Développement de nucléosides visant l’inhibition de méthyltransférases et synthèse d’une nouvelle famille à visée thérapeutique

Labbé, Marc-Olivier

09 1900

Le travail présenté dans cet ouvrage porte sur la synthèse diastéréosélective d’analogues de nucléosides et leurs usages thérapeutiques. L’intérêt pour cette classe de molécules comme agents anti-cancer et/ou antiviraux réside dans l’existence d’acides nucléiques (sous la forme d’ADN ou d’ARN) nécessaires à la reproduction des cellules cancéreuses et la réplication virale. Plusieurs cofacteurs enzymatiques importants possèdent également une structure nucléosidique et occupent des rôles clés dans les processus cellulaires. La première partie concerne le développement d’une sonde chimique pour l’inhibition de protéines méthyltransférases (PMTs). Cette famille d’enzymes assure la méthylation de protéines, soit une modification post-traductionnelle qui a été associée récemment à certaines maladies incluant le cancer. Sur la base de la structure du cofacteur naturel S-adénosyl-L-méthionine (SAM) et d’inhibiteurs émergents, de nouveaux nucléosides fluorés ont été conçus et synthétisés pour potentiellement améliorer l’activité inhibitrice vis-à-vis certaines de ces enzymes. En collaboration avec le SGC de Toronto, les analogues de nucléosides ont été testés biologiquement et certains ont présenté une activité intéressante contre la lysine méthyltransférase SETDB1. La seconde partie, quant à elle, porte sur la synthèse d’une nouvelle famille d’analogues de nucléosides C2'-fluorés comportant un centre quaternaire fonctionnalisé en position C3'. Différentes bases azotées ont été introduites diastéréosélectivement et, plus de vingt analogues de nucléosides et pronucléotides ont été préparés. Une collaboration avec le laboratoire de la Pre Mona Nemer à l’Université d’Ottawa a permis de les tester in vitro sur des lignées cellulaires cancéreuses du pancréas, où certains montrent une activité biologique intéressante. / The work presented in this manuscript describes the diastereoselective synthesis of nucleoside analogues and their therapeutic uses. The interest in this important class of molecules as anticancer and/or antiviral agents stems from the administration of modified nucleosides that interfere with cell division and viral replication through incorporation into DNA and RNA and/or inhibition of essential enzymes. These analogues thus compete with their natural counterparts to inhibit the synthesis of nucleotides which is the limiting process in cell proliferation. The first objective of this thesis is the development of a chemical probe with inhibitory properties against protein methyltransferases (PMTs). This enzyme family is responsible for protein methylation, a post-translational modification recently linked to cancer and other diseases. Based on the structure of the natural cofactor, S-adenosyl-L-methionine (SAM), novel fluorinated nucleoside analogues were synthesized in an effort to further improve biological activity. In collaboration with the SGC in Toronto, two of these compounds showed interesting activity toward the lysine methyltransferase SETDB1. The second part of this thesis describes the synthesis of a new family of nucleoside analogues bearing a C2' fluorine and a novel all-carbon quaternary center at C3'. Generation of these molecules required optimization of the glycosylation reaction to incorporate various nucleobases as well as modifications to the substituents on the sugar backbone. This resulted in the synthesis of more than twenty analogues including pronucleotides. The biological activity of these molecules was determined in collaboration with Pre Mona Nemer’s laboratory at the University of Ottawa. Such nucleoside analogues have shown interesting activity against pancreatic cancer cell lines.

Analogues de nucléosides

S-adénosyl-L-méthionine

Méthyltranférases

SETDB1

Cancer

Centre quaternaire

Pronucléotides

Pancréas

Glycosylation

Diastéréosélectivité

Nucleoside analogues

S-adenosyl-L-methionine

Methyltransferases

Quaternary center

Pronucleotides

Pancreas

Glycosylation

Diastereoselectivity

Theoretical Studies of Molecular Recognition in Protein-Ligand and Protein-Protein Complexes

Yang, Hui

January 2010

No description available.

