Metal-Catalyzed Radical Polymerization up to High Pressure

Schröder, Hendrik

02 September 2015

No description available.

540

high pressure

kinetics

spectroscopy

pulsed-laser polymerization

iron

N,O ligands

Chemie  (PPN62138352X)

Modeling of solution and surface–initiated atom transfer radical polymerization

Mastan, Erlita

01 December 2015

Controlled radical polymerization (CRP) can be viewed as the middle ground between living anionic polymerization (LAP) and conventional free radical polymerization (FRP). It combines the precise control over polymer structure offered by LAP, under a tolerant reaction condition similar to FRP. One of the most studied CRP is atom transfer radical polymerization (ATRP), with over 10,000 papers published since its introduction in 1995. Despite the numerous studies, knowledge on its fundamental mechanism is still lacking, as evident from the lack of expression for full MWD and polydispersity that account for termination reaction. Since termination is unavoidable in ATRP, the existing expressions give inaccurate predictions as dead chains accumulate. In this study, we derived expressions for full MWD at low conversion and for polydispersity. These expressions allow us to quantify and gain better understanding on the contribution of termination. In addition, the resulting polydispersity expression shows better agreement than the existing equation when correlated with experiment data. In addition to the aforementioned questions, there are also controversies regarding the kinetics of surface-initiated ATRP, with researchers divided into two schools of theories. We evaluated the validity of these theories by comparing their predictions to experimental trends. Both theories were found to be inadequate in explaining all the experimental observations, thus triggering an investigation of the graft density. Graft density is an important determining property for polymer brushes, yet little is known about what affects its final value. Through simulations, we investigated the effect of experiment factors on the grafting density. A decrease in the amount of deactivator is found to decrease the grafting density, which could be explained by an increase in the number of monomers added per activation cycle. This knowledge allows us to explain the conflicting experiment observations regarding the growth trends of polymer layers reported in the literatures. / Thesis / Doctor of Philosophy (PhD) / Polymer materials are used almost everywhere in our daily life from clothing to water bottle. This wide range of applications owes to the nearly infinite possible properties that polymer can possess. Different polymerization processes to synthesize polymers have their own weaknesses and strengths. Herein we investigated the fundamental mechanism of one of the currently most attractive polymerization systems, atom transfer radical polymerization (ATRP). This process allows the synthesis of polymers with precisely tailored chain microstructures, making it possible to create polymer with sophisticated properties. Using modeling approaches, we derived explicit expressions for determining chain properties, allowing detailed investigation of how various factors affect these properties. Through these investigations, we obtained better understanding on the mechanism of ATRP in solution and on surface. This knowledge is crucial in providing insight and guiding experimental designs for better control over the material properties.

Kinetic modeling

Monte Carlo simulation

Bond-fluctuation method

Surface-initiated polymerization

SI-ATRP

Graft polymerization

Molecular weight distribution

Chain length distribution

Polydispersity index

Dispersity

Radical termination

Controlled radical polymerization

A Radical Approach to Syntheses and Mechanisms

Hancock, Amber N.

