Lipase chemoselectivity - kinetics and applications

Hedfors, Cecilia

January 2009

A chemoselective catalyst is preferred in a chemical reaction where protecting groups otherwise are needed. The two lipases Candida antarctica lipase B and Rhizomucor miehei lipase showed large chemoselectivity ratios, defined as (kcat/KM)OH / (kcat/KM)SH, in a transacylation reaction with ethyl octanoate as acyl donor and hexanol or hexanethiol as acyl acceptor (paper I). The chemoselectivity ratio of the uncatalyzed reaction was 120 in favour of the alcohol. Compared to the uncatalyzed reaction, the chemoselectivity was 730 times higher for Candida antarctica lipase B and ten times higher for Rhizomucor miehei lipase. The KM towards the thiol was more than two orders of magnitude higher than the KM towards the corresponding alcohol. This was the dominating contribution to the high chemoselectivity displayed by the two lipases. In a novel approach, Candida antarctica lipase B was used as catalyst for enzymatic synthesis of thiol-functionalized polyesters in a one-pot reaction without using protecting groups (paper II). Poly(e-caprolactone) with a free thiol at one of the ends was synthesized in an enzymatic ring-opening polymerization initiated with mercaptoethanol or terminated with either 3-mercaptopropionic acid or g-thiobutyrolactone.

Candida antarctica lipase B

Rhizomucor miehei lipase

active site titration

kinetics

chemoselectivity

thiol

alcohol

thiol-functionalized polyesters

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Elaboration en phase fondue de matériaux polymères à activité biologique / In melt preparation of biologically active polymeric materials

Belkhir, Kedafi

29 March 2017

L’objectif de cette thèse était d’allier, dans un même polymère, le contrôle de l’architecture macromoléculaire, la fonctionnalité et la possibilité de sa mise en oeuvre en phase fondue, tout en préservant l’aspect environnemental. Les structures polymères synthétisées sont basées sur des chaînes biodégradables et/ou biosourcées d’acide polylactic (PLA), de polyhydroxybutyrate (PHB) et de polycaprolactone (PCL). Ces dernières ont été assemblées dans des structures macromoléculaires branchées à design contrôlé et portant des fonctions thiols, ces fonctions ont permis le greffage de monomères dotés de groupements ammoniums quaternaires, sur les structures obtenues, via une addition radicalaire thiol-ène.Les produits obtenus ont été mélangés en phase fondue, par extrusion, avec des matrices de PLA et de PCL, pour préparer des films. Ces derniers ont fait l’objet d’une étude d’activité antibactérienne qui a montré une grande efficacité envers différents types de bactéries / The aim of this work was to develop polymers that combine controlled macromolecular architectures, functionality, melt processing and an environmentally friendly aspect. The obtained polymeric structures were based on biodegradable and/or biosourced chains of polylactic acid (PLA), polycaprolactone (PCL) and polyhydroxybutyrate (PHB). The lasts were assembled in branched macromolecular structures with controlled design and bearing thiol functions, these functions allowed the grafting of quaternary ammoniumcontaining monomers on the branched structures according to a thiol-ene radical addition mechanism. The final products were blended with neat matrices of PLA and PCL in the melt state, by extrusion process, to make polymeric films. The obtained film-shaped blends were subjected to antibacterial activity study showing there high efficiency against different types of bacteria

PLA

PCL

PHB

Architecture macromoléculaire

Thiol-ène

Polymères fonctionnels

Polymères antibactériens

PLA

PCL

PHB

Macromolecular design

Thiol-ene

Functional polymers

Antibacterial polymers

Studium fotodegradace piva metodou fluorescenční spektroskopie / Study of beer photodegradation by fluorescence spectroscopy

Tayari, Tomáš

January 2021

If a beer is exposed to visible light, it will become light-damaged over time, which is characterised by an undesirable odour and flavour of the drink. The confirmed cause of the above-mentioned flavour in beer is 3-methyl-2-buten-1-thiol (MBT). This substance is formed by non-enzymatic reactions in which riboflavin (vitamin B2) plays the role of photocatalyst and breaks down after transferring its excitation energy, charged by absorption of visible light. The loss of riboflavin results in a change in optical properties of the sample. The aim of this work is to investigate the possibilities of optical detection of light damage, through the analysis of riboflavin content, based on fluorescence and absorption of the sample. Since riboflavin is degraded when light damage occurs, it is possible to determine whether or not a sample is light damaged from its content in beer. Optical detection of light damage is non- invasive and can therefore determine the quality of the beer directly in the commercial bottle without the need to open it.

