S-Adenosylmethionine chemistry

Abstract

Glycerol dehydratase activating enzyme (GD-AE) is a radical S-adenosyl-l-methionine (SAM) enzyme that installs a catalytically essential amino acid backbone radical onto glycerol dehydratase in bacteria under anaerobic conditions. Although GD-AE is closely homologous to other radical SAM activases that have been shown to cleave the S-C(5') bond of SAM to produce 5'-deoxyadenosine (5'-dAdoH) and methionine, GD-AE from Clostridium butyricum has been reported to instead cleave the S-C(γ) bond of SAM to yield 5'-deoxy-5'-(methylthio)adenosine (MTA). Here we re-investigate the SAM cleavage reaction catalyzed by GD-AE and show that it produces the widely observed 5'-dAdoH, and not the less conventional product MTA., (Copyright © 2021. Published by Elsevier Inc.)

Published

2022

9. Examining Pathways of Iron and Sulfur Acquisition, Trafficking, Deployment, and Storage in Mineral-Grown Methanogen Cells.

Author

Payne D, Shepard EM, Spietz RL, Steward K, Brumfield S, Young M, Bothner B, Broderick WE, Broderick JB, and Boyd ES

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Biological Transport, Carrier Proteins, Electron Spin Resonance Spectroscopy, Gene Expression Regulation, Bacterial, Iron chemistry, Metal Nanoparticles, Sulfides chemistry, Iron metabolism, Methanococcus metabolism, Sulfides metabolism

Abstract

Methanogens have a high demand for iron (Fe) and sulfur (S); however, little is known of how they acquire, deploy, and store these elements and how this, in turn, affects their physiology. Methanogens were recently shown to reduce pyrite (FeS 2 ), generating aqueous iron sulfide (FeS aq ) clusters that are likely assimilated as a source of Fe and S. Here, we compared the phenotypes of Methanococcus voltae grown with FeS 2 or ferrous iron [Fe(II)] and sulfide (HS - ). FeS 2 -grown cells are 33% smaller yet have 193% more Fe than Fe(II)/HS - -grown cells. Whole-cell electron paramagnetic resonance revealed similar distributions of paramagnetic Fe, although FeS 2 -grown cells showed a broad spectral feature attributed to intracellular thioferrate-like nanoparticles. Differential proteomic analyses showed similar expression of core methanogenesis enzymes, indicating that Fe and S source does not substantively alter the energy metabolism of cells. However, a homolog of the Fe(II) transporter FeoB and its putative transcriptional regulator DtxR were up-expressed in FeS 2 -grown cells, suggesting that cells sense Fe(II) limitation. Two homologs of IssA, a protein putatively involved in coordinating thioferrate nanoparticles, were also up-expressed in FeS 2 -grown cells. We interpret these data to indicate that, in FeS 2 -grown cells, DtxR cannot sense Fe(II) and therefore cannot downregulate FeoB. We suggest this is due to the transport of Fe(II) complexed with sulfide (FeS aq ), leading to excess Fe that is sequestered by IssA as a thioferrate-like species. This model provides a framework for the design of targeted experiments aimed at further characterizing Fe acquisition and homeostasis in M. voltae and other methanogens. IMPORTANCE FeS 2 is the most abundant sulfide mineral in the Earth's crust and is common in environments inhabited by methanogenic archaea. FeS 2 can be reduced by methanogens, yielding aqueous FeS aq clusters that are thought to be a source of Fe and S. Here, we show that growth of Methanococcus voltae on FeS 2 results in smaller cell size and higher Fe content per cell, with Fe likely stored intracellularly as thioferrate-like nanoparticles. Fe(II) transporters and storage proteins were upregulated in FeS 2 -grown cells. These responses are interpreted to result from cells incorrectly sensing Fe(II) limitation due to assimilation of Fe(II) as FeS aq . These findings have implications for our understanding of how Fe/S availability influences methanogen physiology and the biogeochemical cycling of these elements.

Published

2021

10. HydG, the "dangler" iron, and catalytic production of free CO and CN - : implications for [FeFe]-hydrogenase maturation.

Author

Shepard EM, Impano S, Duffus BR, Pagnier A, Duschene KS, Betz JN, Byer AS, Galambas A, McDaniel EC, Watts H, McGlynn SE, Peters JW, Broderick WE, and Broderick JB

Subjects

Biocatalysis, Iron chemistry, Iron metabolism, Catalysis, Bacterial Proteins metabolism, Bacterial Proteins chemistry, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Carbon Monoxide chemistry, Carbon Monoxide metabolism, Clostridium acetobutylicum enzymology, Clostridium acetobutylicum metabolism

Abstract

The organometallic H-cluster of the [FeFe]-hydrogenase consists of a [4Fe-4S] cubane bridged via a cysteinyl thiolate to a 2Fe subcluster ([2Fe]H) containing CO, CN-, and dithiomethylamine (DTMA) ligands. The H-cluster is synthesized by three dedicated maturation proteins: the radical SAM enzymes HydE and HydG synthesize the non-protein ligands, while the GTPase HydF serves as a scaffold for assembly of [2Fe]H prior to its delivery to the [FeFe]-hydrogenase containing the [4Fe-4S] cubane. HydG uses l-tyrosine as a substrate, cleaving it to produce p-cresol as well as the CO and CN- ligands to the H-cluster, although there is some question as to whether these are formed as free diatomics or as part of a [Fe(CO)2(CN)] synthon. Here we show that Clostridium acetobutylicum (C.a.) HydG catalyzes formation of multiple equivalents of free CO at rates comparable to those for CN- formation. Free CN- is also formed in excess molar equivalents over protein. A g = 8.9 EPR signal is observed for C.a. HydG reconstituted to load the 5th "dangler" iron of the auxiliary [4Fe-4S][FeCys] cluster and is assigned to this "dangler-loaded" cluster state. Free CO and CN- formation and the degree of activation of [FeFe]-hydrogenase all occur regardless of dangler loading, but are increased 10-35% in the dangler-loaded HydG; this indicates the dangler iron is not essential to this process but may affect relevant catalysis. During HydG turnover in the presence of myoglobin, the g = 8.9 signal remains unchanged, indicating that a [Fe(CO)2(CN)(Cys)] synthon is not formed at the dangler iron. Mutation of the only protein ligand to the dangler iron, H272, to alanine nearly completely abolishes both free CO formation and hydrogenase activation, however results show this is not due solely to the loss of the dangler iron. In experiments with wild type and H272A HydG, and with different degrees of dangler loading, we observe a consistent correlation between free CO/CN- formation and hydrogenase activation. Taken in full, our results point to free CO/CN-, but not an [Fe(CO)2(CN)(Cys)] synthon, as essential species in hydrogenase maturation.