Chemistry

quantum chemical

molecular recognition

supermolecular approach

solvation correction

nonbonded interactions

HIV-1

Reverse Transcriptase

non-nucleoside inhibitor

trp 229

Botulinum neurotoxin B

synaptotagmin II

ASADH

structure-based drug design

Veränderungen in der Genexpression fremdstoffmetabolisierender Enzyme und Bedeutung genetischer Polymorphismen unter besonderer Berücksichtigung von HIV-Virustatika

Gashaw, Isabella

20 October 2003

Die Therapie der HIV Infektion besteht aus Kombination mehrerer antiretroviraler Substanzen und birgt ein erhöhtes Risiko an Arzneimittelwechselwirkungen. Das bekannte Problem der Virusresistenz kann zudem durch Enzyminduktion begünstigt werden. Das Ziel der vorliegenden Arbeit lag in Untersuchungen zu Einflüssen der Virustatika auf die Expression von Cytochrom P450 Enzymen: 1A1, 1B1, 3A4 sowie der P-Glykoproteins (MDR1) an immortalisierten Zellsystemen. Die Protease Inhibitoren Indinavir, Nelfinavir, Ritonavir und Saquinavir induzierten die Regulation der mRNA Expression über den Aryl-Kohlenwasserstoff-Rezeptor (AhR) und den Pregnan-X-Rezeptor (PXR) dosisabhängig und signifikant. Die Nukleosidischen Reverse Transkriptase Inhibitoren Zalcitabin, Zidovudin und Lamivudin sowie der Nicht-Nukleosidische Inhibitor Nevirapin zeigten induktive Eigenschaften nur für die AhR Zielgene CYP1A1 und CYP1B1. Amprenavir und Efavirenz aktivierten die PXR-Regulation. Die möglichen Auswirkungen der Induktion der untersuchten Gene wurden ausführlich diskutiert. Die molekularen Grundlagen der interindividuell variierenden Aktivität von CYP3A wurden in einer Probandenstudie untersucht. Es wurden die mRNA Expression in den Leukozyten, die Aktivität des Enzyms und einige bekannte Polymorphismen unter Einwirkung von Rifampicin untersucht und diskutiert. / The therapy of HIV infection requires a combination of several antiretroviral substances accompanying risk factors for drug-drug interactions. Moreover, virus resistance can be promoted by enzyme induction caused by antiretroviral drugs. The aim of the study was to investigate the influences of antiretroviral substances on the expression of cytochrome P450 enzymes: 1A1, 1B1, 3A4 and p-glycoprotein (MDR1) using immortalized cell systems. The protease inhibitors indinavir, nelfinavir, ritonavir and saquinavir induced significantly the regulation of mRNA expression through the aryl hydrocarbon receptor (AhR) and the pregnane-x-receptor (PXR) in a concentration-dependent manner. The nucleoside reverse transcriptase inhibitors zalcitabine, zidovudine and lamivudine and the non-nucleoside reverse transcriptase inhibitor nevirapine showed inductive properties only for the AhR target genes CYP1A1 and CYP1B1.Amprenavir and efavirenz activated the PXR target genes. Potentially effects of the described induction are discussed. In a second part of the work, the molecular mechanisms of the individual varying activity of the CYP3A enzyme were investigated applying an in vivo study. CYP3A4 mRNA expression and rifampicin mediated induction in leucocytes were correlated with systemic enzyme activity under induction and known polymorphisms.

Cytochrom P450

MDR1

HIV

CYP1A1

CYP1B1

CYP3A4

P-Glykoprotein

Antiretrovirale Therapie

HEPG2

COLO-320

HELA

Alprazolam

Protease Inhibitoren

RT-PCR

cytochrome P450

MDR1

HIV

CYP1A1

CYP1B1

CYP3A4

P-Glycoprotein

antiretroviral therapy

HEPG2

COLO-320

HELA

alprazolam

protease inhibitors

RT-PCR

570 Biowissenschaften, Biologie

32 Biologie

VS 8750

WG 4050

XD 8000

ddc:570

Mycobacterium tuberculosis kinases as potential drug targets: production of recombinant kinases in E. coli for functional characterization and enzyme inhibition screening against the medicinal plant Pelargonium sidoides

