31 results on '"Melanie S. Rogers"'
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2. Dynamic Long-Range Interactions Influence Substrate Binding and Catalysis by Human Histidine Triad Nucleotide Binding Proteins (HINTs), Key Regulators of Multiple Cellular Processes and Activators of Antiviral ProTides
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Alexander Strom, Rachit Shah, Rafal Dolot, Melanie S. Rogers, Cher-Ling Tong, David Wang, Youlin Xia, John D. Lipscomb, and Carston R. Wagner
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Analgesics, Opioid ,Kinetics ,Nucleotides ,Humans ,Histidine ,Drug Tolerance ,Biochemistry ,Antiviral Agents ,Article ,Catalysis - Abstract
Human histidine triad nucleotide binding (hHINT) proteins catalyze nucleotide phosphoramidase and acyl-phosphatase reactions that are essential for the activation of antiviral proTides, such as Sofosbuvir and Remdesivir. hHINT1 and hHINT2 are highly homologous but exhibit disparate roles as regulators of opioid tolerance (hHINT1) and mitochondrial activity (hHINT2). NMR studies of hHINT1 reveal a pair of dynamic surface residues (Q62, E100) which gate a conserved water channel leading to the active site 13 Å away. hHINT2 crystal structures identify analogous residues (R99, D137) and water channel. hHINT1 Q62 variants significantly alter the steady-state k(cat) and K(m) for turnover of the fluorescent substrate (TpAd), while stopped-flow kinetics indicate the K(D) also changes. hHINT2, like hHINT1, exhibits a burst-phase of adenylation, monitored by fluorescent tryptamine release, prior to rate-limiting hydrolysis and nucleotide release. hHINT2 exhibits a much smaller burst-phase amplitude than hHINT1, which is further diminished in hHINT2 R99Q. Kinetic simulations suggest that amplitude variations can be accounted for by a variable fluorescent yield of the E•S complex from changes in the environment of bound TpAd. Isothermal titration calorimetry measurements of inhibitor binding shows that these hHINT variants also alter the thermodynamic binding profile. We propose that these altered surface residues engender long-range dynamic changes that affect the orientation of bound ligands, altering the thermodynamic and kinetic characteristics of hHINT active site function. Thus, studies of the cellular roles and proTide activation potential by hHINTs should consider the importance of long-range interactions and possible protein binding surfaces far from the active site.
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- 2022
3. <scp>6‐phenylpyrrolocytosine</scp> as a fluorescent probe to examine nucleotide flipping catalyzed by a <scp>DNA</scp> repair protein
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Sreenivas Kanugula, Melanie S. Rogers, Delshanee Kotandeniya, Natalia Y. Tretyakova, Jenna Fernandez, Robert H. E. Hudson, Freddys Rodriguez, and John D. Lipscomb
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Alkylation ,DNA Repair ,Guanine ,Biophysics ,Guanosine ,Cytidine ,010402 general chemistry ,01 natural sciences ,Biochemistry ,Article ,Biomaterials ,Cytosine ,DNA Adducts ,O(6)-Methylguanine-DNA Methyltransferase ,chemistry.chemical_compound ,Pyrroles ,A-DNA ,Nucleotide ,Base Pairing ,Fluorescent Dyes ,chemistry.chemical_classification ,010405 organic chemistry ,Organic Chemistry ,General Medicine ,Molecular biology ,0104 chemical sciences ,Kinetics ,chemistry ,CpG site ,Biocatalysis ,Mutagenesis, Site-Directed ,CpG Islands ,Tumor Suppressor Protein p53 ,DNA ,Alkyltransferase - Abstract
Cellular exposure to tobacco-specific nitrosamines causes formation of promutagenic O(6)-[4-oxo-4-(3-pyridyl)but-1-yl]guanine (O(6)-POB-G) and O(6)-methylguanine (O(6)-Me-G) adducts in DNA. These adducts can be directly repaired by O(6)-alkylguanine-DNA alkyltransferase (AGT). Repair begins by flipping the damaged base out of the DNA helix. AGT binding and base-flipping have been previously studied using pyrrolocytosine as a fluorescent probe paired to the O(6)-alkyl-guanine lesion, but low fluorescence yield limited the resolution of steps in the repair process. Here, we utilize the highly fluorescent 6-phenylpyrrolo-2’-deoxycytidine (6-phenylpyrrolo-C) to investigate AGT-DNA interactions. Synthetic oligodeoxynucleotide duplexes containing O(6)-POB-G and O(6)-Me-G adducts were placed within the CpG sites of codons 158, 245, and 248 of the p53 tumor suppressor gene and base-paired to 6-phenylpyrrolo-C in the opposite strand. Neighboring cytosine was either unmethylated or methylated. Stopped-flow fluorescence measurements were performed by mixing the DNA duplexes with C145A or R128G AGT variants. We observe a rapid, two-step, nearly irreversible binding of AGT to DNA followed by two slower steps, one of which is base-flipping. Placing 5-methylcytosine immediately 5’ to the alkylated guanosine causes a reduction in rate constant of nucleotide flipping. O(6)-POB-G at codon 158 decreased the base flipping rate constant by 3.5-fold compared with O(6)-Me-G at the same position. A similar effect was not observed at other codons.
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- 2020
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4. Salicylate 5-Hydroxylase: Intermediates in Aromatic Hydroxylation by a Rieske Monooxygenase
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Melanie S. Rogers and John D. Lipscomb
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biology ,Chemistry ,Active site ,Chromophore ,Photochemistry ,Hydroxylation ,Biochemistry ,Hydrocarbons, Aromatic ,Article ,Catalysis ,law.invention ,Mixed Function Oxygenases ,Oxygen ,chemistry.chemical_compound ,Electron transfer ,Kinetics ,Reaction rate constant ,Catalytic cycle ,law ,biology.protein ,Electron paramagnetic resonance ,Oxidation-Reduction - Abstract
Rieske oxygenases (ROs) catalyze a large range of oxidative chemistry. We have shown that cis-dihydrodiol-forming Rieske dioxygenases first react with their aromatic substrates via an active site nonheme Fe(III)-superoxide; electron transfer from the Rieske cluster then completes the product-forming reaction. Alternatively, two-electron-reduced Fe(III)-peroxo or hydroxo-Fe(V)-oxo activated oxygen intermediates are possible and may be utilized by other ROs to expand the catalytic range. Here, the reaction of a Rieske monooxygenase, salicylate 5-hydroxylase, that does not form a cis-dihydrodiol is examined. Single-turnover kinetic studies show fast binding of salicylate and O2. Transfer of the Rieske electron required to form the gentisate product occurs through bonds over ∼12 A and must also be very fast. However, the observed rate constant for this reaction is much slower than expected and sensitive to substrate type. This suggests that initial reaction with salicylate occurs using the same Fe(III)-superoxo-level intermediate as Rieske dioxygenases and that this reaction limits the observed rate of electron transfer. A transient intermediate (λmax = 700 nm) with an electron paramagnetic resonance (EPR) at g = 4.3 is observed after the product is formed in the active site. The use of 17O2 (I = 5/2) results in hyperfine broadening of the g = 4.3 signal, showing that gentisate binds to the mononuclear iron via its C5-OH in the intermediate. The chromophore and EPR signal allow study of product release in the catalytic cycle. Comparison of the kinetics of single- and multiple-turnover reactions shows that re-reduction of the metal centers accelerates product release ∼300-fold, providing insight into the regulatory mechanism of ROs.
