Investigations of the Natural Product Antibiotic Thiostrepton from Streptomyces azureus and Associated Mechanisms of Resistance

Myers, Cullen Lucan

January 2013

The persistence and propagation of bacterial antibiotic resistance presents significant challenges to the treatment of drug resistant bacteria with current antimicrobial chemotherapies, while a dearth in replacements for these drugs persists. The thiopeptide family of antibiotics may represent a potential source for new drugs and thiostrepton, the prototypical member of this antibiotic class, is the primary subject under study in this thesis. Using a facile semi-synthetic approach novel, regioselectively-modified thiostrepton derivatives with improved aqueous solubility were prepared. In vivo assessments found these derivatives to retain significant antibacterial ability which was determined by cell free assays to be due to the inhibition of protein synthesis. Moreover, structure-function studies for these derivatives highlighted structural elements of the thiostrepton molecule that are important for antibacterial activity. Organisms that produce thiostrepton become insensitive to the antibiotic by producing a resistance enzyme that transfers a methyl group from the co-factor S-adenosyl-L-methionine (AdoMet) to an adenosine residue at the thiostrepton binding site on 23S rRNA, thus preventing binding of the antibiotic. Extensive site-directed mutagenesis was performed on this enzyme to generate point mutations at key active site residues. Ensuing biochemical assays and co-factor binding studies on these variants identified amino acid residues in the active site that are essential to the formation of the AdoMet binding pocket and provided direct evidence for the involvement of an active site arginine in the catalytic mechanism of the enzyme. Certain bacteria that produce neither thiostrepton nor the resistance methyltransferase express the thiostrepton binding proteins TIP-AL and TIP-AS, that irreversibly bind to the antibiotic, thereby conferring resistance by sequestration. Here, it was found that the point mutation of the previously identified reactive amino acid in TIP-AS did not affect covalent binding to the antibiotic, which was immediately suggestive of a specific, high affinity non-covalent interaction. This was confirmed in binding studies using chemically synthesized thiostrepton derivatives. These studies further revealed structural features from thiostrepton important in this non-covalent interaction. Together, these results indicate that thiostrepton binding by TIP-AS begins with a specific non-covalent interaction, which is necessary to properly orient the thiostrepton molecule for covalent binding to the protein. Finally, the synthesis of a novel AdoMet analogue is reported. The methyl group of AdoMet was successfully replaced with a trifluoromethyl ketone moiety, however, the hydrated form (germinal diol) of this compound was found to predominate in solution. Nevertheless, the transfer of this trifluoroketone/ trifluoropropane diol group was demonstrated with the thiopurine methyltransferase.

thiostrepton

ribosome

antibiotics

antibiotic resistance

methyltransferase

site-directed mutagenesis

S-Adenosyl-L-methionine

enzymology

semi-synthesis

isothermal titration calorimetry

thiostrepton derivatives

AdoMet analogue

Chemistry

Studies into the structural basis of the DNA uridine endonuclease activity of exonuclease III homolog Mth212 / Untersuchungen zur strukturellen Voraussetzungen der DNA Uridin-Endonuklease Aktivität von einem Exonuklease III Homolog - Mth212

Tseden, Khaliun

02 May 2011

No description available.

570 Biowissenschaften, Biologie

Biology (incl. Psychology)

DNA Uridin-Endonuklease

gerichtete Evolution

gezielte Mutagenese

DNA uridine endonuclease

directed evolution

directed mutagenesis

42.13

WJD 300: Mutationen {Biologie, Genetik}

The Role of Specific Amino Acids in the Formation of Ternary Complexes in Nitrogenase Regulation in the Photosynthetic Bacterium Rhodobacter capsulatus

