Bioactivity of selected medicinal plants used for the treatment of sexually transmitted diseases

Mamba, Phiwokuhle Bongisile

January 2017

Background: Sexually transmitted diseases (STD's) have a major impact on sexual and reproductive health worldwide. Each year, the World Health Organization (WHO) estimates 448 million new cases of curable STD's are diagnosed. The emergence of drug resistance in STD related microorganisms and potential side effects demand the discovery of newer drugs. The exploration of newer anti-microbial substances from natural sources may serve as promising alternatives. In this study, twelve medicinal plant species used traditionally in the treatment of STD's are investigated in this regard. Methods: Ethanol plant extracts and three flavonoids were evaluated for their antimicrobial properties against one fungi and three bacteria, through the micro-dilution assay. To determine the anti-inflammatory activities of the extracts and compounds, the inhibitory effect was measured on the pro-inflammatory enzyme lipoxygenase, 15-LOX. Extracts were further evaluated for their inhibitory effect on the supercoiling activity of bacterial DNA gyrase by using the DNA gyrase kit. The extracts and compounds were lastly investigated for their anti-HIV activities against recombinant HIV-1 enzyme using non-radioactive HIV-RT colorimetric assay. Results: Acacia karroo and Rhoicissus tridentata extracts showed good antimicrobial activity with MIC values ranging between 0.4 and 3.1 mg/ml. Extracts of Jasminum fluminense, Solanum tomentosum and flavonoid 2 and 3 had good anti-inflammatory activity with IC50 less than the positive control quercetin (IC50 = 48.86 ug/ml). Extracts of Diospyros mespiliformis, Peltophorum africanum, Rhoicissus tridentata and flavonoids 1 and 2 showed the best inhibitory activity against the bacterial DNA gyrase. A. karroo and flavonoid 3 exhibited moderate HIV RT inhibition activity of 66.8 and 63.7 % respectively. R. tridentata and Terminalia sericea had the best RT inhibition activity (75.7 and 100 %) compared to the positive control doxorubicin (96.5%) at 100 ug/ml concentration. Conclusion: The observed activities may lead to new multi-target drugs against sexually transmitted diseases. / Dissertation (MSc)--University of Pretoria, 2017. / Plant Science / MSc / Unrestricted

UCTD

Sexually transmitted diseases

Antimicrobial

Anti-inflammatory

DNA gyrase

Artifizielle DNA - bindende Proteine: Herstellung und Charakterisierung von rekombinanten Proteinen zur gezielten Anwendung in der direkten Detektion oder Anreicherung von Nukleinsäuren