Published

2021

11. S -Adenosyl-l-ethionine is a Catalytically Competent Analog of S -Adenosyl-l-methione (SAM) in the Radical SAM Enzyme HydG.

Author

Impano S, Yang H, Shepard EM, Swimley R, Pagnier A, Broderick WE, Hoffman BM, and Broderick JB

Subjects

Biocatalysis, Electron Spin Resonance Spectroscopy, Escherichia coli Proteins chemistry, Ethionine analogs & derivatives, Ethionine chemistry, Free Radicals chemistry, Free Radicals metabolism, Models, Molecular, Molecular Structure, Trans-Activators chemistry, Escherichia coli Proteins metabolism, Ethionine metabolism, Trans-Activators metabolism

Abstract

Radical S-adenosyl-l-methionine (SAM) enzymes initiate biological radical reactions with the 5'-deoxyadenosyl radical (5'-dAdo•). A [4Fe-4S] + cluster reductively cleaves SAM to form the Ω organometallic intermediate in which the 5'-deoxyadenosyl moiety is directly bound to the unique iron of the [4Fe-4S] cluster, with subsequent liberation of 5'-dAdo•. Here we present synthesis of the SAM analog S-adenosyl-l-ethionine (SAE) and show SAE is a mechanistically-equivalent SAM-alternative for HydG, both supporting enzymatic turnover of substrate tyrosine and forming the organometallic intermediate Ω. Photolysis of SAE bound to HydG forms an ethyl radical trapped in the active site. The ethyl radical withstands prolonged storage at 77 K and its EPR signal is only partially lost upon annealing at 100 K, making it significantly less reactive than the methyl radical formed by SAM photolysis. Upon annealing above 77K, the ethyl radical adds to the [4Fe-4S] 2+ cluster, generating an ethyl-[4Fe-4S] 3+ organometallic species termed Ω E .

Published

2021

12. Active-Site Controlled, Jahn-Teller Enabled Regioselectivity in Reductive S-C Bond Cleavage of S -Adenosylmethionine in Radical SAM Enzymes.

Author

Impano S, Yang H, Jodts RJ, Pagnier A, Swimley R, McDaniel EC, Shepard EM, Broderick WE, Broderick JB, and Hoffman BM

Subjects

Bacterial Proteins chemistry, Bacterial Proteins radiation effects, Biocatalysis, Catalytic Domain, Clostridium acetobutylicum enzymology, Density Functional Theory, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins radiation effects, Light, Models, Chemical, Molecular Structure, Oxidation-Reduction radiation effects, Oxidoreductases Acting on Sulfur Group Donors radiation effects, Photolysis, S-Adenosylmethionine radiation effects, Thermotoga maritima enzymology, Oxidoreductases Acting on Sulfur Group Donors chemistry, S-Adenosylmethionine chemistry

Abstract

Catalysis by canonical radical S -adenosyl-l-methionine (SAM) enzymes involves electron transfer (ET) from [4Fe-4S] + to SAM, generating an R 3 S 0 radical that undergoes regioselective homolytic reductive cleavage of the S-C5' bond to generate the 5'-dAdo· radical. However, cryogenic photoinduced S-C bond cleavage has regioselectively yielded either 5'-dAdo· or ·CH 3 , and indeed, each of the three SAM S-C bonds can be regioselectively cleaved in an RS enzyme. This diversity highlights a longstanding central question: what controls regioselective homolytic S-C bond cleavage upon SAM reduction? We here provide an unexpected answer, founded on our observation that photoinduced S-C bond cleavage in multiple canonical RS enzymes reveals two enzyme classes: in one, photolysis forms 5'-dAdo·, and in another it forms ·CH 3 . The identity of the cleaved S-C bond correlates with SAM ribose conformation but not with positioning and orientation of the sulfonium center relative to the [4Fe-4S] cluster. We have recognized the reduced-SAM R 3 S 0 radical is a ( 2 E ) state with its antibonding unpaired electron in an orbital doublet, which renders R 3 S 0 Jahn-Teller (JT)-active and therefore subject to vibronically induced distortion. Active-site forces induce a JT distortion that localizes the odd electron in a single priority S-C antibond, which undergoes regioselective cleavage. In photolytic cleavage those forces act through control of the ribose conformation and are transmitted to the sulfur via the S-C5' bond, but during catalysis thermally induced conformational changes that enable ET from a cluster iron generate dominant additional forces that specifically select S-C5' for cleavage. This motion also can explain how 5'-dAdo· subsequently forms the organometallic intermediate Ω.

Published

2021

13. Radical SAM Enzyme Spore Photoproduct Lyase: Properties of the Ω Organometallic Intermediate and Identification of Stable Protein Radicals Formed during Substrate-Free Turnover.

Author

Pagnier A, Yang H, Jodts RJ, James CD, Shepard EM, Impano S, Broderick WE, Hoffman BM, and Broderick JB

Subjects

Catalytic Domain, Density Functional Theory, Deoxyadenosines chemistry, Electron Spin Resonance Spectroscopy, Geobacillus enzymology, Iron-Sulfur Proteins chemistry, Models, Molecular, Proteins genetics, Proteins metabolism, S-Adenosylmethionine metabolism, Free Radicals chemistry, Proteins chemistry, S-Adenosylmethionine chemistry

