Your search keyword '"Britt RD"' showing total 38 results

1. Organometallic Fe 2 (μ-SH) 2 (CO) 4 (CN) 2 Cluster Allows the Biosynthesis of the [FeFe]-Hydrogenase with Only the HydF Maturase.

Author

Zhang Y, Tao L, Woods TJ, Britt RD, and Rauchfuss TB

Subjects

Catalysis, Catalytic Domain, Electron Spin Resonance Spectroscopy, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase metabolism, Molecular Conformation, Organometallic Compounds chemistry, Organometallic Compounds metabolism, Oxidation-Reduction, Bacterial Proteins metabolism, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Trans-Activators metabolism

Abstract

The biosynthesis of the active site of the [FeFe]-hydrogenases (HydA1), the H-cluster, is of interest because these enzymes are highly efficient catalysts for the oxidation and production of H 2 . The biosynthesis of the [2Fe] H subcluster of the H-cluster proceeds from simple precursors, which are processed by three maturases: HydG, HydE, and HydF. Previous studies established that HydG produces an Fe(CO) 2 (CN) adduct of cysteine, which is the substrate for HydE. In this work, we show that by using the synthetic cluster [Fe 2 (μ-SH) 2 (CN) 2 (CO) 4 ] 2- active HydA1 can be biosynthesized without maturases HydG and HydE.

Published

2022

2. Accumulation and Pulse Electron Paramagnetic Resonance Spectroscopic Investigation of the 4-Oxidobenzyl Radical Generated in the Radical S -Adenosyl-l-methionine Enzyme HydG.

Author

Rao G, Chen N, Marchiori DA, Wang LP, and Britt RD

Subjects

Electron Spin Resonance Spectroscopy, Free Radicals chemistry, Free Radicals metabolism, Models, Molecular, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, S-Adenosylmethionine chemistry, S-Adenosylmethionine metabolism, Shewanella chemistry, Shewanella metabolism

Abstract

The radical S -adenosyl-l-methionine (SAM) enzyme HydG cleaves tyrosine to generate CO and CN - ligands of the [FeFe] hydrogenase H-cluster, accompanied by the formation of a 4-oxidobenzyl radical (4-OB • ), which is the precursor to the HydG p -cresol byproduct. Native HydG only generates a small amount of 4-OB • , limiting detailed electron paramagnetic resonance (EPR) spectral characterization beyond our initial EPR lineshape study employing various tyrosine isotopologues. Here, we show that the concentration of trapped 4-OB • is significantly increased in reactions using HydG variants, in which the "dangler Fe" to which CO and CN - bind is missing or substituted by a redox-inert Zn 2+ ion. This allows for the detailed characterization of 4-OB • using high-field EPR and electron nuclear double resonance spectroscopy to extract its g -values and 1 H/ 13 C hyperfine couplings. These results are compared to density functional theory-predicted values of several 4-OB • models with different sizes and protonation states, with a best fit to the deprotonated radical anion configuration of 4-OB • . Overall, our results depict a clearer electronic structure of the transient 4-OB • radical and provide new insights into the radical SAM chemistry of HydG.

Published

2022

3. A Night-Time Edge Site Intermediate in the Cyanobacterial Circadian Clock Identified by EPR Spectroscopy.

Author

Chow GK, Chavan AG, Heisler J, Chang YG, Zhang N, LiWang A, and Britt RD

Subjects

Electron Spin Resonance Spectroscopy, Phosphorylation, Circadian Clocks physiology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Circadian Rhythm Signaling Peptides and Proteins chemistry, Circadian Rhythm Signaling Peptides and Proteins metabolism, Cyanobacteria chemistry, Cyanobacteria metabolism

Abstract

As the only circadian oscillator that can be reconstituted in vitro with its constituent proteins KaiA, KaiB, and KaiC using ATP as an energy source, the cyanobacterial circadian oscillator serves as a model system for detailed mechanistic studies of day-night transitions of circadian clocks in general. The day-to-night transition occurs when KaiB forms a night-time complex with KaiC to sequester KaiA, the latter of which interacts with KaiC during the day to promote KaiC autophosphorylation. However, how KaiB forms the complex with KaiC remains poorly understood, despite the available structures of KaiB bound to hexameric KaiC. It has been postulated that KaiB-KaiC binding is regulated by inter-KaiB cooperativity. Here, using spin labeling continuous-wave electron paramagnetic resonance spectroscopy, we identified and quantified two subpopulations of KaiC-bound KaiB, corresponding to the "bulk" and "edge" KaiBC sites in stoichiometric and substoichiometric KaiB i C 6 complexes ( i = 1-5). We provide kinetic evidence to support the intermediacy of the "edge" KaiBC sites as bridges and nucleation sites between free KaiB and the "bulk" KaiBC sites. Furthermore, we show that the relative abundance of "edge" and "bulk" sites is dependent on both KaiC phosphostate and KaiA, supporting the notion of phosphorylation-state controlled inter-KaiB cooperativity. Finally, we demonstrate that the interconversion between the two subpopulations of KaiC-bound KaiB is intimately linked to the KaiC phosphorylation cycle. These findings enrich our mechanistic understanding of the cyanobacterial clock and demonstrate the utility of EPR in elucidating circadian clock mechanisms.

Published

2022

4. Quantum Chemical Study of a Radical Relay Mechanism for the HydG-Catalyzed Synthesis of a Fe(II)(CO) 2 (CN)cysteine Precursor to the H-Cluster of [FeFe] Hydrogenase.

Author

Chen N, Rao G, Britt RD, and Wang LP

Subjects

Biocatalysis, Iron chemistry, Ligands, Models, Chemical, Quantum Theory, Thermoanaerobacter enzymology, Tyrosine chemistry, Bacterial Proteins chemistry, Coordination Complexes chemistry, Cysteine chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

The [FeFe] hydrogenase catalyzes the redox interconversion of protons and H 2 with a Fe-S "H-cluster" employing CO, CN, and azadithiolate ligands to two Fe centers. The biosynthesis of the H-cluster is a highly interesting reaction carried out by a set of Fe-S maturase enzymes called HydE, HydF, and HydG. HydG, a member of the radical S -adenosylmethionine (rSAM) family, converts tyrosine, cysteine, and Fe(II) into an organometallic Fe(II)(CO) 2 (CN)cysteine "synthon", which serves as the substrate for HydE. Although key aspects of the HydG mechanism have been experimentally determined via isotope-sensitive spectroscopic methods, other important mechanistic questions have eluded experimental determination. Here, we use computational quantum chemistry to refine the mechanism of the HydG catalytic reaction. We utilize quantum mechanics/molecular mechanics simulations to investigate the reactions at the canonical Fe-S cluster, where a radical cleavage of the tyrosine substrate takes place and proceeds through a relay of radical intermediates to form HCN and a COO •- radical anion. We then carry out a broken-symmetry density functional theory study of the reactions at the unusual five-iron auxiliary Fe-S cluster, where two equivalents of CN - and COOH • coordinate to the fifth "dangler iron" in a series of substitution and redox reactions that yield the synthon as the final product for further processing by HydE.

Published

2021

5. Trapping a cross-linked lysine-tryptophan radical in the catalytic cycle of the radical SAM enzyme SuiB.

Author

Balo AR, Caruso A, Tao L, Tantillo DJ, Seyedsayamdost MR, and Britt RD

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Catalysis, Cloning, Molecular, Electron Spin Resonance Spectroscopy, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Iron-Sulfur Proteins genetics, Iron-Sulfur Proteins metabolism, Kinetics, Lysine metabolism, Models, Molecular, Oxidation-Reduction, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Ribosomal Proteins genetics, Ribosomal Proteins metabolism, S-Adenosylmethionine metabolism, Streptococcus enzymology, Streptococcus genetics, Substrate Specificity, Thermodynamics, Tryptophan metabolism, Bacterial Proteins chemistry, Iron-Sulfur Proteins chemistry, Lysine chemistry, Ribosomal Proteins chemistry, S-Adenosylmethionine chemistry, Streptococcus chemistry, Tryptophan chemistry

Abstract

The radical S -adenosylmethionine (rSAM) enzyme SuiB catalyzes the formation of an unusual carbon-carbon bond between the sidechains of lysine (Lys) and tryptophan (Trp) in the biosynthesis of a ribosomal peptide natural product. Prior work on SuiB has suggested that the Lys-Trp cross-link is formed via radical electrophilic aromatic substitution (rEAS), in which an auxiliary [4Fe-4S] cluster (AuxI), bound in the SPASM domain of SuiB, carries out an essential oxidation reaction during turnover. Despite the prevalence of auxiliary clusters in over 165,000 rSAM enzymes, direct evidence for their catalytic role has not been reported. Here, we have used electron paramagnetic resonance (EPR) spectroscopy to dissect the SuiB mechanism. Our studies reveal substrate-dependent redox potential tuning of the AuxI cluster, constraining it to the oxidized [4Fe-4S] 2+ state, which is active in catalysis. We further report the trapping and characterization of an unprecedented cross-linked Lys-Trp radical (Lys-Trp•) in addition to the organometallic Ω intermediate, providing compelling support for the proposed rEAS mechanism. Finally, we observe oxidation of the Lys-Trp• intermediate by the redox-tuned [4Fe-4S] 2+ AuxI cluster by EPR spectroscopy. Our findings provide direct evidence for a role of a SPASM domain auxiliary cluster and consolidate rEAS as a mechanistic paradigm for rSAM enzyme-catalyzed carbon-carbon bond-forming reactions., Competing Interests: The authors declare no competing interest.