Naumann, Andreas

05 September 2013

Methoden zur direkten Detektion oder Anreicherung von doppelsträngiger DNA (dsDNA) bieten ein hohes Potential zum Einsatz in der molekularen Diagnostik. Bereits etablierte Methoden für die Nukleinsäure - Detektion (NAD) basieren in der Regel auf der Hybridisierung des komplementären Stranges gefolgt von der optischen Detektion oder enzymatischer Amplifikation. DNA - bindende oder organisierende Proteine (z.B. endogene Transkriptionsfaktoren) bieten im Kontrast zu den Hybridisierungsreaktionen eine überaus interessante Alternative um dsDNA direkt und zugleich spezifisch zu detektieren oder diese aus einem komplexen Gemisch heraus anzureichern. Im Rahmen der Entwicklung von neuartigen NAD - Assays zur direkten Detektion oder Anreicherung von Nukleinsäuren wurden vier DNA - bindende Proteine kloniert und in HEK293 und E. coli exprimiert. Der Cys2His2 - Zinkfinger (ZFD) vom humanen Transkriptionsfaktor Sp1 wurde mit MBP und 9×Lys - MBP fusioniert. Das MBP - Derivat 9×Lys - MBP ist eine erweiterte Variante mit neun aufeinanderfolgenden Lysinen im N - terminalen Bereich, welche eine regioselektive Immobilisierung ermöglichen soll. Der humane Sp3 - ZFD wurde mit EGFP fusioniert. Die Mitglieder der Sp - Familie binden spezifisch die Konsensussequenz 5’ - GGG GCG GGG - 3’ (GC - Box). Zusätzlich wurde die C - terminale DNA - bindende Domäne der E. coli DNA - Gyrase Untereinheit A (gyrA - CTD) ebenfalls mit MBP fusioniert. Die Domäne bindet spezifisch repetitive extragene Palindrome (REP), welche bislang nur auf bakteriellen Chromosomen vorkommen. Sämtliche MBP - Fusionsproteine liegen nach der Expression löslich vor und konnten über eine native Strategie aufgereinigt werden. Transiente Transfektionsexperimente in HEK293 zeigten einen destabilisierenden Effekt der Sp3 - ZFD und eine massive einhergehende Degradierung des EGFP - Fusionsproteins nach 120 h. Die Analyse der mRNA - Integrität nach Transfektion des Expressionsplasmids, sowie zellbiologische und proteinbiochemische Untersuchungen mit Durchflusszytometrie bzw. Western Blots deuten auf eine posttranslationale Modulierung von EGFP - Sp3 hin. Um die Hypothese der proteasomalen Degradierung von EGFP - Sp3 zu belegen, wurden transfizierte HEK293 mit dem reversiblen Proteasominhibitor MG132 behandelt. In Gegenwart von 1 µM MG132 konnte das zytosolische Fusionsprotein stabilisiert werden. Die hier präsentierten Daten offenbaren die humane Sp3 - ZFD als ein neues Substrat für das 26S - Proteasom. Lediglich die SUMOylierung von Wildtyp - Sp3 im Bereich der inhibitorischen Domäne (ID) ist bislang beschrieben worden. Die Funktionalität, Affinität und kinetische Parameter der mit MBP fusionierten Sp1 - ZFD und gyrA - CTD wurden anhand von Oberflächenplasmonresonanz (BIAcore) bzw. EMSAs analysiert. Sämtliche gewonnenen MBP - Fusionsproteine sind funktionell und interagieren mit dsDNA. Fusionsproteine mit Sp1 - Domäne zeigten in EMSAs ebenso eine Bindung an unspezifische dsDNA. In sensitiveren BIAcore - Assays mit immobilisierter dsDNA wurden (um den Faktor 2) geringere Assoziations (ka) - und Dissoziationsraten (kd) von MBP - Sp1 ermittelt, wenn bestimmte Basen innerhalb der GC - Box ausgetauscht wurden. Die Affinität (Kd) von MBP - Sp1 mit 4×10 - 9 M zur GC - Box und deren Derivate ist vergleichbar mit der Kd von nativem Sp1. Die EMSA - Experimente für MBP - gyrA zeigen eine deutliche Präferenz zum spezifischen dsDNA - Oligo in Gegenwart von humaner gDNA, eine interessante Eigenschaft die durchaus zur Anwendung in einem Assay zur Anreicherung von bakterieller DNA dienen kann. Nach der vorausgehenden Charakterisierung der MBP - Fusionsproteine wurden diese auf verschiedenen gängigen festen und semifesten Substraten über physische Adsorption, kovalent oder Affinität immobilisiert um das Konzept der direkten Detektion von dsDNA mit funktionellen Proteinen als neuartige Komponente in NAD - Assays umzusetzen. Lediglich MBP - Sp1 zeigte auf Glas und Polystyren - Mikrotiterplatten nach kovalenter oder adsorptiver Immobilisierung eine ausgeprägte Funktionalität hinsichtlich der Bindung von dsDNA. Die Immobilisierung von 9×Lys - MBP - Sp1 über identische Strategien führten zum massiven Verlust der ZFD - Funktion. Aus dieser Datenlage heraus wurde erfolgreich ein simples Lumineszenz - basiertes Mikrotiterplatten - Assay mit MBP - Sp1 entwickelt um PCR - Amplikons direkt aus einer analytischen PCR auf gDNA von S. aureus, welche die GC - Box beinhalten, nachzuweisen. Das spezifische Amplikon konnte mittels des simplen Assays in Gegenwart von 100fachem Überschuss an humaner gDNA nachgewiesen werden. Mit einem höheren Anteil an humaner gDNA wurde die PCR massiv inhibiert, ein negativer Effekt der bislang im Bereich der diagnostischen NAD - Assays nicht optimal adressiert wurde. Die magnetische Separation von bakterieller und humaner gDNA wurde dazu mit MBP - gyrA umgesetzt. Zunächst erfolgte die regioselektive Immobilisierung von MBP - gyrA auf Protein A - funktionalisierte magnetische Nanopartikel mittels MBP - Antikörper, wodurch die Funktionalität hinsichtlich der Bindung von dsDNA gewährleistet werden konnte. Dieses