Abstract

Spore photoproduct lyase is a radical S -adenosyl-l-methionine (SAM) enzyme with the unusual property that addition of SAM to the [4Fe-4S] 1+ enzyme absent substrate results in rapid electron transfer to SAM with accompanying homolytic S-C5' bond cleavage. Herein, we demonstrate that this unusual reaction forms the organometallic intermediate Ω in which the unique Fe atom of the [4Fe-4S] cluster is bound to C5' of the 5'-deoxyadenosyl radical (5'-dAdo • ). During catalysis, homolytic cleavage of the Fe-C5' bond liberates 5'-dAdo • for reaction with substrate, but here, we use Ω formation without substrate to determine the thermal stability of Ω. The reaction of Geobacillus thermodenitrificans SPL ( Gt SPL) with SAM forms Ω within ∼15 ms after mixing. By monitoring the decay of Ω through rapid freeze-quench trapping at progressively longer times we find an ambient temperature decay time of the Ω Fe-C5' bond of τ ≈ 5-6 s, likely shortened by enzymatic activation as is the case with the Co-C5' bond of B 12 . We have further used hand quenching at times up to 10 min, and thus with multiple SAM turnovers, to probe the fate of the 5'-dAdo • radical liberated by Ω. In the absence of substrate, Ω undergoes low-probability conversion to a stable protein radical. The WT enzyme with valine at residue 172 accumulates a Val • ; mutation of Val172 to isoleucine or cysteine results in accumulation of an Ile • or Cys • radical, respectively. The structures of the radical in WT, V172I, and V172C variants have been established by detailed EPR/DFT analyses.

Published

2020

14. Natural selection based on coordination chemistry: computational assessment of [4Fe-4S]-maquettes with non-coded amino acids.

Author

Szilagyi RK, Hanscam R, Shepard EM, and McGlynn SE

Abstract

Cysteine is the only coded amino acid in biology that contains a thiol functional group. Deprotonated thiolate is essential for anchoring iron-sulfur ([Fe-S]) clusters, as prosthetic groups to the protein matrix. [Fe-S] metalloproteins and metalloenzymes are involved in biological electron transfer, radical chemistry, small molecule activation and signalling. These are key metabolic and regulatory processes that would likely have been present in the earliest organisms. In the context of emergence of life theories, the selection and evolution of the cysteine-specific R-CH 2 -SH side chain is a fascinating question to confront. We undertook a computational [4Fe-4S]-maquette modelling approach to evaluate how side chain length can influence [Fe-S] cluster binding and stability in short 7-mer and long 16-mer peptides, which contained either thioglycine, cysteine or homocysteine. Force field-based molecular dynamics simulations for [4Fe-4S] cluster nest formation were supplemented with density functional theory calculations of a ligand-exchange reaction between a preassembled cluster and the peptide. Secondary structure analysis revealed that peptides with cysteine are found with greater frequency nested to bind preformed [4Fe-4S] clusters. Additionally, the presence of the single methylene group in cysteine ligands mitigates the steric bulk, maintains the H-bonding and dipole network, and provides covalent Fe-S(thiolate) bonds that together create the optimal electronic and geometric structural conditions for [4Fe-4S] cluster binding compared to thioglycine or homocysteine ligands. Our theoretical work forms an experimentally testable hypothesis of the natural selection of cysteine through coordination chemistry., Competing Interests: We have no competing interests., (© 2019 The Author(s).)

Published

2019

15. Photoinduced Electron Transfer in a Radical SAM Enzyme Generates an S -Adenosylmethionine Derived Methyl Radical.

Author

Yang H, Impano S, Shepard EM, James CD, Broderick WE, Broderick JB, and Hoffman BM

Subjects

Acetyltransferases chemistry, Acetyltransferases metabolism, Catalytic Domain, Electron Transport, Enzyme Activation, Hydrolases metabolism, Methane chemistry, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Photolysis, Hydrolases chemistry, Iron-Sulfur Proteins chemistry, Methane analogs & derivatives, S-Adenosylmethionine chemistry

Abstract

Radical SAM (RS) enzymes use S -adenosyl-l-methionine (SAM) and a [4Fe-4S] cluster to initiate a broad spectrum of radical transformations throughout all kingdoms of life. We report here that low-temperature photoinduced electron transfer from the [4Fe-4S] 1+ cluster to bound SAM in the active site of the hydrogenase maturase RS enzyme, HydG, results in specific homolytic cleavage of the S-CH 3 bond of SAM, rather than the S-C5' bond as in the enzyme-catalyzed (thermal) HydG reaction. This result is in stark contrast to a recent report in which photoinduced ET in the RS enzyme pyruvate formate-lyase activating enzyme cleaved the S-C5' bond to generate a 5'-deoxyadenosyl radical, and provides the first direct evidence for homolytic S-CH 3 bond cleavage in a RS enzyme. Photoinduced ET in HydG generates a trapped • CH 3 radical, as well as a small population of an organometallic species with an Fe-CH 3 bond, denoted Ω M . The • CH 3 radical is surprisingly found to exhibit rotational diffusion in the HydG active site at temperatures as low as 40 K, and is rapidly quenched: whereas 5'-dAdo • is stable indefinitely at 77 K, • CH 3 quenches with a half-time of ∼2 min at this temperature. The rapid quenching and rotational/translational freedom of • CH 3 shows that enzymes would be unable to harness this radical as a regio- and stereospecific H atom abstractor during catalysis, in contrast to the exquisite control achieved with the enzymatically generated 5'-dAdo • .

Published

2019

16. Radical S-adenosylmethionine maquette chemistry: Cx 3 Cx 2 C peptide coordinated redox active [4Fe-4S] clusters.

Author

Galambas A, Miller J, Jones M, McDaniel E, Lukes M, Watts H, Copié V, Broderick JB, Szilagyi RK, and Shepard EM

Subjects

Cysteine chemistry, Ferredoxins chemistry, Iron-Sulfur Proteins chemistry, C-Peptide chemistry, S-Adenosylmethionine chemistry

Abstract

The synthesis and characterization of short peptide-based maquettes of metalloprotein active sites facilitate an inquiry into their structure/function relationships and evolution. The [4Fe-4S]-maquettes of bacterial ferredoxin metalloproteins (Fd) have been used in the past to engineer redox active centers into artificial metalloenzymes. The novelty of our study is the application of maquettes to the superfamily of [4Fe-4S] cluster and S-adenosylmethionine-dependent radical metalloenzymes (radical SAM). The radical SAM superfamily enzymes contain site-differentiated, redox active [4Fe-4S] clusters coordinated to Cx 3 Cx 2 C or related motifs, which is in contrast to the Cx 2 Cx 2 C motif found in bacterial ferredoxins (Fd). Under an optimized set of experimental conditions, a high degree of reconstitution (80-100%) was achieved for both radical SAM- and Fd-maquettes. Negligible chemical speciation was observed for all sequences, with predominantly [4Fe-4S] 2+ for the 'as-reconstituted' state. However, the reduction of [4Fe-4S] 2+ -maquettes provides low conversion (7-17%) to the paramagnetic [4Fe-4S] + state, independent of either the spacing of the cysteine residues (Cx 3 Cx 2 C vs. Cx 2 Cx 2 C), the nature of intervening amino acids, or the length of the cluster binding motif. In the absence of the stabilizing protein environment, the reduction process is proposed to proceed via [4Fe-4S] 2+ cluster disassembly and reassembly in a more reduced state. UV-Vis and EPR spectroscopic techniques are employed as analytical tools to quantitate the as-reconstituted (or oxidized) and one-electron reduced states of the [4Fe-4S] clusters, respectively. We demonstrate that short Fd and radical SAM derived 7- to 9-mer peptides containing appropriate cysteine motifs function equally well in coordinating redox active [4Fe-4S] clusters.