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- 2019
5. Enzyme Substrate Complex of the H200C Variant of Homoprotocatechuate 2,3-Dioxygenase: Mössbauer and Computational Studies
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Eckard Münck, John D. Lipscomb, Melanie S. Rogers, Katlyn K. Meier, Elena G. Kovaleva, and Emile L. Bominaar
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0301 basic medicine ,chemistry.chemical_classification ,Enzyme substrate complex ,030102 biochemistry & molecular biology ,biology ,Stereochemistry ,Electron Spin Resonance Spectroscopy ,Active site ,Nanotechnology ,Article ,Dioxygenases ,Substrate Specificity ,Catalysis ,Inorganic Chemistry ,Spectroscopy, Mossbauer ,03 medical and health sciences ,Residue (chemistry) ,030104 developmental biology ,Enzyme ,chemistry ,Dioxygenase ,Mössbauer spectroscopy ,biology.protein ,Physical and Theoretical Chemistry ,Low symmetry - Abstract
The extradiol, aromatic ring-cleaving enzyme homoprotocatechuate 2,3-dioxygenase (HPCD) catalyzes a complex chain of reactions that involve second sphere residues of the active site. The importance of the second-sphere residue His200 was demonstrated in studies of HPCD variants, such as His200Cys (H200C), which revealed significant retardations of certain steps in the catalytic process as a result of the substitution, allowing novel reaction cycle intermediates to be trapped for spectroscopic characterization. As the H200C variant largely retains the wild-type active site structure and produces the correct ring-cleaved product, this variant presents a valuable target for mechanistic HPCD studies. Here, the high-spin Fe(II) states of resting H200C and the H200C-homoprotocatechuate enzyme-substrate (ES) complex have been characterized with Mössbauer spectroscopy to assess the electronic structures of the active site in these states. The analysis reveals a high-spin Fe(II) center in a low symmetry environment that is reflected in the values of the zero-field splitting (ZFS) (D ≈ - 8 cm(-1), E/D ≈ 1/3 in ES), as well as the relative orientations of the principal axes of the (57)Fe magnetic hyperfine (A) and electric field gradient (EFG) tensors relative to the ZFS tensor axes. A spin Hamiltonian analysis of the spectra for the ES complex indicates that the magnetization axis of the integer-spin S = 2 Fe(II) system is nearly parallel to the symmetry axis, z, of the doubly occupied dxy ground orbital deduced from the EFG and A-values, an observation, which cannot be rationalized by DFT assisted crystal-field theory. In contrast, ORCA/CASSCF calculations for the ZFS tensor in combination with DFT calculations for the EFG- and A-tensors describe the experimental data remarkably well.
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- 2016
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6. Is Arming Teachers Our Nation's Best Response to Gun Violence? The Perspective of Public Health Students
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Ericka A. Lara Ovares, Cem Akkus, Tara Twyman, Marwa Fadlalla, Olushola Olaitan Ogunleye, Melanie S. Rogers, and Kalpita Patel
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medicine.medical_specialty ,Firearms ,Safety Management ,education ,Poison control ,Criminology ,Suicide prevention ,Occupational safety and health ,03 medical and health sciences ,Politics ,Political science ,Injury prevention ,medicine ,Humans ,0501 psychology and cognitive sciences ,Gun Violence ,030505 public health ,Schools ,Public health ,05 social sciences ,Perspective (graphical) ,Public Health, Environmental and Occupational Health ,Human factors and ergonomics ,United States ,AJPH Gun Violence Prevention ,Public Health ,School Teachers ,0305 other medical science ,050104 developmental & child psychology - Abstract
An editorial is presented which addresses the perspectives of graduate public health students regarding the potential arming of teachers as a means of preventing gun violence in American schools. Gun-related injuries and deaths at U.S. schools in 2018 are examined, including a shooting at Marjory Stoneman Douglas High School in Parkland, Florida. Mental well-being is assessed, along with a gag rule which is designed to prevent the number of gun violence-related deaths from being revealed.
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- 2018
7. NRVS Studies of the Peroxide Shunt Intermediate in a Rieske Dioxygenase and Its Relation to the Native FeII O2 Reaction
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Brent S. Rivard, Kiyoung Park, Shinji Kitao, Michael Hu, Jiyong Zhao, Martin Srnec, Makina Saito, Lei V. Liu, Makoto Seto, Melanie S. Rogers, Edward I. Solomon, Yasuhiro Kobayashi, Yoshitaka Yoda, Lars H. Böttger, John D. Lipscomb, and Kyle D. Sutherlin
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0301 basic medicine ,Models, Molecular ,Iron ,Isopenicillin N synthase ,010402 general chemistry ,01 natural sciences ,Biochemistry ,Peroxide ,Catalysis ,Article ,Dioxygenases ,03 medical and health sciences ,chemistry.chemical_compound ,Colloid and Surface Chemistry ,Dioxygenase ,Nuclear resonance vibrational spectroscopy ,biology ,Chemistry ,Spectrum Analysis ,General Chemistry ,Nonheme iron ,0104 chemical sciences ,Peroxides ,Crystallography ,030104 developmental biology ,Comamonas ,biology.protein ,Thermodynamics ,Density functional theory - Abstract
The Rieske dioxygenases are a major subclass of mononuclear nonheme iron enzymes that play an important role in bioremediation. Recently, a high-spin FeIII–(hydro)-peroxy intermediate (BZDOp) has been trapped in the peroxide shunt reaction of benzoate 1,2-dioxygenase. Defining the structure of this intermediate is essential to understanding the reactivity of these enzymes. Nuclear resonance vibrational spectroscopy (NRVS) is a recently developed synchrotron technique that is ideal for obtaining vibrational, and thus structural, information on Fe sites, as it gives complete information on all vibrational normal modes containing Fe displacement. In this study, we present NRVS data on BZDOp and assign its structure using these data coupled to experimentally calibrated density functional theory calculations. From this NRVS structure, we define the mechanism for the peroxide shunt reaction. The relevance of the peroxide shunt to the native FeII/O2 reaction is evaluated. For the native FeII/O2 reaction, an FeIII–superoxo intermediate is found to react directly with substrate. This process, while uphill thermodynamically, is found to be driven by the highly favorable thermodynamics of proton-coupled electron transfer with an electron provided by the Rieske [2Fe-2S] center at a later step in the reaction. These results offer important insight into the relative reactivities of FeIII–superoxo and FeIII–hydroperoxo species in nonheme Fe biochemistry.