Lukman, Vishani

01 1900

Tuberculosis (TB) is an infectious and fatal disease that ranks as the second leading killer worldwide. It is caused by Mycobacterium tuberculosis (Mtb) which is an obligate intracellular parasite that colonizes the alveolar macrophages of the immune system. The major health concern associated with TB is its co-infection with HIV and the development of strains with multi-drug resistance. The elimination of TB has been hindered due to the lack of understanding of the survival strategies used by this pathogen. Thus, research towards discovering new effective antibacterial drugs is necessary and a group of Mtb kinase enzymes were targeted in this study because these enzymes are crucial for metabolism, pathogenesis and, hence, the survival of Mtb. Kinases are a group of structurally distinct and diverse proteins that catalyze the transfer of the phosphate group from high energy donor molecules such as ATP (or GTP) to a substrate. The phosphorylation of proteins modifies the activity of specific proteins which is subsequently used to control complex cellular processes within Mtb. The starting point of this research targeted eight specific Mtb kinases namely; Nucleoside diphosphokinase, Homoserine kinase, Acetate kinase, Glycerol kinase, Thiamine monophosphate kinase, Ribokinase, Aspartokinase and Shikimate kinase. The aim of this project was to subclone the gene sequences for these eight recombinant Mtb kinases and express them in Escherichia coli, to purify the proteins and determine their activity. In the effort to find new lead compounds, the final stage of this study focused on the basic screening of the TB kinases against an extract prepared from Pelargonium sidoides, a medicinal plant, to identify any inhibitory effects. Although this traditional medicinal plant has been broadly researched and extensively used to treat TB, there is still a lack of understanding of this plant’s scientific curative effect. Various molecular and biochemical methods were used to achieve the aims of this project. The putative gene sequence was obtained from the annotated genome of H37Rv, deposited at NCBI as NC_000962.2. The genes encoding the kinases were successfully PCR-amplified from genomic DNA, cloned into an expression vector in-frame with a C- or N-terminal 6-histidine-tag and expressed in E. coli BL21 (DE3). The purification of the protein was complex, but various different methods and techniques were explored to obtain sufficient amounts of protein. The functional characterization of the kinases involved an HPLC enzyme assay that showed that the recombinant kinases were active. These enzymes were then screened against the potential inhibitory compounds in P. sidoides using enzyme assays to generate dose-response curves. This allowed an effective comparison not only of the Mtb kinases’ activity under normal conditions but also the kinases’ activity in the presence of a potential inhibitor. Overall, the inhibition of the enzymes required the presence of higher concentrations of the P. sidoides extract. However, the SK enzyme results presented a significantly higher inhibition and the lowest IC50 value, in comparison to the other kinases, which makes this kinase an attractive potential drug target against TB. In summation, cloning and purification of SK was successful, resulting in a concentration of 2030 μg/ml of purified enzyme and its activity analysis demonstrated enzyme functionality. This activity was reduced to zero in the presence of 1 x 102 mg/ml dilution of P. sidoides plant extract. This research conducted has extended the quality of information available in this field of study. These interesting results, proposing and identifying SK as a suitable potential target can be a starting point to significantly contribute and progress in this field of research, with the eventual goal of developing a drug to combat this fatal disease. / Life Sciences / M. Sc. (Life Sciences)

Tuberculosis

Mycobacterium tuberculosis

Kinases

Nucleoside diphosphokinase

Homoserine kinase

Acetate kinase

Glycerol kinase

Thiamine monophosphate kinase

Ribokinase

Aspartokinase

Shikimate kinase

Pelargonium sidoides

Cloning

E. coli expression

Protein purification

Functional characterization

Inhibitory screens

616.995

Tuberculosis -- Prevention

Mycobacterium tuberculosis

Mycobacterium tuberculosis -- Infection

Tuberculosis -- Microbiology

Medical sciences

Synthesis of ring A of (+)-Ambruticin S and bicyclic nucleosides for antisense drug technology