Choolaei, Zahra

08 1900

L'azote est l'un des éléments les plus essentiels dans le monde pour les êtres vivants, car il est essentiel pour la production des éléments de base de la cellule, les acides aminés, les acides nucléiques et les autres constituants cellulaires. L’atmosphère est composé de 78% d'azote gazeux, une source d'azote inutilisable par la plupart des organismes à l'exception de ceux qui possèdent l’enzyme nitrogénase, tels que les bactéries diazotrophique. Ces micro-organismes sont capables de convertir l'azote atmosphérique en ammoniac (NH3), qui est l'une des sources d'azote les plus préférables. Cette réaction exigeant l’ATP, appelée fixation de l'azote, est catalysée par une enzyme, nitrogénase, qui est l'enzyme la plus importante dans le cycle de l'azote. Certaines protéines sont des régulateurs potentiels de la synthèse de la nitrogénase et de son activité; AmtB, DraT, DraG, les protéines PII, etc.. Dans cette thèse, j'ai effectué diverses expériences afin de mieux comprendre leurs rôles détailés dans Rhodobacter capsulatus. La protéine membranaire AmtB, très répandue chez les archaea, les bactéries et les eucaryotes, est un membre de la famille MEP / Amt / Rh. Les protéines AmtB sont des transporteurs d'ammonium, importateurs d'ammonium externe, et ont également été suggéré d’agir comme des senseurs d'ammonium. Il a été montré que l’AmtB de Rhodobacter capsulatus fonctionne comme un capteur pour détecter la présence d'ammonium externe pour réguler la nitrogénase. La nitrogénase est constituée de deux métalloprotéines nommées MoFe-protéine et Fe-protéine. L'addition d'ammoniaque à une culture R. capsulatus conduit à une série de réactions qui mènent à la désactivation de la nitrogénase, appelé "nitrogénase switch-off". Une réaction critique dans ce processus est l’ajout d’un groupe ADP-ribose à la Fe-protéine par DraT. L'entrée de l'ammoniac dans la cellule à travers le pore AmtB est contrôlée par la séquestration de GlnK. GlnK est une protéine PII et les protéines PII sont des protéines centrales dans la régulation du métabolisme de l'azote. Non seulement la séquestration de GlnK par AmtB est importante dans la régulation nitrogénase, mais la liaison de l'ammonium par AmtB ou de son transport partiel est également nécessaire. Les complexes AmtB-GlnK sont supposés de lier DraG, l’enzyme responsable pour enlever l'ADP-ribose ajouté à la nitrogénase par DraT, ainsi formant un complexe ternaire. Dans cette thèse certains détails du mécanisme de transduction du signal et de transport d'ammonium ont été examinés par la génération et la caractérisation d’un mutant dirigé, RCZC, (D335A). La capacité de ce mutant, ainsi que des mutants construits précédemment, RCIA1 (D338A), RCIA2 (G344C), RCIA3 (H193E) et RCIA4 (W237A), d’effectuer le « switch-off » de la nitrogénase a été mesurée par chromatographie en phase gazeuse. Les résultats ont révélé que tous les résidus d'acides aminés ci-dessus ont un rôle essentiel dans la régulation de la nitrogénase. L’immunobuvardage a également été effectués afin de vérifier la présence de la Fe-protéine l'ADP-ribosylée. D335, D388 et W237 semblent être cruciales pour l’ADP-ribosylation, puisque les mutants RCZC, RCIA1 et RCIA4 n'a pas montré de l’ADP-ribosylation de la Fe-protéine. En outre, même si une légère ADP-ribosylation a été observée pour RCIA2 (G344C), nous le considérons comme un résidu d'acide aminé important dans la régulation de la nitrogénase. D’un autre coté, le mutant RCIA3 (H193E) a montré une ADP-ribosylation de la Fe-protéine après un choc d'ammonium, par conséquent, il ne semble pas jouer un rôle important dans l’ADP-ribosylation. Par ailleurs R. capsulatus possède une deuxième Amt appelé AmtY, qui, contrairement à AmtB, ne semble pas avoir des rôles spécifiques. Afin de découvrir ses fonctionnalités, AmtY a été surexprimée dans une souche d’E. coli manquant l’AmtB (GT1001 pRSG1) (réalisée précédemment par d'autres membres du laboratoire) et la formation des complexes AmtY-GlnK en réponse à l'addition d’ammoniac a été examinée. Il a été montré que même si AmtY est en mesure de transporter l'ammoniac lorsqu'il est exprimé dans E. coli, elle ne peut pass’ associer à GlnK en réponse à NH4 +. / Nitrogen is one of the most vital elements in the world for living creatures since it is essential for the production of the basic building blocks of the cell; amino acids, nucleic acids and other cellular constituents. The atmosphere is 78% nitrogen gas (N2), a source of nitrogen unusable by most organisms except for those possessing the enzyme nitrogenase, such as diazotrophic bacteria species. These microorganisms are capable of converting atmospheric nitrogen to ammonia (NH3), which is one of the most preferable nitrogen sources. This ATP demanding reaction, called nitrogen fixation, is catalysed by the nitrogenase enzyme, which is the most important enzyme in the nitrogen cycle. Some proteins are potential regulators of nitrogenase synthesis and activity; AmtB, DraT, DraG, PII proteins and etc. In this thesis I performed various experiments in order to better understand their roles in Rhodobacter capsulatus, in more detail. The membrane protein AmtB, which is widespread among archaea, bacteria and eukaryotes, is a member of the MEP/Amt/Rh family. The AmtB proteins are ammonium transporters, taking up external ammonium, and have also been suggested to sense the presence of ammonium. It has been shown that in Rhodobacter capsulatus AmtB functions as a sensor for the presence of external ammonium in order to regulate nitrogenase. Nitrogenase consists of two metalloprotein components named MoFe-protein and Fe-protein. The addition of ammonium to R. capsulatus culture medium leads to a series of reactions which result in the deactivation of nitrogenase, called “nitrogenase switch-off”. A critical reaction in this process is one in which DraT adds an ADP-ribose group to the Fe-protein of nitrogenase. The entrance of ammonia through the AmtB pore is regulated by GlnK sequestration. GlnK is a PII protein and PII proteins are one of the central proteins in the regulation of nitrogen metabolism. Not only is GlnK-AmtB sequestration important in nitrogenase regulation, but binding of ammonium by AmtB or its partial transport is also necessary. AmtB-GlnK complexes are thought to bind DraG, which is responsible for removing the ADP-ribose that DraT adds to nitrogenase, to form a ternary complex. In this thesis details of the signal transduction mechanism and ammonium transport were examined by generating and characterizing RCZC, a (D335A) site- directed mutant of AmtB. The ability of this mutant, as well as previously constructed mutants RCIA1 (D338A), RCIA2 (G344C), RCIA3 (H193E) and RCIA4 (W237A), to “switch-off” nitrogenase activity was measured by gas chromatography. The results revealed that all the above amino acid residues have critical roles in nitrogenase regulation. Immunoblotting was also carried out to check the presence of ADP-ribosylated Fe-protein. D335, D388 and W237 seem to be crucial for NifH ADP-ribosylation, since their mutants (RCZC, RCIA1 and RCIA4 respectively) didn't show ADP-ribosylation on Fe-protein. In addition, although a slight ADP-ribosylation was observed for RCIA2 (G344C) we still consider it as an important amino acid residue in this matter whereas the remaining mutant RCIA3 (H193E) showed Fe-protein ADP-ribossylation after an ammonium shock, therefore it doesn't seem to be important in NifH ADP-ribosylation. In addition R. capsulatus possesses a second Amt called AmtY, which in contrast to AmtB, doesn't appear to have any specific roles. In order to find out its functionality, AmtY was overexpressed in an E. coli strain lacking AmtB (GT1001 pRSG1) (which was carried out previously by other lab members) and AmtY-GlnK complex formation in response to ammonium addition was examined. It was shown that even though AmtY is able to take up ammonia when expressed in E. coli it fails to associate with GlnK in response to NH4+.