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- 2018
8. A Long-Lived FeIII-(Hydroperoxo) Intermediate in the Active H200C Variant of Homoprotocatechuate 2,3-Dioxygenase: Characterization by Mössbauer, Electron Paramagnetic Resonance, and Density Functional Theory Methods
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Elena G. Kovaleva, Melanie S. Rogers, Emile L. Bominaar, Katlyn K. Meier, Eckard Münck, John D. Lipscomb, and Michael M. Mbughuni
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Semiquinone ,010402 general chemistry ,Photochemistry ,01 natural sciences ,Article ,Dioxygenases ,law.invention ,Inorganic Chemistry ,Spectroscopy, Mossbauer ,03 medical and health sciences ,Reaction rate constant ,law ,Mössbauer spectroscopy ,Physical and Theoretical Chemistry ,Electron paramagnetic resonance ,Hyperfine structure ,030304 developmental biology ,0303 health sciences ,biology ,Chemistry ,Electron Spin Resonance Spectroscopy ,Active site ,0104 chemical sciences ,Crystallography ,biology.protein ,Density functional theory ,Electric field gradient - Abstract
The extradiol-cleaving dioxygenase homoprotocatechuate 2,3-dioxygenase (HPCD) binds substrate homoprotocatechuate (HPCA) and O2 sequentially in adjacent ligand sites of the active site Fe(II). Kinetic and spectroscopic studies of HPCD have elucidated catalytic roles of several active site residues, including the crucial acid-base chemistry of His200. In the present study, reaction of the His200Cys (H200C) variant with native substrate HPCA resulted in a decrease in both kcat and the rate constants for the activation steps following O2 binding by >400 fold. The reaction proceeds to form the correct extradiol product. This slow reaction allowed a long-lived (t1/2 = 1.5 min) intermediate, H200C-HPCAInt1 (Int1), to be trapped. Mossbauer and parallel mode electron paramagnetic resonance (EPR) studies show that Int1 contains an S1 = 5/2 Fe(III) center coupled to an SR = 1/2 radical to give a ground state with total spin S = 2 (J > 40 cm(-1)) in Hexch = JŜ1·ŜR. Density functional theory (DFT) property calculations for structural models suggest that Int1 is a (HPCA semiquinone(•))Fe(III)(OOH) complex, in which OOH is protonated at the distal O and the substrate hydroxyls are deprotonated. By combining Mossbauer and EPR data of Int1 with DFT calculations, the orientations of the principal axes of the (57)Fe electric field gradient and the zero-field splitting tensors (D = 1.6 cm(-1), E/D = 0.05) were determined. This information was used to predict hyperfine splittings from bound (17)OOH. DFT reactivity analysis suggests that Int1 can evolve from a ferromagnetically coupled Fe(III)-superoxo precursor by an inner-sphere proton-coupled-electron-transfer process. Our spectroscopic and DFT results suggest that a ferric hydroperoxo species is capable of extradiol catalysis.
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- 2015
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9. Rate-Determining Attack on Substrate Precedes Rieske Cluster Oxidation during Cis-Dihydroxylation by Benzoate Dioxygenase
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Christopher J. Cramer, Sarmistha Chakrabarty, Melanie S. Rogers, John D. Lipscomb, Matthew B. Neibergall, Daniel J. Marell, and Brent S. Rivard
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Pseudomonas putida ,Stereochemistry ,Chemistry ,Iron ,Reactive intermediate ,Substrate (chemistry) ,Photochemistry ,Biochemistry ,Catalysis ,Article ,Oxygen ,Metal ,Reaction rate constant ,Bacterial Proteins ,Models, Chemical ,Dihydroxylation ,Dioxygenase ,visual_art ,Oxygenases ,visual_art.visual_art_medium ,Oxidation-Reduction ,Bond cleavage - Abstract
Rieske dearomatizing dioxygenases utilize a Rieske iron-sulfur cluster and a mononuclear Fe(II) located 15 Å across a subunit boundary to catalyze O2-dependent formation of cis-dihydrodiol products from aromatic substrates. During catalysis, O2 binds to the Fe(II) while the substrate binds nearby. Single-turnover reactions have shown that one electron from each metal center is required for catalysis. This finding suggested that the reactive intermediate is Fe(III)-(H)peroxo or HO-Fe(V)═O formed by O-O bond scission. Surprisingly, several kinetic phases were observed during the single-turnover Rieske cluster oxidation. Here, the Rieske cluster oxidation and product formation steps of a single turnover of benzoate 1,2-dioxygenase are investigated using benzoate and three fluorinated analogues. It is shown that the rate constant for product formation correlates with the reciprocal relaxation time of only the fastest kinetic phase (RRT-1) for each substrate, suggesting that the slower phases are not mechanistically relevant. RRT-1 is strongly dependent on substrate type, suggesting a role for substrate in electron transfer from the Rieske cluster to the mononuclear iron site. This insight, together with the substrate and O2 concentration dependencies of RRT-1, indicates that a reactive species is formed after substrate and O2 binding but before electron transfer from the Rieske cluster. Computational studies show that RRT-1 is correlated with the electron density at the substrate carbon closest to the Fe(II), consistent with initial electrophilic attack by an Fe(III)-superoxo intermediate. The resulting Fe(III)-peroxo-aryl radical species would then readily accept an electron from the Rieske cluster to complete the cis-dihydroxylation reaction.
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- 2015
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10. @AJPHThinkTank: Bringing #PublicHealth to a Device Near You
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Olushola Olaitan Ogunleye, Ericka A. Lara Ovares, Melanie S. Rogers, Tara Twyman, Marwa Fadlalla, Cem Akkus, and Kalpita Patel
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medicine.medical_specialty ,Public health ,Public Health, Environmental and Occupational Health ,MEDLINE ,Library science ,United States ,Political science ,medicine ,Humans ,AJPH Editor's Choice ,Social media ,Public Health ,Periodicals as Topic ,Social Media - Published
- 2019
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11. AJPH Instagram Photo Contest—National Public Health Week 'Changing Our Future Together'
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Marwa Fadlalla, Olushola Olaitan Ogunleye, Kalpita Patel, Tara Twyman, Cem Akkus, Melanie S. Rogers, and Ericka A. Lara Ovares
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medicine.medical_specialty ,AJPH Images of Health ,History ,Event (relativity) ,Public health ,Public Health, Environmental and Occupational Health ,Media studies ,CONTEST ,Slogan ,medicine ,Humans ,Public Health ,Social Media ,Societies, Medical - Abstract
The article announces that a photograph taken by Amy Upham has been selected as the winner of the journal's 2018 Instagram Photo Contest, and it mentions the "Changing Our Future Together" slogan, student protesters from a Christian school in North Carolina, and the March for Our Lives event.