Chen, Bin

08 1900

La synthèse énantiosélective de la (+)-ambruticine S, un produit naturel antifongique a été effectuée au sein de notre groupe. Trois approches ont été développées pour la synthèse du fragment lactone (cycle A). Ces trois voies d’accès au cycle A ont pour intermédiaire commun le methyl α-D-glycopyranoside déjà porteur du diol requis et disponible commercialement à bon prix. Une désoxygénation de l’hydroxyle en C-4 et l’homologation d’un carbone de la chaine latérale en C-6 ont permis l’obtention du cycle lactonique A. Le deuxième projet est une collaboration entre le groupe Hanessian et ISIS Pharmaceuticals afin de développer de nouveaux oligonucléosides antisens. Les nucléosides antisens [4.3.0]-bicycliques cis et trans ont été synthétisés avec succès à partir d’un monosaccharide naturel commun, L-arabinose, porteur des stéréocentres requis. Un réaction clé d’allylation de Sakurai a permis d’obtenir les diastéréoisomères cis et trans dans des conditions de contrôle de type Felkin-Ahn et de contrôle par chélation respectivement. Les composés bicycliques finaux cibles ont été obtenus par une réaction d’aldol intramoléculaire catalyzéé par la proline, par métathèse de fermeture de cycle et par l’application de la méthode de Vorbrüggen pour la synthèse de nucléosides. / An enantioselective synthesis of the antifungal natural product (+)-ambruticin S has been accomplished in our group. For the synthesis of a ring A lactone fragment, three approaches were developed. They all started from commercially available and inexpensive methyl α-D-glycopyranoside, which already possesses the required diol unit. A deletion of the hydroxyl group at C-4 and a one-carbon homologation of the C-6 side chain furnished the ring A lactone. The second project is an ongoing collaboration between the Hanessian group and ISIS pharmaceuticals to develop new antisense oligonucleosides. The cis- and trans-[4.3.0]bicyclic antisense nucleosides were successfully synthesized from a common natural monosaccharide, L-arabinose, which bears the required stereocenters. A key Sakurai allylation led to the cis- and trans diastereomers under Felkin-Ahn and chelation-controlled conditions respectively. The final bicyclic targets were achieved by a practical proline-catalyzed intramolecular aldol reaction and ring-closing metathesis (RCM) strategy, and application of the Vorbrüggen method for nucleoside synthesis.

(+)-Ambruticine S

methyl α-D-glycopyranoside

L-arabinose

allylation de Sakurai

réaction d’aldol intramoléculaire

métathèse de fermeture de cycle

glycosylation de Vorbrüggen

(+)-Ambruticin S

methyl α-D-glycopyranoside

[4.3.0]bicyclic antisense nucleoside

L-arabinose

Sakurai allylation

intramolecular aldol reaction

Ring-Closing Metathesis (RCM)

Vorbrüggen glycosylation

Bicouches lipidiques modèles pour l'étude des interactions de substances exogènes avec les membranes biologiques : exemple d'un principe actif squalénisé, le ddC-SQ / Interactions between exogene molecules and lipidic model membranes : example of a squalenoyl prodrug, SQddC

Allain, Vanessa

15 December 2011

Les principes actifs, dans leur chemin vers leur cible thérapeutique, rencontrent une ou plusieurs membranes biologiques (plasmique, intracellulaire). Les interactions entre un principe actif et ces membranes sont importantes : d’une part les propriétés pharmacocinétiques de la molécule active (transport, distribution, accumulation) en dépendent, d’autre part le principe actif peut modifier les propriétés structurales des membranes. L’étude de ces interactions est rendue difficile par la complexité des membranes en termes de composition (lipidique et protéique) et de structure (hétérogénéité de l’organisation). Par conséquent, l’utilisation de systèmes modèles simplifiés est nécessaire. Au cours de ce travail de thèse nous avons cherché à réaliser des bicouches lipidiques modèles dont les caractéristiques se rapprochaient de celles des membranes biologiques en complexifiant progressivement leur composition lipidique. Nous avons ensuite étudié l’interaction d’une molécule anti-VIH squalénisée, le ddC-SQ, avec nos modèles de membrane.Un des rôles essentiels des membranes biologiques étant de séparer deux milieux aqueux de composition ionique différente, nous avons étudié dans un premier temps l’influence de la nature du milieu d’hydratation sur les propriétés thermiques et structurales des bicouches lipidiques. A pH physiologique, nous avons mis en évidence que seuls les ions divalents (à faibles concentrations) induisaient de profondes modifications structurales en provoquant la formation de vésicules unilamellaires dans les systèmes simples. Une seconde partie de nos travaux a consisté à étudier l’interaction d’un antiviral squalénisé, le ddC-squalène (ddC-SQ), avec nos différentes bicouches modèles. Cet analogue nucléosidique a été associé de manière covalente à une chaîne de squalène afin d’améliorer ses propriétés pharmacocinétiques. Cette squalénisation confère à la molécule la capacité de s’auto-assembler en nanoparticules présentant une structure cubique bicontinue. Les résultats obtenus ont révélé que le principe actif squalénisé interagissait fortement avec les membranes à l’inverse de la molécule native. L’organisation structurale des systèmes modèles est profondément modifiée par l’insertion du ddC-SQ, ce qui pourrait influer sur l’activité du composé. / Drugs must cross one or more biological membranes (plasma membrane, intracellular membrane) to reach their intracellular target. Interactions between drug and membranes play a significant role in the pharmacokinetic properties of drug such as transport, distribution, accumulation. Moreover, drugs may alter membrane properties. The complexity of the composition (protein and lipid) and the structural properties (heterogeneity) of membranes leads to a difficult investigation of these interactions. Consequently, use of simplified model membranes is needed. In this work, model lipid bilayer systems in which the lipid organization mimics the arrangement of lipids in natural membrane have been developed. In this way, the complexity of lipid composition mixtures has been progressively increased. The primary function of membrane is to physically separate aqueous compartments from their surroundings. The intracellular and extracellular fluids differ in ionic composition. This study firstly consists to estimate the influence of aqueous medium nature on the thermodynamic and structural properties of these model membranes.In physiological conditions (pH 7.4, ionic strength 150 mM), the most significant change was obtained in the presence of divalent ions. Markedly change in lipid organization was observed and the formation of unilamellar vesicles has been evidenced (at low concentrations) in simple model bilayers. Interactions of an antiretroviral nucleoside analogue, the SQddC, with lipid systems constitute the second part of our work. Squalene has been covalently coupled to ddC, in order to improve its therapeutic index. Squalenoylation leads to amphiphilic prodrugs which self-organize as nanoparticles. ddC weakly interacts with lipid membranes while SQddC-SQ can insert into membranes between hydrophobic alkyl chains and induce disruption of lipid organization. Consequently, the efficacy and/or toxicity of this drug could change.

Membranes modèles

Séparations de phases

Sphingomyéline

Analogue nucléosidique

Dideoxycytidine (ddC)

Squalénisation

DdC squalène (ddC-SQ)

Calorimétrie (DSC)

Model membranes

Phase separations

Phosphatidylcholine

Sphingomyelin

Cholesterol

PH

Ions

Nucleoside analogue

Dideoxycytidine (ddC)

Squalenoylation

DdC squalene (SQddC)

X ray diffraction (XRD)

Differential scanning calorimetry (DSC)

The kinase MK2 in DNA replication upon genotoxic stress and chemotherapy / Die Kinase MK2 in der DNA-Replikation nach genotoxischem Stress und Chemotherapie

Köpper, Frederik

17 October 2012

No description available.

570 Biowissenschaften, Biologie

WF 200

Biology (incl. Psychology)

MK2

MAPKAPK2

p38

replikativer Stress

ultraviolette Strahlung

Gemzitabin

Nukleosid-Analoga

Chemotherapie

DNA-Replikation

Transläsions-Synthese

PCNA

Chk1

ATR

H2AX

MK2

MAPKAPK2

p38

replicative stress

ultraviolet irradiation

gemcitabine

nucleoside analogues

chemotherapy

DNA replication

translesion synthesis

PCNA

Chk1

ATR

H2AX

42.13

Synthesis of ring A of (+)-Ambruticin S and bicyclic nucleosides for antisense drug technology