DESIGN OF HIGHLY STABLE LOW-DENSITY SELF-ASSEMBLED MONOLAYERS USING THIOL-YNE CLICK REACTION FOR THE STUDY OF PROTEIN-SURFACE INTERACTIONS

Safazadeh Haghighi, Leila

01 January 2016

Protein adsorption on solid surfaces is a common yet complicated phenomenon that is not fully understood. Self-assembled monolayers have been utilized in many studies, as well-defined model systems for studying protein-surface interactions in the atomic level. Various strategies, including the use of single component SAMs[1, 2], combinations of long and short alkanethiolates with methyl- and hydroxyl- terminal groups[3, 4], and using mixtures of alkanethiolates with similar chain length and varying terminal functional group [5] have been used to effectively control the surface wettability and determine the effect of surface composition and wettability on protein adsorption. In this dissertation we report key new findings on the effect of surface density of functional groups on protein adsorption phenomenon. In The first phase of this research, we developed a novel approach for preparation of low-density self-assembled monolayers(LD-SAMs) on gold surfaces, based on radical-initiated thiol-yne click chemistry. This approach provides exceptional adsorbate stability and conformational freedom of interfacial functional groups, and is readily adapted for low-density monolayers of varied functionality. The resulting monolayers have two distinct phases: a highly crystalline head phase adjacent to the gold substrate, and a reduced density tail phase, which is in contact with the environment. First, we investigated the feasibility of the proposed chemistry in solution-phase. In this approach, we synthesized “Y” shaped carboxylate-terminated thiol adsorbates via radical-initiated thiol-yne reaction. The LD-SAMs were then prepared through immersion of gold substrates into the solution of synthesized adsorbate molecules in hexane. The chemical structuring and electrochemical properties of resultant LD-SAMs were analyzed and compared with those of analogous traditional well-packed monolayers, using techniques such as Fourier transform infrared spectroscopy, ellipsometry, electrochemical impedance spectroscopy, reductive desorption, and contact angle goniometry. Characterization results indicated that resulting LD-SAMs have a lower average crystallinity, and higher electrochemical stability compared to well-packed monolayers. In addition, using a three-electrode system, we were able to show a reversible change in LD-SAM surface wettability, in response to an applied voltage. This remodeling capacity confirms the low density of the surface region of LD-SAM coatings. The second area of work was focused on using the developed chemistry in solid-phase. The solid-phase approach minimized the required synthesis steps in solution-phase method, and used the photo-initiated thiol-yne click-reaction for grafting of acid-terminated alkynes to thiol-terminated monolayers on a gold substrate to create similar LD-SAMs as what were prepared through solution-phase process. We characterized the resulting monolayers and compared them to analogous well-packed SAMs and the also low-density monolayers prepared through the solution phase approach. The results confirmed the proposed two-phase structure, with a well-packed phase head phase and a loosely-packed tail phase. In addition, the electrochemical studies, indicated that the resultant monolayers were less stable than the monolayers prepared via solution-phase, but they are yet significantly more stable than typical well-packed monolayers. The less stability of these monolayers were attributed to the partial desorption of adsorbates from the gold substrate due to UV irradiation during the grafting process. Building on the established chemistry, we studied the effect of lateral packing density of functional groups in a monolayer on the adsorption of Bovine serum albumin protein. we used surface plasmon resonance spectroscopy (SPR) and spectroscopic ellipsometry, to evaluate BSA adsorption on carboxylate‑, hydroxyl-, or alkyl- terminated LD-SAMs. It was found that for the LD-SAMs, the magnitude of protein adsorption is consistently higher than that of a pure component, well-packed SAM for all functionalities studied. In addition, it was seen that the magnitude of BSA adsorption the LD-SAMs, was consistently higher than that of a pure component, well-packed SAM for all functionalities studied. The difference of protein adsorption on LD-SAMs and SAMs can not be associated to difference in lateral packing density, unless we eliminate the impact of other contributing factors in protein adsorption such as surface energy. In order to better understand the impact of packing density on protein-surface interactions, we prepared the mixed SAMs of (carboxylate/alkyl) and (hydroxyl/alkyl) with matching surface energy as the carboxylate and hydroxyl terminated LD-SAMs. It was found that the energy-matched mixed SAMs of carboxylate and hydroxyl functionality adsorbed more protein than the LD-SAMs. However, an opposite trend was seen for the alkyl surfaces, where surface energies are comparable for LD-SAMs and pure component SAMs, indicating that BSA proteins have higher affinity for methyl- terminated LD-SAMs than well-packed SAMs.