Published

2021

6. Structural Properties and Catalytic Implications of the SPASM Domain Iron-Sulfur Clusters in Methylorubrum extorquens PqqE.

Author

Zhu W, Walker LM, Tao L, Iavarone AT, Wei X, Britt RD, Elliott SJ, and Klinman JP

Subjects

Bacterial Proteins chemistry, Biocatalysis, Crystallography, X-Ray, Endopeptidases chemistry, Iron chemistry, Methylobacterium extorquens metabolism, Models, Molecular, Molecular Structure, Sulfur chemistry, Bacterial Proteins metabolism, Endopeptidases metabolism, Iron metabolism, Methylobacterium extorquens chemistry, Sulfur metabolism

Abstract

Understanding the relationship between the metallocofactor and its protein environment is the key to uncovering the mechanism of metalloenzymes. PqqE, a radical S- adenosylmethionine enzyme in pyrroloquinoline quinone (PQQ) biosynthesis, contains three iron-sulfur cluster binding sites. Two auxiliary iron-sulfur cluster binding sites, designated as AuxI and AuxII, use distinctive ligands compared to other proteins in the family while their functions remain unclear. Here, we investigate the electronic properties of these iron-sulfur clusters and compare the catalytic efficiency of wild-type (WT) Methylorubrum extorquens AM1 PqqE to a range of mutated constructs. Using native mass spectrometry, protein film electrochemistry, and electron paramagnetic resonance spectroscopy, we confirm the previously proposed incorporation of a mixture of [2Fe-2S] and [4Fe-4S] clusters at the AuxI site and are able to assign redox potentials to each of the three iron-sulfur clusters. Significantly, a conservative mutation at AuxI, C268H, shown to selectively incorporate a [4Fe-4S] cluster, catalyzes an enhancement of uncoupled S- adenosylmethionine cleavage relative to WT, together with the elimination of detectable peptide cross-linked product. While a [4Fe-4S] cluster can be tolerated at the AuxI site, the aggregate findings suggest a functional [2Fe-2S] configuration within the AuxI site. PqqE variants with nondestructive ligand replacements at AuxII also show that the reduction potential at this site can be manipulated by changing the electronegativity of the unique aspartate ligand. A number of novel mechanistic features are proposed based on the kinetic and spectroscopic data. Additionally, bioinformatic analyses suggest that the unique ligand environment of PqqE may be relevant to its role in PQQ biosynthesis within an oxygen-dependent biosynthetic pathway.

Published

2020

7. Monitoring Protein-Protein Interactions in the Cyanobacterial Circadian Clock in Real Time via Electron Paramagnetic Resonance Spectroscopy.

Author

Chow GK, Chavan AG, Heisler JC, Chang YG, LiWang A, and Britt RD

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Circadian Rhythm Signaling Peptides and Proteins genetics, Circadian Rhythm Signaling Peptides and Proteins metabolism, Electron Spin Resonance Spectroscopy, Synechococcus genetics, Synechococcus metabolism, Bacterial Proteins chemistry, Circadian Rhythm Signaling Peptides and Proteins chemistry, Synechococcus chemistry

Abstract

The cyanobacterial circadian clock in Synechococcus elongatus consists of three proteins, KaiA, KaiB, and KaiC. KaiA and KaiB rhythmically interact with KaiC to generate stable oscillations of KaiC phosphorylation with a period of 24 h. The observation of stable circadian oscillations when the three clock proteins are reconstituted and combined in vitro makes it an ideal system for understanding its underlying molecular mechanisms and circadian clocks in general. These oscillations were historically monitored in vitro by gel electrophoresis of reaction mixtures based on the differing electrophoretic mobilities between various phosphostates of KaiC. As the KaiC phospho-distribution represents only one facet of the oscillations, orthogonal tools are necessary to explore other interactions to generate a full description of the system. However, previous biochemical assays are discontinuous or qualitative. To circumvent these limitations, we developed a spin-labeled KaiB mutant that can differentiate KaiC-bound KaiB from free KaiB using continuous-wave electron paramagnetic resonance spectroscopy that is minimally sensitive to KaiA. Similar to wild-type (WT-KaiB), this labeled mutant, in combination with KaiA, sustains robust circadian rhythms of KaiC phosphorylation. This labeled mutant is hence a functional surrogate of WT-KaiB and thus participates in and reports on autonomous macroscopic circadian rhythms generated by mixtures that include KaiA, KaiC, and ATP. Quantitative kinetics could be extracted with improved precision and time resolution. We describe design principles, data analysis, and limitations of this quantitative binding assay and discuss future research necessary to overcome these challenges.

Published

2020

8. Identity and function of an essential nitrogen ligand of the nitrogenase cofactor biosynthesis protein NifB.

Author

Rettberg LA, Wilcoxen J, Jasniewski AJ, Lee CC, Tanifuji K, Hu Y, Britt RD, and Ribbe MW

Subjects

Alanine genetics, Alanine metabolism, Bacterial Proteins genetics, Electron Spin Resonance Spectroscopy, Histidine genetics, Histidine metabolism, Ligands, Methanosarcina genetics, Mutagenesis, Nitrogenase genetics, X-Ray Absorption Spectroscopy, Bacterial Proteins metabolism, Methanosarcina metabolism, Nitrogen metabolism, Nitrogenase biosynthesis

Abstract

NifB is a radical S-adenosyl-L-methionine (SAM) enzyme that is essential for nitrogenase cofactor assembly. Previously, a nitrogen ligand was shown to be involved in coupling a pair of [Fe 4 S 4 ] clusters (designated K1 and K2) concomitant with carbide insertion into an [Fe 8 S 9 C] cofactor core (designated L) on NifB. However, the identity and function of this ligand remain elusive. Here, we use combined mutagenesis and pulse electron paramagnetic resonance analyses to establish histidine-43 of Methanosarcina acetivorans NifB (MaNifB) as the nitrogen ligand for K1. Biochemical and continuous wave electron paramagnetic resonance data demonstrate the inability of MaNifB to serve as a source for cofactor maturation upon substitution of histidine-43 with alanine; whereas x-ray absorption spectroscopy/extended x-ray fine structure experiments further suggest formation of an intermediate that lacks the cofactor core arrangement in this MaNifB variant. These results point to dual functions of histidine-43 in structurally assisting the proper coupling between K1 and K2 and concurrently facilitating carbide formation via deprotonation of the initial carbon radical.

Published

2020

9. The binuclear cluster of [FeFe] hydrogenase is formed with sulfur donated by cysteine of an [Fe(Cys)(CO) 2 (CN)] organometallic precursor.

Author

Rao G, Pattenaude SA, Alwan K, Blackburn NJ, Britt RD, and Rauchfuss TB

Subjects

Bacterial Proteins metabolism, Catalysis, Catalytic Domain, Cysteine metabolism, Electron Spin Resonance Spectroscopy, Iron metabolism, Organometallic Compounds metabolism, Sulfur metabolism, Bacterial Proteins chemistry, Cysteine chemistry, Hydrogenase chemistry, Iron chemistry, Organometallic Compounds chemistry, Sulfur chemistry

Abstract

The enzyme [FeFe]-hydrogenase (HydA1) contains a unique 6-iron cofactor, the H-cluster, that has unusual ligands to an Fe-Fe binuclear subcluster: CN - , CO, and an azadithiolate (adt) ligand that provides 2 S bridges between the 2 Fe atoms. In cells, the H-cluster is assembled by a collection of 3 maturases: HydE and HydF, whose roles aren't fully understood, and HydG, which has been shown to construct a [Fe(Cys)(CO) 2 (CN)] organometallic precursor to the binuclear cluster. Here, we report the in vitro assembly of the H-cluster in the absence of HydG, which is functionally replaced by adding a synthetic [Fe(Cys)(CO) 2 (CN)] carrier in the maturation reaction. The synthetic carrier and the HydG-generated analog exhibit similar infrared spectra. The carrier allows HydG-free maturation to HydA1, whose activity matches that of the native enzyme. Maturation with 13 CN-containing carrier affords 13 CN-labeled enzyme as verified by electron paramagnetic resonance (EPR)/electron nuclear double-resonance spectra. This synthetic surrogate approach complements existing biochemical strategies and greatly facilitates the understanding of pathways involved in the assembly of the H-cluster. As an immediate demonstration, we clarify that Cys is not the source of the carbon and nitrogen atoms in the adt ligand using pulse EPR to target the magnetic couplings introduced via a 13 C 3 , 15 N-Cys-labeled synthetic carrier. Parallel mass-spectrometry experiments show that the Cys backbone is converted to pyruvate, consistent with a cysteine role in donating S in forming the adt bridge. This mechanistic scenario is confirmed via maturation with a seleno-Cys carrier to form HydA1-Se, where the incorporation of Se was characterized by extended X-ray absorption fine structure spectroscopy., Competing Interests: The authors declare no competing interest.