Chen, Bin

08 1900

La synthèse énantiosélective de la (+)-ambruticine S, un produit naturel antifongique a été effectuée au sein de notre groupe. Trois approches ont été développées pour la synthèse du fragment lactone (cycle A). Ces trois voies d’accès au cycle A ont pour intermédiaire commun le methyl α-D-glycopyranoside déjà porteur du diol requis et disponible commercialement à bon prix. Une désoxygénation de l’hydroxyle en C-4 et l’homologation d’un carbone de la chaine latérale en C-6 ont permis l’obtention du cycle lactonique A. Le deuxième projet est une collaboration entre le groupe Hanessian et ISIS Pharmaceuticals afin de développer de nouveaux oligonucléosides antisens. Les nucléosides antisens [4.3.0]-bicycliques cis et trans ont été synthétisés avec succès à partir d’un monosaccharide naturel commun, L-arabinose, porteur des stéréocentres requis. Un réaction clé d’allylation de Sakurai a permis d’obtenir les diastéréoisomères cis et trans dans des conditions de contrôle de type Felkin-Ahn et de contrôle par chélation respectivement. Les composés bicycliques finaux cibles ont été obtenus par une réaction d’aldol intramoléculaire catalyzéé par la proline, par métathèse de fermeture de cycle et par l’application de la méthode de Vorbrüggen pour la synthèse de nucléosides. / An enantioselective synthesis of the antifungal natural product (+)-ambruticin S has been accomplished in our group. For the synthesis of a ring A lactone fragment, three approaches were developed. They all started from commercially available and inexpensive methyl α-D-glycopyranoside, which already possesses the required diol unit. A deletion of the hydroxyl group at C-4 and a one-carbon homologation of the C-6 side chain furnished the ring A lactone. The second project is an ongoing collaboration between the Hanessian group and ISIS pharmaceuticals to develop new antisense oligonucleosides. The cis- and trans-[4.3.0]bicyclic antisense nucleosides were successfully synthesized from a common natural monosaccharide, L-arabinose, which bears the required stereocenters. A key Sakurai allylation led to the cis- and trans diastereomers under Felkin-Ahn and chelation-controlled conditions respectively. The final bicyclic targets were achieved by a practical proline-catalyzed intramolecular aldol reaction and ring-closing metathesis (RCM) strategy, and application of the Vorbrüggen method for nucleoside synthesis.

(+)-Ambruticine S

methyl α-D-glycopyranoside

L-arabinose

allylation de Sakurai

réaction d’aldol intramoléculaire

métathèse de fermeture de cycle

glycosylation de Vorbrüggen

(+)-Ambruticin S

methyl α-D-glycopyranoside

[4.3.0]bicyclic antisense nucleoside

L-arabinose

Sakurai allylation

intramolecular aldol reaction

Ring-Closing Metathesis (RCM)

Vorbrüggen glycosylation

Mycobacterium tuberculosis kinases as potential drug targets: production of recombinant kinases in E. coli for functional characterization and enzyme inhibition screening against the medicinal plant Pelargonium sidoides

