Explorando novas facetas da interação entre a Enzima Clorocatecol 1,2-dioxigenase e seus ligantes / Exploring new facets of the interaction between the enzyme chlorocatechol 1,2-dioxygenase and its ligands

Natasha Faiani Furtado

17 October 2014

O uso intensivo de produtos organoclorados contendo estruturas aromáticas em sua composição tem crescido de forma rápida nos últimos anos em face de sua ampla utilização em vários setores da indústria moderna. A decomposição de tais compostos é lenta, dada sua grande estabilidade química, tornando-os poluentes recorrentes do meio-ambiente. Diferentes estratégias estão disponíveis para tentar solucionar este problema. Os chamados processos de bioremediação estão entre elas e vem ganhando espaço dentre as possíveis escolhas em face de sua maior eficiência e por estarem baseados no uso de moléculas como enzimas, que não afetam o ambiente, para realizar a tarefa de degradação de substâncias tóxicas. Neste contexto se coloca a enzima clorocatecol 1,2-dioxigenase de Pseudomonas. putida, alvo de estudos deste trabalho. Nosso grupo tem trabalhado no entendimento do mecanismo de ação da enzima clorocatecol 1,2-dioxigenase de Pseudomonas. putida há alguns anos já que acreditamos que a utilização de forma mais eficiente e efetiva possível da enzima clorocatecol 1,2-dioxigenase de Pseudomonas. putida passa necessariamente pelo conhecimento acerca de maneiras de controle da atividade enzimática. Com isso, os resultados obtidos consistiram na otimização dos processos de expressão e purificação que permitiram a obtenção da proteína pura e com bom rendimento, após mudança no vetor de expressão. Foram feitos ensaios de atividade enzimática com diferentes substratos e desenvolvimento de um protocolo de caracterização cinética, para assim avaliar a existência de mecanismos de inibição/modulação da reação pelo substrato e/ou produto. Análise da estrutura secundária por meio de dicroísmo circular e dicroísmo circular com radiação síncrotron para avaliar a integridade estrutural frente da nova construção. Também foram realizados testes para separação dos ligantes enzima clorocatecol 1,2-dioxigenase de Pseudomonas putida para análise em espectrômetro de massas afim de se identificar as moléculas anfipáticas que podem estar presentes em seu sítio hidrofóbico. Por fim, ensaios de interação proteína-lipídio utilizando calorimetria diferencial de varredura, ressonância paramagnética eletrônica e dicroísmo circular indicam uma provável interação com modelos de membrana, principalmente, quando na presença de PIP2 (fosfatidilinositol-4,5-bisfosfato). / The use of chlorinated compounds bearing aromatic structures in their chemical composition has quickly grown in the last few years due to their general presence in processes of modern industry. The degradation of such compounds is slow, due to their high chemical stability, thus making them frequent polutants of the environment. Different strategies to tackle this problem are available. The so-called bioremediation methods are among those strategies and have been gaining many applications because of their higher efficiency and due to the use of enzymes, which do not affect the environment, to perform the degradation task. Chlorocatechol 1,2-dioxygenase from Pseudomonas putida is one of those enzymes and is the object of study of this project. Our group has been working on understanding the mechanism of action of Chlorocatechol 1,2-dioxygenase from Pseudomonas putida since we believe that a more efficient use of Chlorocatechol 1,2-dioxygenase from Pseudomonas putida necessarily involves knowledge about ways of controlling the enzymatic activity. Thus, our results consisted in the optimization of the expression and purification protocols that allow the production of pure protein in high yields after changing its expression vector. Assays of enzyme activity with different substrates and development of a protocol for kinetic characterization was also done to assess the existence of mechanisms of inhibition/modulation of the reaction by the substrate and/or product. Analysis of the secondary structure by circular dichroism and synchrotron radiation circular dichroism was also performed to assess the integrity of the new construction. Tests were also carried out to separate the amphipatic ligands present in the Chlorocatechol 1,2-dioxygenase from Pseudomonas putida structure for analysis in a mass spectrometer in order to identify which kind of amphipathic molecule may be present in enzyme hydrophobic site. Finally, lipid-protein interactions were investigated by means of differential scanning calorimetry, electron paramagnetic resonance and circular dichroism. The results indicated a potential interaction with model membranes, especially in the presence of PIP2 (phosphatidylinositol 4,5-bisphosphate).