Published

2019

17. H-cluster assembly intermediates built on HydF by the radical SAM enzymes HydE and HydG.

Author

Byer AS, Shepard EM, Ratzloff MW, Betz JN, King PW, Broderick WE, and Broderick JB

Subjects

Bacterial Proteins chemistry, Clostridium acetobutylicum enzymology, Electron Spin Resonance Spectroscopy, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Protein Conformation, S-Adenosylmethionine chemistry, S-Adenosylmethionine metabolism, Spectroscopy, Fourier Transform Infrared, Bacterial Proteins metabolism, Clostridium acetobutylicum metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

[FeFe]-hydrogenase catalyzes the reversible reduction of protons to H 2 at a complex metallocofactor site, the H-cluster. Biosynthesis of this active-site H-cluster requires three maturation enzymes: the radical S-adenosylmethionine enzymes HydE and HydG synthesize the nonprotein ligands, while the GTPase HydF provides a scaffold for assembly of the 2Fe subcluster of the H-cluster ([2Fe] H ) prior to its transfer to hydrogenase. To delineate the assembly and delivery steps for the 2Fe precursor cluster coordinated to HydF ([2Fe] F ), we have heterologously expressed HydF in the presence of HydE alone (HydF E ) or HydG alone (HydF G ), and characterized the resulting purified HydF E and HydF G using UV-visible, EPR, and FTIR spectroscopies and biochemical assays. The iron-sulfur clusters on HydF are modified by co-expression with HydE or HydG, as evidenced by the changes in the visible, EPR, and FTIR spectral features. Further, biochemical assays show that HydF E is capable of activating HydA ΔEFG to a limited extent (~ 1% of WT) even though the normal source of CO and CN - ligands of [2Fe] H (HydG) was absent. Activation assays performed with HydF G , in contrast, exhibit no ability to mature HydA ΔEFG . It appears that in the case of HydF E , trace diatomics from the cellular environment are incorporated into a [2Fe] F -like precursor on HydF in the absence of HydG. We conclude that the product of HydE, presumably the dithiomethylamine ligand of [2Fe] H , is absolutely essential to the activation process, while the diatomic products of HydG can be provided from alternate sources.

Published

2019

18. Characterization of the Preprocessed Copper Site Equilibrium in Amine Oxidase and Assignment of the Reactive Copper Site in Topaquinone Biogenesis.

Author

Adelson CN, Johnston EM, Hilmer KM, Watts H, Dey SG, Brown DE, Broderick JB, Shepard EM, Dooley DM, and Solomon EI

Subjects

Binding Sites, Catalytic Domain, Dihydroxyphenylalanine biosynthesis, Models, Molecular, Amine Oxidase (Copper-Containing) chemistry, Amine Oxidase (Copper-Containing) metabolism, Copper chemistry, Dihydroxyphenylalanine analogs & derivatives

Abstract

Copper-dependent amine oxidases produce their redox active cofactor, 2,4,5-trihydroxyphenylalanine quinone (TPQ), via the Cu II -catalyzed oxygenation of an active site tyrosine. This study addresses possible mechanisms for this biogenesis process by presenting the geometric and electronic structure characterization of the Cu II -bound, prebiogenesis (preprocessed) active site of the enzyme Arthrobacter globiformis amine oxidase (AGAO). Cu II -loading into the preprocessed AGAO active site is slow ( k obs = 0.13 h -1 ), and is preceded by Cu II binding in a separate kinetically favored site that is distinct from the active site. Preprocessed active site Cu II is in a thermal equilibrium between two species, an entropically favored form with tyrosine protonated and unbound from the Cu II site, and an enthalpically favored form with tyrosine bound deprotonated to the Cu II active site. It is shown that the Cu II -tyrosinate bound form is directly active in biogenesis. The electronic structure determined for the reactive form of the preprocessed Cu II active site is inconsistent with a biogenesis pathway that proceeds through a Cu I -tyrosyl radical intermediate, but consistent with a pathway that overcomes the spin forbidden reaction of 3 O 2 with the bound singlet substrate via a three-electron concerted charge-transfer mechanism.

Published

2019

19. Secondary structure analysis of peptides with relevance to iron-sulfur cluster nesting.

Author

Hanscam R, Shepard EM, Broderick JB, Copié V, and Szilagyi RK

Subjects

Amino Acids chemistry, Hydrolysis, Protein Structure, Secondary, Iron-Sulfur Proteins chemistry, Molecular Dynamics Simulation, Peptides chemistry

Abstract

Peptides coordinated to iron-sulfur clusters, referred to as maquettes, represent a synthetic strategy for constructing biomimetic models of iron-sulfur metalloproteins. These maquettes have been successfully employed as building blocks of engineered heme-containing proteins with electron-transfer functionality; however, they have yet to be explored in reactivity studies. The concept of iron-sulfur nesting in peptides is a leading hypothesis in Origins-of-Life research as a plausible path to bridge the discontinuity between prebiotic chemical transformations and extant enzyme catalysis. Based on past biomimetic and biochemical research, we put forward a mechanism of maquette reconstitution that guides our development of computational tools and methodologies. In this study, we examined a key feature of the first stage of maquette formation, which is the secondary structure of aqueous peptide models using molecular dynamics simulations based on the AMBER99SB empirical force field. We compared and contrasted S…S distances, [2Fe-2S] and [4Fe-4S] nests, and peptide conformations via Ramachandran plots for dissolved Cys and Gly amino acids, the CGGCGGC 7-mer, and the GGCGGGCGGCGGW 16-mer peptide. Analytical tools were developed for following the evolution of secondary structural features related to [Fe-S] cluster nesting along 100 ns trajectories. Simulations demonstrated the omnipresence of peptide nests for preformed [2Fe-2S] clusters; however, [4Fe-4S] cluster nests were observed only for the 16-mer peptide with lifetimes of a few nanoseconds. The origin of the [4Fe-4S] nest and its stability was linked to a "kinked-ribbon" peptide conformation. Our computational approach lays the foundation for transitioning into subsequent stages of maquette reconstitution, those being the formation of iron ion/iron-sulfur coordinated peptides. © 2018 Wiley Periodicals, Inc., (© 2018 Wiley Periodicals, Inc.)