Lukman, Vishani

01 1900

Tuberculosis (TB) is an infectious and fatal disease that ranks as the second leading killer worldwide. It is caused by Mycobacterium tuberculosis (Mtb) which is an obligate intracellular parasite that colonizes the alveolar macrophages of the immune system. The major health concern associated with TB is its co-infection with HIV and the development of strains with multi-drug resistance. The elimination of TB has been hindered due to the lack of understanding of the survival strategies used by this pathogen. Thus, research towards discovering new effective antibacterial drugs is necessary and a group of Mtb kinase enzymes were targeted in this study because these enzymes are crucial for metabolism, pathogenesis and, hence, the survival of Mtb. Kinases are a group of structurally distinct and diverse proteins that catalyze the transfer of the phosphate group from high energy donor molecules such as ATP (or GTP) to a substrate. The phosphorylation of proteins modifies the activity of specific proteins which is subsequently used to control complex cellular processes within Mtb. The starting point of this research targeted eight specific Mtb kinases namely; Nucleoside diphosphokinase, Homoserine kinase, Acetate kinase, Glycerol kinase, Thiamine monophosphate kinase, Ribokinase, Aspartokinase and Shikimate kinase. The aim of this project was to subclone the gene sequences for these eight recombinant Mtb kinases and express them in Escherichia coli, to purify the proteins and determine their activity. In the effort to find new lead compounds, the final stage of this study focused on the basic screening of the TB kinases against an extract prepared from Pelargonium sidoides, a medicinal plant, to identify any inhibitory effects. Although this traditional medicinal plant has been broadly researched and extensively used to treat TB, there is still a lack of understanding of this plant’s scientific curative effect. Various molecular and biochemical methods were used to achieve the aims of this project. The putative gene sequence was obtained from the annotated genome of H37Rv, deposited at NCBI as NC_000962.2. The genes encoding the kinases were successfully PCR-amplified from genomic DNA, cloned into an expression vector in-frame with a C- or N-terminal 6-histidine-tag and expressed in E. coli BL21 (DE3). The purification of the protein was complex, but various different methods and techniques were explored to obtain sufficient amounts of protein. The functional characterization of the kinases involved an HPLC enzyme assay that showed that the recombinant kinases were active. These enzymes were then screened against the potential inhibitory compounds in P. sidoides using enzyme assays to generate dose-response curves. This allowed an effective comparison not only of the Mtb kinases’ activity under normal conditions but also the kinases’ activity in the presence of a potential inhibitor. Overall, the inhibition of the enzymes required the presence of higher concentrations of the P. sidoides extract. However, the SK enzyme results presented a significantly higher inhibition and the lowest IC50 value, in comparison to the other kinases, which makes this kinase an attractive potential drug target against TB. In summation, cloning and purification of SK was successful, resulting in a concentration of 2030 μg/ml of purified enzyme and its activity analysis demonstrated enzyme functionality. This activity was reduced to zero in the presence of 1 x 102 mg/ml dilution of P. sidoides plant extract. This research conducted has extended the quality of information available in this field of study. These interesting results, proposing and identifying SK as a suitable potential target can be a starting point to significantly contribute and progress in this field of research, with the eventual goal of developing a drug to combat this fatal disease. / Life Sciences / M. Sc. (Life Sciences)

Tuberculosis

Mycobacterium tuberculosis

Kinases

Nucleoside diphosphokinase

Homoserine kinase

Acetate kinase

Glycerol kinase

Thiamine monophosphate kinase

Ribokinase

Aspartokinase

Shikimate kinase

Pelargonium sidoides

Cloning

E. coli expression

Protein purification

Functional characterization

Inhibitory screens

616.995

Tuberculosis -- Prevention

Mycobacterium tuberculosis

Mycobacterium tuberculosis -- Infection

Tuberculosis -- Microbiology

Medical sciences

Efeito da imunização com enzimas recombinantes do metabolismo de nucleotídeos de Schistosoma mansoni sobre o desenvolvimento da esquistossomose mansônica experimental