AmtB

AmtY

Le transport d'ammonium

Mutagenèse dirigée

ADP ribosylation

Fixation de l'azote

Ammonium transport

Site directed mutagenesis

Nitrogen fixation

Rôle de l’extrémité C-terminale dans l’expression du canal calcique Cav1.2 à la membrane plasmique

Le Coz, Florian

07 1900

Le canal calcique de type L, Cav1.2, joue un rôle clé dans le couplage excitation-contraction des myocytes ventriculaires. Il a été montré que la sous-unité Cavα1 était sujette à l’épissage alternatif et que ce phénomène pouvait mener à une protéine tronquée en C-terminal au niveau de l’exon 45 (Liao, Yong et al. 2005). D’autres groupes ont étudié différentes délétions au niveau de l’extrémité C-terminale (De Jongh, Warner et al. 1991; Gao, Cuadra et al. 2001). Les courants mesurés dans la configuration cellule entière, était significativement plus grands que le canal « pleine longueur ». Nous avons décidé de tester certaines de ces délétions (ΔC2030, ΔC1935, ΔC1856, ΔC1733, ΔC1700) en présence ou en absence de la sous-unité auxiliaire Cavβ3, susceptible d’interagir avec l’extrémité C-terminale de la sous-unité Cavα1 par l’intermédiaire de son domaine SH3 (Lao, Kobrinsky et al. 2008). Les résultats obtenus dans les ovocytes de Xénope ont mis en évidence que les sous-unités Cavα1.2 tronquées montraient des courants globaux plus élevés que le canal « pleine longueur » en présence de la sous-unité auxiliaire Cavβ3 et que les sous-unités Cavα1.2 tronquées donnaient des courants en absence de la sous-unité Cavβ3 contrairement à la sous-unité Cavα1.2 « pleine longueur ». Afin de vérifier si l’augmentation des courants macroscopiques était le résultat d’une augmentation du nombre de sous-unités Cavα1.2 à la membrane, nous avons choisi de quantifier la fluorescence spécifiquement due à cette sous-unité en utilisant la méthode de cytométrie de flux (FACS : « Fluorescence Activated Cell Sorting »). L’épitope HA a été inséré dans une région extracellulaire de la sous-unité Cavα1 du canal calcique Cav1.2 et un anticorps anti-HA couplé au FITC (« Fluorescein IsoThioCyanate ») a été utilisé pour observer la fluorescence. Nos résultats confirment que la sous-unité Cavα1-HA du canal calcique Cav1.2, s’exprime à la membrane plasmique en présence de la sous-unité auxiliaire Cavβ3, et qu’en absence de celle-ci, ne s’exprime que peu ou pas à la membrane. Les mêmes résultats ont été obtenus pour les trois délétions testées dans les mêmes conditions soit Cavα1.2-HA ΔC1935, Cavα1.2-HA ΔC1856 et Cavα1.2-HA ΔC1733. Ensemble, ces résultats suggèrent que l’augmentation des courants macroscopiques observés après une délétion partielle du C-terminal n’est pas causée par une augmentation du nombre de protéines Cavα1.2 à la membrane. / The L-type calcium channel, Cav1.2, plays an important role in the excitation-contraction coupling of the ventricular myocytes. It has been shown that the alternative splicing of Cavα1.2 subunit could lead to a truncated protein in the C-terminus at exon 45 (Liao, Yong et al. 2005). Many groups have studied deletions in the C-terminus (De Jongh, Warner et al. 1991; Gao, Cuadra et al. 2001). The currents, measured in the whole cell configuration, were significantly higher with the full-length channel. We chose to test some of these deletions (ΔC2030, ΔC1935, ΔC1856, ΔC1733, ΔC1700) in the presence or absence of the Cavβ3 auxiliary subunit which is likely to interact with the C-terminus of the Cavα1.2 subunit through its SH3 domain (Lao, Kobrinsky et al. 2008). The truncated Cavα1.2 subunit, expressed in Xenopus Oocytes, showed macroscopic currents that were greater than those of the full length channel in presence of the Cavβ3 subunit. In addition, the truncated Cavα1.2 subunits displayed currents in the absence of the Cavβ3 subunit in contrast with the Cavα1.2 full length subunit. To investigate whether the larger macroscopic currents resulted in an increase in the number of Cavα1.2 subunits at the plasma membrane, we chose the FACS (« Fluorescence Activated Cell Sorting ») method. An HA-tag was inserted in an extracellular region of the Cavα1.2 subunit and a FITC (« Fluorescein IsoThioCyanate ») coupled anti-HA antibody was used to measure fluorescence. Our results showed that the Cavα1.2-HA subunit of L- type channel is expressed at the plasma membrane in the presence of the Cavβ3 subunit whereas the Cavα1.2-HA subunit is slightly or not expressed at the plasma membrane in its absence. The same results were obtained for the three C-terminal deletions tested under the same conditions (CaVα1.2-HA ΔC1935, CaVα1.2-HA ΔC1856 and CaVα1.2-HA ΔC1733). Taken together, these results suggest that the increased macroscopic currents observed after a partial deletion of the C-terminus is not caused by an increased number of Cavα1.2 proteins expressed at the plasma membrane. Keywords:

Calcium

Canal ionique

Gating

Mutagénèse dirigée

FACS

Electrophysiologie

Immunobuvardage de type Western

Calcium

Ion channel

Gating

Directed Mutagenesis

FACS

Electrophysiology

Western-blot

Investigations of the Natural Product Antibiotic Thiostrepton from Streptomyces azureus and Associated Mechanisms of Resistance

Myers, Cullen Lucan

January 2013

The persistence and propagation of bacterial antibiotic resistance presents significant challenges to the treatment of drug resistant bacteria with current antimicrobial chemotherapies, while a dearth in replacements for these drugs persists. The thiopeptide family of antibiotics may represent a potential source for new drugs and thiostrepton, the prototypical member of this antibiotic class, is the primary subject under study in this thesis. Using a facile semi-synthetic approach novel, regioselectively-modified thiostrepton derivatives with improved aqueous solubility were prepared. In vivo assessments found these derivatives to retain significant antibacterial ability which was determined by cell free assays to be due to the inhibition of protein synthesis. Moreover, structure-function studies for these derivatives highlighted structural elements of the thiostrepton molecule that are important for antibacterial activity. Organisms that produce thiostrepton become insensitive to the antibiotic by producing a resistance enzyme that transfers a methyl group from the co-factor S-adenosyl-L-methionine (AdoMet) to an adenosine residue at the thiostrepton binding site on 23S rRNA, thus preventing binding of the antibiotic. Extensive site-directed mutagenesis was performed on this enzyme to generate point mutations at key active site residues. Ensuing biochemical assays and co-factor binding studies on these variants identified amino acid residues in the active site that are essential to the formation of the AdoMet binding pocket and provided direct evidence for the involvement of an active site arginine in the catalytic mechanism of the enzyme. Certain bacteria that produce neither thiostrepton nor the resistance methyltransferase express the thiostrepton binding proteins TIP-AL and TIP-AS, that irreversibly bind to the antibiotic, thereby conferring resistance by sequestration. Here, it was found that the point mutation of the previously identified reactive amino acid in TIP-AS did not affect covalent binding to the antibiotic, which was immediately suggestive of a specific, high affinity non-covalent interaction. This was confirmed in binding studies using chemically synthesized thiostrepton derivatives. These studies further revealed structural features from thiostrepton important in this non-covalent interaction. Together, these results indicate that thiostrepton binding by TIP-AS begins with a specific non-covalent interaction, which is necessary to properly orient the thiostrepton molecule for covalent binding to the protein. Finally, the synthesis of a novel AdoMet analogue is reported. The methyl group of AdoMet was successfully replaced with a trifluoromethyl ketone moiety, however, the hydrated form (germinal diol) of this compound was found to predominate in solution. Nevertheless, the transfer of this trifluoroketone/ trifluoropropane diol group was demonstrated with the thiopurine methyltransferase.

thiostrepton

ribosome

antibiotics

antibiotic resistance

methyltransferase

site-directed mutagenesis

S-Adenosyl-L-methionine

enzymology

semi-synthesis

isothermal titration calorimetry

thiostrepton derivatives

AdoMet analogue

Chemistry

Conception rationnelle de nouvelles protéines thérapeutiques dans l'hémophilie : variants du facteur Xa dépourvus du domaine Gla / Rational Design of new haemostatic drugs in haemophilia : Gla domain less factor Xa variants