24 October 2011

The critically important nature of radical and radical ion mechanisms in biology and chemistry continues to be recognized as our understanding of these unique transient species grows. The work presented herein demonstrates the versatility of kinetic studies for understanding the elementary chemical reactions of radicals and radical ions. Chapter 2 discusses the use of direct ultrafast kinetics techniques for investigation of crucially important enzymatic systems; while Chapter 3 demonstrates the value of indirect competition kinetics techniques for development of synthetic methodologies for commercially valuable classes of compounds. The mechanism of decay for aminyl radical cations has received considerable attention because of their suspected role as intermediates in the oxidation of tertiary amines by monoamine oxygenases and the cytochrome P450 family of enzymes. Radical cations are believed to undergo deprotonation as a key step in catalysis. KIE studies performed by previous researchers indicate N,N-dimethylaniline radical cations deprotonate in the presence of the bases acetate and pyridine. By studying the electrochemical kinetics of the reaction of para substituted N,N-dimethylaniline radical cations with acetate anion, we have produced compelling evidence to the contrary. Rather than deprotonation, acetate reacts with N,N-dimethylaniline radical cation by electron transfer, generating the neutral amine and acetoxyl radical. Transport properties of reactants and solvent polarity changes were investigated and confirmed not to influence the electrochemical behavior forming the basis for our mechanistic hypothesis. To reconcile our conclusion with earlier results, KIEs were reinvestigated electrochemically and by nanosecond laser flash photolysis. Rather than a primary isotope effect (associated with C-H bond cleavage), we believe the observed KIEs are secondary, and can be rationalized on the basis of a quantum effect due to hyperconjugative stabilization in aromatic radical cations during an electron transfer reaction. Product studies performed by constant potential coulometry indicate N,N-dimethylaniline radical cations are catalytic in carboxylate oxidations. Collectively, our results suggest that aminyl radical cation deprotonations may not be as facile as was previously thought, and that in some cases, may not occur at all. Interest in design and synthesis of selenium containing heterocycles stems from their ability to function as antioxidants, anti-virals, anti-inflammatories, and immunomodulators. To establish synthetic feasibility of intramolecular homolytic substitution at selenium for preparation of selenocycles, we set out to determine what factors influence cyclization kinetics. A series of photochemically labile Barton and Kim esters have been syntheisized and employed as radical precursors. The effect of leaving radical stability on kinetics has been investigated through determination of rate constants and activation parameters for intramolecular homolytic substitution of the corresponding radicals via competition experiments. Notable leaving group effects on measured kinetic parameters show more facile reactions for radical precursors with more stable leaving radicals. Moreover, cyclizations to form six-membered (as opposed to five- membered) ring systems exhibited order of magnitude decreases in rate constants for a given leaving radical. Our results are congruent with expectations for radical cyclizations trends for the varied experimental parameters and suggest homolytic substitution affords a convenient means for synthesis of selenocycles. / Ph. D.

Carboxylate

Deprotonation

Electron Transfer

Radical Cyclization

Homolytic Substitution

Selenium

Radical Trap

Rate Constant

Deuterium Isotope Effect

Arrhenius Parameter

N

Mechanism

Kinetics

Cyclic Voltammetry

Constant Potential Coulometry

Competition Kinetics.

Amine Radical Cation

N-dimethylaniline

Digital Simulations

Laser Flash Photolysis

Syntéza a vlastnosti neuroaktivních steroidů / Synthesis and Properties of Neuroactive Steroids

Kapras, Vojtěch

January 2016

Herein is reported the synthesis of molecular probes for action of neuroactive steroids in vitro and in living organisms. In the first part, preparation of enantiomeric pregnane steroids is investigated, ultimately resulting into the total synthesis of ent-progesterone. The chirality of the target molecule is introduced by a highly effective organocatalytic asymmetric Robinson annulation. A new method for the sequential construction of five-membered carbocyclic ring is introduced as the key step. This is composed of substrate-controlled copper-catalyzed conjugate addition followed by radical oxygenation and subsequent thermal cyclization employing the persistent radical effect. The synthesis of truncated neurosteroid analogs is described and their biological activity at the NMDA receptor is compared with the native hormone. In the second part, methodology for specific deuterium labeling of both angular methyls of the 5β-pregnane steroid core is explored. Special attention was paid to the Barton-McCombie deoxygenation as the tool for introduction of the last deuterium atom into the methyl group. Both positions were labelled with total of three deuterium atoms in high isotopic purity.

Réactivité des composés organiques volatils avec le radical nitrate : développement d’une relation de type structure réactivité / VOC reactivity with the nitrate radical : development of a structure reactivity relationship