Self-Assembled Monolayers

Proteins

Thiol-Yne Click Reaction

Biomedical

Chemical Engineering

Single channel analysis of thiol binding to a putative site of alcohol action on the glycine receptor

Goldstein, Beth Erlichman

23 October 2009

An alcohol and anesthetic binding pocket is hypothesized to exist among transmembrane domains of the α1 glycine receptor (GlyR). Prior work has shown that amino acid residue serine-267 plays a significant role in the enhancing effects of alcohol and anesthetics and is theorized to form part of an alcohol and anesthetic binding cavity among subunit transmembrane domains. Propyl methanethiosulfonate (PMTS), an alcohol-like thiol, was previously shown to bind to a cysteine residue introduced at position 267 (S267C) and this resulted in permanent enhancement of GlyR function. If ethanol is binding to residue 267 in wildtype GlyR to potentiate receptor function then we hypothesized that covalent thiol labeling would produce receptor enhancement by the same mechanisms as ethanol. Using outside-out patch single channel electrophysiology we determined the open and closed dwell-times and burst properties of S267C GlyR in the absence and presence of PMTS. The primary consequence of PMTS binding to S267C GlyR was an increase in the lengths of burst durations, paralleling the main effect of ethanol on wildtype GlyR. Our findings thus provide a new line of evidence suggesting that ethanol is exerting its enhancing effects on the GlyR through its interactions with amino acid residue 267 in the second transmembrane domain. / text

Alcohol

Anesthetic

Glycine receptor

Thiol binding

Amino acid

Transmembrane domains

Propyl methanethiosulfonate

Amino acid residue 267

Adsorption of molecular thin films on metal and metal oxide surfaces

Besharat, Zahra

January 2016

Metal and metal oxides are widely used in industry, and to optimize their performance their surfaces are commonly functionalized by the formation of thin films. Self-assembled monolayers (SAMs) are deposited on metals or metal oxides either from solution or by gas deposition. Thiols with polar terminal groups are utilized for creating the responsive surfaces which can interact electrostatically with other adsorbates. Surface charge effects wetting and adhesion, and many other surface properties. Polar terminal groups in thiols could be used to modify these factors. Mixed SAMs can provide more flexible surfaces, and could change the resulting surface properties under the influence of factors such as pH, temperature, and photo-illumination. Therefore, in order to control these phenomena by mixed polar-terminated thiols, it is necessary to understand the composition and conformation of the mixed SAMs and their response to these factors. In this work, mixtures of thiols with carboxylic and amino terminal groups were studied. Carboxylic and amino terminal groups of thiol interact with each other via hydrogen bonding in solution and form a complex. Complexes adsorb to the surface in non-conventional orientations. Unmixed SAMs from each type, either carboxylic terminated thiols or amino terminated thiols are in standing up orientation while SAMs from complexes are in an axially in-plane orientation. Selenol is an alternative to replace thiols for particular applications such as contact with biological matter which has a better compatibility with selenol than sulfur. However, the    Se-C bond is weaker than the S-C bond which limits the application of selenol. Understanding the selenol adsorption mechanism on gold surfaces could shed some light on Se-C cleavage and so is investigated in this work. Se-C cleavage happens in the low coverage areas on the step since atoms at steps have lower coordination making them more reactive than atoms on the terraces.  Another area where the self-assembly of molecules is of importance is for dye sensitized solar cells, which are based on the adsorption of the dye onto metal oxides surfaces such as TiO2.The interface between the SAM of dye and the substrate is an important factor to consider when designing dyes and surfaces in dye sensitized solar cells (DSSCs). The quality of the self-assembled monolayers of the dye on the TiO2 surface has a critical influence on the efficiency of the DSSCs.  Creation of just a monolayer of dye on the surface could lead to an efficient current of photo-excited electrons to the TiO2 and degeneration of the dye by redox. This work, T-PAC dye showed island growth with some ad-layer that is not in contact with the surface, whereas the MP13 dye adsorption is laminar growth.  Cuprite (Cu2O) is the initial and most common corrosion product for copper under atmospheric conditions. Copper could be a good replacement for noble metal as catalysts for methanol dehydrogenation. Knowledge about the structure of Cu2O(100) and Cu2O(111) surfaces could be used to obtain a deeper understanding of methanol dehydrogenation mechanisms with respect to adsorption sites on the surfaces. In this work, a detailed study was done of Cu2O(100) surface which revealed the possible surface structures as the result of different preparation conditions. Studies of the structure of Cu2O(100) and Cu2O(111) surfaces show that Cu2O(100) has a comparatively stable surface and reduces surface reactivity. As a consequence, dehydrogenation of methanol is more efficient on the Cu2O(111) surface. The hydrogen produced from methanol dehydrogenation is stored in oxygen adatom sites on both surfaces. / <p>QC 20161107</p>

Self assembled monolayer (SAM)

dye synthesis solar cell (DSSC)

thiol

selenol

Cu2O(100)

Cu2O(111) and dehydrogenation

Caracterização funcional de uma nova proteína antioxidante: Ohr (Organic Hydroperoxide Resistance Protein). Vias de redução e expressão em Xylella fastidiosa / Functional characterization of a new antioxidant protein: Ohr (Organic Hydroperoxide Resistance Protein). Pathways of reduction and expression in Xylella fastidiosa

Cussiol, José Renato Rosa

13 April 2010

Xylella fastidiosa é uma bactéria gram-negativa, colonizadora do xilema de plantas economicamente importantes, sendo responsável por diversas patogenias como a doença de Pierce em videiras e a clorose variegada dos citros (CVC). Plantas, ao serem infectadas por patógenos, dispõem de um maquinário de defesa que inclui a geração de espécies reativas de oxigênio (ROS). Peróxidos de lipídios podem ser formados pelo ataque de ROS à membrana bacteriana ou pela ação de lipoxigenases. O sistema da AhpR (alquil hidroperóxido redutase) foi inicialmente caracterizado como o principal responsável pela defesa contra hidroperóxidos orgânicos em bactéria. Recentemente, foi descrito um gene em muitas bactérias patógenas no qual a sua deleção conferia a célula uma maior susceptibilidade a hidroperóxidos orgânicos, mas não a H2O2 ou a geradores de superóxido (Mongkolsuk et al., 1998 e Ochsner et al., 2001). Por esta razão, este gene foi denominado ohr (organic hydroperoxide resistance gene). O objetivo desse trabalho foi caracterizar funcionalmente a proteína ohr de X. fastidiosa. Inicialmente, demonstramos que ohr possui atividade peroxidase dependente de tiól sendo que sua capacidade de reagir com hidroperóxidos é devida á presença de um par de cisteínas conservadas em seu sítio ativo. Também mostramos que ohr possui um enovelamento alfa/beta único, não observado nas estruturas de outras peroxidases dependentes de tiól como peroxirredoxinas e glutationa peroxidases. Análises do sítio ativo de ohr mostraram que seus prováveis substratos são moléculas hidrofóbicas e alongadas. Corroborando esta hipótese, demonstramos que enzimas lipoiladas, classicamente relacionadas com o metabolismo intermediário, interagem física e funcionalmente com ohr, enquanto que os sistemas tiorredoxina e glutationa, classicamente relacionados a tióis peroxidases, não sustentam a atividade peroxidásica de ohr. Este resultado representa a primeira descrição de uma peroxidase que é diretamente reduzida por grupos lipóicos de enzimas. Também fornecemos evidências que indicam que ohr atua na redução de hidroperóxidos derivados de ácidos graxos insaturados. De fato, análise cinética de estado estacionário por bi substrato mostra que ohr decompõem hidroperóxidos orgânicos com alta eficiência (kcat/KM ~ 106M-1.s1) através de um mecanismo ping-pong, sendo aproximadamente dez mil vezes mais eficiente do que na presença de H2O2. Esses dados em conjunto mostram que ohr é central na resposta bacteriana contra o estresse induzido por hidroperóxidos orgânicos, mas não por H2O2 e define uma nova classe de enzimas antioxidantes com propriedade únicas: peroxidases dependentes de grupos lipóicos. Outro objetivo desse trabalho foi estudar a via de regulação gênica de ohr em Xylella fastidiosa. Na maioria dos organismos, ohr é regulada por uma proteína repressora denominada ohrR (Sukchawalit et al., 2001), mas em algumas bactérias foi descrito que a expressão de ohr era regulada positivamente por um fator sigma alternativo (&#963;E) de função extra citoplasmática (Gourion et al., 2008). Nossos resultados mostraram que ohr de X. fastidiosa não está sob controle de nenhuma dessas proteínas, sendo provavelmente expressa constitutivamente. Análises por northern blot não mostraram alterações nos níveis de ohr em células submetidas a estresse oxidativo ou etanólico. Esses resultados, ainda que preliminares, indicam que possivelmente o controle da expressão gênica de ohr em X. fastidiosa é distinto daqueles descritos até o momento na literatura para outras bactérias. / Xylella fastidiosa is a gram-negative bacterium, which colonizes the xylem from economically important plants, being responsible for several diseases such as Pierce disease (PD) in gravepines and citrus variegated clorosis (CVC). Plants, when infected by pathogens, are able to defend themselves through several mechanisms which include the generation of reactive oxygen species (ROS). Lipid hydroperoxides can be generated from the attack of ROS to the bacterial membrane or by the action of lipoxygenases. The alkyl hydroperoxide reductase system (AhpR) was initially characterized as the main responsible for the detoxification of organic hydroperoxides in bacteria. Recently, it was also characterized another gene in many pathogenic bacteria, whose deletion renders cells susceptibility to organic hydroperoxide treatments but not by H2O2 or by superoxide generators (Mongkolsuk et al., 1998 and Ochsner et al., 2001). For this reason, it was named ohr (organic hydroperoxide resistance gene). The goal of this work was to functionally characterize ohr, the product of ohr gene from Xylella fastidiosa. Initially, we demonstrated that ohr possesses Cys-based thiol-dependent peroxidase activity. Later, we showed that ohr possesses a unique alpha/beta fold not observed in the structures of other thiol peroxidases such as peroxiredoxins and glutathione peroxidases. Analyses of ohr active site showed that its likely substrates are elongated and hydrophobic molecules. Furthermore, we showed that lipoylated enzymes, classically related with the intermediary metabolism, interacts physically and functionally with ohr while classical thiol-dependent pathways, such as thioredoxin and glutathione, failed to support ohr activity. This finding represents the first evidence of a peroxidase that is directly reduced by lipoyl groups of enzymes. Also, we obtained evidences indicating that ohr acts in the detoxification of peroxides derived from unsaturated fatty acids. In fact, steady-state kinetics using bi-substrate analysis showed that ohr decomposes organic peroxides with high efficiency (kcat/KM ~ 106 M-1.s-1 through a ping-pong mechanism, at least ten thousand times more efficiently than hydrogen peroxide (H2O2). All these results together shows that ohr is central in the response of bacteria to the stress induced by organic hydroperoxides but not by H2O2 and defines a new class of antioxidant enzymes with unique properties such as lipoyl-dependent peroxidase activity. Another goal of this work was to study the regulation of ohr expression in Xylella fastidiosa. ohr expression is regulated in most bacteria by a repressor protein named ohrR (Sukchawalit et al., 2001) but, in some bacteria, ohr expression is positively regulated by an alternative sigma factor (&#963;E) with extracitoplasmatic function (Gourion et al., 2008). Our results showed that ohr from X. fastidiosa was not under the control of none of these regulators, probably being constitutively expressed. Through northern blot analysis, we did not observed any changes in ohr levels in cells submitted to oxidative or ethanolic stress. These results, indicates that ohr expression probably differs from that previously described on literature for other bacteria.

Ácido lipóico

Lipoic acid

Ohr

Ohr

Peroxidase dependente de tiol

Thiol-dependent peroxidase

Xylella fastidiosa

Xylella fastidiosa

Caracterização cinética e busca de inibidores de Ohr (Organic Hydroperoxide Resistance protein) de Xylella fastidiosa. / Kinetic characterization and search for inhibitors of Ohr (Organic Hydroperoxide Resistance protein) from Xylella fastidiosa

Alegria, Thiago Geronimo Pires

27 April 2012

A Xylella fastidiosa é uma bactéria gram-negativa, colonizadora do xilema e é o agente responsável por doenças em plantas cultivadas. No Brasil, a principal doença causada por esta bactéria é a CVC (Clorose Variegada dos Citros), a qual traz grandes prejuízos à produção de laranja dos estados de São Paulo e Minas Gerais. Apesar do atual controle da doença, ainda não se desenvolveu um método específico para o controle da bactéria. Durante a interação planta-patógeno ocorre uma geração exacerbada de oxidantes por parte do hospedeiro, na tentativa de eliminar o patógeno de seu organismo. Dessa forma, os patógenos são expostos a hidroperóxidos derivados de ácidos graxos, formados a partir da ação de lipoxigenases ou ainda pela reação direta de lipídeos com espécies oxidantes. Durante o processo evolutivo, foram selecionados mecanismos de defesa contra estas espécies oxidantes por parte dos patógenos. Dentre estes mecanismos, encontra-se a enzima Ohr (Organic Hydroperoxide Resistance protein), uma peroxidase baseada em resíduos de cisteínas, dependente de grupos lipoil e que possui alta atividade frente à hidroperóxidos orgânicos. Esta proteína provavelmente atua na proteção da célula bacteriana e possui algumas particularidades que fazem dela um alvo em potencial para o desenvolvimento de drogas. Os objetivos deste projeto foram caracterizar possíveis substratos fisiológicos de Ohr de X. fastidiosa, e ainda, buscar moléculas capazes de inibir a atividade peroxidásica desta enzima. Inicialmente demonstramos que Ohr é capaz de reduzir hidroperóxidos de ácido graxo com alta eficiência (kcat/KM ~ 106 M-1.s-1)e, além disso, estes hidroperóxidos são capazes de inativar Ohr em um processo dose dependente, provavelmente devido à alta afinidade entre estes e a enzima. Porém, a enzima não apresentou atividade frente à hidroperóxido de fosfolipídeo (fosfatidilcolina) e hidroperóxido de colesterol. Ademais, elucidamos a estrutura de Ohr na conformação oxidada (ponte dissulfeto), auxiliando no entendimento da dinâmica do ciclo catalítico da enzima. Por fim, selecionamos um composto capaz de inibir a atividade peroxidásica de Ohr in vitro, e temos indícios de que este é capaz de afetar o crescimento bacteriano em situação de estresse oxidativo. / Xylella fastidiosa is a gram-negative bacterium that colonizes the xylem and is the causative agent for several plant diseases. In Brazil, the main disease caused by this bacterium is the CVC (Citrus Variegated Chlorosis), which provokes large losses to the orange production in São Paulo and Minas Gerais states. Despite the current disease control, it has not been yet developed a specific method to eliminate the bacterium. During the plant-pathogen interactions, hosts produce an exacerbated amount of oxidants, in an attempt to eliminate the pathogen. Among them, fatty acids hydroperoxides are formed by the lipoxygenase action or even by the direct reaction between lipids and oxidant species. During the evolutionary process, pathogen defense mechanisms against oxidative species have evolved. Among them, Ohr (Organic Hydroperoxide Resistance protein) that is a Cys-based, lipoyl dependent peroxidase, displaying high activity towards organic hydroperoxides. This protein probably plays a central role in oxidative stress response and presnts some particularities, which make it a potential target for drug design. The objectives of this project were to characterize possible physiological substrates of Ohr from X. fastidiosa and search for molecules capable of inhibiting its peroxidase activity. Initially, we demonstrated that Ohr reduced fatty acid hydroperoxides with high efficiency (kcat/KM ~ 106 M-1.s-1). Moreover, these hydroperoxides inactivated Ohr in a dose-dependent manner, probably due to the high affinity between them and the enzyme. However, the enzyme did not display any activity towards phospholipids (posphatidilcholine) hydroperoxides and cholesterol hydroperoxide. Besides, we elucidated the structure of Ohr in the oxidized form (disulfide bond), which gave us insights on the dynamics of structural elements in the catalytic site. Ultimately, we identified a compound that was able to inhibit the peroxidase activity of Ohr in vitro, and we gained evidences that this compound can affect the bacterial growth under oxidative stress.

3.Lipid hydroperoxides

Hidroperóxidos de lipídeos

Ohr

Ohr

Peroxidase dependente de tiol

Thiol dependent peroxidase

Xylella fastidiosa

THIOL-NORBORNENE HYDROGELS WITH TUNABLE MECHANICAL PROPERTIES FOR ENGINEERED EXTRACELLULAR MATRICES

Han Nguyen (6631871)

11 June 2019

The extracellular matrix (ECM) governs many cellular processes through biochemical and mechanical cues. Particularly, the effect ECM mechanical properties on cells fate has been well established over the years. Many hydrogel systems have been used to mimic the dynamic stiffening processes occurring in ECM. However, changes in ECM stiffness does not fully recapitulate the mechanics of native ECM, as viscoelasticity is also a major factor contributing to ECM dynamic property. This thesis describes the design and characterization of an enzyme-crosslinked hydrogel system that is not only capable of being stiffened on demand, but also can be tuned to obtain viscoelasticity. The first objective of this thesis was to utilize horseradish peroxidase (HRP) to crosslink thiol-norbornene hydrogel and use mushroom tyrosinase (MT) to create secondary DOPA-dimer crosslinks that stiffened the hydrogel. The cytocompatibility of HRP-mediated thiol-norbornene gelation and the effect of stiffening on cell fate was evaluated. The second objective of this thesis represented the first step towards developing a hydrogel system whose viscoelasticity could be dynamically tuned. Thiol-norbornene hydrogel was designed to yield dynamically adaptable boronic ester bonds via partial enzymatic reaction. Thiol-norborne hydrogel was made to contain hydroxyl phenol as well as boronic acid residues within its network. MT, in this case was used to oxidize the hydroxy phenol moieties into DOPA, which then complexed with boronic acid, created dynamic bonds, introducing viscoelasticity to an initial elastic hydrogel.