Neris, Débora Meira

29 August 2012

Made available in DSpace on 2016-08-17T18:39:46Z (GMT). No. of bitstreams: 1 5245.pdf: 1568165 bytes, checksum: 9fc25ff9dc83339e50628c08854efd2c (MD5) Previous issue date: 2012-08-29 / Universidade Federal de Sao Carlos / Schistosimiasis mansoni is a neglected chronic parasitic disease that affects thousands of people worldwide, caused by the trematode Schistosoma mansoni. In the infected host the disease is characterized by the presence of granuloma, imunnopathological response of the cellular infiltration against egg antigens. Thus, the host-parasite relation favors hepatosplenomegaly, acite and hepatic fibrosis. Current chemotherapy is based on the use of Praziquantel (PZQ), used against all species of Schistosoma spp for over 30 years. The main issue is that the PZQ is practically inactive against immature schistosomula and favors the resistance growth of the existent lineages, which makes the study for new drugs and vaccines that can contribute to the control of this disease even more urgent. One of the paths on the search for new therapeutic targets is the study of essential enzymes to the S. mansoni. In particular, it is known that the enzymes Adenylate Kinase 1 and 2 (ADK), Uridine cytidine Kinase 1 and 2 (UCK), Hypoxanthine guanine phosphoribosyltransferase (HGPRT) e Purine nucleoside phosphorilase 1 (PNP) are found on the metabolic pathways of the parasite s nucleotide, participating in the metabolism of purines and pyrimidines. Our goals in this study were to assess the immunization with these enzymes, using the S. mansoni cercariae infected murine model, and subsequently analyze the acting in oviposition and growth of adult worms. Our results showed that the immunization in Balb/c mice with the UCK enzyme was capable of inducing a specific immune response, which favored a significant reduction of the parasitic load (adult worms). However, it was not possible to observe significant reduction in the number of eliminated eggs. Regarding the immunization with PNP and HGPRT enzymes, the mice had a reduction in the number of eggs per gram of feces. The data obtained are considered interesting and can be new targets for immunotherapy against schistosomiasis mansoni. Thereby, new assays must be made with different dosages of the enzymes for a better assessment on how these enzymes modulate the parasitic load through the eggs reduction, reduction in the adult worms retrieving, as well as the antibody levels during the murine infection by the S.mansoni. / A esquistossomose mansônica é uma doença parasitária, crônica e negligenciada que afeta milhares de pessoas ao redor do mundo, causada pelo trematódeo Schistosoma mansoni. No hospedeiro infectado a doença é caracterizada pela presença do granuloma, resultado imunopatológico do infiltrado celular contra antígenos dos ovos A quimioterapia atual é baseada no uso do Praziquantel (PZQ), usado contra todas as espécies de Schistosoma spp há mais de 30 anos. O principal problema é que o PZQ é praticamente inativo contra esquistossomulos imaturos e favorece o desenvolvimento de resistência das linhagens existentes. Um dos caminhos na busca por novos alvos terapêuticos é o estudo de enzimas que são essenciais para o S. mansoni. Em especial, sabe-se que as enzimas Adenilato Quinase 1 e 2 (ADK), Uridina Citidina Quinase 1 e 2 (UCK), Hipoxantina-guanina fosforibosiltransferase (HGPRT) e Purina Nucleosídeo Fosforilase 1 (PNP) são encontradas nas vias metabólicas de nucleotídeos do parasito, participando do metabolismo de purinas e pirimidinas. A estratégia de utilizar enzimas do parasito na esquistossomose mansônica murina foi de avaliar uma resposta induzida por estas enzimas quando aplicadas em camundongos BALB/c e desafiados com cercarias de S. mansoni. Desta forma, avaliamos a fase crônica de camundongos imunizados e infectados com S. mansoni, onde foram analisadas amostras parasitológicas, hematológicas, sorológicas e fluidos da cavidade peritoneal. Nosso objetivo neste estudo foi avaliar a imunização com essas enzimas, usando o modelo murino infectado com cercarias de S. mansoni e posteriormente avaliar a ação na oviposição e desenvolvimento de vermes adultos. Nossos resultados demonstraram que a imunização em camundongos Balb∕c com a enzima UCK foi capaz de induzir uma resposta imune específica, a qual favoreceu a diminuição significativa da carga parasitária (vermes adultos). No entanto, não foi possível observar redução significativa no número de ovos eliminados. Em relação à imunização com as enzimas PNP e HGPRT os camundongos que receberam as imunizações com PNP e HGPRT tiveram redução no número de ovos por grama de fezes. Os dados obtidos são considerados interessantes e podem ser considerados novos alvos para a imunoterapia contra a esquistosomose mansônica. Dessa forma, novos ensaios deverão ser realizados com diferentes doses das enzimas para melhor avaliar como essas enzimas modulam a carga parasitária através da redução de ovos, diminuição na recuperação de vermes adultos, assim como os níveis de anticorpos durante a infecção murina pelo S. mansoni.

Biotecnologia

Imunização

Schistosoma mansoni

Purinas

Pirimidinas

Enzimas recombinantes

Esquistossomose mansônica

Adenilato Quinase 1 e 2

Uridina Citidina Quinase 1 e 2

Purina Nucleosídeo Fosforilase1

Schistosomiasis mansoni

Immunization

Purine nucleoside phosphorilase 1

OUTROS