Published

2019

10. Incorporation of Ni 2+ , Co 2+ , and Selenocysteine into the Auxiliary Fe-S Cluster of the Radical SAM Enzyme HydG.

Author

Rao G, Alwan KB, Blackburn NJ, and Britt RD

Subjects

Catalytic Domain, Cysteine chemistry, Bacterial Proteins chemistry, Cobalt chemistry, Iron-Sulfur Proteins chemistry, Nickel chemistry, Selenocysteine chemistry, Shewanella chemistry

Abstract

The radical SAM enzyme HydG generates CO- and CN - -containing Fe complexes that are involved in the bioassembly of the [FeFe] hydrogenase active cofactor, the H-cluster. HydG contains a unique 5Fe-4S cluster in which the fifth "dangler" Fe and the coordinating cysteine molecule have both been shown to be essential for its function. Here, we demonstrate that this dangler Fe can be replaced with Ni 2+ or Co 2+ and that the cysteine can be replaced with selenocysteine. The resulting HydG variants were characterized by electron paramagnetic resonance and X-ray absorption spectroscopy, as well as subjected to a Tyr cleavage assay. Both Ni 2+ and Co 2+ are shown to be exchange-coupled to the 4Fe-4S cluster, and selenocysteine substitution does not alter the electronic structure significantly. XAS data provide details of the coordination environments near the Ni, Co, and Se atoms and support a close interaction of the dangler metal with the FeS cluster via an asymmetric SeCys bridge. Finally, while we were unable to observe the formation of novel organometallic species for the Ni 2+ and Co 2+ variants, the selenocysteine variant retains the activity of wild type HydG in forming [Fe(CO) x (CN) y ] species. Our results provide more insights into the unique auxiliary cluster in HydG and expand the scope of artificially generated Fe-S clusters with heteroatoms.

Published

2019

11. High-Field EPR Spectroscopic Characterization of Mn(II) Bound to the Bacterial Solute-Binding Proteins MntC and PsaA.

Author

Gagnon DM, Hadley RC, Ozarowski A, Nolan EM, and Britt RD

Subjects

Electron Spin Resonance Spectroscopy, Models, Molecular, Bacterial Proteins chemistry, Manganese chemistry, Staphylococcus aureus chemistry, Streptococcus pneumoniae chemistry

Abstract

During infection, the bacterial pathogens Staphylococcus aureus and Streptococcus pneumoniae employ ATP-binding cassette (ABC) transporters to acquire Mn(II), an essential nutrient, from the host environment. Staphylococcal MntABC and streptococcal PsaABC attract the attention of the biophysical and bacterial pathogenesis communities because of their established importance during infection. Previous biophysical examination of Mn(II)-MntC and Mn(II)-PsaA using continuous-wave (≈9 GHz) electron paramagnetic resonance (EPR) spectroscopy revealed broad, difficult-to-interpret spectra (Hadley et al. J. Am. Chem. Soc. 2018, 140, 110-113). Herein, we employ high-frequency (>90 GHz), high-field (>3 T) EPR spectroscopy to investigate the Mn(II)-binding sites of these proteins and determine the spin Hamiltonian parameters. Our analyses demonstrate that the zero-field splitting (ZFS) is large for Mn(II)-MntC and Mn(II)-PsaA at +2.72 and +2.87 GHz, respectively. The measured 55 Mn hyperfine coupling values for Mn(II)-MntC and Mn(II)-PsaA of 241 and 236 MHz, respectively, demonstrate a more covalent interaction between Mn(II) and the protein compared to Mn(II) in aqueous solution (≈265 MHz). These studies indicate that MntC and PsaA bind Mn(II) in a similar coordination geometry. Comparison of the ZFS values determined herein with those ascertained for other Mn(II) proteins suggests that the Mn(II)-MntC and Mn(II)-PsaA coordination spheres are not five-coordinate in solution.

Published

2019

12. An Intermediate Conformational State of Cytochrome P450cam-CN in Complex with Putidaredoxin.

Author

Chuo SW, Wang LP, Britt RD, and Goodin DB

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Biocatalysis, Camphor 5-Monooxygenase genetics, Camphor 5-Monooxygenase metabolism, Catalytic Domain, Ferredoxins metabolism, Oxidation-Reduction, Protein Binding, Pseudomonas putida enzymology, Pseudomonas putida genetics, Pseudomonas putida metabolism, Substrate Specificity, Bacterial Proteins chemistry, Camphor 5-Monooxygenase chemistry, Ferredoxins chemistry, Molecular Dynamics Simulation, Protein Conformation

Abstract

Cytochrome P450cam is an archetypal example of the vast family of heme monooxygenases and serves as a model for an enzyme that is highly specific for both its substrate and reductase. During catalysis, it undergoes significant conformational changes of the F and G helices upon binding its substrate and redox partner, putidaredoxin (Pdx). Recent studies have shown that Pdx binding to the closed camphor-bound form of ferric P450cam results in its conversion to a fully open state. However, during catalytic turnover, it remains unclear whether this same conformational change also occurs or whether it is coupled to the formation of the critical compound I intermediate. Here, we have examined P450cam bound simultaneously by camphor, CN - , and Pdx as a mimic of the catalytically competent ferrous oxy-P450cam-Pdx state. The combined use of double electron-electron resonance and molecular dynamics showed direct observation of intermediate conformational states of the enzyme upon CN - and subsequent Pdx binding. This state is coupled to the movement of the I helix and residues at the active site, including Arg-186, Asp-251, and Thr-252. These movements enable occupation of a water molecule that has been implicated in proton delivery and peroxy bond cleavage to give compound I. These findings provide a detailed understanding of how the Pdx-induced conformational change may sequentially promote compound I formation followed by product release, while retaining stereoselective hydroxylation of the substrate of this highly specific monooxygenase.

Published

2019

13. DEPC modification of the Cu A protein from Thermus thermophilus.

Author

Devlin T, Hofman CR, Acevedo ZPV, Kohler KR, Tao L, Britt RD, Hoke KR, and Hunsicker-Wang LM

Subjects

Bacterial Proteins metabolism, Copper chemistry, Copper metabolism, Diethyl Pyrocarbonate metabolism, Electron Transport Complex IV metabolism, Histidine metabolism, Models, Molecular, Oxidation-Reduction, Thermus thermophilus enzymology, Thermus thermophilus metabolism, Bacterial Proteins chemistry, Diethyl Pyrocarbonate chemistry, Electron Transport Complex IV chemistry, Histidine chemistry, Thermus thermophilus chemistry

Abstract

The Cu A center is the initial electron acceptor in cytochrome c oxidase, and it consists of two copper ions bridged by two cysteines and ligated by two histidines, a methionine, and a carbonyl in the peptide backbone of a nearby glutamine. The two ligating histidines are of particular interest as they may influence the electronic and redox properties of the metal center. To test for the presence of reactive ligating histidines, a portion of cytochrome c oxidase from the bacteria Thermus thermophilus that contains the Cu A site (the TtCu A protein) was treated with the chemical modifier diethyl pyrocarbonate (DEPC) and the reaction followed through UV-visible, circular dichroism, and electron paramagnetic resonance spectroscopies at pH 5.0-9.0. A mutant protein (H40A/H117A) with the non-ligating histidines removed was similarly tested. Introduction of an electron-withdrawing DEPC-modification onto the ligating histidine 157 of TtCu A increased the reduction potential by over 70 mV, as assessed by cyclic voltammetry. Results from both proteins indicate that DEPC reacts with one of the two ligating histidines, modification of a ligating histidine raises the reduction potential of the Cu A site, and formation of the DEPC adduct is reversible at room temperature. The existence of the reactive ligating histidine suggests that this residue may play a role in modulating the electronic and redox properties of TtCu A through kinetically-controlled proton exchange with the solvent. Lack of reactivity by the metalloproteins Sco and azurin, both of which contain a mononuclear copper center, indicate that reactivity toward DEPC is not a characteristic of all ligating histidines.