Kerdouci, Jamila

08 December 2011

Durant la nuit, le radical nitrate (NO3) est le principal oxydant troposphérique des composés organiques. La compréhension de l'implication des composés organiques dans les processus de chimie troposphérique exige donc une connaissance des constantes cinétiques de leurs réactions avec le radical NO3. Toutefois, au regard du nombre considérable de composés organiques émis ou formés dans la troposphère, il est difficilement envisageable d'appréhender la réactivité de chaque composé en nous reposant exclusivement sur des études de laboratoire. Celles-ci se doivent d'être complétées par l'usage de méthodes prédictives. Nous avons donc, au cours de ce travail, développé une relation de type structure-réactivité (SAR) qui permet le calcul des constantes de vitesse des réactions des composés organiques avec le radical nitrate. Cette méthode prédictive empirique permet d'estimer la réactivité d'un composé à partir de sa structure moléculaire et a été élaborée à partir de constantes cinétiques expérimentales publiées dans la littérature. De plus, conjointement au développement de cette SAR, les constantes cinétiques des réactions d'aldéhydes et d'éthers insaturés avec le radical nitrate ont été mesurées au laboratoire. Ces études expérimentales ont ainsi contribué à étoffer la base de données cinétiques sur laquelle repose cette SAR afin de permettre son parachèvement. Cette SAR reproduit, à un facteur deux près, plus de 90% des constantes cinétiques des alcènes et des composés aliphatiques oxygénés saturés et insaturés / The nitrate radical (NO3) is the main oxidant of organic compounds in the night-time troposphere. Thus, comprehension of organic compounds involvement in tropospheric chemical processes requires the knowledge of the rate coefficients for their reactions with the nitrate radical. Nevertheless, considering the wide range of organic compounds emitted or formed in the atmosphere, it is difficult to determine the reactivity of each compound only with laboratory studies. Thereby, these experimental studies have to be completed by predictive methods. In this study, a group-additivity method is therefore used to develop a new Structure-Activity Relationship (SAR) which allows prediction of the rate constants for reactions of organic compounds with the NO3 radical. This empirical method is based on the prediction of a rate constant leaning only on the molecular structure of the organic compound. It relies on experimental rate constants available in the literature. Moreover, the rate constants of unsaturated aldehydes and ethers with the nitrate radical have been measured. Thereby, these experimental studies contribute to expend the kinetic database used for the SAR development and allow its improvement. For saturated and unsaturated oxygenated compounds, more than 90% of the rate constants are reproduced within a factor of two

Radical nitrate

Étude cinétiques

Composés organiques volatils

Relation stucture réactivité

Gas-phase reaction

Nitrate radical

Volatile organic compounds

Stucture-activity relationship

Kineticss study

Elimination de substances pharmaceutiques d'effluents urbains par un procédé d'oxydation avancée basé sur le radical sulfate / Elimination of pharmaceutical substances from urban wastewater effluent using sulfate radical based advanced oxidation process

Mahdi ahmed, Moussa

15 October 2013

Ce travail est consacré à l’étude d’un procédé d’oxydation avancée (POA) basé sur la génération de radicaux sulfates (SO4•-) pour l’élimination de substances pharmaceutiques dans le cadre du traitement d’effluents urbains. Quatre substances pharmaceutiques azotées (carbamazépine, diclofénac, sulfaméthoxazole et ciprofloxacine) appartenant à des familles thérapeutiques différentes ont été choisies en tant que contaminants modèles. L’évaluation de la performance cinétique des procédés basés sur la génération de HO• (H2O2/Fe(II) et UV-C/H2O2) et de SO4•- (HSO5-/Co2+, UV-C/S2O82- et UV-C/HSO5-) a été conduite dans des effluents de stations d'épuration traités biologiquement. La comparaison des procédés non photochimiques et photochimiques a été conduite dans les mêmes conditions optimales et montre que les procédés générant des SO4•- sont moins inhibés par la matrice environnementale que les procédés produisant HO•. La réaction de transfert électronique est mise en évidence par l’identification de produits de transformation des contaminants d’étude par chromatographie liquide couplée à un spectromètre de masse à haute résolution. Le début d’oxydation démarre par un transfert d’un électron sur les groupements azotés générant ainsi un radical cation qui réagit avec l’eau ou l’O2. La dégradation du sulfaméthoxazole est le cas le plus évident grâce à sa fonction amine primaire (aniline) qui se transforme en fonction nitro. On peut par conséquent envisager des nouvelles stratégies de traitement des eaux usées urbaines par la génération de SO4•-. / This work is devoted to the study of an alternative advanced oxidation process (AOP) generating sulfate radical (SO4•-) for the removal of pharmaceuticals in municipal wastewater effluents. Four nitrogen containing pharmaceuticals (carbamazepine, diclofenac, sulfamethoxazole and ciprofloxacin) belonging to different therapeutic classes were chosen as model contaminants. The evaluation of the kinetic performance of processes based on the generation of HO• (H2O2/Fe(II) and UV-C/H2O2 ) and SO4•- (HSO5-/Co2+, UV-C/S2O82- and UV-C/HSO5- ) was conducted in biologically treated effluent. Comparison of photochemical and non- photochemical processes performed under the same optimal conditions showed that the processes generating SO4•- are less inhibited by the environmental matrix than processes producing HO•. This electron transfer reaction is demonstrated by the identification of transformation products using liquid chromatography coupled to high resolution mass spectrometer. Oxidation of parent compounds starts by an electron transfer reaction on the nitrogen groups thereby generating a cation radical which further reacts with water or O2. The sulfamethoxazole degradation pathway gives more insights into this mechanism due to the primary amine moiety (aniline) which is converted into nitro function. This treatment system can be regarded as a new strategy for the treatment of urban wastewater contaminated by pharmaceutical residues through the generation of SO4•-.

