X-ray characterization of PaPheOH, a bacterial phenylalanine hydroxylase /

Ekström, Fredrik,

January 2003

Diss. (sammanfattning) Umeå : Univ., 2003. / Härtill 4 uppsatser.

Cyanide Assimilation in Pseudomonas Fluorescens: Characterization of Cyanide Oxygenase as a Pterin-Dependent Multicomponent Enzyme Complex

Fernandez, Ruby

05 1900

Cyanide utilization in Pseudomonas fluorescens NCIMB 11764 occurs via oxidative conversion to carbon dioxide and ammonia, the latter satisfying the nitrogen requirement. Substrate attack is initiated by an enzyme referred to as cyanide oxygenase (CNO), previously shown to require components in both high (H) (>30 kDa) and low (L) (<10 kDa) molecular weight cell fractions. In this study, tetrahydrobiopterin (H4biopterin) was identified as a cofactor in fraction L, thus making CNO appear as a pterin- dependent hydroxylase. CNO was purified 150-fold (specific activity 0.9 U/mg) and quantitatively converted cyanide to formate and ammonia as reaction products. When coupled with formate dehydrogenase, the complete enzymatic system for cyanide oxidation to carbon dioxide and ammonia was reconstituted. CNO was found to be an aggregate of known enzymes that included NADH oxidase (Nox), NADH peroxidase (Npx), cyanide dihydratase (CynD) and carbonic anhydrase (CA). A complex multi-step reaction mechanism is proposed in which Nox generates hydrogen peroxide which in turn is utilized by Npx to catalyze the oxygenation of cyanide to formamide accompanied by the consumption of one and two molar equivalents of oxygen and NADH, respectively. The further hydrolysis of formamide to ammonia and formate is thought to be mediated by CynD. The role of H4biopterin and of the enzyme CA in the proposed process remains unclear, but the involvement of each in reactive oxygen and radical chemistry is consistent with the proposed formation of such species in the catalytic process. H4biopterin may additionally serve as a protein stabilizing agent along with a protein co-purifying with CynD identified as elongation factor Tu, a known chaperone. At least two of the CNO components (Nox and CynD) are complex oligomeric proteins whose apparent association with Npx and CA appears to be favored in bacterial cells induced with cyanide allowing their purification in toto as a multiprotein enzyme complex.

Pseudomonas fluorescens.

Cyanides.

Oxygenases.

cyanide

oxygenase

multicomponent

Model studies of catechol dioxygenases.