Published

2019

14. An Aminoimidazole Radical Intermediate in the Anaerobic Biosynthesis of the 5,6-Dimethylbenzimidazole Ligand to Vitamin B12.

Author

Gagnon DM, Stich TA, Mehta AP, Abdelwahed SH, Begley TP, and Britt RD

Subjects

Anaerobiosis, Electron Spin Resonance Spectroscopy, S-Adenosylmethionine metabolism, Bacterial Proteins metabolism, Benzimidazoles metabolism, Biosynthetic Pathways, Desulfuromonas metabolism, Vitamin B 12 metabolism

Abstract

Organisms that perform the de novo biosynthesis of cobalamin (vitamin B12) do so via unique pathways depending on the presence of oxygen in the environment. The anaerobic biosynthesis pathway of 5,6-dimethylbenzimidazole, the so-called "lower ligand" to the cobalt center, has been recently identified. This process begins with the conversion of 5-aminoimidazole ribotide (AIR) to 5-hydroxybenzimidazole (HBI) by the radical S-adenosyl-l-methionine (SAM) enzyme BzaF, also known as HBI synthase. In this work we report the characterization of a radical intermediate in the reaction of BzaF using electron paramagnetic resonance spectroscopy. Using various isotopologues of AIR, we extracted hyperfine parameters for a number of nuclei, allowing us to propose plausible chemical compositions and structures for this intermediate. Specifically, we find that an aminoimidazole radical is formed in close proximity to a fragment of the ribose ring. These findings induce the revision of past proposed mechanisms and illustrate the ability of radical SAM enzymes to tightly control the radical chemistry that they engender.

Published

2018

15. X-ray and EPR Characterization of the Auxiliary Fe-S Clusters in the Radical SAM Enzyme PqqE.

Author

Barr I, Stich TA, Gizzi AS, Grove TL, Bonanno JB, Latham JA, Chung T, Wilmot CM, Britt RD, Almo SC, and Klinman JP

Subjects

Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Models, Molecular, Protein Conformation, Temperature, Bacterial Proteins chemistry, Endopeptidases chemistry, Iron-Sulfur Proteins chemistry, Methylobacterium extorquens chemistry

Abstract

The Radical SAM (RS) enzyme PqqE catalyzes the first step in the biosynthesis of the bacterial cofactor pyrroloquinoline quinone, forming a new carbon-carbon bond between two side chains within the ribosomally synthesized peptide substrate PqqA. In addition to the active site RS 4Fe-4S cluster, PqqE is predicted to have two auxiliary Fe-S clusters, like the other members of the SPASM domain family. Here we identify these sites and examine their structure using a combination of X-ray crystallography and Mössbauer and electron paramagnetic resonance (EPR) spectroscopies. X-ray crystallography allows us to identify the ligands to each of the two auxiliary clusters at the C-terminal region of the protein. The auxiliary cluster nearest the RS site (AuxI) is in the form of a 2Fe-2S cluster ligated by four cysteines, an Fe-S center not seen previously in other SPASM domain proteins; this assignment is further supported by Mössbauer and EPR spectroscopies. The second, more remote cluster (AuxII) is a 4Fe-4S center that is ligated by three cysteine residues and one aspartate residue. In addition, we examined the roles these ligands play in catalysis by the RS and AuxII clusters using site-directed mutagenesis coupled with EPR spectroscopy. Lastly, we discuss the possible functional consequences that these unique AuxI and AuxII clusters may have in catalysis for PqqE and how these may extend to additional RS enzymes catalyzing the post-translational modification of ribosomally encoded peptides.

Published

2018

16. Regulation of nitric oxide signaling by formation of a distal receptor-ligand complex.

Author

Guo Y, Suess DLM, Herzik MA Jr, Iavarone AT, Britt RD, and Marletta MA

Subjects

Bacterial Proteins chemistry, Bacterial Proteins isolation & purification, Histidine Kinase antagonists & inhibitors, Histidine Kinase metabolism, Ligands, Models, Molecular, Nitric Oxide chemistry, Bacterial Proteins metabolism, Nitric Oxide metabolism, Shewanella metabolism, Signal Transduction

Abstract

The binding of nitric oxide (NO) to the heme cofactor of heme-nitric oxide/oxygen binding (H-NOX) proteins can lead to the dissociation of the heme-ligating histidine residue and yield a five-coordinate nitrosyl complex, an important step for NO-dependent signaling. In the five-coordinate nitrosyl complex, NO can reside on either the distal or proximal side of the heme, which could have a profound influence over the lifetime of the in vivo signal. To investigate this central molecular question, we characterized the Shewanella oneidensis H-NOX (So H-NOX)-NO complex biophysically under limiting and excess NO conditions. The results show that So H-NOX preferably forms a distal NO species with both limiting and excess NO. Therefore, signal strength and complex lifetime in vivo will be dictated by the dissociation rate of NO from the distal complex and the rebinding of the histidine ligand to the heme.

Published

2017

17. Electron Paramagnetic Resonance Characterization of Three Iron-Sulfur Clusters Present in the Nitrogenase Cofactor Maturase NifB from Methanocaldococcus infernus.

Author

Wilcoxen J, Arragain S, Scandurra AA, Jimenez-Vicente E, Echavarri-Erasun C, Pollmann S, Britt RD, and Rubio LM

Subjects

Electron Spin Resonance Spectroscopy, Molybdoferredoxin chemistry, Substrate Specificity, Bacterial Proteins chemistry, Iron Compounds chemistry, Methanocaldococcus enzymology, Nitrogenase chemistry, S-Adenosylmethionine chemistry

Abstract

NifB utilizes two equivalents of S-adenosyl methionine (SAM) to insert a carbide atom and fuse two substrate [Fe-S] clusters forming the NifB cofactor (NifB-co), which is then passed to NifEN for further modification to form the iron-molybdenum cofactor (FeMo-co) of nitrogenase. Here, we demonstrate that NifB from the methanogen Methanocaldococcus infernus is a radical SAM enzyme able to reductively cleave SAM to 5'-deoxyadenosine radical and is competent in FeMo-co maturation. Using electron paramagnetic resonance spectroscopy we have characterized three [4Fe-4S] clusters, one SAM binding cluster, and two auxiliary clusters probably acting as substrates for NifB-co formation. Nitrogen coordination to one or more of the auxiliary clusters in NifB was observed, and its mechanistic implications for NifB-co dissociation from the maturase are discussed.

Published

2016

18. Biochemical and Spectroscopic Characterization of a Radical S-Adenosyl-L-methionine Enzyme Involved in the Formation of a Peptide Thioether Cross-Link.

Author

Bruender NA, Wilcoxen J, Britt RD, and Bandarian V

Subjects

Amino Acid Motifs, Amino Acid Substitution, Bacterial Proteins chemistry, Bacterial Proteins genetics, Biocatalysis, Computational Biology, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins genetics, Iron-Sulfur Proteins metabolism, Mutagenesis, Site-Directed, Mutation, Oxidation-Reduction, Oxidoreductases Acting on Sulfur Group Donors chemistry, Oxidoreductases Acting on Sulfur Group Donors genetics, Peptide Fragments metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Substrate Specificity, Bacterial Proteins metabolism, Cysteine metabolism, Cystine metabolism, Models, Molecular, Oxidoreductases Acting on Sulfur Group Donors metabolism, Protein Processing, Post-Translational, S-Adenosylmethionine metabolism, Thermoanaerobacter enzymology

Abstract

Peptide-derived natural products are a class of metabolites that afford the producing organism a selective advantage over other organisms in their biological niche. While the polypeptide antibiotics produced by the nonribosomal polypeptide synthetases (NRPS) are the most widely recognized, the ribosomally synthesized and post-translationally modified peptides (RiPPs) are an emerging group of natural products with diverse structures and biological functions. Both the NRPS derived peptides and the RiPPs undergo extensive post-translational modifications to produce structural diversity. Here we report the first characterization of the six cysteines in forty-five (SCIFF) [Haft, D. H. and Basu M. K. (2011) J. Bacteriol. 193, 2745-2755] peptide maturase Tte1186, which is a member of the radical S-adenosyl-l-methionine (SAM) superfamily. Tte1186 catalyzes the formation of a thioether cross-link in the peptide Tte1186a encoded by an orf located upstream of the maturase, under reducing conditions in the presence of SAM. Tte1186 contains three [4Fe-4S] clusters that are indispensable for thioether cross-link formation; however, only one cluster catalyzes the reductive cleavage of SAM. Mechanistic imperatives for the reaction catalyzed by the thioether forming radical SAM maturases will be discussed.

Published

2016

19. The Radical SAM Enzyme HydG Requires Cysteine and a Dangler Iron for Generating an Organometallic Precursor to the [FeFe]-Hydrogenase H-Cluster.