Marlu, Raphaël

07 February 2013

Introduction : L'hémophilie est une maladie génétique de la coagulation due à un déficit en facteur VIII ou en facteur IX. Ces déficits sont responsables d'un déficit du complexe ténase intrinsèque (VIIIa-IXa). De plus, le complexe ténase extrinsèque (facteur tissulaire - VIIa) est physiologiquement rapidement inhibé par le TFPI lié au facteur Xa. Nous avons évalué la capacité d'une forme tronquée du facteur Xa (GDXa), dépourvue de domaine Gla à se lier au TFPI et à soulager l'inhibition physiologique du complexe ténase extrinsèque. Matériel et Méthodes : Dans une première partie, nous avons évalué la capacité du GDXa à restaurer la génération de thrombine de plasmas d'hémophiles A et B sévères sans et avec inhibiteurs. Nous avons également comparé les profils de génération de thrombine obtenus après addition du GDXa à ceux obtenus en présence d'anticorps neutralisants anti-TFPI ou anti-antithrombine. Enfin, nous avons comparé les cinétiques enzymatiques de neutralisation du facteur Xa et du GDXa par le TFPI et l'antithrombine. Dans une seconde partie, nous avons étudié in silico les interactions entre la chaîne lourde du facteur Xa et le TFPI pour détecter les zones d'interaction défavorables. Cette étude a identifié des acides aminés du facteur Xa qui pourraient être substitués pour optimiser l'interaction avec le TFPI. Les résultats in silico ont orienté nos choix de mutagenèse dirigée pour concevoir différents variants moléculaires du GDXa (R138F, R138G, R138I) où l'arginine 138 est substituée. Ces variants protéiques ont été produits de façon recombinante dans des cellules HEK293E. La capacité des différents variants à restaurer la génération de thrombine de plasmas d'hémophiles a été testée avec les surnageants de culture cellulaires correspondants. Résultats : Dans la première partie, nous avons montré que le GDXa est capable de restaurer la génération de thrombine de plasmas d'hémophiles A et B sans et avec inhibiteurs. Comparativement au facteur Xa, le GDXa montre une affinité moindre pour le TFPI tandis que les affinités du GDXa et du facteur Xa pour l'antithrombine sont identiques. Enfin, malgré une demi-vie courte, l'effet du GDXa sur la génération de thrombine est maintenu pendant au moins une heure. Dans la seconde partie, nous avons produit les différents variants R138F, R138G et R138I en cellules HEK293E et montré que les surnageants de culture cellulaire étaient capables de restaurer la génération de thrombine de plasmas d'hémophiles de façon plus efficace que le GDXa. Conclusion : Comme le GDXa est capable de restaurer la génération de thrombine de plasmas d'hémophiles, nos résultats suggèrent que le GDXa pourrait être une alternative efficace aux thérapeutiques hémostatiques court-circuitantes actuelles chez les hémophiles sans ou avec inhibiteurs. Les résultats obtenus renforcent l'hypothèse que l'activité pro-coagulante du GDXa serait liée à la formation d'un complexe GDXa-TFPI limitant la formation du complexe Xa-TFPI nécessaire à l'inhibition physiologique du complexe ténase extrinsèque. De plus, notre approche rationnelle basée sur une étude in silico visant à augmenter l'affinité du TFPI pour le GDXa a permis de produire différents variants moléculaires du GDXa dont l'activité procoagulante in vitro est augmentée par rapport au GDXa. / Background: Hemophilia is caused by deficiencies in coagulation factor VIII or IX, resulting in direct blockade of the intrinsic tenase complex and indirect blockade of the extrinsic tenase complex which is rapidly inhibited upon binding of factor Xa to tissue factor pathway inhibitor (TFPI). We evaluated the ability of Gla-domainless factor Xa (GDXa), a truncated form of factor Xa devoid of procoagulant properties, to bind to TFPI and to alleviate the physiological inhibition of the extrinsic tenase. Design and Methods: In the first part of this work, we evaluated the ability of GDXa to restore coagulation in plasmas from hemophilia A and B patients without and with inhibitors, using a thrombin generation assay triggered by a low concentration of tissue factor. We then compared its efficacy to generate thrombin to depletion of antithrombin or TFPI by specific antibodies. Finally, we compared the kinetics of neutralization of factor Xa and GDXa by antithrombin and TFPI. In the second part of this work, we realized an in silico study of the interactions between factor Xa heavy chain and TFPI. The aim was to detect unfavorable interactions and to identify amino-acid candidates for mutagenesis in order to increase affinity for TFPI. Taking into account the results of this in silico study, we produced by genic engienering different molecular variants of GDXa (R138F, R138G, R138I) where Arg138 was substituted by site directed mutagenesis. Proteins were produced in HEK293E cells. We tested dialyzed cell culture supernatants containing each variant to restore thrombin generation in plasmas from severe hemophilia patients. Results: In the first part of this work, we showed that GDXa was able to restore thrombin generation in plasma samples from hemophiliacs. This effect was observed for plasma from hemophilia A patients without or with inhibitors and for plasma from hemophilia B patients. GDXa had a lower affinity than factor Xa for TFPI whereas the affinities of both proteins for antithrombin were similar. Finally, despite a short half-life in plasma, the effect of GDXa on thrombin generation was sustained for at least one hour. In the second part of this work, we produced the different variants R138F, R138G et R138I in HEK293E cells and showed that cell culture supernatants were able to restore thrombin generation in a more efficient way than GDXa. Conclusions: As GDXa was able to restore thrombin generation in plasma from hemophilia patients, our results suggest that it may be an effective alternative to current treatments for hemophilia with or without inhibitors. Results sustained the hypothesis that GDXa coagulant activity is through TFPI binding and competition with factor Xa to bind TFPI resulting in limiting factor Xa-TFPI formation, which is essential for inhibition of extrinsic tenase complex. Furthermore, rational design of GDXa variants based on an in silico study lead to production of proteins whose coagulant activity is increased compared to GDXa."

Factor Xa dépourvu du domaine Gla

TFPI

Génération de thrombine

Etude in silico

Mutagénèses dirigées

Hémophilie

Gla domainless factor Xa

TFPI

Thrombin Generation

In silico study

Site directed mutagenesis

Haemophilia

Cílená mutageneze ve studiu lidských cytochromů P450 rodiny 1 a jejich interakčních partnerů / Site-directed mutagenesis of human cytochromes P450 family 1 and their interacting partners

Milichovský, Jan

January 2016

Cytochromes P450 represent a large group of proteins metabolizing variety of substrates. Many of them are responsible for metabolism of xenobiotics including drugs and chemical carcinogens. Heme-protein cytochrome b5 is a single-electron donor cooperating with a NADPH:cytochrome P450 reductase and NADH:cytochrome b5 reductase 3 enzyme. Cytochrome b5 can affect the xenobiotic metabolism via modulation of the cytochromes P450 activity. One of the goals of the Ph.D. thesis was to utilize site directed mutagenesis of cytochromes P450 family 1 to elucidate the mechanism of their nitroreductase activity. Another aim was to study the interaction between cytochrome b5 and cytochromes P450 of the 1A subfamily using site directed mutagenesis on presumed protein-protein contact interface. Another goal was to utilize the combination of theoretical and experimental approaches to explain variance in the reduction state of several human cytochromes P450 heterologously expressed in intact bacterial cells. The results found in the thesis show that nitroreductase activity of CYP1A1, CYP1A2 and CYP1B1 is mediated by the presence of a particular hydroxyl group in their active centre. Single mutation introducing a hydroxyl group to the specific part of CYP1B1 active site to the active site turned on its artificial...

Construção e análise de mutantes fluorescentes da troponina I / Construction and analysis of fluorescent mutants of troponin I

Deodoro Camargo Silva Gonçalves de Oliveira

10 August 2001

A troponina (Tn) regula a contração do músculo estriado esquelético de vertebrados. Ela é composta de três subunidades: troponina I (TnI), troponina C (TnC) e troponina T (TnT). A TnI tem a função inibitória que é neutralizada pela ligação de Ca2+ nos sítios regulatórios do N-domínio da TnC, e a TnT posiciona o complexo no filamento fino. Para monitorar o sinal do Ca2+ sendo transmitido da TnC para a TnI as propriedades espectrais únicas do 5-hidroxitriptofano (5HW) foram utilizadas. O 5HW foi incorporado em mutantes pontuais de TnI com um único códon para triptofano. Foram identificadas duas sondas espectrais intrínsecas na TnI capazes de detectar a ligação de Ca2+ na Tn: as TnIs com 5HW nas posições 100 e 121. Complexos troponina reconstituídos com estes mutantes fluorescentes de TnI, Tn-TnIF100HW e Tn-TnIM121HW, apresentaram respectivamente 12 e 70 % de aumento na intensidade do espectro de emissão devido à ligação de Ca2+ na TnC. Nos complexos binários (TnC-TnI) as TnIs com 5HW nas posições 106 e 121 também captam a ligação do Ca2+ na TnC. A análise da fluorescência destas sondas demonstrou que: 1) as regiões da TnI que respondem ao N-domínio regulatório da TnC ocupado com Ca2+ são a região inibitória da TnI, resíduos 96 até 116, e a região vizinha que inclui a posição 121 da TnI; 2) mutações pontuais e a incorporação de 5HW na TnI podem afetar tanto a afinidade como a cooperatividade da ligação de Ca2+ na TnC, confirmando o papel da TnI em modular a afinidade da TnC por Ca2+; 3) as constantes de dissociação de Ca2+ surpreendentemente altas, Kd ~ 10-8 M, calculadas a partir dos sinais das sondas na região inibitória da TnI, sugerem a possibilidade de que os sítios do domínio N-terminal da TnC sejam os sítios de ligação de Ca2+ de maior afinidade no complexo troponina. / Vertebrate striated muscle contraction is regulated by troponin (Tn). Tn is composed of three subunits: troponin I (TnI), troponin C (TnC) and troponin T (TnT). TnI has an inhibitory role that is neutralized by calcium binding to the regulatory sites in the N-domain of TnC, and TnT positions the troponin complex on the thin filament. In order to follow the Ca2+ induced conformational change that is transmitted from TnC to TnI, the unique spectral properties of 5-hydroxytryptophan (5HW) incorporated as point-mutants of TnI were used. It was possible to identify two new TnI intrinsic spectral probes sensitive to Ca2+ binding to Tn: TnI with single 5HW at positions 100 and 121. Trimeric troponin complexes reconstituted with two fluorescent mutants of TnI, Tn-TnIF100HW and Tn-TnIM121HW, showed respectively 12 and 70 % increase in the emission spectra when Ca2+ bound to TnC. In the binary complexes (TnC-TnI) two TnIs with 5HW at positions 106 and 121 were also sensitive to Ca2+ binding to TnC. Fluorescence analysis of these probes showed: 1) the regions in TnI that respond to Ca2+ binding to the regulatory N-domain of TnC are the inhibitory region of TnI (residues 96 to 116), and a neighbor region that includes position 121; 2) point mutations and incorporation of 5HW in TnI can affect both the affinity and the cooperativity of Ca2+ binding to TnC, confirming the role of TnI as a modulator of the Ca2+ affinity of TnC; 3) the high dissociation constant for sites in the N-terminal domain of TnC (Kd ~ 10-8 M), derived from data using probes in the inhibitory region of TnI suggested the possibility that these sites are the high affinity Ca2+ binding sites in the troponin complex.