Published

2019

20. Paradigm Shift for Radical S-Adenosyl-l-methionine Reactions: The Organometallic Intermediate Ω Is Central to Catalysis.

Author

Byer AS, Yang H, McDaniel EC, Kathiresan V, Impano S, Pagnier A, Watts H, Denler C, Vagstad AL, Piel J, Duschene KS, Shepard EM, Shields TP, Scott LG, Lilla EA, Yokoyama K, Broderick WE, Hoffman BM, and Broderick JB

Subjects

Acetyltransferases, Bacteria chemistry, Bacteria metabolism, Biocatalysis, Cobamides chemistry, Deoxyadenosines chemistry, Electron Spin Resonance Spectroscopy, Enzymes chemistry, Escherichia coli chemistry, Escherichia coli enzymology, Escherichia coli metabolism, Models, Molecular, Protein Conformation, S-Adenosylmethionine chemistry, Bacteria enzymology, Cobamides metabolism, Deoxyadenosines metabolism, Enzymes metabolism, S-Adenosylmethionine metabolism

Abstract

Radical S-adenosyl-l-methionine (SAM) enzymes comprise a vast superfamily catalyzing diverse reactions essential to all life through homolytic SAM cleavage to liberate the highly reactive 5'-deoxyadenosyl radical (5'-dAdo·). Our recent observation of a catalytically competent organometallic intermediate Ω that forms during reaction of the radical SAM (RS) enzyme pyruvate formate-lyase activating-enzyme (PFL-AE) was therefore quite surprising, and led to the question of its broad relevance in the superfamily. We now show that Ω in PFL-AE forms as an intermediate under a variety of mixing order conditions, suggesting it is central to catalysis in this enzyme. We further demonstrate that Ω forms in a suite of RS enzymes chosen to span the totality of superfamily reaction types, implicating Ω as essential in catalysis across the RS superfamily. Finally, EPR and electron nuclear double resonance spectroscopy establish that Ω involves an Fe-C5' bond between 5'-dAdo· and the [4Fe-4S] cluster. An analogous organometallic bond is found in the well-known adenosylcobalamin (coenzyme B 12 ) cofactor used to initiate radical reactions via a 5'-dAdo· intermediate. Liberation of a reactive 5'-dAdo· intermediate via homolytic metal-carbon bond cleavage thus appears to be similar for Ω and coenzyme B 12 . However, coenzyme B 12 is involved in enzymes catalyzing only a small number (∼12) of distinct reactions, whereas the RS superfamily has more than 100 000 distinct sequences and over 80 reaction types characterized to date. The appearance of Ω across the RS superfamily therefore dramatically enlarges the sphere of bio-organometallic chemistry in Nature.

Published

2018

21. Compositional and structural insights into the nature of the H-cluster precursor on HydF.

Author

Scott AG, Szilagyi RK, Mulder DW, Ratzloff MW, Byer AS, King PW, Broderick WE, Shepard EM, and Broderick JB

Abstract

Assembly of an active [FeFe]-hydrogenase requires dedicated maturation enzymes that generate the active-site H-cluster: the radical SAM enzymes HydE and HydG synthesize the unusual non-protein ligands - carbon monoxide, cyanide, and dithiomethylamine - while the GTPase HydF serves as a scaffold for assembly of the 2Fe subcluster containing these ligands. In the current study, enzymatically cluster-loaded HydF ([2Fe]F) is produced by co-expression with HydE and HydG in an Escherichia coli host followed by isolation and examination by FTIR and EPR spectroscopy. FTIR reveals the presence of well-defined terminal CO and CN- ligands; however, unlike in the [FeFe]-hydrogenase, no bridging CO is observed. Exposure of this loaded HydF to exogenous CO or H2 produces no significant changes to the FTIR spectrum, indicating that, unlike in the [FeFe]-hydrogenase, the 2Fe cluster in loaded HydF is coordinatively saturated and relatively unreactive. EPR spectroscopy reveals the presence of both [4Fe-4S] and [2Fe-2S] clusters on this loaded HydF, but provides no direct evidence for these being linked to the [2Fe]F. Using the chemical reactivity and FTIR data, a large collection of computational models were evaluated. Their scaled quantum chemical vibrational spectra allowed us to score various [2Fe]F structures in terms of their ability to reproduce the diatomic stretching frequencies observed in the FTIR experimental spectra. Collectively, the results provide new insights that support the presence of a diamagnetic, but spin-polarized FeI-FeI oxidation state for the [2Fe]F precursor cluster that is coordinated by 4 CO and 2 CN- ligands, and bridged to an adjacent iron-sulfur cluster through one of the CN- ligands.