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- 2018
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12. Hydrazine and amphetamine binding to amine oxidases: old drugs with new prospects
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Peter F. Knowles, M. Mure, Christian R. Kurtis, Melanie S Rogers, Simon E. V. Phillips, Colin G. Saysell, Carrie M. Wilmot, Winston S. Tambyrajah, David M. Dooley, Michael J. McPherson, Doreen E. Brown, and Jeremy M. Murray
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Amine oxidase ,Monoamine Oxidase Inhibitors ,Pyridones ,Stereochemistry ,TCP binding ,Molecular Conformation ,Protonation ,Isomerism ,Catalytic Domain ,medicine ,Organic chemistry ,Hydrazine (antidepressant) ,Enzyme Inhibitors ,Amphetamine ,Biological Psychiatry ,Binding Sites ,Molecular Structure ,Chemistry ,Amphetamines ,Tranylcypromine ,Psychiatry and Mental health ,Hydrazines ,Neurology ,Catalytic cycle ,Amine gas treating ,Amine Oxidase (Copper-Containing) ,Neurology (clinical) ,Copper ,Protein Binding ,medicine.drug - Abstract
Tranylcypromine (TCP), an amphetamine, is a reversible inhibitor of copper-containing amine oxidases. We have solved the structure of the complex of TCP with the amine oxidase from E. coli (ECAO) and shown that only the (+)-enantiomer of TCP binds. Kinetic studies on 2-phenylethylamine and TCP binding to wild-type ECAO and mutational variants fully support the model in which binding of the protonated amine is the first step in the catalytic cycle. Hydrazines are irreversible inhibitors of copper-containing amine oxidases. Binding of hydrazines leads to an adduct ("Adduct 1") with a chromophore at 430 nm which converts at higher pH to another adduct ("Adduct 2") with a chromophore at 520 nm. We have determined the structures of Adduct 1 and 2 for 2-hydrazinopyridine reacted with ECAO. It has been found that Adduct 1 corresponds to the hydrazone and azo tautomers whilst Adduct 2 corresponds to the azo tautomer coordinated to the active site copper. The implications of these results in developing more specific drugs are discussed.
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- 2007
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13. The Stacking Tryptophan of Galactose Oxidase: A Second-Coordination Sphere Residue that Has Profound Effects on Tyrosyl Radical Behavior and Enzyme Catalysis
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David M. Dooley, R.K. Spooner, P.F. Knowles, Melanie S Rogers, S.J. Firbank, S.E. Deacon, E.M Tyler, C.R Kurtis, N. Akyumani, S. Tamber, S.E.V. Phillips, Michael J. McPherson, and Khaled F. Mahmoud
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Coordination sphere ,Free Radicals ,Stereochemistry ,Radical ,Crystallography, X-Ray ,Photochemistry ,Galactose Oxidase ,Biochemistry ,Catalysis ,Protein Structure, Secondary ,Article ,Substrate Specificity ,Enzyme catalysis ,chemistry.chemical_compound ,Oxidoreductase ,Indole test ,chemistry.chemical_classification ,Binding Sites ,Molecular Structure ,Spectrophotometry, Atomic ,Tryptophan ,Galactose ,Kinetics ,chemistry ,Galactose oxidase ,Mutation ,Tyrosine ,Azide ,Oxidation-Reduction - Abstract
The function of the stacking tryptophan, W290, a second-coordination sphere residue in galactose oxidase, has been investigated via steady-state kinetics measurements, absorption, CD and EPR spectroscopy, and X-ray crystallography of the W290F, W290G, and W290H variants. Enzymatic turnover is significantly slower in the W290 variants. The Km for D-galactose for W290H is similar to that of the wild type, whereas the Km is greatly elevated in W290G and W290F, suggesting a role for W290 in substrate binding and/or positioning via the NH group of the indole ring. Hydrogen bonding between W290 and azide in the wild type-azide crystal structure are consistent with this function. W290 modulates the properties and reactivity of the redox-active tyrosine radical; the Y272 tyrosyl radicals in both the W290G and W290H variants have elevated redox potentials and are highly unstable compared to the radical in W290F, which has properties similar to those of the wild-type tyrosyl radical. W290 restricts the accessibility of the Y272 radical site to solvent. Crystal structures show that Y272 is significantly more solvent exposed in the W290G variant but that W290F limits solvent access comparable to the wild-type indole side chain. Spectroscopic studies indicate that the Cu(II) ground states in the semireduced W290 variants are very similar to that of the wild-type protein. In addition, the electronic structures of W290X-azide complexes are also closely similar to the wild-type electronic structure. Azide binding and azide-mediated proton uptake by Y495 are perturbed in the variants, indicating that tryptophan also modulates the function of the catalytic base (Y495) in the wild-type enzyme. Thus, W290 plays multiple critical roles in enzyme catalysis, affecting substrate binding, the tyrosyl radical redox potential and stability, and the axial tyrosine function.
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- 2007
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14. Structural Basis for Substrate and Oxygen Activation in Homoprotocatechuate 2,3-Dioxygenase: Roles of Conserved Active Site Histidine-200
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John D. Lipscomb, Melanie S. Rogers, and Elena G. Kovaleva
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Models, Molecular ,Stereochemistry ,Crystallography, X-Ray ,Biochemistry ,Article ,Conserved sequence ,Dioxygenases ,Substrate Specificity ,Residue (chemistry) ,Bacterial Proteins ,Oxidoreductase ,Dioxygenase ,Catalytic Domain ,Brevibacterium ,Histidine ,Enzyme kinetics ,Conserved Sequence ,chemistry.chemical_classification ,biology ,Chemistry ,Active site ,Hydrogen-Ion Concentration ,biology.organism_classification ,Oxygen ,Kinetics ,Amino Acid Substitution ,biology.protein ,Mutagenesis, Site-Directed ,Protons - Abstract
Kinetic and spectroscopic studies have shown that the conserved active site residue His200 of the extradiol ring-cleaving homoprotocatechuate 2,3-dioxygenase (FeHPCD) from Brevibacterium fuscum is critical for efficient catalysis. The roles played by this residue are probed here by analysis of the steady-state kinetics, pH dependence, and X-ray crystal structures of the FeHPCD position 200 variants His200Asn, His200Gln, and His200Glu alone and in complex with three catecholic substrates (homoprotocatechuate, 4-sulfonylcatechol, and 4-nitrocatechol) possessing substituents with different inductive capacity. Structures determined at 1.35-1.75 Å resolution show that there is essentially no change in overall active site architecture or substrate binding mode for these variants when compared to the structures of the wild-type enzyme and its analogous complexes. This shows that the maximal 50-fold decrease in kcat for ring cleavage, the dramatic changes in pH dependence, and the switch from ring cleavage to ring oxidation of 4-nitrocatechol by the FeHPCD variants can be attributed specifically to the properties of the altered second-sphere residue and the substrate. The results suggest that proton transfer is necessary for catalysis, and that it occurs most efficiently when the substrate provides the proton and His200 serves as a catalyst. However, in the absence of an available substrate proton, a defined proton-transfer pathway in the protein can be utilized. Changes in the steric bulk and charge of the residue at position 200 appear to be capable of altering the rate-limiting step in catalysis and, perhaps, the nature of the reactive species.