Author

Suess DL, Pham CC, Bürstel I, Swartz JR, Cramer SP, and Britt RD

Subjects

Electron Spin Resonance Spectroscopy, Bacterial Proteins chemistry, Cysteine chemistry, Hydrogenase chemistry, Iron chemistry, Iron-Sulfur Proteins chemistry, Organometallic Compounds chemistry, S-Adenosylmethionine chemistry, Trans-Activators chemistry

Abstract

Three maturase enzymes-HydE, HydF, and HydG-synthesize and insert the organometallic component of the [FeFe]-hydrogenase active site (the H-cluster). HydG generates the first organometallic intermediates in this process, ultimately producing an [Fe(CO)2(CN)] complex. A limitation in understanding the mechanism by which this complex forms has been uncertainty regarding the precise metallocluster composition of HydG that comprises active enzyme. We herein show that the HydG auxiliary cluster must bind both l-cysteine and a dangler Fe in order to generate the [Fe(CO)2(CN)] product. These findings support a mechanistic framework in which a [(Cys)Fe(CO)2(CN)](-) species is a key intermediate in H-cluster maturation.

Published

2016

20. Formation of Hexacoordinate Mn(III) in Bacillus subtilis Oxalate Decarboxylase Requires Catalytic Turnover.

Author

Zhu W, Wilcoxen J, Britt RD, and Richards NG

Subjects

Biocatalysis, Electron Spin Resonance Spectroscopy, Hydrogen-Ion Concentration, Oxalates chemistry, Oxidation-Reduction, Oxygen chemistry, Recombinant Proteins chemistry, Bacillus subtilis enzymology, Bacterial Proteins chemistry, Carboxy-Lyases chemistry, Coordination Complexes chemistry, Manganese chemistry

Abstract

Oxalate decarboxylase (OxDC) catalyzes the disproportionation of oxalic acid monoanion into CO2 and formate. The enzyme has long been hypothesized to utilize dioxygen to form mononuclear Mn(III) or Mn(IV) in the catalytic site during turnover. Recombinant OxDC, however, contains only tightly bound Mn(II), and direct spectroscopic detection of the metal in higher oxidation states under optimal catalytic conditions (pH 4.2) has not yet been reported. Using parallel mode electron paramagnetic resonance spectroscopy, we now show that substantial amounts of Mn(III) are indeed formed in OxDC, but only in the presence of oxalate and dioxygen under acidic conditions. These observations provide the first direct support for proposals in which Mn(III) removes an electron from the substrate to yield a radical intermediate in which the barrier to C-C bond cleavage is significantly decreased. Thus, OxDC joins a small list of enzymes capable of stabilizing and controlling the reactivity of the powerful oxidizing species Mn(III).

Published

2016

21. Biosynthesis of the [FeFe] Hydrogenase H Cluster: A Central Role for the Radical SAM Enzyme HydG.

Author

Suess DL, Kuchenreuther JM, De La Paz L, Swartz JR, and Britt RD

Subjects

Catalysis, Electron Spin Resonance Spectroscopy, Escherichia coli genetics, Shewanella metabolism, Bacterial Proteins chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Shewanella enzymology

Abstract

Hydrogenase enzymes catalyze the rapid and reversible interconversion of H2 with protons and electrons. The active site of the [FeFe] hydrogenase is the H cluster, which consists of a [4Fe-4S]H subcluster linked to an organometallic [2Fe]H subcluster. Understanding the biosynthesis and catalytic mechanism of this structurally unusual active site will aid in the development of synthetic and biological hydrogenase catalysts for applications in solar fuel generation. The [2Fe]H subcluster is synthesized and inserted by three maturase enzymes-HydE, HydF, and HydG-in a complex process that involves inorganic, organometallic, and organic radical chemistry. HydG is a member of the radical S-adenosyl-l-methionine (SAM) family of enzymes and is thought to play a prominent role in [2Fe]H subcluster biosynthesis by converting inorganic Fe(2+), l-cysteine (Cys), and l-tyrosine (Tyr) into an organometallic [(Cys)Fe(CO)2(CN)](-) intermediate that is eventually incorporated into the [2Fe]H subcluster. In this Forum Article, the mechanism of [2Fe]H subcluster biosynthesis is discussed with a focus on how this key [(Cys)Fe(CO)2(CN)](-) species is formed. Particular attention is given to the initial metallocluster composition of HydG, the modes of substrate binding (Fe(2+), Cys, Tyr, and SAM), the mechanism of SAM-mediated Tyr cleavage to CO and CN(-), and the identification of the final organometallic products of the reaction.

Published

2016

22. Biochemical and Spectroscopic Studies of Epoxyqueuosine Reductase: A Novel Iron-Sulfur Cluster- and Cobalamin-Containing Protein Involved in the Biosynthesis of Queuosine.

Author

Miles ZD, Myers WK, Kincannon WM, Britt RD, and Bandarian V

Subjects

Catalysis, Bacillus subtilis chemistry, Bacillus subtilis genetics, Bacillus subtilis metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins genetics, Iron-Sulfur Proteins metabolism, Nucleoside Q biosynthesis, Nucleoside Q chemistry, Nucleoside Q genetics, Oxidoreductases chemistry, Oxidoreductases genetics, Oxidoreductases metabolism, Vitamin B 12 chemistry, Vitamin B 12 genetics, Vitamin B 12 metabolism

Abstract

Queuosine is a hypermodified nucleoside present in the wobble position of tRNAs with a 5'-GUN-3' sequence in their anticodon (His, Asp, Asn, and Tyr). The 7-deazapurine core of the base is synthesized de novo in prokaryotes from guanosine 5'-triphosphate in a series of eight sequential enzymatic transformations, the final three occurring on tRNA. Epoxyqueuosine reductase (QueG) catalyzes the final step in the pathway, which entails the two-electron reduction of epoxyqueuosine to form queuosine. Biochemical analyses reveal that this enzyme requires cobalamin and two [4Fe-4S] clusters for catalysis. Spectroscopic studies show that the cobalamin appears to bind in a base-off conformation, whereby the dimethylbenzimidazole moiety of the cofactor is removed from the coordination sphere of the cobalt but not replaced by an imidazole side chain, which is a hallmark of many cobalamin-dependent enzymes. The bioinformatically identified residues are shown to have a role in modulating the primary coordination sphere of cobalamin. These studies provide the first demonstration of the cofactor requirements for QueG.

Published

2015

23. Circadian rhythms. A protein fold switch joins the circadian oscillator to clock output in cyanobacteria.

Author

Chang YG, Cohen SE, Phong C, Myers WK, Kim YI, Tseng R, Lin J, Zhang L, Boyd JS, Lee Y, Kang S, Lee D, Li S, Britt RD, Rust MJ, Golden SS, and LiWang A

Subjects

Bacterial Proteins genetics, Circadian Rhythm Signaling Peptides and Proteins genetics, Phosphorylation, Protein Folding, Protein Structure, Secondary, Synechococcus metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Circadian Rhythm, Circadian Rhythm Signaling Peptides and Proteins chemistry, Circadian Rhythm Signaling Peptides and Proteins metabolism, Synechococcus physiology

Abstract

Organisms are adapted to the relentless cycles of day and night, because they evolved timekeeping systems called circadian clocks, which regulate biological activities with ~24-hour rhythms. The clock of cyanobacteria is driven by a three-protein oscillator composed of KaiA, KaiB, and KaiC, which together generate a circadian rhythm of KaiC phosphorylation. We show that KaiB flips between two distinct three-dimensional folds, and its rare transition to an active state provides a time delay that is required to match the timing of the oscillator to that of Earth's rotation. Once KaiB switches folds, it binds phosphorylated KaiC and captures KaiA, which initiates a phase transition of the circadian cycle, and it regulates components of the clock-output pathway, which provides the link that joins the timekeeping and signaling functions of the oscillator., (Copyright © 2015, American Association for the Advancement of Science.)

Published

2015

24. Ammonia Binds to the Dangler Manganese of the Photosystem II Oxygen-Evolving Complex.

Author

Oyala PH, Stich TA, Debus RJ, and Britt RD

Subjects

Bacterial Proteins chemistry, Binding Sites, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Hydrogen Bonding, Manganese chemistry, Models, Molecular, Photosystem II Protein Complex chemistry, Protein Conformation, Synechocystis chemistry, Ammonia metabolism, Bacterial Proteins metabolism, Manganese metabolism, Photosystem II Protein Complex metabolism, Synechocystis metabolism

Abstract

High-resolution X-ray structures of photosystem II reveal several potential substrate binding sites at the water-oxidizing/oxygen-evolving 4MnCa cluster. Aspartate-61 of the D1 protein hydrogen bonds with one such water (W1), which is bound to the dangler Mn4A of the oxygen-evolving complex. Comparison of pulse EPR spectra of (14)NH3 and (15)NH3 bound to wild-type Synechocystis PSII and a D1-D61A mutant lacking this hydrogen-bonding interaction demonstrates that ammonia binds as a terminal NH3 at this dangler Mn4A site and not as a partially deprotonated bridge between two metal centers. The implications of this finding on identifying the binding sites of the substrate and the subsequent mechanism of dioxygen formation are discussed.