January 2001

Lam Chun Pong. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2001. / Includes bibliographical references. / Abstracts in English and Chinese. / Table of Contents --- p.i / Acknowledgements --- p.v / Abstracts --- p.vi / Abbreviations --- p.viii / Chapter CHAPTER 1. --- SYNTHESIS AND REACTIVITY STUDIES OF MODEL COMPLEXES FOR INTRADIOL DIOXYGENASES WITH BENZIMIDAZOLE- CONTAINING LIGAND / Chapter I.1 --- Introduction / Chapter I.1.1 --- General Background --- p.1 / Chapter I.1.2 --- A General Review on the Modeling Chemistry for Catechol Dioxygenases --- p.3 / Chapter I.1.3 --- Intradiol Dioxygenases --- p.3 / Chapter I.1.3.1 --- Early model studies for intradiol dioxygenases --- p.5 / Chapter I.1.3.2 --- Factors affecting enzymatic reactivity for intradiol dioxygenases --- p.6 / Chapter I.1.3.3 --- Other functional models for intradiol dioxygenases --- p.7 / Chapter I.1.3.4 --- Reactivity studies of model complexes --- p.8 / Chapter I.1.4 --- Extradiol Dioxygenases --- p.8 / Chapter I.1.4.1 --- Early model studies for extradiol dioxygenases --- p.11 / Chapter I.1.4.2 --- Iron(III) complexes with extradiol properties --- p.12 / Chapter I.1.5 --- Objective of This Work --- p.14 / Chapter I.2 --- Results and Discussion / Chapter I.2.1 --- Synthesis of the Ligand Ntb --- p.15 / Chapter I.2.2 --- Synthesis of the Model Complex [Fe(ntb)Cl2]Cl --- p.16 / Chapter I.2.3 --- Synthesis of Enzyme-Substrate Model Complexes --- p.16 / Chapter I.2.4 --- Oxygenation Reactivities of Enzyme-Substrate Model Complexes 2-4 --- p.18 / Chapter I.2.4.1 --- Oxygenation of [Fe(ntb)(dbc)](C104) (2) in DMF --- p.18 / Chapter I.2.4.2 --- Oxygenation of [Fe(ntb)(cat)](Cl04) (3) in DMF --- p.21 / Chapter I.2.4.3 --- Oxygenation of [Fe(ntb)(tcc)](ClO4) (4) in DMF --- p.23 / Chapter I.2.4.4 --- Comparison of the oxygenation reactivities of complexes2-4 --- p.25 / Chapter I.2.5 --- Identification of Oxidative Cleavage Products --- p.27 / Chapter I.2.5.1 --- Isolation of oxidative cleavage products of complex 2 --- p.27 / Chapter I.2.5.2 --- Identification of cleavage products --- p.27 / Chapter I.2.6 --- Physical Characterization of Complexes 1-4 --- p.29 / Chapter I.2.6.1 --- Melting-points --- p.29 / Chapter I.2.6.2 --- Cyclic Voltammograms --- p.30 / Chapter I.2.6.3 --- EPR spectra --- p.31 / Chapter I.2.7 --- Molecular Structures of Complexes 1-4 --- p.34 / Chapter I.2.7.1 --- Molecular structure of [Fe(ntb)Cl2]Cl-4H20 (1) --- p.34 / Chapter I.2.7.2 --- Molecular structure of [Fe(ntb)(dbc)](Cl04)-2Me0H-H20 (2) --- p.36 / Chapter I.2.7.3 --- Molecular structure of [Fe(ntb)(cat)](ClO4) H20 (3) --- p.38 / Chapter I.2.7.4 --- Molecular structure of [Fe(ntb)(tcc)](Cl04).Me2C(0).H20 (4) --- p.41 / Chapter I.2.7.5 --- Comparison of the molecular structures of complexes 1-4 --- p.43 / Chapter I.3 --- Experimentals for Chapter 1 --- p.45 / Chapter I.4 --- References for Chapter 1 --- p.49 / Chapter CHAPTER II --- iron(iii) complexes containing N202 and N3O type ligands as models for INTRADIOL DIOXYGENASES / Chapter II.1 --- Introduction / Chapter II.1.1 --- Brief Remarks on Model Studies of Intradiol Dioxygenases. --- p.53 / Chapter II.1.2 --- Objective of This Work --- p.53 / Chapter II.2 --- Results and Discussion / Chapter II.2.1 --- Synthesis of N202 and N30 Type Ligands --- p.55 / Chapter II.2.2 --- Synthesis of Model Complexes --- p.57 / Chapter II.2.2.1 --- Model complex with ligand L1H --- p.57 / Chapter II.2.2.2 --- Model complex with ligand L2H2 --- p.58 / Chapter II.2.3 --- Synthesis of Enzyme-Substrate Model Complexes --- p.59 / Chapter II.2.3.1 --- Synthesis of enzyme-substrate model complexes from 14.… --- p.59 / Chapter II.2.3.2 --- Attempted synthesis of enzyme-substrate model complexes starting from 15 --- p.61 / Chapter II.2.4 --- Reaction of Complex 16 with Dioxygen --- p.61 / Chapter II.2.4.1 --- Oxygenation of [Fe(L1)(dbc)] (16) in DMF --- p.65 / Chapter II.2.5 --- Identification of Oxidative Cleavage Products --- p.64 / Chapter II.2.5.1 --- Isolation of oxidative cleavage products of complex 16 --- p.64 / Chapter II.2.5.2 --- Identification of cleavage products --- p.65 / Chapter II.2.6 --- "Physical Characterization of L1H, L2H2, Complexes 14-18" --- p.66 / Chapter II.2.6.1 --- NMR spectra --- p.67 / Chapter II.2.6.2 --- Melting-points --- p.69 / Chapter II.2.6.3 --- Mass spectra --- p.69 / Chapter II.2.6.4 --- Cyclic voltammogram --- p.69 / Chapter II.2.6.4 --- EPR spectra --- p.70 / Chapter II.2.7 --- "Molecular Structures of Complexes 14,15 and 18" --- p.71 / Chapter II.2.7.1 --- Molecular structure of [Fe(L1)(MeOH)Cl][BPh4].MeOH (14) --- p.72 / Chapter II.2.7.2 --- Molecular structure of [Fe(L2)Cl].MeOH (15) --- p.75 / Chapter II.2.7.3 --- Molecular structure of [Et3 Nh]3［Fe(tcc)3］.H2O(18) --- p.78 / Chapter II.3 --- Experimentals for Chapter 2 --- p.80 / Chapter II.4 --- References for Chapter 2 --- p.87 / APPENDIX 1 General Procedures and Physical Measurements --- p.89 / "APPENDIX 2 Selected Crystallographic Data for Complexes 1-4, 15,16 and 18.…" --- p.90 / Table A-l.Selected crystallographic data for complexes 1-4 --- p.91 / "Table A-2.Selected crystallographic data for complexes 15, 16 and 18" --- p.92 / "APPENDIX 3 Other Physical Data for Ligand L1H L2H2, Complexes 2 and 16" --- p.93 / Figure A-l.1H NMR spectrum of ligand L1H --- p.94 / Figure A-2.13C NMR spectrum of ligand L1H --- p.94 / Figure A-3.1H NMR spectrum of ligand L2H2 --- p.95 / Figure A-4.13C NMR spectrum of ligand L2H2 --- p.95 / Figure A-5.GC spectrum of the oxidative cleavage products of complex 2 --- p.96 / Figure A-6.- A-l 1.Mass spectra of the oxidative cleavage products of Complex 2 --- p.96 / Figure A-12.GC spectrum of the oxidative cleavage products of complex 16 --- p.99 / Figure A-13.- A-23.Mass spectra of the oxidative cleavage products of Complex 16 --- p.99 / Figure A-24.GC spectrum of dbcH2 standard --- p.105 / Figure A-25.Mass spectrum of dbcH2 standard --- p.106 / Figure A-26.GC spectrum of dbcq standard --- p.106 / Figure A-27.Mass spectrum of dbcq standard --- p.107