Procédé d’oxydation avancée

Substances pharmaceutiques

Radical anion sulfate

Traitement tertiaire

Eaux usées domestiques

Advanced oxidation processes

Pharmaceutical substances

Sulfate radical anion

Tertiary treatment

Urban wastewater

Traitement de l’acétaldéhyde par décharges électriques impulsionnelles dans les mélanges de gaz atmosphériques : cinétique et efficacité énergétique / Treatment of acetaldehyde by pulsed electric discharges in mixtures of atmospheric gases : kinetic and energy efficiency

Faider, Wilfrid

14 February 2013

Cette thèse a pour objet l’analyse de la cinétique de la conversion de l’acétaldéhyde, CH₃CHO, à des concentrations initiales inférieures ou égale à 5000 ppm dans un mélange de gaz à base d’azote et contenant jusqu’à 20% d’oxygène, à température ambiante. L’étude a été réalisée en utilisant trois réacteurs mettant en œuvre des décharges de qualités spatiales différentes. Il s’agit d’un réacteur (UV510) à décharge pré-ionisée (photo-déclenchée) par rayonnement UV produisant un plasma homogène, et de deux réacteurs à décharge à barrière diélectrique (DBD), de géométrie plane (plan-plan) et de géométrie cylindrique (tige-tube) alimentés par impulsion HT et produisant des plasmas non homogènes à faible (plan) ou forte (cylindre) filamentation ; un diagnostic d’imagerie rapide (ns) de la DBD de géométrie plane montre que le plasma peut être considéré quasi-homogène. En s’appuyant sur une modélisation 0D auto-cohérente de la décharge photo-déclenchée, l’étude de la cinétique du mélange N₂/CH₃CHO montre l’importance des états métastables de la molécule d’azote, triplet A³Σu⁺, et singlets (groupe a' ¹∑⁻u, a ¹∏g, et w ¹Δu) dans la dissociation de l’acétaldéhyde. Un coefficient minimum de 6.5×10⁻¹¹ cm³.s⁻¹ est estimé pour le quenching des singlets par l’acétaldéhyde. Le coefficient du triplet est estimé entre 4.2×10⁻¹¹ cm³.s⁻¹ et 6.5×10⁻¹¹ cm³.s⁻¹. Cette dissociation produit des radicaux (CH₃, CH₃CO, HCO, H, O) et des molécules (CH₄, CH₂CO, C₂H₄, C₂H₂, H₂, CO). Ainsi les sous-produits majoritaires mesurés à la fin de la post décharge temporelle sont le méthane, le dihydrogène, le monoxyde de carbone et l’éthane. Les minoritaires sont l’acétylène, l’éthène, l’acétone et l’acétonitrile. Dans les mélanges contenant de l’oxygène, l’importance de la dissociation de CH₃CHO par quenching des états métastables de N₂ diminue au profit des processus d’oxydation par le radical hydroxyle, OH, et l’oxygène atomique, O (³P). La mesure résolue en temps du radical OH dans la post-décharge du réacteur UV510 montre une très forte réactivité de ce radical avec les sous-produits de conversion de l’acétaldéhyde. Une densité maximum de OH égale à 3.5×10¹⁴ cm⁻³ a été mesurée pour 10 % d’oxygène et 5000 ppm d’acétaldéhyde. Le schéma cinétique adopté pour ces mélanges donne, par la modélisation auto-cohérente, une valeur de densité plus élevée. Toutefois, la conversion de l’acétaldéhyde dans N₂/O₂/CH₃CHO est bien expliquée par le modèle, de même que les concentrations produites de méthane et d’éthane. Enfin, la comparaison de l’efficacité énergétique des trois réacteurs étudiés montre que l’homogénéité de la décharge favorise, pour des