Biorremediação

cinética enzimática

Clorocatecol 1,2- dioxigenase

interação com membranas

Pseudomonas putida

Bioremediation

interaction with membranes.

Pseudomonas putida

Metabolic labelling of bacterial isoprenoids produced by the methylerythritol phosphate pathway : a starting point towards a new inhibitor / Marquage métabolique des isoprénoïdes bactériens produits par la voie du méthylérythritol phosphate : un point de départ vers un nouvel inhibiteur

Baatarkhuu, Zoljargal

05 September 2017

Les isoprénoïdes, présents dans tous les organismes vivants, sont synthétisés selon deux processus: la voie du Mevalonate et la voie Méthylérythritol phosphate (MEP). Cette dernière, absente chez l’humain, est très étudiée car elle représente une cible pour le développement de nouveaux antimicrobiens. Le ME-N3, un analogue du méthylérythritol portant un azoture, a été synthétisé et exploité dans des expériences de marquage métabolique de la voie MEP en utilisant un couplage bioorthogonale suivi d’une analyse par LC/MS. De façon intéressante, nous avons découvert que le MEP-N3, un analogue du MEP, inhibe l'enzyme IspD d’ E. coli (3ème enzyme de la voie MEP). Les études cinétiques ont révélé que le MEP-N3 possède la meilleure activité inhibitrice sur IspD d’ E.coli en comparaison avec les inhibiteurs connus, et que le mécanisme d'inhibition est de type mixte. Une étude détaillée du mécanisme de la réaction catalysée par IspD a été réalisée pour la première fois, en utilisant une analyse cinétique à deux substrats. / Isoprenoids, present in all living organisms, are synthesised according to two routes: the Mevalonate and the Methylerythritol phosphate (MEP) pathways. The MEP pathway, absent in humans, is extensively investigated as it is a target for the development of new antimicrobials. ME-N3 an azide tagged analogue of methylerythritol was synthesised and utilised for metabolic labelling studies of the MEP pathway using bioorthogonal ligation followed by LC-MS analysis. Interestingly, we found that MEP-N3, an analogue of MEP, inhibits E.coli IspD (3rd enzyme of the MEP pathway). Further inhibition kinetic studies revealed that MEP-N3 possesses the highest inhibitory activity on E.coli ispD when compared to known inhibitors. In addition, the mechanism of inhibition of E.coli ispD by MEP-N3 was found to be best described using a mixed type model. Moreover, determination of the IspD reaction mechanism has been carried out for the first time, by virtue of a bisubstrate steady state kinetic analysis.

Isoprénoïde

Voie du méthylérythritol phosphate

IspD

Marquage métabolique

Inhibition enzymatique

Cinétique enzymatique

Isoprenoid

Methylerythritol phosphate pathway

IspD

Metabolic labelling

Enzyme inhibition

Enzyme kinetics

Mathematical Modeling of Blood Coagulation

Perdomo, Joana L

01 January 2016

Blood coagulation is a series of biochemical reactions that take place to form a blood clot. Abnormalities in coagulation, such as under-clotting or over- clotting, can lead to significant blood loss, cardiac arrest, damage to vital organs, or even death. Thus, understanding quantitatively how blood coagulation works is important in informing clinical decisions about treating deficiencies and disorders. Quantifying blood coagulation is possible through mathematical modeling. This review presents different mathematical models that have been developed in the past 30 years to describe the biochemistry, biophysics, and clinical applications of blood coagulation research. This review includes the strengths and limitations of models, as well as suggestions for future work.

92-02: Research exposition (monographs

survey articles)

92C50: Medical applications (general)

enzyme kinetics

etc.)

Medical Biomathematics and Biometrics

Other Applied Mathematics

DISCOVERY OF NEW ANTIMICROBIAL OPTIONS AND EVALUATION OF AMINOGLYCOSIDE RESISTANCE ENZYME-ASSOCIATED RESISTANCE EPIDEMIC

Holbrook, Selina Y. L.