Published

2018

22. Decarboxylation involving a ferryl, propionate, and a tyrosyl group in a radical relay yields heme b .

Author

Streit BR, Celis AI, Moraski GC, Shisler KA, Shepard EM, Rodgers KR, Lukat-Rodgers GS, and DuBois JL

Subjects

Carboxy-Lyases genetics, Catalysis, Catalytic Domain, Crystallography, X-Ray, Decarboxylation, Electron Spin Resonance Spectroscopy, Heme chemistry, Kinetics, Models, Molecular, Mutation, Oxidation-Reduction, Carboxy-Lyases metabolism, Ferric Compounds chemistry, Free Radicals chemistry, Heme metabolism, Hydrogen Peroxide chemistry, Propionates chemistry, Tyrosine chemistry

Abstract

The H 2 O 2 -dependent oxidative decarboxylation of coproheme III is the final step in the biosynthesis of heme b in many microbes. However, the coproheme decarboxylase reaction mechanism is unclear. The structure of the decarboxylase in complex with coproheme III suggested that the substrate iron, reactive propionates, and an active-site tyrosine convey a net 2e - /2H + from each propionate to an activated form of H 2 O 2 Time-resolved EPR spectroscopy revealed that Tyr-145 formed a radical species within 30 s of the reaction of the enzyme-coproheme complex with H 2 O 2 This radical disappeared over the next 270 s, consistent with a catalytic intermediate. Use of the harderoheme III intermediate as substrate or substitutions of redox-active side chains (W198F, W157F, or Y113S) did not strongly affect the appearance or intensity of the radical spectrum measured 30 s after initiating the reaction with H 2 O 2 , nor did it change the ∼270 s required for the radical signal to recede to ≤10% of its initial intensity. These results suggested Tyr-145 as the site of a catalytic radical involved in decarboxylating both propionates. Tyr-145 • was accompanied by partial loss of the initially present Fe(III) EPR signal intensity, consistent with the possible formation of Fe(IV)=O. Site-specifically deuterated coproheme gave rise to a kinetic isotope effect of ∼2 on the decarboxylation rate constant, indicating that cleavage of the propionate Cβ-H bond was partly rate-limiting. The inferred mechanism requires two consecutive hydrogen atom transfers, first from Tyr-145 to the substrate Fe/H 2 O 2 intermediate and then from the propionate Cβ-H to Tyr-145 • ., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

23. Iron-Sulfur Cluster States of the Hydrogenase Maturase HydF.

Author

Shepard EM, Byer AS, and Broderick JB

Subjects

Clostridium enzymology, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Models, Molecular, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Published

2017

24. Monovalent Cation Activation of the Radical SAM Enzyme Pyruvate Formate-Lyase Activating Enzyme.

Author

Shisler KA, Hutcheson RU, Horitani M, Duschene KS, Crain AV, Byer AS, Shepard EM, Rasmussen A, Yang J, Broderick WE, Vey JL, Drennan CL, Hoffman BM, and Broderick JB

Subjects

Acetyltransferases, Amino Acid Sequence, Binding Sites, Cations, Monovalent chemistry, Cations, Monovalent metabolism, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Enzyme Activation, Enzymes chemistry, Escherichia coli chemistry, Escherichia coli metabolism, Models, Molecular, S-Adenosylmethionine chemistry, Enzymes metabolism, Escherichia coli enzymology, S-Adenosylmethionine metabolism

Abstract

Pyruvate formate-lyase activating enzyme (PFL-AE) is a radical S-adenosyl-l-methionine (SAM) enzyme that installs a catalytically essential glycyl radical on pyruvate formate-lyase. We show that PFL-AE binds a catalytically essential monovalent cation at its active site, yet another parallel with B 12 enzymes, and we characterize this cation site by a combination of structural, biochemical, and spectroscopic approaches. Refinement of the PFL-AE crystal structure reveals Na + as the most likely ion present in the solved structures, and pulsed electron nuclear double resonance (ENDOR) demonstrates that the same cation site is occupied by 23 Na in the solution state of the as-isolated enzyme. A SAM carboxylate-oxygen is an M + ligand, and EPR and circular dichroism spectroscopies reveal that both the site occupancy and the identity of the cation perturb the electronic properties of the SAM-chelated iron-sulfur cluster. ENDOR studies of the PFL-AE/[ 13 C-methyl]-SAM complex show that the target sulfonium positioning varies with the cation, while the observation of an isotropic hyperfine coupling to the cation by ENDOR measurements establishes its intimate, SAM-mediated interaction with the cluster. This monovalent cation site controls enzyme activity: (i) PFL-AE in the absence of any simple monovalent cations has little-no activity; and (ii) among monocations, going down Group 1 of the periodic table from Li + to Cs + , PFL-AE activity sharply maximizes at K + , with NH 4 + closely matching the efficacy of K + . PFL-AE is thus a type I M + -activated enzyme whose M + controls reactivity by interactions with the cosubstrate, SAM, which is bound to the catalytic iron-sulfur cluster.

Published

2017

25. Electron Spin Relaxation and Biochemical Characterization of the Hydrogenase Maturase HydF: Insights into [2Fe-2S] and [4Fe-4S] Cluster Communication and Hydrogenase Activation.

Author

Shepard EM, Byer AS, Aggarwal P, Betz JN, Scott AG, Shisler KA, Usselman RJ, Eaton GR, Eaton SS, and Broderick JB

Subjects

Catalysis, Catalytic Domain, Clostridium enzymology, Electron Spin Resonance Spectroscopy, Hydrogenase chemistry, Iron metabolism, Iron-Sulfur Proteins chemistry, Oxidation-Reduction, Protein Conformation, S-Adenosylmethionine metabolism, Sulfur metabolism, Hydrogenase metabolism, Iron chemistry, Iron-Sulfur Proteins metabolism, S-Adenosylmethionine chemistry, Sulfur chemistry

Abstract

Nature utilizes [FeFe]-hydrogenase enzymes to catalyze the interconversion between H 2 and protons and electrons. Catalysis occurs at the H-cluster, a carbon monoxide-, cyanide-, and dithiomethylamine-coordinated 2Fe subcluster bridged via a cysteine to a [4Fe-4S] cluster. Biosynthesis of this unique metallocofactor is accomplished by three maturase enzymes denoted HydE, HydF, and HydG. HydE and HydG belong to the radical S-adenosylmethionine superfamily of enzymes and synthesize the nonprotein ligands of the H-cluster. These enzymes interact with HydF, a GTPase that acts as a scaffold or carrier protein during 2Fe subcluster assembly. Prior characterization of HydF demonstrated the protein exists in both dimeric and tetrameric states and coordinates both [4Fe-4S] 2+/+ and [2Fe-2S] 2+/+ clusters [Shepard, E. M., Byer, A. S., Betz, J. N., Peters, J. W., and Broderick, J. B. (2016) Biochemistry 55, 3514-3527]. Herein, electron paramagnetic resonance (EPR) is utilized to characterize the [2Fe-2S] + and [4Fe-4S] + clusters bound to HydF. Examination of spin relaxation times using pulsed EPR in HydF samples exhibiting both [4Fe-4S] + and [2Fe-2S] + cluster EPR signals supports a model in which the two cluster types either are bound to widely separated sites on HydF or are not simultaneously bound to a single HydF species. Gel filtration chromatographic analyses of HydF spectroscopic samples strongly suggest the [2Fe-2S] + and [4Fe-4S] + clusters are coordinated to the dimeric form of the protein. Lastly, we examined the 2Fe subcluster-loaded form of HydF and showed the dimeric state is responsible for [FeFe]-hydrogenase activation. Together, the results indicate a specific role for the HydF dimer in the H-cluster biosynthesis pathway.