Dynamic Hydrogel

Thiol-norbornene

Horseradish Peroxidase

Glucose Oxidase

Tyrosinase

Boronic Ester

Conserved structural and dynamic aspects behind Ohr enzymatic catalysis: Ohr as potential drug targets / Aspectos estruturais e dinâmicos envolvidos na catálise enzimática das proteinas Ohr: Ohr como potenciais alvos de drogas

Domingos, Renato Mateus

07 December 2018

Organic hydroperoxide resistance (Ohr) proteins are highly efficient thiol-based peroxidases that play central roles in bacterial response towards organic hydroperoxides. In Fungi, Ohr frequently presents a N-terminal extension, which is predicted to target them to mitochondria. The catalytic triad of Ohr comprises the peroxidatic Cys (Cp), the catalytic Arg (Rc) and a Glu (Ec) are fully conserved and interact among themselves by a salt bridge network in a reduced form of the enzyme (the so-called closed state). After getting oxidized to sulfenic acid (Cys-SOH), Cp condenses with the sulfhydryl group of resolution Cys (Cr) in a disulfide bond. The absence of negativity of the thiolate (RS-) in Cp facilitates the opening of the Arg-loop (containing the Rc) away from the active site, generating the so-called open state. However, the molecular events associated with the high reactivity of Ohr enzymes towards hydroperoxides and its specific reducibility by the dihydrolipoamide (DHL) or by lipoylated proteins were still elusive before this work. Additionally, several factors support the idea of Ohr as a target for drug development: (i) Ohr displays unique physicochemical properties; (ii) bacteria mutant for Ohr (&Delta; ohr) are highly sensitive to oxidative stress; (iii) the indications that Ohr might be involved in bacterial virulence; and (iv) its absence in mammals and vascularized plants. In this thesis, several aspects of Ohr enzymes were evaluated. In chapter 2, we biochemically characterized the Ohr homologs from the ascomycete fungus Mycosphaerella fijiensis Mf_1 (MfOhr), the causative agent of Black Sigatoka disease in banana plants, which presented extraordinary reactivity towards linoleic acid hydroperoxides (kobs = 3.18 (± 2.13) ×108 M-1.s-1). Furthermore, through subcellular fractionation of M fijiensis protoplast cells followed by western blot analysis, we confirmed the in silico prediction that MfOhr is a mitochondrial protein. In chapter 3 and 4, we described seven new crystallographic structures from two opportunistic pathogen, one from Xylella fastidiosa and six from Chromobacterium violaceum (including the first representative of the complex between Ohr and its biological reductant, DHL). Taken together these structures might represent new snapshots along the catalysis. Furthermore, several molecular modelling approaches, such as classical mechanics (MM), steered molecular dynamics (SMD), hybrid quantum mechanics (QM-MM) and together with enzymatic assays of point mutations, indicated that Ohr underwent unique structural switches to allow an intermittent opening (oxidized state) and returning to a more stable closed form (reduced state) of an Arg-loop along catalysis. Remarkably, dihydrolipoamide directly assisted the closing the Arg-loop and thereby the turnover of the enzyme. In chapter 5, we describe the identification of two compounds (C-31 & C-42) that could represent a framework for further studies attempting to find specific Ohr inhibitors, either through ab initio design of chemical compounds and virtual screening using pharmacophoric models. The IC50 calculated for C-31 and C-42 were 124.4-248.5 µM and 243.3-321.7 µM, respectively. Finally, this thesis highlights several new aspects related to Ohr function: 1 - evidence that eukaryotic Ohr are preferentially located in mitochondria and share several biochemical properties with the prokaryotic ones; 2 - the network of polar interactions among residues of the catalytic triad (Cp, Rc and E) strongly contributed to stabilize Ohr in the closed state, in an optimum configuration for hydroperoxide reduction; 3 - evidence that disulfide bond formation and the product release (alcohol derived from hydroperoxide reduction) facilitate the opening of the Rc loop to an intermediate state (probably not to the excessively open state presented in crystallographic structures); 4 - mapping the interactions between the biological reductant (DHL) and the Ohr active site; 5 - strong indications that DHL is not able to fit and react with Ohr in the close conformation; 6 - the first trials for search of molecules to specifically target Ohr proteins, although further assays must be performed to verify the specificity of the selected compounds to target Ohr. Therefore, we describe relevant new information for an antioxidant protein that displays highly efficient catalysis, comparable to other very important hydroperoxide removing enzymes, such as GSH peroxidase and peroxiredoxin / As proteínas Ohr (Organic