01 January 2018

The extensive and sometimes incorrect and noncompliant use of various types of antimicrobial agents has accelerated the development of antimicrobial resistance (AMR). In fact, AMR has become one of the greatest global threat to human health in this era. The broad-spectrum antibiotics aminoglycosides (AGs) display excellent potency against most Gram-negative bacteria, mycobacteria, and some Gram-positive bacteria, such as Staphylococcus aureus. The AG antibiotics amikacin, gentamicin, kanamycin, and tobramycin are still commonly prescribed in the U.S.A. for the treatment of serious infections. Unfortunately, bacteria evolve to acquire resistance to AGs via four different mechanisms: i) changing in membrane permeability to resist drugs from entering, ii) upregulating efflux pumps for active removal of intracellular AGs, iii) modifying the antimicrobial target(s) to prevent drugs binding to their targets, and iv) acquiring resistance enzymes to chemically inactivate the compounds. Amongst all, the acquisition of resistance enzymes, AG-modifying enzymes (AMEs), is the most common resistance mechanism identified. Depending on the chemistry each enzyme catalyzes, AMEs can be further divided into AG N-acetyltransferases (AACs), AG O-phosphotransferases (APHs), and AG O-nucleotidyltransferases. To overcome AME-related resistance, we need to better understand these resistance enzymes and further seek ways to either escape or inhibit their actions. In this dissertation, I summarized my efforts to characterize the AAC(6') domain and its mutant enzymes from a bifunctional AME, AAC(6')-Ie/APH(2")-Ia as well as another common AME, APH(3')-IIa. I also explained my attempt to inhibit the action of various AAC enzymes using metal salts. In an effort to explore the current resistance epidemic, I evaluated the resistance against carbapenem and AG antibiotics and the correlation between the resistance profiles and the AME genes in a collection of 122 Pseudomonas aeruginosa clinical isolates obtained from the University of Kentucky Hospital System. Besides tackling the resistance mechanisms in bacteria, I have also attempted to explore a new antifungal option by repurposing an existing antipsychotic drug, bromperidol, and a panel of its derivatives into a combination therapy with the azole antifungals against a variety of pathogenic yeasts and filamentous fungi.

aminoglycoside-modifying enzyme (AME)

enzyme engineering

substrate promiscuity

enzyme kinetics

minimum inhibitory concentrations (MICs)

drug combination

Bacteria

Bacterial Infections and Mycoses

Fungi

Medicinal and Pharmaceutical Chemistry

Microbiology

Pharmaceutics and Drug Design

Vliv cytochromu b5 na enzymovou kinetiku hydroxylace Sudanu I lidským cytochromem P450 1A1 / Effect of cytochrome b5 on enzyme kinetics of Sudan I hydroxylation catalyzed by human cytochrome P450 1A1

Netolický, Jakub

January 2019

Cytochromes P450 are the major xenobiotics converting enzymes. They are classified as mixed function monooxygenases (MFO). Isoform 1A1 is a extrahepatic form found mainly in the lung and other tissues. It is strongly induced by polycyclic aromatic hydrocarbons and their derivatives via the Ah receptor. As a marker reaction for this enzyme can be used hydroxylation of Sudan I, which has previously been widely used as a azo dye in industry, but since 1980s it is banned for coloring food and cosmetics for its negative influence on the organism. NADPH:cytochrome P450 reductase is the major electron donor for cytochrome P450 catalyzed monooxygenation reactions. Another electron carrier for cytochrome P450 catalyzed reactions is cytochrome b5. It was shown that cytochrome b5 can stimulate, inhibit or have no effect on P450 catalyzed reactions. This thesis aims to evaluate the influence of the ration between NADPH:cytochrome P450 reductase and cytochrome b5 on cytochrome P450 1A1 catalyzed Sudan I hydroxylation. The main goal is to characterize the influence of electron donor and electron transfer ratios on hydroxylation of Sudan I, and to determine the kinetic parameters KM and VMAX for selected protein ratios. Partial aims of the thesis were to characterize the recombinant proteins used in this study...

Redesign of Alpha Class Glutathione Transferases to Study Their Catalytic Properties

Nilsson, Lisa O

January 2001

<p>A number of active site mutants of human Alpha class glutathione transferase A1-1 (hGST A1-1) were made and characterized to determine the structural determinants for alkenal activity. The choice of mutations was based on primary structure alignments of hGST A1-1 and the Alpha class enzyme with the highest alkenal activity, hGST A4-4, from three different species and crystal structure comparisons between the human enzymes. The result was an enzyme with a 3000-fold change in substrate specificity for nonenal over 1-chloro-2,4-dinitrobenzene (CDNB).</p><p>The C-terminus of the Alpha class enzymes is an α-helix that folds over the active site upon substrate binding. The rate-determining step is product release, which is influenced by the movements of the C-terminus, thereby opening the active site. Phenylalanine 220, near the end of the C-terminus, forms an aromatic cluster with tyrosine 9 and phenylalanine 10, positioning the β-carbon of the cysteinyl moiety of glutathione. The effects of phenylalanine 220 mutations on the mobility of the C-terminus were studied by the viscosity dependence of k_cat and k_cat/K_m with glutathione and CDNB as the varied substrates. </p><p>The compatibility of slightly different subunit interfaces within the Alpha class has been studied by heterodimerization between monomers from hGST A1-1 and hGST A4-4. The heterodimer was temperature sensitive, and rehybridized into homodimers at 40 ˚C. The heterodimers did not show strictly additive activities with alkenals and CDNB. This result combined with further studies indicates that there are factors at the subunit interface influencing the catalytic properties of hGST A1-1.</p>