milieux pauvres en oxygène (moins de 2 %), la conversion de l’acétaldéhyde. / The present study deals with the kinetics analysis of acetaldehyde (CH₃CHO) conversion in electrical discharges with different spatial qualities et at room temperature. Acetaldehyde concentrations up to 5000 ppm in nitrogen-based gas mixture containing up to 20% of oxygen have been investigated. Three different plasma reactors were used: an UV510 reactor producing a homogeneous plasma thanks to a pre-ionization by UV radiation (photo-triggered), a plane-to-plane and a rod-tube dielectric barrier discharges (DBDs) reactors, In both DBDs reactors discharges were driven by high voltage pulses allowing the production of weakly inhomogeneous plasma in the plane geometry and highly filamentary discharges in the cylindrical one. A high speed imaging diagnostic (ns range) of the plane-to-plane DBD shows that the plasma can be considered quasi-homogeneous. Based on a self-consistent 0D model, the kinetics study of the N₂/CH₃CHO mixture conversion in the photo-triggered discharge shows the importance of nitrogen molecule metastable states , i.e. the triplet A³Σu⁺ and the singlets group a' ¹∑⁻u, a ¹∏g, et w ¹Δu, in the acetaldehyde dissociation process. A minimum coefficient of 6.5×10⁻¹¹ cm³.s⁻¹ has been estimated for the quenching of N₂ singlets state by acetaldehyde. For the triplet states quenching the coefficient of has been evaluated between 4.2×10⁻¹¹ cm³.s⁻¹ and 6.5×10⁻¹¹ cm³.s⁻¹. This dissociation process produces radicals as CH₃, CH₃CO, HCO, H, O, and molecules like CH₄, CH₂CO, C₂H₄, C₂H₂, H₂, CO. Thus, the major by-products detected at the end of the post-discharge time are methane, hydrogen, carbon monoxide and ethane; smaller amounts of acetylene, ethene, acetone and acetonitrile were also detected. In containing oxygen mixtures, the importance of the CH3CHO dissociation processes due to N₂ metastable states quenching of decreases in favor of oxidation processes promoted by the hydroxyl radical, OH, and atomic oxygen, O (³P). Time-resolved measurements of the OH radical in the photo-triggered post-discharge show a very high reactivity of this radical with the by-products of acetaldehyde conversion. A maximum density of OH radical equal to 3.5×10¹⁴ cm⁻³ was measured for 10% oxygen and 5000 ppm of acetaldehyde. The kinetic scheme adopted in the self-consistent model for the same gas mixture gives a higher density value; by the way the model is in good agreement with the acetaldehyde conversion in N₂/O₂/CH₃CHO mixtures, as well as with the methane and ethane produced concentrations. Finally, the comparison of the three studied reactors energy efficiency shows that, for low oxygen content (less than 2%), the homogeneity of the discharge promotes the acetaldehyde conversion.

COV

Acétaldéhyde

Conversion

DBD

Décharge photo-déclenchée

Cinétique

Quenching

Métastable d’azote

Radical hydroxyle

OH

VOCs

Acetaldehyde

Conversion

DBD

Photo-triggered discharge

Kinetics

Quenching

Metastable nitrogen

Hydroxyl radical

OH

Études des réactions primaires en solutions par la radiolyse pulsée picoseconde / Picosecond Pulse Radiolysis Study of Primary Reactions in Solutions