- Published
- 2015
15. Cofactor processing in galactose oxidase
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Simon E. V. Phillips, Peter F. Knowles, Ramon Hurtado Guerrero, Michael J. McPherson, Melanie S Rogers, Malcolm A. Halcrow, David M. Dooley, and S.J. Firbank
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Structural similarity ,Stereochemistry ,Coenzymes ,Galactose Oxidase ,Biochemistry ,Cofactor ,chemistry.chemical_compound ,Thioether ,Aspergillus nidulans ,Animals ,Peptide bond ,Amino Acid Sequence ,Binding site ,Protein Structure, Quaternary ,Peptide sequence ,chemistry.chemical_classification ,Binding Sites ,biology ,Chemistry ,biology.organism_classification ,Amino acid ,Enzyme ,Galactose oxidase ,Intramolecular force ,biology.protein ,Protein Processing, Post-Translational ,Copper ,Biogenesis - Abstract
GO (galactose oxidase; E.C. 1.1.3.9) is a monomeric 68 kDa enzyme that contains a single copper ion and an amino acid-derived cofactor. The enzyme is produced by the filamentous fungus Fusarium graminearum as an extracellular enzyme. The enzyme has been extensively studied by structural, spectroscopic, kinetic and mutational approaches that have provided insight into the catalytic mechanism of this radical enzyme. One of the most intriguing features of the enzyme is the post-translational generation of an organic cofactor from active-site amino acid residues. Biogenesis of this cofactor involves the autocatalytic formation of a thioether bond between Cys-228 and Tyr-272, the latter being one of the copper ligands. Formation of this active-site feature is closely linked to the loss of an N-terminal 17 amino acid prosequence. When copper and oxygen are added to this pro-form of GO (pro GO), purified in copper-free conditions from the heterologous host Aspergillus nidulans, mature GO is formed by an autocatalytic process. Structural comparison of pro GO with mature GO reveals overall structural similarity, but with some regions showing significant local differences in main-chain position. Some side chains of the active-site residues differ significantly from their positions in the mature enzyme. These structural effects of the prosequence suggest that it may act as an intramolecular chaperone to provide an open active-site structure conducive to copper binding and chemistry associated with cofactor formation. The prosequence is not mandatory for processing, as a recombinant form of GO lacking this region and purified under copper-free conditions can also be processed in an autocatalytic copper- and oxygen-dependent manner.
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- 2003
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16. Copper-tyrosyl radical enzymes
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Melanie S Rogers and David M. Dooley
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chemistry.chemical_classification ,Free Radicals ,biology ,Chemistry ,Galactose Oxidase ,Biochemistry ,Catalysis ,Enzymes ,Analytical Chemistry ,Electron Transport Complex IV ,Cross-Linking Reagents ,Enzyme ,Galactose oxidase ,biology.protein ,Tyrosine ,Cytochrome c oxidase ,Copper ,Biogenesis - Abstract
Advances have been made since 2000 that contribute to our understanding of the biogenesis, structure and mechanism of copper-containing tyrosyl radical enzymes. Efforts to detail the biogenesis of galactose oxidase have produced the structure of the precursor enzyme, which provides a framework for emerging mechanistic studies. The role of the tyrosyl radical of cytochrome c oxidase is being defined in studies that aim to understand the His–Tyr crosslink, the location of the radical and, by direct attempts, to provide evidence for the radical during turnover.
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- 2003
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17. Characterization of the active site of galactose oxidase and its active site mutational variants Y495F/H/K and W290H by circular dichroism spectroscopy
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David M. Dooley, Melanie S Rogers, Andrew J. Baron, Michael J. McPherson, and Peter F. Knowles
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Circular dichroism ,biology ,Absorption spectroscopy ,Chemistry ,Stereochemistry ,Copper protein ,Active site ,chemistry.chemical_element ,Copper ,Inorganic Chemistry ,Galactose oxidase ,Materials Chemistry ,biology.protein ,Physical and Theoretical Chemistry ,Tyrosine ,Histidine - Abstract
Circular dichroism spectroscopy (CD) has been used to investigate the generation of the tyrosine radical in wild-type galactose oxidase and the active site variants Y495F/H/K and W290H. Oxidation was observed in all the variants except Y495K and the radical was noted to have a greater stability at pH 4.6 compared to pH 7.0, especially in Y495H and W290H. In the axial tyrosine variants active site oxidation to generate the radical species was confirmed by the presence of characteristic CD bands, particularly a negative band, in the 350 to 450 nm region. The band at 810 nm in the optical absorption spectrum of WT-GO is absent in oxidized Y495 variants consistent with the Y495 → Y272 via Cu(II)dA, assignment (M.L. McGlashen, D.D. Eads, T.G. Spiro and J.W. Whittaker, J. Phys. Chem., 99 (1995) 4918–4922 [1]). CD spectra of either oxidized or semi-reduced proteins are pH-dependent between pH 4.6 and 7.0 with differing intersities and dispersions. The presence of a positive CD band between 309 and 321 nm (N(π) → Cu(II)) confirmed the coordination of histidine to the copper ion in the variants studied here. The slight wavelength and intensity shifts seen in this transition is ascribed to perturbation of coupling of the dyssymmetric environment to the electronic transitions of the copper site.
- Published
- 1998
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18. Effects of polymerization on the oxygen carrying and redox properties of diaspirin cross-linked hemoglobin
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Abdu I. Alayash, Melanie S. Rogers, Robert E. Cashon, and Beth A. Brockner Ryan
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Carbon Monoxide ,Aspirin ,Polymers ,Chemistry ,Nitric oxide binding ,Inorganic chemistry ,Biophysics ,chemistry.chemical_element ,Bohr effect ,Cooperativity ,Photochemistry ,Biochemistry ,Oxygen ,Redox ,Hemoglobins ,Cross-Linking Reagents ,Polymerization ,Structural Biology ,Carbon monoxide binding ,Hemoglobin ,Oxidation-Reduction ,Molecular Biology - Abstract
Human hemoglobin site specifically cross-linked with bis(3,5-dibromosalicyl)fumarate results in a low oxygen affinity hemoglobin-based red cell substitute (alpha-DBBF). Polymerization of alpha-DBBF by bis(maleoylglycylamide) polyethylene glycol (BMAA-PEG) yields poly alpha-DBBF which offers the added benefits of reduced renal clearance and increased retention in the vascular circulation. Oxygen equilibrium curves for poly alpha-DBBF are slightly left-shifted (higher O2 affinity) compared to those of alpha-DBBF; with a diminished cooperativity and a reduced Bohr effect. In rapid mixing experiments (oxygen dissociation and carbon monoxide binding), poly alpha-DBBF exhibits a several fold increase in the overall rate of deoxygenation and carbon monoxide binding kinetics over its cross-linked counterpart. The rate of nitric oxide binding to the oxidized form of poly alpha-DBBF shows little or no change compared to the intramolecularly cross-linked derivative. The reduction of cyanomet poly alpha-DBBF by dithionite is several fold faster than that of HbA0 and alpha-DBBF whereas the slow subsequent cyanide dissociation from the ferrous iron remained unchanged among all proteins. The propensity of poly alpha-DBBF for auto-oxidation is slightly enhanced over alpha-DBBF whereas the extent of oxidative modification by hydrogen peroxide is very similar. Polymerization appears to selectively modify ligand interactions and redox kinetics of the tetrameric cross-linked form which reflects a possibly more open heme pocket. The data suggests that changes in oxygenation properties of hemoglobin brought about by a given modification are not necessarily predictive of other functional changes.