Estrutura e função de proteínas

Fuorescência

Mutação sítio-dirigida

Regulação da contração muscular

Troponina

Fluorescence

Protein structure and function

Regulation of muscle contraction

Site-directed mutagenesis

Troponin

DNA Repair Proteins in Mycobacteria and their Physiological Importance

Sang, Pau Biak

January 2014

DNA repair proteins in mycobacteria and their physiological importance Mycobacterium tuberculosis, the causative organism of tuberculosis, resides in the host macrophages where it is subjected to a plethora of stresses like reactive oxygen species (ROS) and reactive nitrogen intermediate(RNI) which are generated as a part of the host’s primary immune response. These stresses can damage the cellular components of the pathogen including DNA and its precursors. Two common damages to DNA and its precursors caused by ROS and RNI are oxidation of guanine to 8-oxo-guanine and deamination of cytosine to uracil. Mycobacteria, which are known to have high G+C content, must be more susceptible to such damages, and are thus equipped with the mechanisms to counteract these damages. One such mechanism is to hydrolyse the 8-oxo-dGTP into 8-oxo-dGMP to avoid its incorporation in the DNA during its synthesis. This job is done by a protein called MutT.In mycobacteria four homologs of MutT, namely MutT1, MutT2, MutT3 and MutT4 have been annotated. The second mechanism deals with the repair of uracil residues present in DNA which are generated by deamination of cytosines or incorporation of dUTP during DNA synthesis. This is taken care of by a protein called uracil DNA glycosylase (UDG) which excises uracil by cleaving the N-C1’ glycosidic bond between the uracil and the deoxyribose sugar in a DNA repair pathway called the base excision repair (BER). In this study, the biochemical properties and physiological role of mycobacterial MutT2 and, MSMEG_0265 (MsmUdgX), a novel uracil DNA glycosylase superfamily protein, have been investigated. I.Biochemical characterization of MutT2 from mycobacteria and its antimutator role. Nucleotide pool, the substrate for DNA synthesis is one of the targets of ROS which is generated in the macrophage upon Mycobacterium tuberculosis infection. Thus, the pathogen is at increased risk of accumulating oxidised guanine nucleotides such as 8-oxo-dGTP and 8-oxo-GTP. By hydrolysing the damaged guanine nucleotides before their incorporation into nucleic acids, MutT proteins play a critical role inallowing organisms to avoid their deleterious effects. Mycobacteria possess several MutT proteins. Here, we have purified recombinantM. tuberculosisMutT2 (MtuMutT2) andM. smegmatisMutT2 (MsmMutT2) proteins as representative of slow and fast growing mycobacteria, for the purpose of biochemical characterization. UnlikeEscherichia coliMutT, which hydrolyzes 8-oxo-dGTP and 8-oxo-GTP, the mycobacterial proteins hydrolyze not only 8-oxo-dGTP and 8-oxo-GTP but also dCTP and 5-methyl-dCTP. Determination of kinetic parameters (KmandVmax) revealed thatwhileMtuMutT2 hydrolyzes dCTP nearly four times better than it does 8-oxo-dGTP,MsmMutT2 hydrolyzes them almost equally well. Also,MsmMutT2 is about 14 times more efficient thanMtuMutT2 in its catalytic activity of hydrolyzing 8-oxo-dGTP.Consistent with these observations,MsmMutT2 but notMtuMutT2 rescuesE. colifor MutT deficiency by decreasing both themutation frequency and A to C mutations (a hallmark of MutT deficiency). We discuss these findings in the context of the physiological significance of MutT proteins. II.Understanding the biochemical properties of MSMEG_0265 (MsmUdgX), a novel uracil DNA glycosylase superfamily protein Uracil DNA glycosylases (UDGs) are base excision repair enzymes which excise uracil from DNA by cleaving the N-glycosidic bond. UDGs are classified into 6 different families based on their two functional motifs, i. e.,motif A and motif B. In mycobacteria, there are two uracil DNA glycosylases, Ung and UdgB which belong to Family 1 and Family 5, respectively. In this study, based on the presence of the two functional motifs, we have discovered yet another uracil DNA glycosylase in M. smegmatis, which we have called MsmUdgX.The motif A and motif B of this protein indicate that it does not belong to any of the UDG families already classified but has highest similarity with Family 4 UDGs. Homologs of this protein are also present in several other organisms like M. avium, Streptomyces ceolicolor, Rhodococcus etc., but absent in M. tuberculosis, archaea and eukaryotes. Activity assays of this protein show that unlike other UDGs, MsmUdgX does not excise uracil, but forms a tight complex with uracil containing single stranded (ss) and double stranded (ds) DNAs, as observed by a shifted band in 8M urea-PAGE as well as SDS-PAGE. It also does not recognize other modified nucleotides that we investigated, in DNA. The protein binds to uracil-DNA in a wide range of pH and the minimum substrate required for its binding is pNUNN. Like Family 4 UDG, the protein has Fe-S cluster but it is not as thermostable as the Family 4 UDGs. Addition of different metal ions does not affect its binding property, and even the presence of M. smegmatis cell free extract does not diminish its binding activity. Since this protein binds specifically to uracil in DNA, an application of the protein for detection of uracil in the genomic DNA is proposed. III. Elucidation of the role of KRRIH loop in MsmUdgX by mutational analysis MsmUdgX is a novel uracil DNA glycosylase superfamily protein which has the highest homology to Family 4 UDGs. However, alignment of MsmUdgX amino acid sequence with that of Family 4 UDGs shows that there is an extra stretch of amino acids which is unique to this group of proteins. This stretch, defined by AGGKRRIH is absent in all Family 4 UDGs and the region KRRIH of the strtch is quite conserved amongst all UdgX proteins. Homology modelling of MsmUdgX, using a Family 4 UDG (TthUdgA) shows that this extra stretch of amino acids forms an outloop near the enzyme active site. Another unique difference between MsmUdgX and Family 4 UDGs is in the motif A where MsmUdgX has GEQPG and the Family 4 UDGs haveGE(A/G)PG. Our work on MsmUdgX has shown that, unlike other UDGs, this protein does not excise uracils, but forms a tight complex with the uracil containing DNA. This unique tight uracil binding property as well as KRRIH amino acid stretch has not been observed for any uracil DNA glycosylase superfamily proteins. So, to gain insight into the role of KRRIH and glutamine (Q) of motif A in MsmUdgX family of proteins, site directed mutagenesis was done in this region and we observed that mutation of His109 of the KRRIH loop to serine (S) leads to a gain of uracil excision activity, whereas changing the R107 to S, ‘RRIH’ to ‘SSAS’ or deleting the loop altogether leads to loss of its complex formation activity. Further, mutation of H109 to other amino acids like G, Q and A also shows uracil excision activity. Mutation of the glutamine in the motif A to alanine so that it is exactly similar to that of Family 4 UDGs, does not affect its uracil binding activity. This observation indicates that the KRRIH loop has an important role in the tight binding and/or uracil excision activity of MsmUdgX. Crystal structure of MsmUdgX in complex with uracil-DNA oligo and MsmUdgX H109S mutants are being studied.IV. Physiological importance of MsmUdgX in M. smegmatis MsmUdgX is a uracil DNA glycosylase superfamily protein which binds tightly to uracil (in DNA) without excising it. To elucidate its role in M. smegmatis, knockout of udgX was generated. Growth comparison of the wild type and the ΔudgX strains does not show any growth differences under the conditions tested. However, overexpression of MsmUdgX in recA deficient strains of E. coli as well as M. smegmatis leads to their retarded growth. Retarded grown is also observed in strains deficient in other DNA repair proteins that work in conjunction with RecA. These observations indicate that repair/release of MsmUdgX-uracil DNA complex might be a RecA dependent process.