Published

2015

25. X-ray crystallographic and EPR spectroscopic analysis of HydG, a maturase in [FeFe]-hydrogenase H-cluster assembly.

Author

Dinis P, Suess DL, Fox SJ, Harmer JE, Driesener RC, De La Paz L, Swartz JR, Essex JW, Britt RD, and Roach PL

Subjects

Catalytic Domain, Models, Molecular, Protein Conformation, Tyrosine chemistry, Bacterial Proteins chemistry, Crystallography, X-Ray methods, Electron Spin Resonance Spectroscopy methods, Hydrogen chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

Hydrogenases use complex metal cofactors to catalyze the reversible formation of hydrogen. In [FeFe]-hydrogenases, the H-cluster cofactor includes a diiron subcluster containing azadithiolate, three CO, and two CN(-) ligands. During the assembly of the H cluster, the radical S-adenosyl methionine (SAM) enzyme HydG lyses the substrate tyrosine to yield the diatomic ligands. These diatomic products form an enzyme-bound Fe(CO)x(CN)y synthon that serves as a precursor for eventual H-cluster assembly. To further elucidate the mechanism of this complex reaction, we report the crystal structure and EPR analysis of HydG. At one end of the HydG (βα)8 triosephosphate isomerase (TIM) barrel, a canonical [4Fe-4S] cluster binds SAM in close proximity to the proposed tyrosine binding site. At the opposite end of the active-site cavity, the structure reveals the auxiliary Fe-S cluster in two states: one monomer contains a [4Fe-5S] cluster, and the other monomer contains a [5Fe-5S] cluster consisting of a [4Fe-4S] cubane bridged by a μ2-sulfide ion to a mononuclear Fe(2+) center. This fifth iron is held in place by a single highly conserved protein-derived ligand: histidine 265. EPR analysis confirms the presence of the [5Fe-5S] cluster, which on incubation with cyanide, undergoes loss of the labile iron to yield a [4Fe-4S] cluster. We hypothesize that the labile iron of the [5Fe-5S] cluster is the site of Fe(CO)x(CN)y synthon formation and that the limited bonding between this iron and HydG may facilitate transfer of the intact synthon to its cognate acceptor for subsequent H-cluster assembly.

Published

2015

26. Biochemistry. One step closer to O₂.

Author

Britt RD and Oyala PH

Subjects

Bacterial Proteins chemistry, Cyanobacteria chemistry, Oxygen chemistry, Photosystem II Protein Complex chemistry

Published

2014

27. The HydG enzyme generates an Fe(CO)2(CN) synthon in assembly of the FeFe hydrogenase H-cluster.

Author

Kuchenreuther JM, Myers WK, Suess DL, Stich TA, Pelmenschikov V, Shiigi SA, Cramer SP, Swartz JR, Britt RD, and George SJ

Subjects

Catalysis, Shewanella putrefaciens enzymology, Spectroscopy, Fourier Transform Infrared, Bacterial Proteins chemistry, Catalytic Domain, Hydrogenase chemistry, Iron Carbonyl Compounds metabolism, Iron-Sulfur Proteins chemistry

Abstract

Three iron-sulfur proteins--HydE, HydF, and HydG--play a key role in the synthesis of the [2Fe](H) component of the catalytic H-cluster of FeFe hydrogenase. The radical S-adenosyl-L-methionine enzyme HydG lyses free tyrosine to produce p-cresol and the CO and CN(-) ligands of the [2Fe](H) cluster. Here, we applied stopped-flow Fourier transform infrared and electron-nuclear double resonance spectroscopies to probe the formation of HydG-bound Fe-containing species bearing CO and CN(-) ligands with spectroscopic signatures that evolve on the 1- to 1000-second time scale. Through study of the (13)C, (15)N, and (57)Fe isotopologs of these intermediates and products, we identify the final HydG-bound species as an organometallic Fe(CO)2(CN) synthon that is ultimately transferred to apohydrogenase to form the [2Fe](H) component of the H-cluster.

Published

2014

28. A radical intermediate in tyrosine scission to the CO and CN- ligands of FeFe hydrogenase.

Author

Kuchenreuther JM, Myers WK, Stich TA, George SJ, Nejatyjahromy Y, Swartz JR, and Britt RD

Subjects

Bacterial Proteins genetics, Carbon Monoxide chemistry, Catalysis, Catalytic Domain, Iron-Sulfur Proteins genetics, Ligands, S-Adenosylmethionine chemistry, Bacterial Proteins chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Shewanella enzymology, Tyrosine chemistry

Abstract

The radical S-adenosylmethionine (SAM) enzyme HydG lyses free l-tyrosine to produce CO and CN(-) for the assembly of the catalytic H cluster of FeFe hydrogenase. We used electron paramagnetic resonance spectroscopy to detect and characterize HydG reaction intermediates generated with a set of (2)H, (13)C, and (15)N nuclear spin-labeled tyrosine substrates. We propose a detailed reaction mechanism in which the radical SAM reaction, initiated at an N-terminal 4Fe-4S cluster, generates a tyrosine radical bound to a C-terminal 4Fe-4S cluster. Heterolytic cleavage of this tyrosine radical at the Cα-Cβ bond forms a transient 4-oxidobenzyl (4OB(•)) radical and a dehydroglycine bound to the C-terminal 4Fe-4S cluster. Electron and proton transfer to this 4OB(•) radical forms p-cresol, with the conversion of this dehydroglycine ligand to Fe-bound CO and CN(-), a key intermediate in the assembly of the 2Fe subunit of the H cluster.

Published

2013

29. The conformation of P450cam in complex with putidaredoxin is dependent on oxidation state.

Author

Myers WK, Lee YT, Britt RD, and Goodin DB

Subjects

Bacterial Proteins chemistry, Camphor 5-Monooxygenase chemistry, Ferredoxins chemistry, Oxidation-Reduction, Protein Binding, Protein Conformation, Pseudomonas putida chemistry, Pseudomonas putida metabolism, Bacterial Proteins metabolism, Camphor 5-Monooxygenase metabolism, Ferredoxins metabolism, Pseudomonas putida enzymology

Abstract

Double electron-electron resonance (DEER) spectroscopy was used to determine the conformational state in solution for the heme monooxygenase P450cam when bound to its natural redox partner, putidaredoxin (Pdx). When oxidized Pdx was titrated into substrate-bound ferric P450cam, the enzyme shifted from the closed to the open conformation. In sharp contrast, however, the enzyme remained in the closed conformation when ferrous-CO P450cam was titrated with reduced Pdx. This result fully supports the proposal that binding of oxidized Pdx to P450cam opposes the open-to-closed transition induced by substrate binding. However, the data strongly suggest that in solution, binding of reduced Pdx to P450cam does not favor the open conformation. This supports a model in which substrate recognition is associated with the open-to-closed transition and electron transfer from Pdx occurs in the closed conformation. The opening of the enzyme in the ferric-hydroperoxo state following electron transfer from Pdx would provide for efficient O2 bond activation, substrate oxidation, and product release.

Published

2013

30. Interaction of PqqE and PqqD in the pyrroloquinoline quinone (PQQ) biosynthetic pathway links PqqD to the radical SAM superfamily.

Author

Wecksler SR, Stoll S, Iavarone AT, Imsand EM, Tran H, Britt RD, and Klinman JP

Subjects

Bacterial Proteins metabolism, Free Radicals chemistry, Free Radicals metabolism, Klebsiella pneumoniae enzymology, PQQ Cofactor chemistry, S-Adenosylmethionine metabolism, Bacterial Proteins chemistry, PQQ Cofactor biosynthesis, S-Adenosylmethionine chemistry

Abstract

pqqD is one of six genes required for PQQ production in Klebsiella pneumoniae. Herein, we demonstrate that PqqD interacts specifically with the radical SAM enzyme PqqE, causing a perturbation in the electronic environment around the [4Fe-4S](+) clusters. This interaction redirects the role for PqqD in PQQ biosynthesis.

Published

2010

31. Infrared and EPR spectroscopic characterization of a Ni(I) species formed by photolysis of a catalytically competent Ni(I)-CO intermediate in the acetyl-CoA synthase reaction.