- Published
- 1995
- Full Text
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19. Active site rearrangement of the 2-hydrazinopyridine adduct in Escherichia coli amine oxidase to an azo copper(II) chelate form: a key role for tyrosine 369 in controlling the mobility of the TPQ-2HP adduct
- Author
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Melanie S Rogers, Colin G. Saysell, Simon E. V. Phillips, Winston S. Tambyrajah, Peter F. Knowles, Michael J. McPherson, Minae Mure, Carrie M. Wilmot, Doreen E. Brown, David M. Dooley, and Christian R. Kurtis
- Subjects
Amine oxidase ,Spectrometry, Mass, Electrospray Ionization ,Cations, Divalent ,Pyridones ,Phenylalanine ,Glutamic Acid ,Photochemistry ,Crystallography, X-Ray ,Spectrum Analysis, Raman ,Biochemistry ,Medicinal chemistry ,Adduct ,Divalent ,Deprotonation ,Enzyme Stability ,Reactivity (chemistry) ,Enzyme Inhibitors ,Chelating Agents ,chemistry.chemical_classification ,Aspartic Acid ,Binding Sites ,biology ,Chemistry ,Escherichia coli Proteins ,Active site ,Substrate (chemistry) ,Cobalt ,Resorcinols ,Hydrogen-Ion Concentration ,Catalytic cycle ,biology.protein ,Mutagenesis, Site-Directed ,Tyrosine ,Spectrophotometry, Ultraviolet ,Amine Oxidase (Copper-Containing) ,Asparagine ,Azo Compounds ,Copper - Abstract
Adduct I (lambda(max) at approximately 430 nm) formed in the reaction of 2-hydrazinopyridine (2HP) and the TPQ cofactor of wild-type Escherichia coli copper amine oxidase (WT-ECAO) is stable at neutral pH, 25 degrees C, but slowly converts to another spectroscopically distinct species with a lambda(max) at approximately 530 nm (adduct II) at pH 9.1. The conversion was accelerated either by incubation of the reaction mixture at 60 degrees C or by increasing the pH (13). The active site base mutant forms of ECAO (D383N and D383E) showed spectral changes similar to WT when incubated at 60 degrees C. By contrast, in the Y369F mutant adduct I was not stable at pH 7, 25 degrees C, and gradually converted to adduct II, and this rate of conversion was faster at pH 9. To identify the nature of adduct II, we have studied the effects of pH and divalent cations on the UV-vis and resonance Raman spectroscopic properties of the model compound of adduct I (2). Strikingly, it was found that addition of Cu2+ to 2 at pH 7 gave a product (3) that exhibited almost identical spectroscopic signatures to adduct II. The X-ray crystal structure of 3 shows that it is the copper-coordinated form of 2, where the +2 charge of copper is neutralized by a double deprotonation of 2. These results led to the proposal that adduct II in the enzyme is TPQ-2HP that has migrated onto the active site Cu2+. The X-ray crystal structure of Y369F adduct II confirmed this assignment. Resonance Raman and EPR spectroscopy showed that adduct II in WT-ECAO is identical to that seen in Y369F. This study clearly demonstrates that the hydrogen-bonding interaction between O4 of TPQ and the conserved Tyr (Y369) is important in controlling the position and orientation of TPQ in the catalytic cycle, including optimal orientation for reactivity with substrate amines.
- Published
- 2005
20. Role of the interactions between the active site base and the substrate Schiff base in amine oxidase catalysis. Evidence from structural and spectroscopic studies of the 2-hydrazinopyridine adduct of Escherichia coli amine oxidase
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Minae Mure, Melanie S Rogers, Peter F. Knowles, Colin G. Saysell, Simon E. V. Phillips, David M. Dooley, Christian R. Kurtis, Doreen E. Brown, Carrie M. Wilmot, and Michael J. McPherson
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Amine oxidase ,Pyridones ,Hydrazone ,Photochemistry ,Crystallography, X-Ray ,Spectrum Analysis, Raman ,Biochemistry ,Medicinal chemistry ,Catalysis ,Adduct ,Substrate Specificity ,chemistry.chemical_compound ,Deprotonation ,Enzyme Stability ,Enzyme Inhibitors ,Nuclear Magnetic Resonance, Biomolecular ,Schiff Bases ,chemistry.chemical_classification ,Schiff base ,Binding Sites ,biology ,Chemistry ,Escherichia coli Proteins ,Titrimetry ,Active site ,Hydrogen-Ion Concentration ,Tautomer ,Solutions ,Kinetics ,biology.protein ,Mutagenesis, Site-Directed ,Amine gas treating ,Spectrophotometry, Ultraviolet ,Amine Oxidase (Copper-Containing) - Abstract
2-Hydrazinopyridine (2HP) is an irreversible inhibitor of copper amine oxidases (CAOs). 2HP reacts directly at the C5 position of the TPQ cofactor, yielding an intense chromophore with lambda(max) approximately 430 nm (adduct I) in Escherichia coli amine oxidase (ECAO). The adduct I form of wild type (WT-ECAO) was assigned as a hydrazone on the basis of the X-ray crystal structure. The hydrazone adduct appears to be stabilized by two key hydrogen-bonding interactions between the TPQ-2HP moiety and two active site residues: the catalytic base (D383) and the conserved tyrosine residue (Y369). In this work, we have synthesized a model compound (2) for adduct I from the reaction of a TPQ model compound (1) and 2HP. NMR spectroscopy and X-ray crystallography show that 2 exists predominantly as the azo form (lambda(max) at 414 nm). Comparison of the UV-vis and resonance Raman spectra of 2 with adduct I in WT, D383E, D383N, and Y369F forms of ECAO revealed that adduct I in WT and D383N is a tautomeric mixture where the hydrazone form is favored. In D383E adduct I, the equilibrium is further shifted in favor of the hydrazone form. UV-vis spectroscopic pH titrations of adduct I in WT, D383N, D383E, and 2 confirmed that D383 in WT adduct I is protonated at pH 7 and stabilizes the hydrazone tautomer by a short hydrogen-bonding interaction. The deprotonation of D383 (pKa approximately 9.7) in adduct I resulted in conversion of adduct I to the azo tautomer with a blue shift of the lambda(max) to 420 nm, close to that of 2. In contrast, adduct I in D383N and D383E is stable and did not show any pH-dependent spectral changes. In Y369F, adduct I was not stable and gradually converted into a new species with lambda(max) at approximately 530 nm (adduct II). A detailed mechanism for the adduct I formation in WT has been proposed that is consistent with the mechanism proposed for the oxidation of substrate by CAOs but addresses some key differences in the active site chemistry of hydrazine inhibitors and substrate amines.