hydroperoxide resistance) são peroxidases dependente de tiól extremamente eficientes e têm um papel central na resposta das bactérias contra peróxidos orgânicos. Em fungos, as proteínas Ohr apresentam uma extensão N-terminal, cujo predições in silico apontam estar associada ao direcionamento da proteína para a mitocôndria. A tríade catalítica é composta pela cisteína peroxidatic (Cp), a arginina (Rc) e o glutamato (Ec) catalíticos que são totalmente conservados e interagem entre eles por uma rede de interações de ponte salina, na forma reduzida da proteína (conformação fechada). Após se tornarem oxidadas em ácido sulfênico (Cis-SOH), a Cp condensa com o grupo sulfidrila da cisteína de resolução (Cr) numa ligação disulfeto. A ausência da carga negativa do tiolato (RS-) da Cp facilita a abertura da alça que contem a Rc para longe do centro ativo, gerando a conformação aberta. No entanto, os eventos moleculares associados a alta reatividade das enzimas Ohr contra hidroperóxidos e a sua redução pela dihydrolipoamida (presente em proteínas lipoiladas), ainda está descrita de forma bem superficial. Adicionalmente, vários fatores suportam a ideia de que a Ohr seria um potencial alvo para o desenvolvimento de drogas: (i) a Ohr exibe propriedade físico-químicas únicas; (ii) as bactérias mutantes para Ohr (&Delta;ohr) são fortemente sensíveis ao stress oxidativo; (iii) indicações de que a Ohr poderá está envolvida na virulência de várias bactérias; e (iv) a ausência de Ohr em mamíferos e plantas vascularizadas. Nesta tese, vários aspetos relacionados com as enzimas Ohr foram avaliados. No Capitulo 2, foi caracterizada bioquimicamente a proteína Ohr homologa de fungo ascomiceto, Mycosphaerella fijiensis Mf_1 (MfOhr), o agente causador da doença de bananas, Sigatoka-negra. A enzima apresentou eficiente atividade contra peroxido de ácido linoleico (kobs = 3.18 (± 2.13) ×108 M-1.s-1). Além disso, através do fracionamento sub celular de protoblasto de M fijiensis seguido de western blot, foram confirmadas as predições in silico de que a MfOhr é uma proteína mitocondrial. No capítulo 3 e 4, foram descritas sete estruturas cristalográficas oriundas de dois patógenos oportunistas, uma de Xylella fastidiosa e seis de Chromobacterium violaceum (incluindo o primeiro representante do complexo entre a Ohr e o seu redutor biológico, DHL). Estas estruturas poderão representar diferentes conformações ao longo do ciclo catalítico. Adicionalmente, várias abordagens de modelagem molecular, tais como mecânica clássica (MM), mecânica molecular direcionada (SMM) e mecânica quântica híbrida (QM-MM), juntamente com ensaios experimentais com mutações pontuais, indicaram que a Ohr sofre várias mudanças conformacionais para permitir uma abertura intermitente (estado oxidado) e o retorno para uma conformação fechada mais estável (estado reduzido) da alça da arginina ao longo da catálise. Notavelmente, a dihydrolipoamide assistiu diretamente o fechamento da alça da arginina e por consequência o turnover da enzima. No capítulo 5, foi descrita a identificação de dois compostos (C-31 e C-42) que representam estudos iniciais com a finalidade de encontrar inibidores específicos para a enzima Ohr. Estes compostos foram encontrados por ab initio design e por varrimento virtual com o uso de modelos farmacofóricos. Os IC50 calculados para o C-31 e C-42 foram de 124.4-248.5 µM e 243.3-321.7 µM, respectivamente. Finalmente, esta tese descreve vários aspetos relacionados com a função da Ohr: 1 - evidências que as Ohr de eucariotos estão preferencialmente localizadas na mitocôndria e partilham várias propriedades bioquímicas com as Ohr de bactéria; 2 - a rede de interações polares entre os resíduos da tríade catalítica (Cp, Rc e Ec) contribuem fortemente para a estabilização do estado fechado, a configuração ótima para a redução de hydroperoxidos; 3 - evidências de que a formação da ligação disulfeto e a liberação do produto (álcool derivado da redução do hydroperoxido) facilitam a abertura da alça da arginina até um estado intermediários (provavelmente não o estado totalmente exposto apresentado nas estruturas cristalográficas) 4 - o mapeamento das interações entre o redutor biológico no centro ativo da Ohr; 5 - fortes indicações de que a DHL não é capaz de interagir e reagir com a Ohr na conformação fechada; 6 - os primeiros ensaios para a procura por moléculas que especificamente interajam com a Ohr, apesar de que futuros ensaios terão de ser executados para verificar a especificidade dos compostos selecionados. Assim, nós descrevemos nova informação relevante sobre uma proteína antioxidante que exibe uma alta eficiência catalítica, comparável com outras importantes enzimas removedores de hydroperoxidos, tais como glutationa peroxidases e peroxiredoxinas

Dihidrolipoamida

Dihydrolipoamide

Ohr

Ohr

Organic hydroperoxide resistance protein

Peroxidase

Peroxidase

Thiol

Tiol