El Omar, Abdel Karim

04 November 2013

Après la découverte des rayonnements ionisants et leurs effets chimiques, il était important d’étudier et de comprendre les mécanismes de formations des radicaux libres et des produits moléculaires caractérisés par leurs courtes durées de vie. Ceci a encouragé les groupes de recherches à développer leurs outils pour qu’ils puissent réaliser ces études. De nos jours la radiolyse impulsionnelle se manifeste comme un outil fondamental permettant de sonder les effets chimiques ainsi que les mécanismes réactionnels dans le milieu étudié.Le laboratoire de Chimie Physique d’Orsay « LCP » est un laboratoire interdisciplinaire abritant la plateforme « ELYSE » qui est un centre de cinétiques rapides. Grâce au laser femtoseconde et à l’accélérateur d’électrons picoseconde, nous avons eu la possibilité, dans le domaine de la radiolyse, de remonter en temps, en étudiant les effets chimiques dans un milieu réactionnel, jusqu’à ~ 5 ps.Nous nous sommes intéressés par les réactions primaires induites par les rayonnements ionisants en solution et ELYSE représentait l’outil principal pour ces études. Les résultats obtenus concernent :- La détermination directe du rendement radiolytique du radical hydroxyle « HO• » en fonction du temps à l’échelle de la picoseconde ;- Etude de l’effet direct du rayonnement ionisant sur les solutions aqueuses concentrées ainsi que la vérification de la réaction de transfert d’électron ultrarapide entre le soluté et le trou positif « H2O•+ » issu lors de la radiolyse de l’eau ;- Etude à température ambiante de la réaction de transfert d’électron entre un électron solvaté (donneur d’électron) et un soluté organique (accepteur d’électron) en milieu visqueux ;- Etude à température ambiante de la solvatation de l’électron dans l’éthylène glycol et dans le propan-2-ol. / Following the discovery of ionizing radiations and their chemical effects, it was important to study and comprehend the formation mechanisms of short lived free radicals and molecular products. In order to perform such studies, researchers and research groups worked on developing tools allowing both formation and detection of those species at short time scales. Nowadays, pulse radiolysis imposed itself as a fundamental and efficient tool allowing scientists to probe chemical effects as well as reaction mechanisms in studied media.The laboratoire de Chimie Physique d’Orsay “LCP” is an interdisciplinary laboratory hosting the platform of fast kinetics known as “ELYSE”. Due to its femtosecond laser and its picosecond electron accelerator, we have the possibility to study chemical effects of ionizing radiations interaction with media at ultrashort times up to ~5 ps.Knowing that we are interested in primary reactions induced in aqueous media by ionizing radiations, ELYSE represents the essential tool in performing our studies. The obtained results concern:- First direct determination of hydroxyl radical “HO•” radiolytic yield as function of time at picosecond time scale ;- Direct effect of ionizing radiation in highly concentrated aqueous solutions as well as investigation of the ultrafast electron transfer reaction between solute molecules and positive holes “H2O•+” formed upon water radiolysis ;- Study at room temperature of electron transfer reaction between solvated electron (electron donor) and organic solutes (electron acceptors) en viscous medium ;- Study at room temperature of electron’s solvation dynamics in ethylene glycol and 2-propanol.

Radiolyse pulsée picoseconde

Effet direct

Trou positif

Solvatation

Radical hydroxyle

Picosecond pulse radiolysis

Direct effect

Positive hole

Solvation dynamics

Hydroxyl radical

Caractérisation de nouvelles enzymes impliquées dans la biosynthèse de cofacteurs de microorganismes. Mécanismes des tyrosine lyases à radical SAM / Characterization of novel enzymes involved in biosynthesis of microbial cofactors. Mechanisms of radical SAM tyrosine lyases

Decamps, Laure

13 January 2014

Le cofacteur F420 est un coenzyme d’oxydoréduction essentiel pour la méthanogenèse chez les archées, un processus qui influence fortement les interactions métaboliques au sein du microbiote intestinal ; en outre, il joue un rôle important dans la pathogénicité de la bactérie Mycobacterium tuberculosis. L’étude de sa biosynthèse présente donc un intérêt majeur en Biologie.La formation du chromophore du F420 est catalysée par la F0-synthase, qui contient, de façon unique, deux domaines caractéristiques des enzymes à radical SAM (rSAM). Ces enzymes catalysent le clivage de la S-adénosylméthionine (SAM) pour former un radical 5′ déoxyadénosyle, capable d’initier un grand nombre de réactions radicalaires.Nous avons réussi à identifier les substrats de la F0-synthase et à reconstituer la synthèse du F0 in vitro. Nous avons également démontré que cette enzyme contient deux centre [4Fe-4S] 2+/1+ rSAM fonctionnels et caractérisé les étapes de la synthèse du F0. Ceci nous a permis de proposer un mécanisme réactionnel pour la F0 synthase. Nous avons ensuite entrepris la comparaison de la F0 synthase avec les deux autres enzymes rSAM tyrosine lyases connues à ce jour : ThiH, impliquée dans la biosynthèse de la vitamine B1, et HydG, impliquée dans la biosynthèse du cofacteur métallique de l’hydrogénase à fer-fer. Nous avons ainsi découvert de nouveaux aspects de la réaction de clivage de la tyrosine par ces enzymes, permettant une meilleure compréhension de ce groupe émergent au sein de la superfamille des enzymes rSAM. / Cofactor F420 is a redox coenzyme crucial for methanogenesis in Archaea, a process which plays a major role in metabolic interactions in the gut microbiota ; It also constitutes a key pathogenicity factor for Mycobacterium tuberculosis. Understanding the biosynthesis of this cofactor is thus of major interest.The biosynthesis of the chromophore of F420 is catalyzed by F0 synthase, which comprises, in a unique manner, two radical SAM (rSAM) domains. These enzymes catalyze the cleavage of S adenosylmethionine (SAM) to produce a 5′-deoxyadenosyl radical, which can initiate a broad range of radical reactions.We succeeded to identify the substrates of F0-synthase and to perform the biosynthesis of F0 in vitro. We ascertained that F0-synthase contains two functional [4Fe-4S]2+/1+ rSAM clusters, and characterized the steps of the reaction of F0 synthesis. Based on these date, we proposed a mechanism for the F0-synthase reaction. Furthermore, we compared F0 synthase with the two other radical SAM tyrosine lyases identified to date: ThiH, which is involved in vitamin B1 biosynthesis, and HydG, which is involved in the biosynthesis of the metal cofactor of iron-iron hydrogenases. We obtained novel insights of the reaction of tyrosine cleavage catalyzed by these enzymes, providing a better understanding of this emerging group in the rSAM enzyme superfamily.

Biosynthèse de cofacteur

F420

F0

Enzyme à radical SAM

Tyrosine

Vitamine

Fer-soufre

Cofactor biosynthesis

F420

F0

Radical SAM enzyme

Tyrosine

Vitamin

Iron-sulfur

Sistemas oxidativos e biomiméticos aplicados à hidrólise enzimática de materiais lignocelulósicos / Oxidative-biomimetic systems applied to enzymatic hydrolysis of lignocellulosic materials

Noriega, Omar Antonio Uyarte

29 June 2016

Inúmeros trabalhos da literatura científica mostram que a remoção parcial de lignina é útil para facilitar o processo de sacarificação enzimática de materiais lignocelulósicos. No entanto, a maioria dos processos de deslignificação aplica condições severas de reação e apresenta custos elevados de processo. Uma alternativa aos processos mais severos de deslignificação envolve a aplicação de sistemas biomiméticos. Estes sistemas demandam condições amenas de reação, compatíveis com a etapa de hidrólise enzimática, porém geralmente são mais lentos e menos eficientes do que os pré-tratamentos químicos e quimiotermomecânicos convencionais. Ponderando estes fatos, o objetivo desta tese foi estudar a aplicação de sistemas oxidativos e biomiméticos na deslignificação de materiais lignocelulósicos prévios a uma etapa de hidrólise enzimática da fração polissacarídica. A estratégia de trabalho consistiu em pré-tratar bagaço de cana (foram empregados 3 cultivares diferentes de cana no presente estudo) com um processo quimiotermomecânico (CTM) em condições amenas de reação (5,0% de Na2SO3 e 2,5% de NaOH) seguido de um tratamento biomimético oxidativo. Esta abordagem visou gerar um material parcialmente deslignificado que pudesse ter a recalcitrância significativamente diminuída pela aplicação de um processo biomimético. Um segundo pré-tratamento foi aplicado em condições mais severas de reação (10% de Na2SO3 e 5,0% de NaOH) e visou gerar um material de referência, com baixa recalcitrância. Os sistemas biomiméticos empregados tiveram origem nos processos naturais de biodegradação de madeira por fungos de decomposição branca e parda e envolveram a ação de: a) Manganês peroxidase, Lacase, ferro e Oxigênio; b) reação de Fenton mediada por quelantes. Estes sistemas foram suplementados ou não com ácidos graxos insaturados, visando gerar radicais organoperoxila no caso dos sistemas suplementados. As reações de Fenton mediadas por quelantes apresentaram emissão de quimiluminescência, o que permitiu otimizar o sistema reacional com base na máxima quimiluminescência obtida. A remoção de lignina obtida com o pré-tratamento CTM variou de acordo com a carga de sulfito alcalino empregada, sendo que para as severidades baixa e alta, a remoção de lignina atingiu 26% e 54%, respectivamente. Os sistemas biomiméticos aplicados no bagaço de cana, após pré-tratamento com sulfito alcalino na condição branda, produziram graus de deslignificação variáveis, sendo que as principais remoções de lignina foram obtidas com o tratamento de Fenton mediado por quelantes e com Oxigênio, atingindo remoções acumuladas de lignina de 44% e 62%, respectivamente. Em todos os casos avaliados, a remoção adicional de lignina promoveu maiores eficiências de conversão enzimática das frações polissacarídicas residuais. A maior conversão de celulose e hemicelulose (acima de 80%) foi obtida com o tratamento Fenton mediado por quelantes aplicado sobre um cultivar de cana de açúcar que apresentava elevado teor de ácidos hidroxicinâmicos, sugerindo uma ação eficiente destes sistemas para a remoção destes ácidos hidroxicinâmicos. / The current scientific literature shows that lignin removal can facilitates subsequent processes of enzymatic saccharification of lignocellulosic materials. However, most of the delignification processes use severe reaction conditions and present high process costs. One alternative for the severe delignification processes includes the use of biomimetic systems. These systems can be applied under mild reaction conditions, which are compatible with the enzymatic hydrolysis step. Nevertheless, biomimetic systems usually present low reaction rates and are less efficient than the more severe chemical and chemithermomechancial processes. Weighing these facts, the main subject of the current PhD thesis was to study oxidative-biomimetic systems suitable for delignification of lignocellulosic materials as a previous step to the enzymatic hydrolysis of the polysaccharide fraction. The experimental approach involved the pretreatment of sugar cane bagasse (three different sugar cane cultivars were evaluated) by a chemithermomechanical (CTM) process under mild reaction conditions (5% of Na2SO3 and 2.5% NaOH), followed by an oxidative-biomimetic system. This approach aimed to prepare a partially delignified material suitable to be treated by the subsequent biomimetic systems, providing significant changes in the material recalcitrance. A second pretreatment under more severe reaction conditions (10% Na2SO3 and 5% NaOH) was performed to prepare a reference material with low recalcitrance. The biomimetic systems used in the current work were based on natural wood decay processes involving white- and brown-rot fungi, and include the actions of: a) Manganese peroxidase, Laccase, Iron íons and Oxygen; b) Chelator Mediated Fenton reactions (CMF). This reaction systems used (or not) the presence of unsaturated fatty acids to induce formation of organoperoxyl radicals. The CMF reactions presented chemiluminescence, which enabled the reaction optimization with basis on maximal chemiluminescence. The lignin removal during the CTM pretreatment varied according to the alkaline-sulfite load used in the reaction. The delignification increased with increased alkaline-sulfite loads reaching 26% and 54% for the less severe and more severe reaction conditions, respectively. Biomimetic systems applied over the mild-pretreated sugar cane bagasse produced varied delignification levels, reaching maximal values for cumulative lignin removal of 44% and 62% for the CMF and Oxigen, respectively. In all cases, the supplementary removal of lignin resulted in more efficient enzymatic hydrolysis of the polysaccharide fraction. The highest cellulose and hemicellulose conversions (over 80%) was obtained with the CMF system applied on a sugar cane cultivar that contained high hydroxycinnamic acids contents, suggesting an efficient action of CMF systems for hydroxycinnamic acids removal.