- Published
- 2005
21. Catalase (KatA) Plays a Role in Protection against Anaerobic Nitric Oxide in Pseudomonas aeruginosa
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Daniel J. Hassett, Melanie S. Rogers, Jeffrey J. Wilson, Thomas M. Makris, Harry K. Mahtani, Bradley D. VanderWielen, Cameron T. McDaniel, John D. Lipscomb, Shengchang Su, Michael J. Schurr, Qian Li, Warunya Panmanee, Rhett A. Kovall, Jack R. Lancaster, and Randall T. Irvin
- Subjects
Bacterial Diseases ,Transcription, Genetic ,Mutant ,lcsh:Medicine ,Biochemistry ,chemistry.chemical_compound ,Medicine and Health Sciences ,Anaerobiosis ,lcsh:Science ,Heme ,0303 health sciences ,Multidisciplinary ,Ecology ,biology ,Catalase ,Enzymes ,Bacterial Pathogens ,Bacterial Biochemistry ,Anti-Bacterial Agents ,Infectious Diseases ,Medical Microbiology ,Pseudomonas aeruginosa ,Nitrogen Oxides ,Anaerobic bacteria ,Anaerobic exercise ,Research Article ,Anaerobic respiration ,Cellular respiration ,Iron ,Biophysics ,Nitric Oxide ,Microbiology ,Microbial Ecology ,03 medical and health sciences ,Pseudomonas Infections ,Microbial Pathogens ,Nitrites ,030304 developmental biology ,Enzyme Kinetics ,030306 microbiology ,lcsh:R ,Biology and Life Sciences ,Bacteriology ,Gene Expression Regulation, Bacterial ,Nitrite reductase ,chemistry ,Biofilms ,Enzymology ,biology.protein ,lcsh:Q ,Bacterial Biofilms - Abstract
Pseudomonas aeruginosa (PA) is a common bacterial pathogen, responsible for a high incidence of nosocomial and respiratory infections. KatA is the major catalase of PA that detoxifies hydrogen peroxide (H2O2), a reactive oxygen intermediate generated during aerobic respiration. Paradoxically, PA displays elevated KatA activity under anaerobic growth conditions where the substrate of KatA, H2O2, is not produced. The aim of the present study is to elucidate the mechanism underlying this phenomenon and define the role of KatA in PA during anaerobiosis using genetic, biochemical and biophysical approaches. We demonstrated that anaerobic wild-type PAO1 cells yielded higher levels of katA transcription and expression than aerobic cells, whereas a nitrite reductase mutant ΔnirS produced ∼50% the KatA activity of PAO1, suggesting that a basal NO level was required for the increased KatA activity. We also found that transcription of the katA gene was controlled, in part, by the master anaerobic regulator, ANR. A ΔkatA mutant and a mucoid mucA22 ΔkatA bacteria demonstrated increased sensitivity to acidified nitrite (an NO generator) in anaerobic planktonic and biofilm cultures. EPR spectra of anaerobic bacteria showed that levels of dinitrosyl iron complexes (DNIC), indicators of NO stress, were increased significantly in the ΔkatA mutant, and dramatically in a ΔnorCB mutant compared to basal levels of DNIC in PAO1 and ΔnirS mutant. Expression of KatA dramatically reduced the DNIC levels in ΔnorCB mutant. We further revealed direct NO-KatA interactions in vitro using EPR, optical spectroscopy and X-ray crystallography. KatA has a 5-coordinate high spin ferric heme that binds NO without prior reduction of the heme iron (K d ∼6 μM). Collectively, we conclude that KatA is expressed to protect PA against NO generated during anaerobic respiration. We proposed that such protective effects of KatA may involve buffering of free NO when potentially toxic concentrations of NO are approached.
- Published
- 2014
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22. Posttranslationally modified tyrosines from galactose oxidase and cytochrome C oxidase
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Melanie S Rogers and David M. Dooley
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chemistry.chemical_classification ,biology ,Chemistry ,Ligand ,Stereochemistry ,Photochemistry ,Redox ,Cofactor ,Amino acid ,Galactose oxidase ,biology.protein ,Cytochrome c oxidase ,Tyrosine ,Bond cleavage - Abstract
Publisher Summary The study of post-translationally modified redox-active amino acids is a new and continuing area of biochemistry. The model studies on compounds representing the galactose oxidase and cytochrome c oxidase cofactors have demonstrated that substitution at the ortho position of the tyrosine side chain may modity the redox potential, the bond dissociation energy, and the pKa of the hydroxyl group. Behavior attributable to such perturbations is evident in studies on both enzymes and the effect of the covalent modification may have different outcomes. In cytochrome c oxidase, the tyrosyl radical species in cytochrome c oxidase is proposed to arise as a result of donating a hydrogen atom (electron + proton) to bound dioxygen to assure O-O bond cleavage. This contrasts with galactose oxidase where the stabilized, cross-linked tyrosyl radical abstracts a hydrogen atom from the activated (by coordination to copper) substrate. Finally, it concludes that the cross-link may also serve a protective role, perhaps controlling the reactivity of the tyrosyl radical, and preventing deleterious ligand radical coupling reactions.
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- 2001
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23. Electron transfer from Phanerochaete chrysosporium cellobiose oxidase to equine cytochrome c and Pseudomonas aeruginosa cytochrome c-551
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Mt Wilson, Melanie S. Rogers, Maurizio Brunori, Gareth D. Jones, and Giovanni Antonini
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Cytochrome ,Stereochemistry ,Cytochrome c Group ,Flavin group ,Cellobiose ,Biochemistry ,Electron Transport ,chemistry.chemical_compound ,Bacterial Proteins ,Animals ,Horses ,Molecular Biology ,Oxidase test ,biology ,Cytochrome b ,Chemistry ,Cytochrome c peroxidase ,Cytochrome c ,Basidiomycota ,Cell Biology ,biology.organism_classification ,Kinetics ,Pseudomonas aeruginosa ,biology.protein ,Chromatography, Gel ,Phanerochaete ,Carbohydrate Dehydrogenases ,Oxidation-Reduction ,Research Article - Abstract
The electron-transfer reactions of cellobiose oxidase (CBO) have been investigated by conventional and by rapid-scan stopped-flow spectroscopy at pH 6.0. Analysis of the absorbance/time/wavelength matrix by Singular Value Decomposition (SVD) confirms earlier studies showing that cellobiose rapidly reduces the flavin group (7.7 s-1; cellobiose, 100 microM) which in turn slowly (0.2 s-1) reduces the cytochrome b moiety. In the presence of CBO, cellobiose reduces cytochromes c in a reaction that does not depend on oxygen or superoxide. The rate limit for this process is independent of the source of the cytochromes c and is identical with the rate of cytochrome b reduction. Rapid-mixing experiments show that cytochrome b may donate electrons very rapidly to either mammalian cytochrome c or bacterial cytochrome c-551. The reactions were second-order (kc = 1.75 x 10(7) M-1 x s-1; kc-551 = 4.3 x 10(6) M-1 x s-1; pH 6.0, 21 degrees C and I0.064) and strongly ionic-strength (I)-dependent: kc decreasing with I and kc-551 increasing with I. These results suggest the electron-transfer site near cytochrome b bears a significant negative charge. Equilibrium gel chromatography confirms that CBO oxidase and positively charged mammalian cytochrome c make stable complexes. These results are discussed in terms of a model suggesting an electron-transfer role for cytochrome b in vivo, possibly connected with radical-mediated cellulose breakdown.