Oxygenases

Catechol

Oxidation

Catalysis

Chemical models

Biomimetics

Oxygenases

Catechols

Oxidation-Reduction

Biochemistry

Models, Chemical

Structural, functional and evolutionary studies on prolyl-hydroxylases

Scotti, John Salvatore

January 2014

This thesis studies the prolyl-hydroxylase family of 2-oxoglutarate dependent oxygenases from structural, functional and evolutionary perspectives. The role of prolyl-hydroxylation was first identified in collagen, wherein hydroxyproline was found to stabilise the collagen triple helix. In the 1960s, the presence of hydroxyproline in collagen was found to be a result of enzyme catalysed protein modification. An enzyme, now known as collagen prolyl-4-hydroxylase (CP4H), was found to be completely dependent on Fe(II), 2-oxoglutarate (2OG) and molecular oxygen for catalysis, and was the inaugural member of enzyme family known as the Fe(II) and 2OG-dependent oxygenases (2OG oxygenases), the members of which have since expanded dramatically – more than 60 2OG oxygenases are predicted to exist in humans alone. It was not until the 21st century that hydroxyproline was found to play roles in human biology beyond its well-characterised role in collagen stabilisation. In animals, cells adapt to low oxygen conditions (hypoxia) via the upregulation of hundreds of target genes as governed by the hypoxia-inducible transcription factor (HIF). The mammalian hypoxic sensing system was discovered to be regulated by a conserved family of hypoxia-inducible factor prolyl-hydroxylases (PHDs or EGLNs), which catalyse the prolyl-4-hydroxylation of a conserved proline residue in HIF-α under normoxic conditions, so targeting HIF-α for proteasomal degradation via the von Hippel-Lindau (pVHL) E3 ubiquitin ligase pathway. As a result, the PHDs are current therapeutic targets for the treatment of anemia and ischemia-related diseases. Thus, hydroxyproline also plays a critical role in mammalian oxygen sensing. However, the discovery also raised the question of the evolutionary origin of these enzymes and what roles, if any, they may play in other organisms. This thesis begins by describing the identification and biochemical characterisation of the first homologue of the human PHDs in prokaryotes, specifically, in Pseudomonas species, which contains pathogens such as P. aeruginosa. Pseudomonas PHD (PPHD) was discovered to catalyse the prolyl-hydroxylation of a conserved region of elongation factor Tu (EF-Tu), a translational GTPase universally conserved in prokaryotes and known for its critical role in bacterial translation. A crystal structure of PPHD, the first of a prokaryotic prolyl-hydroxylase, was then determined, revealing a striking structural homology of PPHD to the human PHDs. The further determination of crystal structures of Pseudomonas EF-Tu and a PPHD:EF-Tu protein-protein complex, the first of any 2OG oxygenase in complex with its full-length protein substrate, provides important insights into the substrate recognition mechanisms of both the CP4Hs and the PHDs and reveals an evolutionarily conserved pathway of substrate recognition that extends to prokaryotes and will be useful in the design of selective inhibitors of the PHDs. Differences were investigated between the PHDs and a recently discovered subfamily of eukaryotic prolyl-3-hydroxylases, which catalyse the hydroxylation of a conserved proline residue in the small ribosomal subunit S23 (RPS23) and have been implicated in translation accuracy and the stress response. Crystal structures of the RPS23 hydroxylases human OGFOD1 and yeast Tpa1 in complex with 2OG-mimetic inhibitors provide insight into their evolutionary origins. Analyses of the structures will be useful for targeting either OGFOD1 or the PHDs for human therapy. The thesis then describes work on human CP4H, a 240 kDa α2β2 heterotetramer. A novel expression and purification protocol is described for the CP4H complex in addition to the first known reports of its crystallisation and diffraction. Further, the foundations of a high-throughput inhibition assay of the human CP4Hs is presented and will be of immediate interest for assaying inhibitors of the human PHDs in clinical trials, some of which are also predicted to inhibit the CP4Hs. In closing, the thesis attempts to synthesise the results presented in order to provide further insight into the question of the ancestral origins of the prolyl-hydroxylases, a family of enzymes whose range of functions and biological roles likely will continue to expand.