Published

2017

26. A Redox Active [2Fe-2S] Cluster on the Hydrogenase Maturase HydF.

Author

Shepard EM, Byer AS, Betz JN, Peters JW, and Broderick JB

Subjects

Bacterial Proteins metabolism, Catalysis, Catalytic Domain, Circular Dichroism, Electron Spin Resonance Spectroscopy, Hydrogen metabolism, Hydrogenase metabolism, Iron metabolism, Iron-Sulfur Proteins metabolism, Oxidation-Reduction, S-Adenosylmethionine chemistry, S-Adenosylmethionine metabolism, Sulfur metabolism, Bacterial Proteins chemistry, Clostridium enzymology, Hydrogen chemistry, Hydrogenase chemistry, Iron chemistry, Iron-Sulfur Proteins chemistry, Sulfur chemistry

Abstract

[FeFe]-hydrogenases are nature's most prolific hydrogen catalysts, excelling at facilely interconverting H2 and protons. The catalytic core common to all [FeFe]-hydrogenases is a complex metallocofactor, referred to as the H-cluster, which is composed of a standard [4Fe-4S] cluster linked through a bridging thiolate to a 2Fe subcluster harboring dithiomethylamine, carbon monoxide, and cyanide ligands. This 2Fe subcluster is synthesized and inserted into [FeFe]-hydrogenase by three maturase enzymes denoted HydE, HydF, and HydG. HydE and HydG are radical S-adenosylmethionine enzymes and synthesize the nonprotein ligands of the H-cluster. HydF is a GTPase that functions as a scaffold or carrier for 2Fe subcluster production. Herein, we utilize UV-visible, circular dichroism, and electron paramagnetic resonance spectroscopic studies to establish the existence of redox active [4Fe-4S] and [2Fe-2S] clusters bound to HydF. We have used spectroelectrochemical titrations to assign iron-sulfur cluster midpoint potentials, have shown that HydF purifies with a reduced [2Fe-2S] cluster in the absence of exogenous reducing agents, and have tracked iron-sulfur cluster spectroscopic changes with quaternary structural perturbations. Our results provide an important foundation for understanding the maturation process by defining the iron-sulfur cluster content of HydF prior to its interaction with HydE and HydG. We speculate that the [2Fe-2S] cluster of HydF either acts as a placeholder for HydG-derived Fe(CO)2CN species or serves as a scaffold for 2Fe subcluster assembly.

Published

2016

27. [FeFe]- and [NiFe]-hydrogenase diversity, mechanism, and maturation.

Author

Peters JW, Schut GJ, Boyd ES, Mulder DW, Shepard EM, Broderick JB, King PW, and Adams MW

Subjects

Archaea classification, Archaea enzymology, Archaea genetics, Archaeal Proteins genetics, Bacteria classification, Bacteria enzymology, Bacteria genetics, Bacterial Proteins genetics, Genetic Variation, Hydrogenase genetics, Iron-Sulfur Proteins genetics, Oxidation-Reduction, Phylogeny, Archaeal Proteins metabolism, Bacterial Proteins metabolism, Hydrogen metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

The [FeFe]- and [NiFe]-hydrogenases catalyze the formal interconversion between hydrogen and protons and electrons, possess characteristic non-protein ligands at their catalytic sites and thus share common mechanistic features. Despite the similarities between these two types of hydrogenases, they clearly have distinct evolutionary origins and likely emerged from different selective pressures. [FeFe]-hydrogenases are widely distributed in fermentative anaerobic microorganisms and likely evolved under selective pressure to couple hydrogen production to the recycling of electron carriers that accumulate during anaerobic metabolism. In contrast, many [NiFe]-hydrogenases catalyze hydrogen oxidation as part of energy metabolism and were likely key enzymes in early life and arguably represent the predecessors of modern respiratory metabolism. Although the reversible combination of protons and electrons to generate hydrogen gas is the simplest of chemical reactions, the [FeFe]- and [NiFe]-hydrogenases have distinct mechanisms and differ in the fundamental chemistry associated with proton transfer and control of electron flow that also help to define catalytic bias. A unifying feature of these enzymes is that hydrogen activation itself has been restricted to one solution involving diatomic ligands (carbon monoxide and cyanide) bound to an Fe ion. On the other hand, and quite remarkably, the biosynthetic mechanisms to produce these ligands are exclusive to each type of enzyme. Furthermore, these mechanisms represent two independent solutions to the formation of complex bioinorganic active sites for catalyzing the simplest of chemical reactions, reversible hydrogen oxidation. As such, the [FeFe]- and [NiFe]-hydrogenases are arguably the most profound case of convergent evolution. This article is part of a Special Issue entitled: Fe/S proteins: Analysis, structure, function, biogenesis and diseases., (Copyright © 2014 Elsevier B.V. All rights reserved.)

Published

2015

28. Inhibition and oxygen activation in copper amine oxidases.

Author

Shepard EM and Dooley DM

Subjects

Amine Oxidase (Copper-Containing) metabolism, Amines chemical synthesis, Amines chemistry, Enzyme Inhibitors chemical synthesis, Enzyme Inhibitors chemistry, Humans, Models, Molecular, Molecular Structure, Amine Oxidase (Copper-Containing) antagonists & inhibitors, Amines pharmacology, Enzyme Inhibitors pharmacology, Oxygen metabolism