- Published
- 1994
24. Spectroscopic identification of the haem ligands of cellobiose oxidase
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Mark C Cox, Melanie S. Rogers, Michael T. Wilson, Gareth D. Jones, Andrew J. Thomson, Geoffrey R. Moore, and Myles R. Cheesman
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Hemeprotein ,Magnetic Resonance Spectroscopy ,Stereochemistry ,Biophysics ,Heme ,Ligands ,Biochemistry ,Nuclear magnetic resonance ,law.invention ,chemistry.chemical_compound ,Structural Biology ,law ,polycyclic compounds ,Genetics ,Electron paramagnetic resonance ,Molecular Biology ,Histidine ,Flavin adenine dinucleotide ,chemistry.chemical_classification ,Magnetic circular dichroism ,Methionine ,Circular Dichroism ,digestive, oral, and skin physiology ,Electron Spin Resonance Spectroscopy ,Cell Biology ,eye diseases ,Cellobiose oxidase ,Enzyme ,chemistry ,Flavocytochrome b ,Carbohydrate Dehydrogenases ,Oxidation-Reduction - Abstract
A spectroscopic study of the flavocytochrome b enzyme, cellobiose oxidase, employing optical, NMR, EPR and near infra-red MCD techniques, has identified the axial ligands of the b-type haem. These are a histidine and a methionine, and this ligation set is discussed in relation to the functional role of the haem group.
- Published
- 1992
25. Galactose Oxidase Pro-Sequence Cleavage and Cofactor Assembly Are Self-Processing Reactions
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Andrew J. Baron, Melanie S Rogers, Michael J. McPherson, David M. Dooley, and and Peter F. Knowles
- Subjects
Amine oxidase ,Colloid and Surface Chemistry ,biology ,Stereochemistry ,Chemistry ,Galactose oxidase ,biology.protein ,General Chemistry ,Cleavage (embryo) ,Biochemistry ,Catalysis ,Self processing ,Cofactor - Published
- 2000
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26. CRYSTAL STRUCTURE OF THE PRECURSOR OF GALACTOSE OXIDASE
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David M. Dooley, Melanie S Rogers, Peter F. Knowles, S.J. Firbank, S.E. Phillips, and M.J. McPherson
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Chemistry ,Stereochemistry ,Galactose oxidase ,Crystal structure ,Biochemistry - Published
- 2000
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27. Investigation of substrate binding to galactose oxidase
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C. Allardyce, Peter F. Knowles, David M. Dooley, R.K. Spooner, Melanie S Rogers, and M.J. McPherson
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Chemistry ,Galactose oxidase ,Polymer chemistry ,Substrate (chemistry) ,Biochemistry - Published
- 2000
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28. Peroxynitrite-mediated heme oxidation and protein modification of crosslinked hemoglobins
- Author
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Beth A. Brockner Ryan, Abdu I. Alayash, and Melanie S. Rogers
- Subjects
Inorganic Chemistry ,chemistry.chemical_compound ,Biochemistry ,Chemistry ,Posttranslational modification ,Heme oxidation ,Peroxynitrite - Published
- 1995
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29. Cross-Link Formation of the Cysteine 228—Tyrosine 272 Catalytic Cofactor of Galactose Oxidase Does Not Require Dioxygen.
- Author
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Melanie S. Rogers, Hurtado-Guerrero, Ramón, Firbank, Susan J., Halcrow, Malcolm A., Dooley, David M., Phillips, Simon E. V., Knowles, Peter F., and McPherson, Michael J.
- Subjects
- *
GALACTOSE , *OXIDASES , *AMINO acids , *COPPER , *PROTEINS , *PROTEIN binding , *X-ray crystallography - Abstract
Galactose oxidase (GO) belongs to a class of proteins that self-catalyze assembly of their redox-active cofactors from active site amino acids. Generation of enzymatically active GO appears to require at least four sequential post-translational modifications: cleavage of a secretion signal sequence, copper-dependent cleavage of an N-terminal pro sequence, copper-dependent formation of a C228-Y272 thioether bond, and generation of the Y272 radical. The last two processes were investigated using a truncated protein (termed premat-GO) lacking the pro sequence and purified under copper-free conditions. Reactions of premat-GO with Cu(II) were investigated using optical, EPR, and resonance Raman spectroscopy, SDS-PAGE, and X-ray crystallography. Premat-GO reacted anaerobically with excess Cu(H) to efficiently form the thioether bond but not the Y272 radical. A potential C228-copper coordinated intennediate (λ[submax] 406 nm) in the processing reaction, which had not yet formed the C228-Y272 cross-link, was identified from the absorption spectrum. A copper-thiolate protein complex, with copper coordinated to C228, H496, and H581, was also observed in a 3 mm anaerobic soak by X-ray crystallography, whereas a 24 h soak revealed the C228-Y272 thioether bond. In solution, addition of oxygenated buffer to premat-GO preincubated with excess Cu(II) generated the Y272 radical state. On the basis of these data, a mechanism for the formation of the C228-Y272 bond and tyrosyl radical generation is proposed. The 406 nm complex is demonstrated to be a catalytically competent processing intermediate under anaerobic conditions. We propose a potential mechanism which is in common with aerobic processing by Cu(II) until the step at which the second electron acceptor is required. [ABSTRACT FROM AUTHOR]
- Published
- 2008
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30. Substrate inhibition of the flavo-haem enzyme cellobiose oxidase from Phanerochaete chrysosporium
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Mt Wilson, Gareth D. Jones, Melanie S. Rogers, and B-L. Liu
- Subjects
Inorganic Chemistry ,chemistry.chemical_classification ,Enzyme ,chemistry ,biology ,Stereochemistry ,Phanerochaete ,Substrate (chemistry) ,Cellobiose oxidase ,biology.organism_classification ,Biochemistry ,Chrysosporium - Published
- 1993
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31. Kinetics of the electron transfer reactions of cellobiose oxidase
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Melanie S. Rogers, Michael T. Wilson, and Gareth D. Jones
- Subjects
Electron Transport ,Electron transfer reactions ,Kinetics ,Chemistry ,Carbohydrate Dehydrogenases ,Cytochrome c Group ,Agaricales ,Cytochrome b Group ,Cellobiose oxidase ,Biochemistry ,Combinatorial chemistry - Published
- 1992
- Full Text
- View/download PDF
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