Author

Bender G, Stich TA, Yan L, Britt RD, Cramer SP, and Ragsdale SW

Subjects

Acetate-CoA Ligase metabolism, Bacterial Proteins metabolism, Binding Sites, Carbon Monoxide metabolism, Catalysis, Electron Spin Resonance Spectroscopy, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Kinetics, Oxidation-Reduction, Photolysis, Thermoanaerobacter enzymology, Acetate-CoA Ligase chemistry, Bacterial Proteins chemistry, Carbon Monoxide chemistry, Nickel chemistry

Abstract

Acetyl-CoA synthase (ACS) catalyzes the synthesis of acetyl-CoA from CO, coenzyme A (CoA), and a methyl group from the CH(3)-Co(3+) site in the corrinoid iron-sulfur protein (CFeSP). These are the key steps in the Wood-Ljungdahl pathway of anaerobic CO and CO(2) fixation. The active site of ACS is the A-cluster, which is an unusual nickel-iron-sulfur cluster. There is significant evidence for the catalytic intermediacy of a CO-bound paramagnetic Ni species, with an electronic configuration of [Fe(4)S(4)](2+)-(Ni(p)(+)-CO)-(Ni(d)(2+)), where Ni(p) and Ni(d) represent the Ni centers in the A-cluster that are proximal and distal to the [Fe(4)S(4)](2+) cluster, respectively. This well-characterized Ni(p)(+)-CO intermediate is often called the NiFeC species. Photolysis of the Ni(p)(+)-CO state generates a novel Ni(p)(+) species (A(red)*) with a rhombic electron paramagnetic resonance spectrum (g values of 2.56, 2.10, and 2.01) and an extremely low (1 kJ/mol) barrier for recombination with CO. We suggest that the photolytically generated A(red)* species is (or is similar to) the Ni(p)(+) species that binds CO (to form the Ni(p)(+)-CO species) and the methyl group (to form Ni(p)-CH(3)) in the ACS catalytic mechanism. The results provide support for a binding site (an "alcove") for CO near Ni(p), indicated by X-ray crystallographic studies of the Xe-incubated enzyme. We propose that, during catalysis, a resting Ni(p)(2+) state predominates over the active Ni(p)(+) species (A(red)*) that is trapped by the coupling of a one-electron transfer step to the binding of CO, which pulls the equilibrium toward Ni(p)(+)-CO formation.

Published

2010

32. Structural basis for hydration dynamics in radical stabilization of bilin reductase mutants.

Author

Kohler AC, Gae DD, Richley MA, Stoll S, Gunn A, Lim S, Martin SS, Doukov TI, Britt RD, Ames JB, Lagarias JC, and Fisher AJ

Subjects

Asparagine genetics, Bacterial Proteins genetics, Catalysis, Catalytic Domain, Crystallography, X-Ray, Histidine genetics, Mutation, Oxidoreductases genetics, Protein Conformation, Bacterial Proteins chemistry, Bile Pigments chemistry, Oxidoreductases chemistry, Phycobilins chemistry, Phycocyanin chemistry, Water chemistry

Abstract

Heme-derived linear tetrapyrroles (phytobilins) in phycobiliproteins and phytochromes perform critical light-harvesting and light-sensing roles in oxygenic photosynthetic organisms. A key enzyme in their biogenesis, phycocyanobilin:ferredoxin oxidoreductase (PcyA), catalyzes the overall four-electron reduction of biliverdin IXalpha to phycocyanobilin--the common chromophore precursor for both classes of biliproteins. This interconversion occurs via semireduced bilin radical intermediates that are profoundly stabilized by selected mutations of two critical catalytic residues, Asp105 and His88. To understand the structural basis for this stabilization and to gain insight into the overall catalytic mechanism, we report the high-resolution crystal structures of substrate-loaded Asp105Asn and His88Gln mutants of Synechocystis sp. PCC 6803 PcyA in the initial oxidized and one-electron reduced radical states. Unlike wild-type PcyA, both mutants possess a bilin-interacting axial water molecule that is ejected from the active site upon formation of the enzyme-bound neutral radical complex. Structural studies of both mutants also show that the side chain of Glu76 is unfavorably located for D-ring vinyl reduction. On the basis of these structures and companion (15)N-(1)H long-range HMQC NMR analyses to assess the protonation state of histidine residues, we propose a new mechanistic scheme for PcyA-mediated reduction of both vinyl groups of biliverdin wherein an axial water molecule, which prematurely binds and ejects from both mutants upon one electron reduction, is required for catalytic turnover of the semireduced state.

Published

2010

33. Pyrroloquinoline quinone biogenesis: demonstration that PqqE from Klebsiella pneumoniae is a radical S-adenosyl-L-methionine enzyme.

Author

Wecksler SR, Stoll S, Tran H, Magnusson OT, Wu SP, King D, Britt RD, and Klinman JP

Subjects

Amino Acid Sequence, Cloning, Organism, Deoxyadenosines metabolism, Escherichia coli metabolism, Kinetics, Molecular Sequence Data, Oxidation-Reduction, PQQ Cofactor genetics, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Klebsiella pneumoniae enzymology, Klebsiella pneumoniae metabolism, PQQ Cofactor biosynthesis, PQQ Cofactor chemistry, S-Adenosylmethionine metabolism

Abstract

Biogenesis of pyrroloquinoline quinone (PQQ) in Klebsiella pneumoniae requires the expression of six genes (pqqA-F). One of these genes (pqqE) encodes a 43 kDa protein (PqqE) that plays a role in the initial steps in PQQ formation [Veletrop, J. S., et al. (1995) J. Bacteriol. 177, 5088-5098]. PqqE contains two highly conserved cysteine motifs at the N- and C-termini, with the N-terminal motif comprised of a CX(3)CX(2)C consensus sequence that is unique to a family of proteins known as radical S-adenosyl-l-methionine (SAM) enzymes [Sofia, H. J., et al. (2001) Nucleic Acids Res. 29, 1097-1106]. PqqE from K. pneumoniae was cloned into Escherichia coli and expressed as the native protein and with an N-terminal His(6) tag. Anaerobic expression and purification of the His(6)-tagged PqqE results in an enzyme with a brownish-red hue indicative of Fe-S cluster formation. Spectroscopic and physical analyses indicate that PqqE contains a mixture of Fe-S clusters, with the predominant form of the enzyme containing two [4Fe-4S] clusters. PqqE isolated anaerobically yields an active enzyme capable of cleaving SAM to methionine and 5'-deoxyadenosine in an uncoupled reaction (k(obs) = 0.011 +/- 0.001 min(-1)). In this reaction, the 5'-deoxyadenosyl radical either abstracts a hydrogen atom from a solvent accessible position in the enzyme or obtains a proton and electron from buffer. The putative PQQ substrate PqqA has not yet been shown to be modified by PqqE, implying that PqqA must be modified before becoming the substrate for PqqE and/or that another protein in the biosynthetic pathway is critical for the initial steps in PQQ biogenesis.

Published

2009

34. Effects of pH on the Rieske protein from Thermus thermophilus: a spectroscopic and structural analysis.

Author

Konkle ME, Muellner SK, Schwander AL, Dicus MM, Pokhrel R, Britt RD, Taylor AB, and Hunsicker-Wang LM

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Circular Dichroism, Crystallography, X-Ray, Electron Transport, Electron Transport Complex III genetics, Electron Transport Complex III metabolism, Kinetics, Models, Molecular, Protein Conformation, Spectrophotometry, Thermus thermophilus genetics, Bacterial Proteins chemistry, Electron Transport Complex III chemistry, Hydrogen-Ion Concentration, Thermus thermophilus metabolism

Abstract

The Rieske protein from Thermus thermophilus (TtRp) and a truncated version of the protein (truncTtRp), produced to achieve a low-pH crystallization condition, have been characterized using UV-visible and circular dichroism spectroscopies. TtRp and truncTtRp undergo a change in the UV-visible spectra with increasing pH. The LMCT band at 458 nm shifts to 436 nm and increases in intensity. The increase at 436 nm versus pH can be fit using the sum of two Henderson-Hasselbalch equations, yielding two pK(a) values for the oxidized protein. For TtRp, pK(ox1) = 7.48 +/- 0.12 and pK(ox2) = 10.07 +/- 0.17. For truncTtRp, pK(ox1) = 7.87 +/- 0.17 and pK(ox2) = 9.84 +/- 0.42. The shift to shorter wavelength and the increase in intensity for the LMCT band with increasing pH are consistent with deprotonation of the histidine ligands. A pH titration of truncTtRp monitored by circular dichroism also showed pH-dependent changes at 315 and 340 nm. At 340 nm, the fit gives pK(ox1) = 7.14 +/- 0.26 and pK(ox2) = 9.32 +/- 0.36. The change at 315 nm is best fit for a single deprotonation event, giving pK(ox1) = 7.82 +/- 0.10. The lower wavelength region of the CD spectra was unaffected by pH, indicating that the overall fold of the protein remains unchanged, which is consistent with crystallographic results of truncTtRp. The structure of truncTtRp crystallized at pH 6.2 is very similar to TtRp at pH 8.5 and contains only subtle changes localized at the [2Fe-2S] cluster. These titration and structural results further elucidate the histidine ligand characteristics and are consistent with important roles for these amino acids.