Abstract

Copper-containing amine oxidases (CuAOs) use both copper and 2,4,5-trihydroxyphenylalanine quinone (TPQ) to catalyze the oxidative deamination of primary amines. The CuAO active site is highly conserved and comprised of TPQ and a mononuclear type II copper center that exhibits five-coordinate, distorted square pyramidal coordination geometry with histidine ligands and equatorially and axially bound water in the oxidized, resting state. The active site is buried within the protein, and CuAOs from various sources display remarkable diversity with respect to the composition of the active site channel and cofactor accessibility. Structural and mechanistic factors that influence substrate preference and inhibitor sensitivity and selectivity have been defined. This Account summarizes the strategies used to design selective CuAO inhibitors based on active site channel characteristics, leading to either enhanced steric fits or the trapping of reactive electrophilic products. These findings provide a framework to support the future development of candidate molecules aimed at minimizing the negative side effects associated with drugs containing amine functionalities. This is vital given the existence of human diamine oxidase and vascular adhesion protein-1, which have distinct amine substrate preferences and are associated with different metabolic processes. Inhibition of these enzymes by antifungal or antiprotozoal agents, as well as classic monoamine oxidase (MAO) inhibitors, may contribute to the adverse side effects associated with drug treatment. These observations provide a rationale for the limited clinical value associated with certain amine-containing pharmaceuticals and emphasize the need for more selective AO inhibitors. This Account also discusses the novel roles of copper and TPQ in the chemistry of O2 activation and substrate oxidation. Reduced CuAOs exist in a redox equilibrium between the Cu(II)-TPQAMQ (aminoquinol) and Cu(I)-TPQSQ (semiquinone). Elucidating the roles of Cu(I), TPQSQ, and TPQAMQ in O2 activation, for example, distinguishing inner-sphere versus outer-sphere electron transfer mechanisms, has been actively investigated since the discovery of TPQSQ in 1991 and has only recently been clarified. Kinetics and spectroscopic studies encompassing metal substitution, stopped-flow and temperature-jump relaxation methods, and oxygen kinetic isotope experiments have provided strong support for an inner-sphere electron transfer step from Cu(I) to O2. Data for two enzymes support a mechanism wherein O2 prebinds to a three-coordinate Cu(I) site, yielding a [Cu(II)(η(1)-O2(-1))](+) intermediate, with H2O2 generated from ensuing rate-determining proton coupled electron transfer from TPQSQ. While kinetics data from the cobalt-substituted yeast enzyme indicated that O2 is reduced through an outer-sphere process involving TPQAMQ, new findings with a bacterial CuAO demonstrate that both the Cu(II) and Co(II) forms of the enzyme operate via parallel mechanisms involving metal-superoxide intermediates. Structural observations of a coordinated TPQSQ-Cu(I) complex in two CuAOs supports previous indications that Cu(II)/(I) ligand substitution chemistry may be mechanistically relevant. Substantial evidence indicates that rapid and reversible inner-sphere reduction of O2 at a three-coordinate Cu(I) site occurs, but the existence of a coordinated semiquinone in some AOs suggests that, in these enzymes, an outer-sphere reaction between O2 and TPQSQ may also be possible, since this is expected to be energetically favorable compared with outer-sphere electron transfer from TPQAMQ to O2.

Published

2015

29. [FeFe]-hydrogenase maturation: insights into the role HydE plays in dithiomethylamine biosynthesis.

Author

Betz JN, Boswell NW, Fugate CJ, Holliday GL, Akiva E, Scott AG, Babbitt PC, Peters JW, Shepard EM, and Broderick JB

Subjects

Catalysis, Catalytic Domain, Deoxyadenosines chemistry, Deoxyadenosines metabolism, Deuterium chemistry, Electron Spin Resonance Spectroscopy, Hydrogenase chemistry, Iron metabolism, Iron-Sulfur Proteins chemistry, Molecular Docking Simulation, Spectrophotometry, Ultraviolet, Sulfur chemistry, Clostridium acetobutylicum enzymology, Dimethylamines metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Protein Processing, Post-Translational, Sulfur metabolism

Abstract

HydE and HydG are radical S-adenosyl-l-methionine enzymes required for the maturation of [FeFe]-hydrogenase (HydA) and produce the nonprotein organic ligands characteristic of its unique catalytic cluster. The catalytic cluster of HydA (the H-cluster) is a typical [4Fe-4S] cubane bridged to a 2Fe-subcluster that contains two carbon monoxides, three cyanides, and a bridging dithiomethylamine as ligands. While recent studies have shed light on the nature of diatomic ligand biosynthesis by HydG, little information exists on the function of HydE. Herein, we present biochemical, spectroscopic, bioinformatic, and molecular modeling data that together map the active site and provide significant insight into the role of HydE in H-cluster biosynthesis. Electron paramagnetic resonance and UV-visible spectroscopic studies demonstrate that reconstituted HydE binds two [4Fe-4S] clusters and copurifies with S-adenosyl-l-methionine. Incorporation of deuterium from D2O into 5'-deoxyadenosine, the cleavage product of S-adenosyl-l-methionine, coupled with molecular docking experiments suggests that the HydE substrate contains a thiol functional group. This information, along with HydE sequence similarity and genome context networks, has allowed us to redefine the presumed mechanism for HydE away from BioB-like sulfur insertion chemistry; these data collectively suggest that the source of the sulfur atoms in the dithiomethylamine bridge of the H-cluster is likely derived from HydE's thiol containing substrate.

Published

2015

30. Radical S-adenosyl-L-methionine chemistry in the synthesis of hydrogenase and nitrogenase metal cofactors.

Author

Byer AS, Shepard EM, Peters JW, and Broderick JB

Subjects

Animals, Humans, Methylation, S-Adenosylmethionine chemistry, Coenzymes biosynthesis, Free Radicals chemistry, Metals chemistry, Protein Methyltransferases metabolism, S-Adenosylmethionine metabolism

Abstract

Nitrogenase, [FeFe]-hydrogenase, and [Fe]-hydrogenase enzymes perform catalysis at metal cofactors with biologically unusual non-protein ligands. The FeMo cofactor of nitrogenase has a MoFe7S9 cluster with a central carbon, whereas the H-cluster of [FeFe]-hydrogenase contains a 2Fe subcluster coordinated by cyanide and CO ligands as well as dithiomethylamine; the [Fe]-hydrogenase cofactor has CO and guanylylpyridinol ligands at a mononuclear iron site. Intriguingly, radical S-adenosyl-L-methionine enzymes are vital for the assembly of all three of these diverse cofactors. This minireview presents and discusses the current state of knowledge of the radical S-adenosylmethionine enzymes required for synthesis of these remarkable metal cofactors., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015