Dissertations / Theses on the topic 'Biotransformation of drugs'

Le thème principal de notre travail consistait en la mise en exergue de l'efficience de la mise en œuvre de techniques hybrides associant l’électrochimie à l’élément biologique (biocapteur) ou l’électrochimie aux performances de la spectrométrie de masse (couplage EC-MS). Les informations fournies, jointes aux résultats des mesures en voltampérométrie sur électrodes solides, permettent une bonne compréhension mécanistique quant au devenir oxydatif de substances médicamenteuses.

Notre champ d'investigation s'est plus spécifiquement focalisé sur deux familles de molécules psychotropes (les phénothiazines, et une dibenzoazépine). Celles-ci connaissent un usage thérapeutique intensif et un regain d’intérêt pour des applications nouvelles, mais leur utilisation optimale souffre de l’existence d'effets secondaires physiopathologiques importants et dont l’étiologie est encore mal connue.

En premier lieu, les résultats de la voltampérométrie cyclique et les différentes modulations en ligne d'une cellule électrochimique couplée à la détection par spectrométrie de masse, nous ont permis de mettre en évidence des différences essentielles dans le devenir des phénothiazines quant aux produits d'oxydations générés. Plus précisément, un comportement clairement distinct entre les phénothiazines garnies de deux (2C) ou trois carbones (3C) entre les deux azotes au niveau de leur chaîne latérale a pu être mis en évidence. Les phénothiazines 3C s'oxydent de manière classique en leur sulfoxyde correspondant. Par contre, les phenothiazines 2C, conjointement à la formation de leur sulfoxyde, souffrent dans des conditions énergiques d’oxydation (persulfate, potentiel élevé) d'une rupture de la chaîne latérale et libèrent la phénothiazine base aisément oxydable et donc subissant elle-même une oxydation. Au vu des structures moléculaires en trois dimensions, nous émettons l’hypothèse que volume trop important de la chaîne latérale des phénothiazines 2C empêcherait le déploiement aisé des structures aromatiques en un radical cation coplanaire lors du phénomène d'oxydation. Les tensions intrastructurelles apparues conduiraient au bris de la chaîne latérale. Différents modes d'oxydation (chimique, électrochimique, enzymatique) ont été utilisés et laissent chacun apparaître la dépendance directe entre la puissance de l'agent oxydant appliqué et les produits d'oxydation obtenus. Chaque technique de détection, de manière individuelle, a bien confirmé la dualité entre les deux groupes de molécules. La mise en commun des divers résultats nous a permis l'identification irrévocable des espèces intermédiaires instables et des composés finaux. Par corollaire, nous avons pu postuler un schéma général d'oxydation pour les dérivés phénothiaziniques. Il nous paraît intéressant de transposer nos résultats aux biotransformations des phénothiazines car les produits identifiés ne possèdent pas l'activité pharmacologique du composé parent mais présentent un profil toxicologique bien répertorié dans la littérature. Nos résultats suggèrent d’approfondir les études de biotransformation afin de déterminer si ‘l’éclatement’ oxydatif des phénothiazines 2C est également observé in vivo. Une relation cause/effet de ces métabolites pourrait ainsi être établie.

En deuxième point, au travers de l'association CE/SM ou CE/CL/SM, nous avons étudié l’électroxydation de la clozapine. La génération et l'identification des principaux métabolites de phases I et II, illustre un mimétisme certain avec le CYP450, et nous a permis de confirmer de nombreuses données de la littérature quant à l'oxydation in vivo et in vitro de la clozapine. L'oxydation électrochimique ne génère cependant pas l'ensemble des réactions de métabolisation prises en charge par le système CYP450. Lors de la combinaison CE/SM, par l'absence de séparation chromatographique dans cette configuration, le spectre de masse présente un pic correspondant à un intermédiaire à demi-vie courte, difficilement et rarement mis en évidence: l'ion nitrénium. Cette espèce hautement réactive envers les fonctions thiols des petites molécules et des protéines, se trouve très régulièrement tenue pour responsable majeur de la toxicité avérée de la clozapine.

L'apparition plus abondante de dérivés déméthylés démontre l'influence du potentiel appliqué à l'électrode de travail lors de l'oxydation électrochimique. En effet, les processus de déméthylation nécessitent des potentiels élevés pour être observés. En présence de glutathion, aux différents pics antérieurement identifiés, des pics supplémentaires relatifs à la formation d'adduits de GSH sur la CLZ apparaissent. Les courbes voltampérométriques réalisées sur la clozapine suggèrent la distinctement la formation de l'ion nitrénium et d'une nouvelle espèce aisément électroréduite, probablement une structure quinone imine. L'addition de GSH provoque la disparition des pics de réduction de la CLZ. Ces comportements en VC corroborent les interprétations issues des mesures par couplage EC/CL/SM.

La dernière partie de notre travail a consisté en la construction d'un biocapteur à pâte de carbone solide avec inclusion au sein de cette matrice de peroxydase de raifort. Basé sur la capacité reconnue de l'HRP à reproduire in vitro des produits d'oxydation similaires à la métabolisation in vivo, nous avons exploité un tel biocapteur pour l'analyse de la clozapine et de composés thiols. Une compréhension fine du mécanisme opérationnel intrinsèque du biocapteur a pu être suggérée. La génération à la surface de l'électrode de l'ion nitrénium par oxydation enzymatique de la clozapine par l'HRP, suivie de sa réduction immédiate fournit un courant ampérométrique substantiel. Sous des conditions de pH optimales, ce courant de réduction autorise la détermination quantitative de la clozapine dans un domaine de linéarité compris entre 1 x 10-5 M et 1 x 10-6 M. L'addition de composés thiols dans le milieu occasionne une chute de courant par action de ceux-ci sur la structure radical cation ou nitrénium par addition nucléophile. La disparition de l'ion nitrénium et la formation d'un adduit GSH-CLZ inhibent tout processus de réduction à l'électrode du biocapteur. Cette diminution de courant proportionnelle aux concentrations en thiols introduits, permet la détermination quantitative de dérivés thiols. Les courbes de calibration exprimées en pourcentage d'inhibition conduisent facilement à l'évaluation de la constante d'inhibition (Ki) et de CI50. L'étude de la réponse ampérométrique de la clozapine à l'EPC/HRP en l'absence ou présence d'un dérivé thiol envisagé permet la détermination de Km et de caractériser le type d'inhibition qui entre en jeu. De tels paramètres cinétiques nous ont habilités à classer les thiols considérés en fonction de leur puissance réactionnelle envers les substances oxydées de la clozapine.

Au terme de ce travail, nous espérons avoir illustré, par l’étude de quelques molécules modèles, l’intérêt de la mise en œuvre des techniques électrochimiques couplées à l’élément biologique ou à la spectrométrie de masse. Des améliorations au niveau de la cellule électrochimique sont envisageables par l’emploi d’électrodes modifiées, elles laissent entrevoir la possibilité de mimer totalement le système CYP450.

Les résultats fournis par ces techniques hybrides et par voltampérométrie cyclique sont complémentaires, ils procurent un éventail d'informations d'une utilité estimable pour une application dans des études prédictives précoces de candidats médicament.
Doctorat en Sciences biomédicales et pharmaceutiques
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Toxicities of sulfur-based drugs have been attributed to formation of highly reactive sulfur oxo-acids and depletion of glutathione by the formation of reactive metabolites. Metabolic activation of these sulfur centers to conceivably toxic reactive metabolites (RMs) that can covalently modify proteins is considered the initial step in drug-induced toxicity. Despite considerable effort and research, detection and characterization of these RMs during drug development and therapy remains a challenge. Methimazole (MMI) and 6-propyl-2-thiouracil (PTU) are two commonly used antithyroid, sulfur-based drugs. Though effective, these drugs are associated with idiosyncratic toxicity. PTU has acquired a black box warning and physicians are calling for its withdrawal. RMs resulting from bioactivation of these drugs have been implicated in the aforementioned adverse reactions. Unfortunately, isolating and detecting RMs using traditional analytical techniques has not been successful due to their high reactivity and short life span, typically less than a minute. Current approaches in drug metabolism studies use microsomal incubations to generate RMs, which are then trapped using nucleophiles. Antithyroid drugs, however, are known to deactivate enzymes involved in their oxidation. Moreover, due to the complex nature of biological matrices and low abundance of possible toxic conjugates, this technique results in poor selectivity and sensitivity. This study developed and optimized an analytical method based on coupling electrochemical redox reactions and mass spectrometry to generate, detect and identify RMs from antithyroid drugs. The metabolites were also compared to those that were generated using chemical oxidants and biological microsomes. Mimicry of enzymatic oxidation of the antithyroid drugs was carried out by electrochemically oxidizing them using a coulometric cell coupled on-line to electrospray ionization mass spectrometry (EC/ESI-MS). Oxidation of MMI and subsequent trapping with nucleophile resulted in formation of adducts with N-acetylcysteine, revealing reactive metabolites. The most-postulated metabolite, sulfenic acid, had never been isolated or detected until now, using electrochemistry on-line with electrospray ionization. The results showed that bioactivation of MMI proceeds predominantly through the S-oxide and not through formation of thiyl radicals. These same trapping experiments were also conducted with PTU, but no conjugates were detected. The lack of conjugates from PTU does not preclude formation of RMs, but asserts radical pathway might be dominant in EC oxidation. A double mixing stopped flow was used to investigate the kinetics and mechanism of reaction of the MMI and the biologically relevant hypochlorous acid (HOCl), a product of oxidation of chloride (Cl-) ions by myeloperoxidase. The products from the chemical oxidations were compared to the electrochemically generated metabolites, some differences were apparent. Human liver microsomes (HLM) were also used, to investigate oxidation of PTU. Oxidation of PTU, resulted in the supposedly toxic S-oxide, but this has never been isolated, save for speculation. A comparison of metabolites that were found with HLM to those generated electrochemically showed some degree of similarity. These results show that in vitro techniques such as chemical oxidations and electrochemistry coupled to mass spectrometry can be used to mimic oxidative metabolism and subsequent high throughput screening of reactive metabolites.

Chez l’homme, de nombreux médicaments ne sont toxiques que chez un petit nombre de patients traités. Divers facteurs de susceptibilité, génétiques et autres (doses quotidiennes, stress inflammatoire, réaction immune, maladie hépatique,…), favoriseraient la survenue de ces toxicités de type idiosyncratique, non prévisibles par des études chez l’animal. Leur prédiction et la caractérisation des mécanismes impliqués représentent donc un challenge majeur. Dans ce travail, nous avons étudié in vitro l’influence d’un stress inflammatoire sur le potentiel cytotoxique, cholestatique et stéatosique de trois médicaments connus par leurs effets de type idiosyncratique au niveau du foie, le diclofenac (DCF), la trovafloxacine (TVX) et l’amiodarone (AMD) en utilisant comme modèles expérimentaux les cellules humaines HepaRG différenciées, métaboliquement compétentes, et pour comparaison les cellules HepaRG non différenciées, les cellules HepG2, les hépatocytes humains primaires ainsi qu’un autre modèle cellulaire eucaryote la levure Saccharomyces cerevisiae. Nos résultats montrent que les cellules HepaRG différenciées sont moins sensibles au DCF que les cellules métaboliquement non compétentes et que cette toxicité implique la voie intrinsèque de l’apoptose, associée à la génération de ROS et d’un stress du réticulum endoplasmique. Elle est aggravée par le TNF-α via la voie apoptotique extrinsèque. La toxicité de DCF est aussi augmentée lors d’un co-traitement avec TVX et encore plus en présence de TNF-α. En revanche, cette cytokine ne potentialise pas les effets cholestatiques des 2 molécules, caractérisés notamment par une dilatation des canalicules biliaires et une inhibition de l’activité de certains transporteurs d’acides biliaires (BSEP, NTCP). Un stress inflammatoire induit par le lipopolysaccharide bactérien aggrave aussi les effets cytotoxiques et stéatosiques de l’AMD via une production de ROS, une inhibition de l’oxydation des acides gras et une accumulation des triglycérides, aboutissant à un contexte de stéatohépatite. De plus, une aggravation de la toxicité de DCF a également été observée dans Saccharomyces cerevisiae portant une mutation au niveau de certains transporteurs de la phase III, tel que Pdr5, et surtout après co-traitement avec la N-acétyl-cystéine via une voie qui pourrait être dépendante des perturbations des ponts di-sulfure au niveau de certaines protéines clés (transporteurs, protéines de signalisation ou facteurs de transcription, ...). Au total, tous ces résultats suggèrent que des facteurs environnementaux tel qu’un stress inflammatoire, et génétiques peuvent moduler la réponse toxique à des médicaments non seulement en induisant des stress oxydants et du réticulum endoplasmique mais aussi en modifiant leur métabolisme et donc les interactions entre médicaments, et certaines voies de signalisation essentielles
In human, many drugs are toxic for only rare patients. Genetic and various other factors (daily doses, inflammatory stress, immune reaction, liver diseases) are thought to favor such idiosyncratic toxicity that is not predictable in animals. Its prediction and mechanisms involved are very challenging. In this work, we have investigated in vitro the influence of an inflammatory stress on cytotoxic, cholestatic and steatotic effects of 3 drugs which are known to cause idiosyncratic hepatotoxicity, i.e. diclofenac (DCF), trovafloxacin (TVX) and amiodarone (AMD), using as experimental models, metabolically competent differentiated HepaRG cells, and for comparison, undifferentiated HepaRG cells, HepG2 cells, primary human hepatocytes as well as a non hepatic eukaryotic cell, the yeast Saccharomyces cerevisiae. Our results show that differentiated HepaRG cells were less sensitive than their undifferentiated counterparts and that toxicity involved intrinsic apoptosis., associated with ROS generation and endoplasmic reticulum stress and was aggravated with TNF-α via extrinsic apoptosis.. DCF toxicity was augmented by co-treatment with TVX and further by co-addition of TNF-α. By contrast, this cytokine did not potentiate cholestatic effects of either drug, typified by dilatation of bile canaliculi and inhibition of some bile acids transporters (BSEP, NTCP). An inflammatory stress induced by the bacterial lipopolysaccharide aggravated cytotoxicity and steatosis induced by AMD, via ROS generation, fatty acid oxidation and triglycerides accumulation leading to a steatohepatitis-like state. Moreover, DCF toxicity was also augmented in S. cerevisiae containing mutations of transporters of phase III, such as Pdr5, and especially after co-treatment with N-acetyl cysteine, via a pathway that is probably dependent on alterations of di-sulfure bounds in critical proteins (transporters, signaling proteins, transcription factors). Together, all the results suggest that environmental factors, such as inflammatory stress or genetic factors can modulate the toxic response to drugs by inducing oxidative and endoplasmic reticulum stress as well as by modifying metabolism, drug-drug interactions and key signaling pathways

The fungus Cunninghamella elegans has in many studies shown to have abiotransformation similar to the metabolism of mammals. If the biotransformation isgeneral, it enables the production of metabolites by the fungus and the use asreference material. The purpose of the project were to examine whether themetabolic process of C. elegans is general, with respect to the formation ofglucosides, and can be applied to different classes of drugs. During the project, theanalyses were performed on a UPLC Q-TOF, run in both MSE and MSMS mode. Themobile phase used consisted of MeOH and 0.1 % formic acid in MQ water. Toincrease the concentration of possible glucosides, the samples were subjected to anacidic or alkaline SPE. Glucosides were detected in the fungal incubates of diclofenac,buprenorphine, norbuprenorphine and oxazepam. For diclofenac, besides twodifferent glucosides (diclofenac glucoside and hydroxylated diclofenac glucoside), ahydroxylated metabolite and a hydroxylated metabolite conjugated with sulfate werediscovered. In the samples containing buprenorphine, the phase I metabolitenorbuprenorphine was also encountered. Further, in the fungal incubates ofdexamethasone a defluorinated metabolite was identified, which is a metabolicpathway never before described for C. elegans.ISSN: 1650

In the first part of this work, magnetized nanoporous silica based microparticles (MMPs) are used for horseradish peroxidase (HRP) immobilization and applied in amperometric peroxidase-based biosensors. A homemade magnetized carbon paste electrode permits the MMPs attraction close to the electrode surface. The resulting original biosensor is applied to the investigation of enzymatic oxidation of model drug compounds namely, clozapine (CLZ) and acetaminophen (APAP) by HRP in the presence of hydrogen peroxide. The biosensor operates at a low applied potential and the signal corresponds to the electro-reduction of electroactive species enzymatically generated. The biosensor allows performing the quantitation of the two drug compounds in the micromolar concentration range. It allows also the study of thiol compounds based on the inhibition of the biosensor response. Interestingly, distinct inhibition results are observed for HRP entrapped in the silica microparticles compared to the soluble HRP.

We expect that this type of biosensors holds high promise in quantitative analysis and in biotransformation studies of drug compounds.

In the second part of this thesis work, HRP immobilized magnetic nanoparticles are injected on-line and magnetically retained, as a microreactor, in the capillary of a CE setup. The purpose of such a configuration is to develop an analytical tool for studying “in vitro” drug biotransformation. The advantages expected are (i) minimum sample (drug compound) and biocomponent (enzyme) consumption, (ii) high analysis throughput, (iii) selectivity and sensitivity. In order to illustrate the potential of such an instrumental configuration, it has been applied to study acetaminophen as model drug compound. The mechanistic information obtained by the HRP/H2O2 system is in agreement with literature data on acetaminophen metabolization. Horseradish peroxidase kinetic studies are realized by this setup and the apparent Michaelis constant is determined. Capillary electrophoresis permitted the identification of APAP off-line biotransformed products such as N-acetyl-p-benzoquinone imine (NAPQI), the APAP dimer and APAP polymers as inferred from literature data. The formation of the APAP dimer was further confirmed by electrospray ionization mass spectrometry.

Doctorat en Sciences biomédicales et pharmaceutiques
info:eu-repo/semantics/nonPublished

Em face das recentes exigências das agências regulatórias quanto à aprovação de novos fármacos, os estudos de biotransformação têm-se tornado uma etapa indispensável para a identificação e otimização de compostos bioativos. O objetivo desses estudos é identificar, já nas fases iniciais da descoberta de fármacos, candidatos que apresentam propriedades indesejáveis como a (i) presença de metabólitos ativos ou tóxicos; (ii) inibição de enzimas metabolizadoras; (iii) depuração metabólica inadequada, entre outras. Neste estudo, foi realizada a caracterização metabólica e a identificação de possíveis inibidores das enzimas do citocromo P450 de oito promissores candidatos a fármacos, identificados através de ensaios virtuais como inibidores da TcGAPDH, Cruzaina e TcDHODH, todas do Trypanosoma cruzi, agente causador da doença de Chagas. Esses compostos foram testados contra as três principais isoformas do citrocromo P450: CYP 3A4, CYP 2D6 e CYP2C9. Os valores de IC50 de 1,4 µM e 1,3 µM contra a CYP2C9 foram encontrados para os compostos Nequimed53 e Nequimed125, enquanto o Nequimed42 inibiu a CYP 3A4 com um valor de IC50 de 7,12 µM. Posteriormente foi conduzida a caracterização metabólica dos compostos Nequimed53 e 125 com foco na identificação dos principais metabólitos, sítios de metabolismo e vias de biotransformação através da técnica de LC-ESI-QqTOF-MS. Para ambos os compostos, a biotransformação por microssomas extraídos de fígado de ratos deu-se preferencialmente por uma única via dependente de NADPH. No caso do Nequimed54, o metabólito formado apresentou uma variação da razão m/z de +16, indicando a ocorrência da hidroxilação do composto parental, enquanto que para o composto Nequimed125, o metabólito formado apresentou uma variação da razão m/z de -28, condizente com a perda de um fragmento etila do composto parental.
In the light of recent demands from regulatory agencies for the acceptance of new drugs, the biotransformation studies have become an essential step for the identification and optimization of bioactive compounds. The objective of these studies is to identify compounds that have undesirable properties such as (i) the presence of toxic or active metabolites, (ii) inhibition of metabolizing enzymes, (iii) excessive metabolic clearance, inter alia. In this study we characterized the metabolism and cytochrome P450 inhibition of eight compounds identified by virtual screening as inhibitors of TcGAPDH, Cruzain and TcDHODH which are of interest as targets for intervention in treatment of Chagas Disease. These compounds were tested against cytochrome P450 isoforms 3A4, 2D6 and 2C9. IC50 values of 1.4 µM and 1.3 µM against CYP 2C9 were observed for Nequimed53 and Nequimed125.while Nequimed42 inhibited CYP 3A4 with an IC50 of 7.1 µM. Subsequently, we characterized the in vitro metabolism of Nequimed53 and 125 with a focus on metabolite identification and biotransformation pathways using the LC-ESI-MS-QqTOF technique. For each, the biotransformation by rat liver microsomes occurred by a single NADPH-dependent pathway. For Nequimed54, the observed metabolite [M+16]+ indicated hydroxylation of parent compound. The metabolite [M-28]+ observed for Nequimed125 indicated desethylation of the parent compound.

Veterinary pharmaceuticals are routinely used in livestock production to treat diseases, prevent infections, and promote growth. However, the potential release of pharmaceuticals from agricultural activities has raised concerns because they may pose detrimental effects to the ecosystems and human health, for example fostering the evolution of antibiotic-resistant bacteria in the natural environment. A better understanding of the environmental fate of veterinary pharmaceuticals is critical to properly assess and mitigate their risks. This dissertation focuses on a major group of veterinary pharmaceuticals, ionophore antibiotics (IPAs), which is sold at over 4 million kilograms per year and constitutes more than one third of the total antibiotic consumption by the livestock industry in the U.S. Despite the extensive usage of IPAs, their environmental fate was not well-understood. Therefore, this study aimed at achieving a comprehensive understanding of the occurrence, persistence, and transformation of IPAs from poultry litter before and after applications to the agricultural lands. Three of the most commonly used members of IPAs were investigated in this study: monensin (MON), salinomycin (SAL), and narasin (NAR). Based on the common management practices of poultry litter, the potential abiotic and biotic transformation reactions of IPAs were examined under varying conditions relevant to the water-soil-litter systems. This dissertation consists of three sections. First, a robust analytical method was developed to quantify IPAs in various environmental compartments, especially in high organic-containing matrices such as poultry litter, and soil and runoff from litter-fertilized lands. Efforts were made to optimize the analytical method with respect to improving extraction recovery, reducing matrix effects, and validating a surrogate standard. Second, lab-scale experiments were set up to determine the chemical properties of IPAs in aqueous environments and to study the abiotic transformation of IPAs, including hydrolysis and photolysis. The results showed that IPAs are prone to hydrolytic transformation in acidic environments, which are likely to be encountered in acidic soils, alum-amended litter (alum: Al₂(SO₄)₃•12H₂O), and acidic runoff. Multiple transformation pathways were proposed based on the identified hydrolysis products. It is also noteworthy that the hydrolysis products of MON still exhibited a toxic effect on the selected microorganism (Bacillus subtilis). SAL and NAR were found to undergo direct photolysis under both UV light and sunlight irradiation. In natural water matrix, IPAs were also degraded by indirect photolysis with hydroxyl radicals generated by light-excited nitrate. Dissolved organic matter can shield IPAs from light and slow down their photolysis. Third, the biodegradation potential of IPAs was first tested in litter and soil microcosms. Factor analysis was conducted to delineate the interaction of water and temperature on IPA degradation in the litter. Litter-fertilized and non-fertilized soil microcosms were compared on the degradation of MON and SAL. Furthermore, the inhibition and biotransformation potential of IPAs were assessed under different redox conditions with litter-enriched cultures. Inhibition tests focused on examining IPAs’ impact on microbial community functions, including denitrification, sulfate-reduction, and methane production. Biodegradation tests were conducted with different electron acceptors, including oxygen, nitrate, sulfate, and organic carbons, with efforts to elucidate primary biotransformation products. On the basis of the results obtained in this study, several recommendations on litter management and IPA selection were made to help mitigate the release and transport of IPAs, as well as enhance their degradation. Overall, this study significantly improved the understanding of the environmental fate of IPAs and the obtained knowledge can aid proper selection of IPAs and management strategies in future applications to minimize the risks of antibiotic micropollutants in the environment.

Orientador: Fábio Cesar Gozzo
Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química
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Resumo: Este trabalho foi dividido em dois capítulos, tendo como temática geral a aplicação de técnicas modernas baseadas em espectrometria de massas (MS) no estudo da biotransformação de fármacos (capítulo I) e em proteômica estrutural por ligação cruzada e mobilidade iônica (capítulo II). No capítulo I, foram estudadas rotas de fragmentação por dissociação induzida por colisão (CID), perfis de metabólitos in vivo em ratos e farmacocinética de derivados de 4-anilinoquinazolina, candidatos a inibidores da enzima adenosina quinase (AK), tendo por essa razão potencial terapêutico no tratamento de doenças como hipertensão, Diabetes mellitus, psoríase e doenças inflamatórias crônicas. O comportamento desses compostos em MS foi inicialmente avaliado com base em suas rotas de fragmentação em fase gasosa por MS sequencial, com auxílio de cálculos teóricos para íons precursores e fragmentos em fase gasosa. Esse conhecimento foi então aplicado na determinação dos perfiis de metabólitos de fases I e II in vivo em ratos e de sua farmacocinética utilizando-se métodos de cromatografia líquida de ultra eficiência acoplada a MS (UPLC-MS). Os resultados permitiram estabelecer as principais vias de fragmentação por CID para essa classe de compostos, bem como os principais metabólitos observados in vivo. No capítulo II, foram realizados estudos fundamentais em proteômica estrutural por MS. Nesse âmbito, o efeito de modificações covalentes advindas de reações de ligação cruzada nas conformações de proteínas-modelo foi investigado empregando-se a técnica de mobilidade iônica acoplada a MS (IM-MS) em duas abordagens instrumentais distintas, que permite determinar as seções de choque de colisão (CCS) de íons em fase gasosa. Os resultados obtidos dos experimentos de IM-MS, aliados a dados provenientes de simulações de dinâmica molecular (MD) dos sistemas em questão, permitiram concluir que as modificações de ligação cruzada aumentam a resistência dos íons de proteína em fase gasosa ao processo de desenovelamento, e geram íons mais compactos em fase gasosa (menor CCS). Um modelo foi proposto para explicar esse fenômeno, correlacionando as conformações observadas com a carga líquida e densidade de carga dos íons de proteínas em fase gasosa
Abstract: This work was divided in two chapters, both grouped under the general theme of application of modern mass spectrometry (MS)-based techniques to the study of drug biotransformation (chapter I) and in structural proteomics by chemical cross-linking and ion mobility (chapter II). In chapter I, collision-induced dissociation (CID) routes, in vivo rat metabolite profiles and pharmacokinetics of a series of 4-anilinoquinazoline derivatives were studied. These derivatives are potential adenosine kinase (AK) inhibitors, having therapeutic potential in treatment of diseases such as hypertension, Diabetes mellitus, psoriasis and chronic inflammatory diseases. The mass spectrometric behavior of such derivatives was initially evaluated in terms of their fragmentation routes by sequential MS, aided by theoretical calculations for gas phase precursor and fragment ions. This knowledge was then applied in the determination of in vivo phase I and II metabolite profiles in rats, as well as pharmacokinetics, using ultra performance liquid chromatography coupled to MS (UPLC-MS). Results allowed the establishment of main CID fragmentation routes for this class of compounds, as well as the main metabolites observed in vivo. The focuses of chapter II were fundamental studies in structural proteomics by a combination of chemical cross-linking, ion mobility and MS. More specifically, the effect of covalent modifications introduced by chemical cross-linking in the conformations of model proteins was investigated by ion mobility-MS (IM-MS) techniques, which allows the determination of collision cross sections (CCS) for gas phase ions. Results from IM-MS experiments, together with data from molecular dynamics (MD) simulations of the studied systems, indicate that the cross-linking modifications increase the resistance of protein ions to gas phase unfolding, also generating more compact ions in the gas phase (smaller CCS). A model was developed to explain this phenomenon, correlating the observed conformations with net charge and charge density of the gas phase protein ion
Doutorado
Quimica Organica
Doutor em Ciências

Introduction: The aim of this study was to evaluate the role of genetic and lifestyle factors in the risk of onset and progression of colorectal and pancreatic cancer. The first part deals with the etiological factors and the importance of polymorphisms in biotransformation enzymes and genetic alterations in the gene CHEK2 in the origin of these malignancies. In the second part, the ABC transporter genes were analyzed as potential prognostic and predictive markers of a treatment's outcome. Materials and methods: The polymorphisms and other genetic alterations were detected using real-time PCR, allelespecific PCR and PCR-RFLP methods in DNA which was extracted from the blood of patients. The frequency of polymorphisms was evaluated and their importance was assessed with regard to the available epidemiological data. Gene expressions were determined by qPCR in paired samples of tumor tissue and adjacent non-tumorous parenchyma. Results: A majority of the observed polymorphisms failed to show a relationship between their presence and the risk of any of these malignancies. CYP2A13 variant allele*7 coding inactive enzyme was found in 7 of 265 controls and in none of 235 pancreatic carcinoma patients. In contrast, GSTP1-codon 105 Val variant allele and GSTT1-null genotype were associated with an elevated...

Charles University Faculty of Pharmacy in Hradec Králové Department of Pharmacology & Toxicology Student: Anna Giannitsi Supervisor: RNDr. Jakub Hofman, Ph.D Title of diploma thesis: The role of biotransformation enzymes in the resistance of cancer cells against standard cytostatics Drug resistance is currently one of the major problems of chemotherapy. Tumor cells are able to defend themselves against the effect of cytostatic drugs due to various mechanisms which leads to a failure of anticancer therapy. The effort to describe new mechanisms of resistance and to develop new therapeutic methods, which would limit this therapeutic obstacle, is logically the subject of many studies. The activity of drug metabolizing enzymes and the subsequent decrease of intercellular concentration of anticancer drugs belongs to one of the possible mechanisms of pharmacokinetic resistance. Enzymes of I. and II. phase of biotransformation participate in this phenomenon. Cytochromes P450, main enzymes of the I. phase, play a major role in the metabolism of many cytostatic agents producing either pharmacologically active or inactive metabolites. Increased expression in tumors and the involvement of individual isoforms into the overall metabolism of cytostatic, which is deactivated by their activity, seems to be one of the...

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We identify cytochrome P450 1A1 (CYP1A1) as a target for tumor-selective drug development in bladder cancer and describe the characterization of ICT2700, designed to be metabolized from a prodrug to a potent cytotoxin selectively by CYP1A1. Elevated CYP1A1 expression was shown in human bladder cancer relative to normal human tissues. RT112 bladder cancer cells, endogenously expressing CYP1A1, were selectively chemosensitive to ICT2700, whereas EJ138 bladder cells that do not express CYP1A1 were significantly less responsive. Introduction of CYP1A1 into EJ138 cells resulted in 75-fold increased chemosensitivity to ICT2700 relative to wild-type EJ138. Negligible chemosensitivity was observed in ICT2700 in EJ138 cells expressing CYP1A2 or with exposure of EJ138 cells to CYP1B1- or CYP3A4-generated metabolites of ICT2700. Chemosensitivity to ICT2700 was also negated in EJ138-CYP1A1 cells by the CYP1 inhibitor alpha-naphthoflavone. Furthermore, ICT2700 did not induce expression of the AhR-regulated CYP1 family, indicating that constitutive CYP1A1 expression is sufficient for activation of ICT2700. Consistent with the selective activity by CYP1A1 was a time and concentration-dependent increase in gamma-H2AX protein expression, indicative of DNA damage, associated with the activation of ICT2700 in RT112 but not EJ138 cells. In mice-bearing CYP1A1-positive and negative isogenic tumors, ICT2700 administration resulted in an antitumor response only in the CYP1A1-expressing tumor model. This antitumor response was associated with detection of the CYP1A1-activated metabolite in tumors but not in the liver. Our findings support the further development of ICT2700 as a tumor-selective treatment for human bladder cancers.