572

Clinical utility, cost-effectiveness and provider perceptions of CYP2C9 and VKORC1 genotyping for chronic warfarin therapy /

Meckley, Lisa M.

January 2008

Thesis (Ph. D.)--University of Washington, 2008. / Vita. Includes bibliographical references (leaves 91-124).

Regulation of cytochrome P450 2A6 and phase II enzymes by unsaturated aldehydes

Mack, Todd Steven.

January 1900

Thesis (M.S.)--The University of North Carolina at Greensboro, 2009. / Directed by Gregory M. Raner; submitted to the Dept. of Chemistry and Biochemistry. Title from PDF t.p. (viewed May 17, 2010). Includes bibliographical references (p. 56-57).

Atividade de enzimas lignocelulolíticas no crescimento de Lentinula edodes em subprodutos energéticos

Regina, Magali [UNESP]

27 October 2004

Made available in DSpace on 2014-06-11T19:31:34Z (GMT). No. of bitstreams: 0 Previous issue date: 2004-10-27Bitstream added on 2014-06-13T20:22:25Z : No. of bitstreams: 1 regina_m_dr_botfca.pdf: 906659 bytes, checksum: 2703d887158a2588e3476685424857a3 (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Universidade Estadual Paulista (UNESP) / O cultivo de cogumelos comestíveis, em subprodutos energéticos, representa o principal exemplo da conversão direta de resíduos lignocelulósicos em um artigo com alto valor agregado, com benefício para o gênero humano e uma fonte de energia biosintética comercialmente importante. O objetivo do trabalho foi verificar a atividade de enzimas lignocelulolíticas do Lentinula edodes crescendo em resíduos agrícolas, utilizando-se três tipos de incubação: meio líquido, sistema estacionário e bioreator. As linhagens LE 95/17, LE 96/22 e Leax foram incubadas em substratos compostos de casca de arroz (CA), serragem de eucalipto (SE), bagaço de mandioca (BM) e bagaço de cana-de-açúcar (BC), suplementado com 20% de farelo de arroz e 1% de CaCO3. Foram avaliados a velocidade de crescimento miceliano e a atividade de enzimas oxidativas e hidrolíticas. As linhagens em meio de cultura líquido não apresentam atividades expressivas de manganês peroxidase e lacase. SE e BC, utilizados no sistema estacionário, mostraram ser os mais eficientes para as atividades de MnP, enquanto que para a atividade da lacase apenas SE. O sistema estacionário, em SE, foi melhor que o bioreator para atividade de enzimas hidrolíticas. O bagaço de mandioca pode ser uma alternativa viável como substrato, ou na forma de complemento à outros substratos, por propiciar um rápido crescimento miceliano. A lignina peroxidase não foi detectada em nenhum dos experimentos. / The cultivation of mushrooms in by-products represents the main example of the direct conversion of lignocellulosic residues in an article with high attached value with benefit for the mankind and source of commercially important biosynthetic energy. The aim of this work was verify the activity of the Lentinula edodes lignocellulolitic enzymes growing in agricultural residues utilizing three kinds of incubation: liquid culture medium, solid static state and bioreactor. The LE 17/95, LE 22/96 and Leax strains were incubated in substrates composed of peel of rice (PR), eucalyptus sawdust (ES), cassava bagasse (CB) and sugar cane bagasse (SB), supplemented with 20% of rice brans and 1% of CaCO3. The mycelium growth velocity, the oxidative and hydrolytic enzymes activity were evaluated. The strains in liquid culture medium don't presented expressive activities of manganese peroxidase (MnP) and laccase. SE and BC utilized in solid static state system showed to be more efficient to MnP activity while laccase only SE. The solid static state system was better than bioreactor to hydrolytic enzymes activity in SE. The cassava bagasse can be a substrate alternative for having a fast mycelium growth. The lignin peroxidase was not detected in the experiments.

Cogumelos comestiveis

Enzimas microbianas

Residuos agricolas

Enzimas extracelulares

Lentinus

Oxygenases

NMR studies on 2-oxoglutarate oxygenases

Leung, Ivanhoe K. H.

January 2012

No description available.

A comparative study of cytochromes P450 2E1 and 2A6 : substrate dynamics, multiple ligand binding, and adduct formatioin by N-acetyl-m-aminophenol /

Harrelson, John P.

January 2005

Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (leaves 200-205).

Structural and functional studies of chromatin modifying enzymes

Walport, Louise J.

January 2013

Epigenetic regulation is a complex process involving the interplay of multiple different cellular factors. Work described in this thesis concerned the characterisation of proteins involved in the binding to, and demethylation of, histone 3 (H3) tails modified by N-methylation. Initial work focussed on the biophysical characterisation of the tandem plant homeodomains (PHD) of the chromatin remodeller CHD4. NMR spectroscopy was used to investigate the solution structure of the tandem PHDs. Studies on a more native-like construct including the C terminal tandem chromodomains are also presented. Binding studies of the PHDs with H3 peptides reveal that the individual PHD fingers can independently bind a histone peptide. The remainder of the work involved characterisation of JmjC histone demethylases (KDMs), enzymes that catalyse removal of Nε-methyl groups from histone lysyl-residues. Initially, two members of the KDM7 subfamily, PHF8 and KIAA1718, were studied; a high throughput screening assay for them was developed, which enabled identification of a selective inhibitor of the KDM2/7 subfamilies of KDMs, the plant growth regulator Daminozide. A disease relevant mutation in PHF8 was studied and shown to cause mis-localisation of the enzyme to the cytoplasm, providing a potential explanation for the clinically observed phenotype. Subsequent chapters describe unprecedented activities for the JmjC KDMs. 2OG oxygenases catalyse a wide range of oxidative reactions, predominantly mediated by initial substrate hydroxylation. The activity of PHF8 with lysine analogous was tested; the results demonstrated that PHF8, and other KDMs, can oxidatively remove Nε-alkyl groups other than methyl groups, such as ethyl and isopropyl groups. The substrate scope of the JmjC KDMs thus has the potential to be wider than previously thought. Observation of β-hydroxylation of the Nε-isopropyl group of a histone peptide including Nε methylisopropyllysine by JMJD2A/E supports the presumed mechanism of histone lysine demethylation as proceeding via initial hydroxylation. This work led to the discovery that JmjC KDMs can catalyse arginine demethylation. This novel arginine demethylase activity by JmjC KDMs was characterised and the work extended to encompass potential arginine demethylase activity in cells. Biochemical characterisation of UTY, a homologue of the H3 K27 demethylases JMJD3 and UTX, which is reported to be inactive, was carried out; UTY was shown to catalyse demethylation at H3 trimethylated at K27 on peptidic substrates, albeit it at substantially lower rates than the other family members. To investigate the reason for this reduced activity, two variants were made, S1142G and P1214I; the latter variant was shown to be considerably more active than wildtype UTY, likely due to an increased peptide-binding interaction. Preliminary experiments in cells did not conclusively demonstrate histone demethylation, but a luciferase assay suggested that UTY may have catalytic activity in cells. Overall the findings in the thesis suggest that the process of cellular epigenetic regulation is likely even more complex than previously thought, with the potential that JmjC KDMs carry out multiple, context dependent functions.

572.8