Published

2009

35. NO formation by a catalytically self-sufficient bacterial nitric oxide synthase from Sorangium cellulosum.

Author

Agapie T, Suseno S, Woodward JJ, Stoll S, Britt RD, and Marletta MA

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Binding Sites, Catalysis, Electron Spin Resonance Spectroscopy, Electron Transport, Electrophoresis, Polyacrylamide Gel, Heme chemistry, Heme metabolism, Kinetics, Models, Chemical, Molecular Sequence Data, Myxococcales genetics, NADP chemistry, NADP metabolism, Nitric Oxide chemistry, Nitric Oxide Synthase genetics, Oxidation-Reduction, Oxygen chemistry, Oxygen metabolism, Protein Binding, Sequence Homology, Amino Acid, Spectrophotometry, Ultraviolet, Substrate Specificity, Bacterial Proteins metabolism, Myxococcales enzymology, Nitric Oxide metabolism, Nitric Oxide Synthase metabolism

Abstract

The role of nitric oxide (NO) in the host response to infection and in cellular signaling is well established. Enzymatic synthesis of NO is catalyzed by the nitric oxide synthases (NOSs), which convert Arg into NO and citrulline using co-substrates O2 and NADPH. Mammalian NOS contains a flavin reductase domain (FAD and FMN) and a catalytic heme oxygenase domain (P450-type heme and tetrahydrobiopterin). Bacterial NOSs, while much less studied, were previously identified as only containing the heme oxygenase domain of the more complex mammalian NOSs. We report here on the characterization of a NOS from Sorangium cellulosum (both full-length, scNOS, and oxygenase domain, scNOSox). scNOS contains a catalytic, oxygenase domain similar to those found in the mammalian NOS and in other bacteria. Unlike the other bacterial NOSs reported to date, however, this protein contains a fused reductase domain. The scNOS reductase domain is unique for the entire NOS family because it utilizes a 2Fe2S cluster for electron transfer. scNOS catalytically produces NO and citrulline in the presence of either tetrahydrobiopterin or tetrahydrofolate. These results establish a bacterial electron transfer pathway used for biological NO synthesis as well as a unique flexibility in using different tetrahydropterin cofactors for this reaction.

Published

2009

36. Structure of the biliverdin radical intermediate in phycocyanobilin:ferredoxin oxidoreductase identified by high-field EPR and DFT.

Author

Stoll S, Gunn A, Brynda M, Sughrue W, Kohler AC, Ozarowski A, Fisher AJ, Lagarias JC, and Britt RD

Subjects

Bacterial Proteins metabolism, Biliverdine metabolism, Electron Spin Resonance Spectroscopy methods, Models, Molecular, Mutagenesis, Site-Directed, Oxidoreductases metabolism, Bacterial Proteins chemistry, Biliverdine chemistry, Oxidoreductases chemistry

Abstract

The cyanobacterial enzyme phycocyanobilin:ferredoxin oxidoreductase (PcyA) catalyzes the two-step four-electron reduction of biliverdin IXalpha to phycocyanobilin, the precursor of biliprotein chromophores found in phycobilisomes. It is known that catalysis proceeds via paramagnetic radical intermediates, but the structure of these intermediates and the transfer pathways for the four protons involved are not known. In this study, high-field electron paramagnetic resonance (EPR) spectroscopy of frozen solutions and single crystals of the one-electron reduced protein-substrate complex of two PcyA mutants D105N from the cyanobacteria Synechocystis sp. PCC6803 and Nostoc sp. PCC7120 are examined. Detailed analysis of Synechocystis D105N mutant spectra at 130 and 406 GHz reveals a biliverdin radical with a very narrow g tensor with principal values 2.00359(5), 2.00341(5), and 2.00218(5). Using density-functional theory (DFT) computations to explore the possible protonation states of the biliverdin radical, it is shown that this g tensor is consistent with a biliverdin radical where the carbonyl oxygen atoms on both the A and the D pyrrole rings are protonated. This experimentally confirms the reaction mechanism recently proposed (Tu, et al. Biochemistry 2007, 46, 1484).

Published

2009

37. Metal trafficking for nitrogen fixation: NifQ donates molybdenum to NifEN/NifH for the biosynthesis of the nitrogenase FeMo-cofactor.

Author

Hernandez JA, Curatti L, Aznar CP, Perova Z, Britt RD, and Rubio LM

Subjects

Azotobacter vinelandii genetics, Azotobacter vinelandii metabolism, Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Biological Transport, Coenzymes genetics, Coenzymes isolation & purification, Iron-Sulfur Proteins genetics, Iron-Sulfur Proteins isolation & purification, Iron-Sulfur Proteins metabolism, Metalloproteins genetics, Metalloproteins isolation & purification, Molybdenum Cofactors, Protein Binding, Pteridines isolation & purification, Transcription Factors genetics, Transcription Factors isolation & purification, Bacterial Proteins metabolism, Coenzymes metabolism, Iron metabolism, Metalloproteins metabolism, Molybdenum metabolism, Nitrogen Fixation, Nitrogenase metabolism, Pteridines metabolism, Transcription Factors metabolism

Abstract

The molybdenum nitrogenase, present in a diverse group of bacteria and archea, is the major contributor to biological nitrogen fixation. The nitrogenase active site contains an iron-molybdenum cofactor (FeMo-co) composed of 7Fe, 9S, 1Mo, one unidentified light atom, and homocitrate. The nifQ gene was known to be involved in the incorporation of molybdenum into nitrogenase. Here we show direct biochemical evidence for the role of NifQ in FeMo-co biosynthesis. As-isolated NifQ was found to carry a molybdenum-iron-sulfur cluster that serves as a specific molybdenum donor for FeMo-co biosynthesis. Purified NifQ supported in vitro FeMo-co synthesis in the absence of an additional molybdenum source. The mobilization of molybdenum from NifQ required the simultaneous participation of NifH and NifEN in the in vitro FeMo-co synthesis assay, suggesting that NifQ would be the physiological molybdenum donor to a hypothetical NifEN/NifH complex.

Published

2008

38. A conserved histidine-aspartate pair is required for exovinyl reduction of biliverdin by a cyanobacterial phycocyanobilin:ferredoxin oxidoreductase.

Author

Tu SL, Sughrue W, Britt RD, and Lagarias JC

Subjects

Amino Acid Sequence, Bacterial Proteins metabolism, Bile Pigments chemistry, Biochemistry methods, Catalysis, Conserved Sequence, Dose-Response Relationship, Drug, Electron Spin Resonance Spectroscopy, Electrons, Hydrogen-Ion Concentration, Kinetics, Models, Chemical, Molecular Sequence Data, Mutagenesis, Site-Directed, Mutation, Oxidoreductases metabolism, Protons, Sequence Homology, Amino Acid, Spectrophotometry, Temperature, Aspartic Acid chemistry, Bacterial Proteins chemistry, Biliverdine chemistry, Cyanobacteria enzymology, Histidine chemistry, Oxidoreductases chemistry

Abstract

Phycocyanobilin:ferredoxin oxidoreductase is a member of the ferredoxin-dependent bilin reductase family and catalyzes two vinyl reductions of biliverdin IXalpha to produce phycocyanobilin, the pigment precursor of both phytochrome and phycobiliprotein chromophores in cyanobacteria. Atypically for ferredoxin-dependent enzymes, phycocyanobilin:ferredoxin oxidoreductase mediates direct electron transfers from reduced ferredoxin to its tetrapyrrole substrate without metal ion or organic cofactors. We previously showed that bound bilin radical intermediates could be detected by low temperature electron paramagnetic resonance and absorption spectroscopies (Tu, S., Gunn, A., Toney, M. D., Britt, R. D., and Lagarias, J. C. (2004) J. Am. Chem. Soc. 126, 8682-8693). On the basis of these studies, a mechanism involving sequential electron-coupled proton transfers to protonated bilin substrates buried within the phycocyanobilin:ferredoxin oxidoreductase protein scaffold was proposed. The present investigation was undertaken to identify catalytic residues in phycocyanobilin:ferredoxin oxidoreductase from the cyanobacterium Nostoc sp. PCC7120 through site-specific chemical modification and mutagenesis of candidate proton-donating residues. These studies identified conserved histidine and aspartate residues essential for the catalytic activity of phycocyanobilin:ferredoxin oxidoreductase. Spectroscopic evidence for the formation of stable enzyme-bound biliverdin radicals for the H85Q and D102N mutants support their role as a "coupled" proton-donating pair during the reduction of the biliverdin exovinyl group.

Published

2006