Biochemistry

glutathione transferase

heterologous expression

heterodimer

hydroxyalkenal

protein redesign

sequential design

dimer-interface interactions

enzyme kinetics

glutathione

dynamic C-terminus

viscosity dependence

Biokemi

Biochemistry

Biokemi

Computational Studies of HIV-1 Protease Inhibitors

Schaal, Wesley

January 2002

<p>Human Immunodeficiency Virus (HIV) is the causative agent of the pandemic disease Acquired Immune Deficiency Syndrome (AIDS). HIV acts to disrupt the immune system which makes the body susceptible to opportunistic infections. Untreated, AIDS is generally fatal. Twenty years of research by countless scientists around the world has led to the discovery and exploitation of several targets in the replication cycle of HIV. Many lives have been saved, prolonged and improved as a result of this massive effort. One particularly successful target has been the inhibition of HIV protease. In combination with the inhibition of HIV reverse transcriptase, protease inhibitors have helped to reduce viral loads and partially restore the immune system. Unfortunately, viral mutations leading to drug resistance and harmful side-effects of the current medicines have identified the need for new drugs to combat HIV.</p><p>This study presents computational efforts to understand the interaction of inhibitors to HIV protease. The first part of this study has used molecular modelling and Comparative Molecular Field Analysis (CoMFA) to help explain the structure-active relationship of a novel series of protease inhibitors. The inhibitors are sulfamide derivatives structurally similar to the cyclic urea candidate drug mozenavir (DMP-450). The central ring of the sulfamides twists to adopt a nonsymmetrical binding mode distinct from that of the cyclic ureas. The energetics of this twist has been studied with <i>ab initio</i> calculations to develop improved empirical force field parameters for use in molecular modelling.</p><p>The second part of this study has focused on an analysis of the association and dissociation kinetics of a broad collection of HIV protease inhibitors. Quantitative models have been derived using CoMFA which relate the dissociation rate back to the chemical structures. Efforts have also been made to improve the models by systematically varying the parameters used to generate them.</p>

Pharmaceutical chemistry

HIV Protease

3D-QSAR

CoMFA

Molecular Modelling

Force Field Parameterization

Quantum Mechanics

DFT

Enzyme Kinetics

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

Structure-Function Studies of Enzymes from Ribose Metabolism

Andersson, C. Evalena

January 2004

<p>In the pentose phosphate pathway, carbohydrates such as glucose and ribose are degraded with production of reductive power and energy. Another important function is to produce essential pentoses, such as ribose 5-phosphate, which later can be used in biosynthesis of nucleic acids and cofactors. </p><p>This thesis presents structural and functional studies on three enzymes involved in ribose metabolism in <i>Escherichia coli</i>. </p><p>Ribokinase is an enzyme that phosphorylates ribose in the presence of ATP and magnesium, as the first step of exogenous ribose metabolism. Two important aspects of ribokinase function, not previously known, have been elucidated. Ribokinase was shown to be activated by monovalent cations, specifically potassium. Structural analysis of the monovalent ion binding site indicates that the ion has a structural rather than catalytic role; a mode of activation involving a conformational change has been suggested. Product inhibition studies suggest that ATP is the first substrate to bind the enzyme. Independent K_d measurements with the ATP analogue AMP-PCP support this. The results presented here will have implications for several enzymes in the protein family to which ribokinase belongs, in particular the medically interesting enzyme adenosine kinase. </p><p>Ribose 5-phosphate isomerases convert ribose 5-phosphate into ribulose 5-phosphate or <i>vice versa</i>. Structural studies on the two genetically distinct isomerases in <i>E. coli</i> have shown them to be fundamentally different in many aspects, including active site architecture. However, a kinetic study has demonstrated both enzymes to be efficient in terms of catalysis. Sequence searches of completed genomes show ribose 5-phosphate isomerase B to be the sole isomerase in many bacteria, although ribose 5-phosphate isomerase A is a nearly universal enzyme. All genomes contain at least one of the two enzymes. These results confirm that both enzymes must be independently capable of supporting ribose metabolism, a fact that had not previously been established.</p>