Mycobacteria

Mycobacterial DNA Repair Proteins

Mycobacteria

MSMEG

MutT2

Bacterial Proteins

Site Directed Mutagenesis

DNA Binding Proteins

DNA Repair Enzymes

Uracil DNA Glycosylase

MsmUdgX

MutT4

MutT2

MutY

Microbiology

Funkční analýza populačně specifických sekvenčních variant genu pro kinázu kontrolního bodu buněčného cyklu CHEK2 / Functional analysis of the population-specific checkpoint kinase gene CHEK2 sequence variants

Stolařová, Lenka

January 2015

CHEK2 gene codes for serin/threonine kinase Chk2 (Checkpoint kinase 2). In response to genomic DNA damage, Chk2 phosphorylates its substrates (proteins Cdc25C, BRCA1 or p53), whose activation leads either to cell cycle arrest, DNA damage repair or induction of apoptosis. Germline mutations in CHEK2 gene increase risk of cancer development. Analysis of high risk breast cancer patients in Czech Republic reveals rare CHEK2 mutations (mainly missense) with yet unknown clinical significance. This work focuses on functional impact of these variants and analysis of kinase activity of variant isoforms of Chk2 kinase. For this purpose, recombinant constructs were expressed in bacterial cells of E. coli. Enzymatic activity of Chk2 kinase isoforms in crude cell lysates was measured by the phosphorylation of Chk2 arteficial substrate spectrophotometrically. Results of in vitro kinase assay were correlated to the results of in silico prediction software. The results show that from 15 analyzed mutations (together with one in frame deletion), kinase activity was abrogated in all variants affecting the kinase domain of Chk2, in concordance with in silico predictions. The same result has been found for a FHA domain variant p.R145Q. No significant changes in kinase activity were observed in case of two FHA domain variants...