System eignet sich insbesondere für die Separation von bakterieller DNA (E. coli oder S. aureus) aus einem komplexen Gemisch mit bis zu 100fachem Überschuss an humaner gDNA. Die Kombination von MBP - gyrA - basierter magnetischer Separation mit NAD - Assays könnte deren Sensitivität signifikant erhöhen. Durch simple Verfahrensweise bietet das System einen wesentlichen Beitrag zur Verringerung des zeitlichen Aufwands für die Generierung therapierelevanter Resultate. / Methods for direct detection or enrichment of double - stranded DNA (dsDNA) possess tremendous potential for use in molecular diagnostics. Already established methods for nucleic acid detection (NAD) are generally based on the hybridization of two complementary strands followed by optical detection or enzymatic amplification. In contrast, DNA - binding or organizing proteins (e.g. endogenous transcriptions factors) are able to read the sequence information directly from dsDNA without prior denaturation of the double strand and subsequent hybridization. In order to develop novel NAD assays or assays for sample preparation, four artificial DNA - binding proteins were cloned, expressed and purified in HEK293 cells or E. coli. The Cys2His2 zinc finger domains (ZFD) from human Sp1 were fused to maltose binding protein (MBP) and its derivate 9×Lys - MBP, an extended variant with nine successive lysine residues in the N - terminal region of the protein to facilitate site - directed immobilization. The human Sp3 - ZFD was fused to green fluorescent protein (EGFP). The family of Sp - transcription factors was known to bind specifically the consensus sequence 5\'' - GGG GCG GGG - 3 \''(GC - box). Moreover, the C - terminal DNA - binding domain of E. coli DNA Gyrase subunit A (gyrA - CTD) was fused to MBP. The CTD binds specifically repetitive extragenic palindromes (REP), which were only found on prokaryotic chromosomes. All MBP fusion proteins were soluble after expression and could be purified to homogeneity. Surprisingly, transient transfection experiments in HEK293 revealed a destabilizing effect of the Sp3 - ZFD accompanied by massive degradation of the EGFP fusion protein after 120 h post transfection. Analysis of mRNA integrity in combination with western blots indicates a posttranslational modulation of EGFP - Sp3. To confirm the hypothesis of proteasomal degradation of EGFP - Sp3, transfected cells were treated with the reversible proteasome inhibitor MG132. In the presence of 1µM MG132 the fusion protein could be stabilized. Taken together, the data presented here identified the human Sp3 - CTD as a new substrate for the 26S proteasome. Only SUMOylation of wild type human Sp3 within the inhibitory domain (ID) has been described so far. Initial EMSA experiments showed that purified MBP - ZFD fusion proteins were functional in terms of interacting with dsDNA containing the specific sequence motiv. However, all proteins bound to unspecific dsDNA as well. Therefore MBP - Sp1 was subjected to BIAcore analysis to determine the rate constants for association ka, dissociation kd and the dissociation constant Kd of the GC - Box - Protein complex as well as mutants of the GC - Box. The determined Kd (4 × 10 - 9 M) for MBP - Sp1 associated with GC - box or its derivatives were found to be comparable with the Kd of native Sp1, however the rate constants were reduced 2 fold in presence of the modified GC - boxes. EMSA experiments with MBP - gyrA revealed functionality and a clear preference for specific dsDNA in the presence of unspecific human genomic DNA (gDNA). After preliminary functional characterization, MBP fusion proteins were immobilized by physical adsorption, covalent or by affinity on various solid substrates or nanoscaled magnetic beads to implement the concept of direct detection of dsDNA or specific enrichment of bacterial DNA, respectively. MBP - Sp1 remains functional after adsorptive or covalent immobilization on different chemical modified glas surfaces. 9×Lys - MBP - Sp1 shows significantly reduced functionality after immobilization on the same glas substrates by similar strategies. Moreover, a simple NAD - assay with adsorptive immobilized MBP - Sp1 on polystyrene in microtiter format was established for direct detection of GC - boxes within PCR - products from S. aureus gDNA. By using the assay, specific PCR - products could be detected in presence up to 100 - fold excess of human gDNA in relation to 10 ng bacterial DNA. Separation of bacterial DNA from human DNA from clinical samples may have an important impact on downstream applications, involving NAD assays. To address this often underestimated technical problem, a new functional protein MBP - gyrA was introduced to overcome some limitations of already established methods. MBP - gyrA was site - directed coupled on nanoscaled magnetic beads by affinity. This system enabled the fast and specific separation of gDNA of E. coli or S.aureus from a huge background of human gDNA. The combination of MBP - gyrA - based magnetic separation with NAD assays could significantly increase the sensitivity and shorten the time for initiation of effective treatment.

info:eu-repo/classification/ddc/600

ddc:600

info:eu-repo/classification/ddc/610

ddc:610

DNA diagnostic; zinc finger; DNA gyrase

DNA Diagnostik, Zinkfinger, DNA Gyrase

DNA diagnostic, zinc finger, DNA gyrase

Effet de la RNase HI sur l’expression génique et sur le surenroulement de l’ADN chez Escherichia coli

Nolent, Flora

01 1900

Les R-loops générés durant la transcription sont impliqués dans de nombreuse fonctions incluant la réplication, la recombinaison et l’expression génique tant chez les procaryotes que chez les eucaryotes. Plusieurs études ont montré qu’un excès de supertours négatifs et des séquences riches en bases G induisent la formation de R-loops. Jusqu’à maintenant, nos résultats nous ont permis d’établir un lien direct entre les topoisomérases, le niveau de surenroulement et la formation de R-loops. Cependant, le rôle physiologique des R-loops est encore largement inconnu. Dans le premier article, une étude détaillée du double mutant topA rnhA a montré qu’une déplétion de RNase HI induit une réponse cellulaire qui empêche la gyrase d’introduire des supertours. Il s’agit ici, de la plus forte évidence supportant les rôles majeurs de la RNase HI dans la régulation du surenroulement de l’ADN. Nos résultats ont également montré que les R-loops pouvaient inhiber l’expression génique. Cependant, les mécanismes exacts sont encore mal connus. L’accumulation d’ARNs courts au détriment d’ARNs pleine longueur peut être causée soit par des blocages durant l’élongation de la transcription soit par la dégradation des ARNs pleine longueur. Dans le deuxième article, nous montrons que l’hypersurenroulement négatif peut mener à la formation de R-loops non-spécifiques (indépendants de la séquence nucléotidique). La présence de ces derniers, engendre une dégradation massive des ARNs et ultimement à la formation de protéines tronquées. En conclusion, ces études montrent l’évidence d’un lien étroit entre la RNase HI, la formation des R-loops, la topologie de l’ADN et l’expression génique. De plus, elles attestent de la présence d’un nouvel inhibiteur de gyrase ou d’un mécanisme encore inconnu capable de réguler son activité. Cette surprenante découverte est élémentaire sachant que de nombreux antibiotiques ciblent la gyrase. Finalement, ces études pourront servir également de base à des recherches similaires chez les cellules eucaryotes. / R-loops generated during transcription elongation are implicated in many DNA reactions, including replication, recombination and gene expression both in prokaryotes and in eukaryotes. Many studies have shown that negative supercoils excess and G-rich sequences induce the formation of R-loops. Up to now, our results allow us to establish a direct link between topoisomerases, supercoiling level, and the formation of R-loops. However, what the physiological significance, if any, of R-loops is still largely unknown. In the first article, a detailed study on double topA rnhA mutants showed that the depletion of RNase HI activity induces a cellular response which renders gyrase unable to perform supercoils. This is the first evidence implicating RNase HI as a major player in DNA supercoiling regulation. Our results also show that R-loops formation can lead to the inhibition of gene expression. However, the exact mechanism(s) leading to the inhibition of gene expression are not yet understood. The accumulation of shorter than full length RNAs could be caused by road-blocks during transcription elongation or by the degradation of full length RNAs. In the second article, we show that hypernegative supercoiling can lead to sequence independent R-loop formation. The physiological consequence is extensive RNA degradation which ultimately culminates in the formation of truncated proteins. In conclusion, this study clearly shows a close link between RNase HI activity, R-loop formation, DNA topology and gene expression. In addition, this study also provides some evidence for the synthesis of a gyrase inhibitor that can regulate gyrase activity directly or indirectly via unidentified mechanisms. This surprising observation is still preliminary taking into consideration that many antibiotics target gyrase. Finally results from this study could open up avenues for research in eukaryotes.

Topoisomérase I

gyrase

RNase HI

R-loops

surenroulement

Topoisomérase I

gyrase

RNase HI

R-loops

supercoiling

Effet de la RNase HI sur l’expression génique et sur le surenroulement de l’ADN chez Escherichia coli

Nolent, Flora

01 1900

Les R-loops générés durant la transcription sont impliqués dans de nombreuse fonctions incluant la réplication, la recombinaison et l’expression génique tant chez les procaryotes que chez les eucaryotes. Plusieurs études ont montré qu’un excès de supertours négatifs et des séquences riches en bases G induisent la formation de R-loops. Jusqu’à maintenant, nos résultats nous ont permis d’établir un lien direct entre les topoisomérases, le niveau de surenroulement et la formation de R-loops. Cependant, le rôle physiologique des R-loops est encore largement inconnu. Dans le premier article, une étude détaillée du double mutant topA rnhA a montré qu’une déplétion de RNase HI induit une réponse cellulaire qui empêche la gyrase d’introduire des supertours. Il s’agit ici, de la plus forte évidence supportant les rôles majeurs de la RNase HI dans la régulation du surenroulement de l’ADN. Nos résultats ont également montré que les R-loops pouvaient inhiber l’expression génique. Cependant, les mécanismes exacts sont encore mal connus. L’accumulation d’ARNs courts au détriment d’ARNs pleine longueur peut être causée soit par des blocages durant l’élongation de la transcription soit par la dégradation des ARNs pleine longueur. Dans le deuxième article, nous montrons que l’hypersurenroulement négatif peut mener à la formation de R-loops non-spécifiques (indépendants de la séquence nucléotidique). La présence de ces derniers, engendre une dégradation massive des ARNs et ultimement à la formation de protéines tronquées. En conclusion, ces études montrent l’évidence d’un lien étroit entre la RNase HI, la formation des R-loops, la topologie de l’ADN et l’expression génique. De plus, elles attestent de la présence d’un nouvel inhibiteur de gyrase ou d’un mécanisme encore inconnu capable de réguler son activité. Cette surprenante découverte est élémentaire sachant que de nombreux antibiotiques ciblent la gyrase. Finalement, ces études pourront servir également de base à des recherches similaires chez les cellules eucaryotes. / R-loops generated during transcription elongation are implicated in many DNA reactions, including replication, recombination and gene expression both in prokaryotes and in eukaryotes. Many studies have shown that negative supercoils excess and G-rich sequences induce the formation of R-loops. Up to now, our results allow us to establish a direct link between topoisomerases, supercoiling level, and the formation of R-loops. However, what the physiological significance, if any, of R-loops is still largely unknown. In the first article, a detailed study on double topA rnhA mutants showed that the depletion of RNase HI activity induces a cellular response which renders gyrase unable to perform supercoils. This is the first evidence implicating RNase HI as a major player in DNA supercoiling regulation. Our results also show that R-loops formation can lead to the inhibition of gene expression. However, the exact mechanism(s) leading to the inhibition of gene expression are not yet understood. The accumulation of shorter than full length RNAs could be caused by road-blocks during transcription elongation or by the degradation of full length RNAs. In the second article, we show that hypernegative supercoiling can lead to sequence independent R-loop formation. The physiological consequence is extensive RNA degradation which ultimately culminates in the formation of truncated proteins. In conclusion, this study clearly shows a close link between RNase HI activity, R-loop formation, DNA topology and gene expression. In addition, this study also provides some evidence for the synthesis of a gyrase inhibitor that can regulate gyrase activity directly or indirectly via unidentified mechanisms. This surprising observation is still preliminary taking into consideration that many antibiotics target gyrase. Finally results from this study could open up avenues for research in eukaryotes.

Topoisomérase I

gyrase

RNase HI

R-loops

surenroulement

Topoisomérase I

gyrase

RNase HI

R-loops

supercoiling

Etude structurale et fonctionnelle des complexes de l'ADN gyrase, une ADN topoisomérase bactérienne de type II / Functional and structural study of the DNA gyrase complexes, a prokaryotic type IIA topoisomerase

Papillon, Julie

27 September 2012

Les ADN topoisomérases (Topos) sont des éléments essentiels de la vie cellulaire eucaryote et procaryote. Ces enzymes interviennent lors de la réplication, de la réparation et également lors de la transcription en modulant la topologie de l'ADN. L'ADN gyrase, une Topoisomérase IIA (TopoIIA) bactérienne particulière, est la seule topoisomérase capable de surenrouler l’ADN négativement en présence d’ATP, une activité indispensable au génome bactérien. Les différentes études structurales et fonctionnelles sur ces enzymes ont permis de proposer un mécanisme catalytique de surenroulement très sophistiqué mais la vision morcelée de ces complexes multi-­‐conformationnels laisse aujourd’hui de nombreuses questions mécanistiques en suspens. Ce travail de thèse a combiné une approche structurale et fonctionnelle pour essayer de répondre aux questions fondamentales mécanistiques encore non élucidées à propos des ADN topoisomérases de type II et à la découverte de nouveaux inhibiteurs « anti-­‐Topo » face à l’émergence de populations bactériennes résistantes aux traitements. / Type II DNA topoisomerases (Topo2A) remodel DNA topology during replication, transcription and chromosome segregation. Most TopoIIA are able to perform ATP-­‐dependent DNA relaxation or decatenation but the bacterial DNA gyraseis the sole type II DNA topoisomerase able to introduce negative supercoils. Several biochemical and structural studies haverevealed a highly sophisticated supercoiling catalytic mechanism but despite a wealth of information, the full architectureof Topo2A and the structural basis for DNA supercoiling remain elusive. Due to their physiological roles, topoisomerasesare also important targets for antibiotics targeting the bacterial enzyme but also anti-­‐cancer molecules inhibiting the humanprotein. This presented work has combinedboth structural and functional approach to answer the fundamental mechanisticquestions still unveiled and to discover new inhibitors against the emergence of resistant bacterial population.

ADN topoisomérases

ADN gyrase

Cryo-microscopie életronique

Surenroulement

Inhibiteurs

Antibiotiques

DNA toposisomerase

DNA gyrase

Cryo-electro microscopy

Supercoiling

Inhibitors

Antibiotics

571.4

572.8

DNA Gyrase And Topo NM From Mycobacteria : Insights into Mechanism And Drug Action

Kumar, Rupesh

January 2014

Maintenance of a topological homeostasis by introduction and removal of the supercoils to relieve excessive strain on the DNA is a hallmark of topoisomerase function in the cell. The requirement of the topoisomerases during DNA transaction processes marks a ubiquitous presence of the enzymes in all the life forms. Different reactions carried out by the enzymes include relaxation of positive and negative supercoils required majorly during DNA replication and transcription, decatenation at the end of DNA replication to separate the daughter chromosomes and removal of lethal knots generated in the circular chromosome. In eubacteria, the enzymes introduce negative supercoils to facilitate easier strand separation for DNA transaction processes. However, in thermophiles, a different enzyme maintains the genome in a positively supercoiled form to protect from denaturation by excessive heat. These varied functions are carried out by different topoisomerases. Therefore, each organism maintains a minimum required set of the enzymes and the absence of a certain enzyme may be compensated for by topoisomerases with dual functions. For example, Mycobacterium tuberculosis and many other slow growing mycobacteria do not possess topoisomerase IV or its homologs. In these organisms, the DNA gyrase is suggested to carry out both negative supercoiling and decatenation reactions. Therefore, the mycobacterial DNA gyrase must be able to manage between both the functions in vivo. In contrast, Mycobacterium smegmatis and few other mycobacteria contain an additional type II topoisomerase which does not resemble any known type II enzyme but could catalyze relaxation and decatenation reactions. Importantly, the enzyme displays a unique ability to introduce limited positive supercoils and may have certain functions inside the cell which remains to be studied. Owing to the indispensability for bacterial survival topoisomerases present themselves as important drug targets. A large number of inhibitors have been found to inhibit the enzyme and thereby killing the bacterial. Among these, quinolones are successfully being used as broad spectrum antibacterial drugs. Although the commonly used quinolones inhibit many bacterial pathogens, a reduced susceptibility is exhibited by some of the pathogens e.g. Mycobacterium tuberculosis. To circumvent the lower efficacy of existing drugs, new and modified quinolones have been developed which are highly effective against mycobacteria. The difference in the susceptibility may be conferred by a difference in the chemical property of the drug and the interacting residues present in the enzyme. In the present thesis efforts have been made to understand the mechanism of the type II topoisomerases from mycobacteria and drug action on these enzymes. The thesis is divided into four chapters. In Chapter I of the thesis an introduction is provided on the topoisomerases, their classification and different reactions catalyzed by these enzymes. As the work in present thesis has been carried out with type II topoisomerases, introduction of type II enzymes, their structure and mechanisms is elaborated. DNA gyrase, its mechanism of reaction and in vitro and in vivo functions are explained in great detail. DNA gyrase and topoisomerase IV are targeted by a range of different inhibitors. These different classes of inhibitors and their mechanism of action are described. Finally, the mechanism of mycobacterial DNA gyrase with structural information and the current understanding of quinolone action on the enzyme are explained. The chapter ends with the objective of the study in the present thesis. In chapter II, the studies are aimed at understanding the molecular basis for decatenation carried out by mycobacterial DNA gyrase. Previous work from the laboratory showed that the enzyme can carry out decatenation more efficiently than its homolog from E. coli. It was shown that the mycobacterial enzyme binds two DNA molecules in trans in a length dependent manner. The ability to bind the second DNA is conferred upon the holoenzyme by ATPase subunit (GyrB) subunit which alone can bind DNA. Similar studies using topo IV from E. coli, the strongest known decatenase showed binding of two DNA molecules and the second DNA binding by ATPase (ParE) subunit. However, GyrB subunit from E. coli DNA gyrase, a weaker decatenase, does not bind second DNA molecule efficiently. The results provide a general mechanism for decatenation by type II enzymes in which efficient binding of second DNA is important. In Chapter III, studies have been carried out using topo NM, an atypical type II topoisomerase from Mycobacterium smegmatis. The enzyme has been characterized previously in the laboratory. In addition to efficient decatenation and relaxation, the enzyme exhibits a unique ability to introduce positive supercoils into the DNA. As demonstrated for the mycobacterial DNA gyrase and topo IV in the Chapter II, the ATPase subunit (Topo N) of topo NM, binds second DNA efficiently. The binding of both gate and transport segments increases with the length of the DNA. Binding of two DNA molecules by the holoenzyme appears to be a cumulative effect of DNA binding to individual subunits. In the absence of any inhibitor, the enzyme accumulates cleaved DNA products with shorter DNA but not with larger DNA. The cleavage of the shorter DNA is supported only in the presence of Mg2+ and Mn2+. Another important property of the enzyme is to introduce positive supercoils which appears to be due to its efficient utilization of ATP and a high rate of reaction. Chapter IV deals with the interaction of mycobacterial gyrase with fluoroquinolones (FQs). Although DNA gyrase is the sole target of the FQs in M. tuberculosis, the lower susceptibility to commonly used FQs have led to the studies to find out more effective quinolones. Previous studies from the laboratory showed a lower susceptibility of the mycobacterial gyrase to ciprofloxacin, but moxifloxacin could inhibit the enzyme efficiently. The better inhibition by moxifloxacin appears to be due to efficient trapping of the enzyme-DNA covalent complex. Both ciprofloxacin and moxifloxacin bind the DNA gyrase from mycobacteria, E. coli and E. coli topo IV, independent of DNA. The extent of binding also correlates with the inhibition potential of the drug against a given enzyme. A general model of quinolone enzyme interaction is provided wherein the quinolones are shown to interact with GyrA subunit or holoenzyme or the enzyme- DNA complex which would finally result in the trapping of the covalent complex.

DNA Gyrase

Mycobacteria

DNA Topoisomerases

Drug Action

DNA Binding

Mycobacterial DNA Gyrase

Mycobacterial Topoisomerases

DNA Decatenation

Topo NM

Quinolone

Fluoroquinolones

Ciprofloxacin

Biochemistry

Characterization of Chromosomally Encoded Toxin-Antitoxin Systems in Streptococcus pyogenes

Zarate Bonilla, Lina Johana

19 September 2019

Streptococcus pyogenes ist ein humanpathogenes Bakterium, welches verschiedene Gewebe besiedeln kann und dadurch unterschiedliche Krankheiten verursacht. Die enorme Anpassungsfähigkeit des Bakteriums beruht auf dessen Fähigkeit, verschiedene, vom Wirt induzierte Stresskonditionen zu ertragen. Genetische Faktoren, die in diesem Zusammenhang eine Rolle spielen, sind Toxin-Antitoxin (TA) Systeme. Typ II TA Systeme kodieren für zwei Proteine, ein Toxin und ein Antitoxin, die einen stabilen TA Komplex bilden. Verschlechtern sich die Wachstumsbedingungen, kann das Antitoxin proteolytisch abgebaut werden, wodurch das freigesetzte Toxin essentielle zelluläre Prozesse des Bakteriums inhibiert. In dieser Studie charakterisierte ich zwei chromosomal kodierte ParDE TA Systeme des pathogenen Bakteriums S. pyogenes. Ähnlich zu anderen Systemen werden das Toxin und das Antitoxin beider hier charakterisierten Systeme co-transkribiert und durch Stresseinwirkung (z.B. Aminosäure-mangel) induziert. Zudem konnten weitere posttranskriptionelle bzw. posttranslationale Mechanismen zur Regulierung der Genexpression beider Systeme nachgewiesen werden. Die extrachromosomale Expression der Toxine ParE1 und ParE2 führten in S. pyogenes und Escherichia coli zum Zelltod, wobei die Co-expression der entsprechenden Antitoxine ParD1 und ParD2 die Toxizität minderte. Allerdings verursachte die Überexpression der Antitoxine allein ebenfalls eine Inhibierung des Zellwachstums. ParD1 hemmte die Zellteilung in E. coli, wobei der N-Terminus des Proteins entscheidend für diesen Effekt zu sein schien. Zusammengefasst erweitern die Ergebnisse dieser Arbeit unser Verständnis von ParE Toxinen und verdeutlichen die diversen Mechanismen, welcher sich TA Systeme bedienen, um die bakterielle Physiologie zu beeinflussen. Zusätzlich gibt diese Arbeit einen Einblick in mögliche Mechanismen, die S. pyogenes implementiert, um Stresskonditionen im Wirt zu überdauern. / Streptococcus pyogenes is a human pathogen with a remarkable ability to colonize different tissues and to endure diverse host-induced stress conditions through mechanisms that have yet to be fully understood. One strategy employed by bacteria to cope with changing environments are toxin-antitoxin (TA) genetic modules. Under non-ideal conditions, the antitoxin is subject to proteolysis and thus the freed toxin protein can target crucial pathways in the cell modulating bacterial growth. This study, describes the characterization of two chromosomally encoded ParDE-like TA systems from the human pathogen S. pyogenes. The antitoxin-toxin genes of the parDEF1 and parDE2 TA systems are co-transcribed and triggered by stress-induced conditions. The parDE2 TA showed an inspected mRNA processing under amino acid starvation which suggest a putative post-transcriptional regulation. At the post-translational level, both systems are controlled by ClpXP antitoxin-protein degradation in vivo, an important factor for TA triggering. Furthermore, bacterial plasmid-based expression of the toxins ParE1 and ParE2 resulted in effects in cell viability while the antitoxin molecules ParD1 and ParD2 were able to prevent the toxins lethality, respectably. Unlike canonical antitoxins, both ParD1 and ParD2 molecules also displayed deleterious effects, which seemed to be exclusive and related with the N-terminus domain potentially involved in DNA-interaction. Finally, the ParE toxins presented remarkable plasticity, able to harm not only gyrase but also topoisomerase IV, two important bacterial drug targets that modulate DNA-topology. These results expand the view on the ParE molecular targets and highlight the diverse mechanisms TAs employ to modulate bacterial physiology. We also provide more insights into possible mechanisms that S. pyogenes employs to endure stress in the host and efficiently cause disease.

Streptococcus pyogenes

Toxin-Antitoxin

Gyrase

Topoisomerase

Streptococcus pyogenes

Toxin-Antitoxin

Gyrase

Topoisomerase

570 Biowissenschaften; Biologie

WF 5200

WF 6850

XD 6404

ddc:570

Synthesis of heterocyclic compounds of medicinal relevance

Shi, Jie

January 2003

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Hétérocycle

2-pyridone

ADN gyrase

Pipéridine

Rhokinase inhibiteurs

Acylguanidine

Na⁺/H⁺ échangeur (NHE-1) inhibiteur

Resistance to Fluoroquinolones in <i>Escherichia coli</i>: Prevention, Genetics and Fitness Costs

Marcusson, Linda L.

January 2007

<p>Antibiotic-resistant bacteria are increasingly a major healthcare problem but very few new classes of antibiotics have been discovered or launched in recent decades. Approaches to dealing with the problem include learning how bacteria evolve to resistance and improving dosing regimens with current antibiotics so as to reduce the selection of resistant bacteria. </p><p>This thesis presents studies examining whether antibiotic dosing at high levels can prevent the selection of fluoroquinolone-resistant mutants in <i>Escherichia coli</i>. It also addresses the genetics of fluoroquinolone resistance in <i>E. coli</i> in relation to fitness costs for the resistant bacteria, and the evolution of <i>E. coli</i> to reduce the costs of resistance.</p><p>The mutant prevention concentration (MPC) of ciprofloxacin was measured for a set of clinical urinary tract infection <i>E. coli</i> strains showing that MPC could not be predicted from the minimum inhibitory concentration (MIC). Results from an <i>in vitro</i> kinetic model showed that an AUC/MPC >22 for ciprofloxacin was the single best pharmacodynamic index that predicted prevention of resistance emergence in the wild-type. Simulating currently approved dosing regimens for three different fluoroquinolones it was found that only a few were effective in preventing the selection of a small sub-population of pre-existing mutants. </p><p>Step-wise selection of fluoroquinolone resistance showed that the accumulation of mutations usually reduced bacterial fitness<i> in vitro</i> and <i>in vivo</i>. Systematic construction of isogenic resistant strains confirmed this result and revealed that some combinations of resistance mutations mutually compensate and increase both resistance and fitness. It was discovered that mutations altering RNA polymerase could ameliorate the fitness costs of fluoroquinolone resistance. Thus, the major fitness cost of fluoroquinolone resistance is due to defective transcription. </p><p>The finding that fluoroquinolone resistance mutations can increase resistance while mutually compensating their fitness costs, shows that resistance to fluoroquinolones can continue to evolve in the absence of antibiotic selection.</p>

Biology

Fluoroquinolone

Escherichia coli

Resistance

Gyrase

Topoisomerase IV

MPC

Fitness compensation

Urinary Tract Infection

Biologi

Resistance to Fluoroquinolones in Escherichia coli: Prevention, Genetics and Fitness Costs

Marcusson, Linda L.

January 2007

Antibiotic-resistant bacteria are increasingly a major healthcare problem but very few new classes of antibiotics have been discovered or launched in recent decades. Approaches to dealing with the problem include learning how bacteria evolve to resistance and improving dosing regimens with current antibiotics so as to reduce the selection of resistant bacteria. This thesis presents studies examining whether antibiotic dosing at high levels can prevent the selection of fluoroquinolone-resistant mutants in Escherichia coli. It also addresses the genetics of fluoroquinolone resistance in E. coli in relation to fitness costs for the resistant bacteria, and the evolution of E. coli to reduce the costs of resistance. The mutant prevention concentration (MPC) of ciprofloxacin was measured for a set of clinical urinary tract infection E. coli strains showing that MPC could not be predicted from the minimum inhibitory concentration (MIC). Results from an in vitro kinetic model showed that an AUC/MPC &gt;22 for ciprofloxacin was the single best pharmacodynamic index that predicted prevention of resistance emergence in the wild-type. Simulating currently approved dosing regimens for three different fluoroquinolones it was found that only a few were effective in preventing the selection of a small sub-population of pre-existing mutants. Step-wise selection of fluoroquinolone resistance showed that the accumulation of mutations usually reduced bacterial fitness in vitro and in vivo. Systematic construction of isogenic resistant strains confirmed this result and revealed that some combinations of resistance mutations mutually compensate and increase both resistance and fitness. It was discovered that mutations altering RNA polymerase could ameliorate the fitness costs of fluoroquinolone resistance. Thus, the major fitness cost of fluoroquinolone resistance is due to defective transcription. The finding that fluoroquinolone resistance mutations can increase resistance while mutually compensating their fitness costs, shows that resistance to fluoroquinolones can continue to evolve in the absence of antibiotic selection.

Biology

Fluoroquinolone

Escherichia coli

Resistance

Gyrase

Topoisomerase IV

MPC

Fitness compensation

Urinary Tract Infection

Biologi