Molecular biology

activation

isomerase

kinase

potassium

product inhibition

ribose

ribose 5-phosphate

x-ray crystallography

enzyme kinetics

fluorescence spectroscopy

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi

Redesign of Alpha Class Glutathione Transferases to Study Their Catalytic Properties

Nilsson, Lisa O

January 2001

A number of active site mutants of human Alpha class glutathione transferase A1-1 (hGST A1-1) were made and characterized to determine the structural determinants for alkenal activity. The choice of mutations was based on primary structure alignments of hGST A1-1 and the Alpha class enzyme with the highest alkenal activity, hGST A4-4, from three different species and crystal structure comparisons between the human enzymes. The result was an enzyme with a 3000-fold change in substrate specificity for nonenal over 1-chloro-2,4-dinitrobenzene (CDNB). The C-terminus of the Alpha class enzymes is an α-helix that folds over the active site upon substrate binding. The rate-determining step is product release, which is influenced by the movements of the C-terminus, thereby opening the active site. Phenylalanine 220, near the end of the C-terminus, forms an aromatic cluster with tyrosine 9 and phenylalanine 10, positioning the β-carbon of the cysteinyl moiety of glutathione. The effects of phenylalanine 220 mutations on the mobility of the C-terminus were studied by the viscosity dependence of kcat and kcat/Km with glutathione and CDNB as the varied substrates. The compatibility of slightly different subunit interfaces within the Alpha class has been studied by heterodimerization between monomers from hGST A1-1 and hGST A4-4. The heterodimer was temperature sensitive, and rehybridized into homodimers at 40 ˚C. The heterodimers did not show strictly additive activities with alkenals and CDNB. This result combined with further studies indicates that there are factors at the subunit interface influencing the catalytic properties of hGST A1-1.

Biochemistry

glutathione transferase

heterologous expression

heterodimer

hydroxyalkenal

protein redesign

sequential design

dimer-interface interactions

enzyme kinetics

glutathione

dynamic C-terminus

viscosity dependence

Biokemi

Biochemistry

Biokemi

Structure-Function Studies of Enzymes from Ribose Metabolism

Andersson, C. Evalena

January 2004

In the pentose phosphate pathway, carbohydrates such as glucose and ribose are degraded with production of reductive power and energy. Another important function is to produce essential pentoses, such as ribose 5-phosphate, which later can be used in biosynthesis of nucleic acids and cofactors. This thesis presents structural and functional studies on three enzymes involved in ribose metabolism in Escherichia coli. Ribokinase is an enzyme that phosphorylates ribose in the presence of ATP and magnesium, as the first step of exogenous ribose metabolism. Two important aspects of ribokinase function, not previously known, have been elucidated. Ribokinase was shown to be activated by monovalent cations, specifically potassium. Structural analysis of the monovalent ion binding site indicates that the ion has a structural rather than catalytic role; a mode of activation involving a conformational change has been suggested. Product inhibition studies suggest that ATP is the first substrate to bind the enzyme. Independent Kd measurements with the ATP analogue AMP-PCP support this. The results presented here will have implications for several enzymes in the protein family to which ribokinase belongs, in particular the medically interesting enzyme adenosine kinase. Ribose 5-phosphate isomerases convert ribose 5-phosphate into ribulose 5-phosphate or vice versa. Structural studies on the two genetically distinct isomerases in E. coli have shown them to be fundamentally different in many aspects, including active site architecture. However, a kinetic study has demonstrated both enzymes to be efficient in terms of catalysis. Sequence searches of completed genomes show ribose 5-phosphate isomerase B to be the sole isomerase in many bacteria, although ribose 5-phosphate isomerase A is a nearly universal enzyme. All genomes contain at least one of the two enzymes. These results confirm that both enzymes must be independently capable of supporting ribose metabolism, a fact that had not previously been established.

Molecular biology

activation

isomerase

kinase

potassium

product inhibition

ribose

ribose 5-phosphate

x-ray crystallography

enzyme kinetics

fluorescence spectroscopy

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi