Efeitos cotton nas enzimas piridínicas e compostos relacionados / Cotton effects on pyridinium coenzymes and related compounds

Adelaide Faljoni-Alario

15 October 1976

O produto de redução da nicotinamida adenina dinucleotídio (NADH) foi convertido no seu derivado hidratado NADH-X (6-hidroxi-l,4,5,6-tetraidronicotinamida adenina dinucleotídio) por ação de íons polibásicos tais como: fosfato, arsenato etc, ou por ação enzimática da gliceraldeído-3-fosfato desidrogenase (GPD). A cinética da hidratação foi acompanhada pelo aumento de absorbância (ΔA285 nm) e o aparecimento de um efeito Cotton a 285 nm , notando-se que quando se parte do anômero β da coenzima, o efeito Cotton positivo só se desenvolve nos estágios finais da reação na presença de enzima. Com base nesses resultados postulou-se a formação de um intermediário que se transforma num produto final, o qual mostra um efeito Cotton positivo a 285 nm. Supõe-se que essa última transformação seja uma epimerização β→α, de maneira que a adição de água não afeta inicialmente a configuração do átomo C1, da ribose. Contudo, após a hidratação, o produto se transforma no epímero α, que é termodinamicamente mais estável. Na ausência da enzima, o efeito Cotton aparece em estágios anteriores, sugerindo que a hidratação, sendo lenta, dá oportunidade à epimerização. Consequentemente não há tanto acúmulo deste intermediário, que apresenta efeito Cotton praticamente nulo. A hidratação do anômero α-NADH, na presença de GDP, mostrou um aumento de absorbância a 285 nm mais rápido do que para a forma β. Por outro lado, o efeito Cotton positivo só começou a aparecer após desenvolvimento de 60% do ΔA285 nm. Isto indicou que também para α-NADH há formação de um intermediário, o qual apresenta um efeito Cotton nulo. Quando β-NADH foi hidratado na ausência da enzima, observou-se um comportamento semelhante, porém, menos marcante com relação ao aparecimento do efeito Cotton. O fato de GPD e íons polibásicos produzirem efeitos semelhantes sobre os anômeros α e β, sugere que a ação enzimática da GPD não é estereoespecífica, produzindo uma mistura de epímeros em C6. Explica, também, o efeito Cotton nulo quando já se tem grande parte da hidratação efetuada. Desta maneira pôde-se afirmar (i) que o intermediário é uma mistura de epímeros em C6; (ii) que com o tempo predomina o epímero termodinamicamente mais estável. Os mesmos estudos foram desenvolvidos com NADPH, desamino-NADH e NMNH, para esclarecimentos a respeito da influência de grupos fosfato, amino e açúcar na catálise da hidratação e dos centros responsáveis pelo efeito Cotton positivo a 285 nm, nos piridinos nucleotídios. Observou-se que NADPH tem comportamento semelhante ao β-NADH, indicando que o grupo fosfato não tem papel importante nas catálises química e enzimática. No caso do mononucleotídio e desamino-dinucleotídio não houve diferença significativa entre as velocidades de hidratação química e enzimática, o que siginifica ser importante a presença do amino grupo da adenina para catálise enzimática no caso de NADH. Os derivados acima, também, apresentaram efeito Cotton positivo nos estágios finais da reação. Com base no fato, que o mononucleotídio também apresentou efeito Cotton positivo, de mesma intensidade dos dinucleotídios, pôde-se afirmar que o açúcar ligado ao anel da nicotinamida é o responsável pela dissimetria do produto formado. Traçou-se o espectro de absorção circular dicróica do isômero 1,6-NADH, ainda desconhecido, para obter-se informações a respeito da sua estrutura. Através dos valores de elipticidades molares, concluiu-se que é mais rígida do que a do 1,4-NADH, presumivelmente, devido a ligação simples, que une os anéis piridínico e ribosídico, ter rotação mais impedida, como consequência da maior proximidade do par de hidrogênios da piridina, com a ribose. O estudo da adição de CN- aos piridinos nucleotídios e compostos relacionados, usando técnica de dicroismo circular, mostrou haver estereosseletividade na adição. O espectro de absorção circular dicróica do aduto β-NAD+/CN- mostrou uma banda negativa larga com máximo em torno de 330 nm. Esta banda é assimétrica, o que permite um desdobramento em outras duas, com máximos a 325 e a 345 nm, de intensidade semelhantes. Em analogia com a redução dos piridinos nucleotídios, que ocorre nas posições 2, 4 e 6, pôde-se afirmar que a adição de CN-, também, ocorre em outras posições e não exclusivamente em 4. A banda de dicroismo circular na região de 345 nm, pareceu indicar a presença do isômero 1,6. O fato deste estar em concentração baixa a ponto de não ser detectável espectrofotometricamente, indicou que a força rotacional é bem maior do que para o isômero 1,4. Tal fato deve estar relacionado com a maior proximidade do CN- ao anel carboidrático. No aduto da forma α do piridino nucleotídio, o espectro de dicroismo circular apresentou uma banda negativa, com máximo de 342 nm e uma inflexão a 325 nm. Essa assimetria mostrou, claramente, a existência dos dois isômeros e, que a adição de CN- em C6 é bastante estereosseletiva. Além da estereosseletividade, pode estar contribuindo, também a menor mobilidade rotacional do anel diidronicotinamídico, quando se tem aduto em C6. A estereosseletividade da adição de cianeto veio corroborar com a proposição de um equilíbrio rápido entre as conformações aberta e fechada para os piridino nucleotídios. A possível existência de uma transição fraca, associada ao núcleo diidronicotinamídico, foi confirmada detectando-se um efeito Cotton associado a ela. Esse efeito foi observado para α-NADH, β-NADH e seus correspondentes adutos de CN-. Realizando-se o mesmo estudo para o complexo de β-NADH.Cu++, verificou-se que o efeito Cotton é 15 vezes mais intenso, confirmando assim, a detecção pioneira dessa transição fraca, presumivelmente de natureza singlete-triplete. / The reduction product of nicotinamide adenine dinucleotide (NADH) is converted into the hydration product NADH-X (6-hydroxy-1,4,5,6-tetrahydronicotinamide adenine dinucleotide) by the action of polybasic ions such as phosphate, arsenate etc., or by enzymatic catalysis with glyceraldehyde-3-phosphate dehydrogenase (GPD). The hydration kinetics were followed by the increase in absorbance at 285 nm. Starting with the β-anomer of the coenzyme, the transition at 285 nm begins to exhibit a positive Cotton effect only in the later stages of the reaction. On the basis of the results, the formation of an interrnediate not exhibiting a Cotton effect at 285 nm is postulated. Since the hydration would not be expected to change the configuration at C1, of the ribose, the appearance of the Cotton effect is presumably due to an epimerization from the β-epimer to the thermodynamically more stabe α-epimer. In the absence of enzyme, the Cotton effect appears at somewhat lower conversions, suggesting that the slower hydration reaction provides greater opportunity for the occurrence of the epimerization. The increase in absorbance at 285 nm is more rapid for the hydration of the α-anomer of NADH than for the β-form in the presence of GPD. A positive Cotton effect is only observed for the forrner after the reaction has gone to about 60% completion. This indicates that an intermediate not exhibiting a Cotton effect is also formed in the case of α-NADH. Similar behavior was observed in the non-enzymatic hydration, however, as in the case of β-NADH, the onset of the Cotton effect occurred at lower conversions. The fact that GPD and polybasic ions produce similar effects on both the α and β anomers suggests that the enzymatic action of GPD is non-stereospecific, producing a mixture of epimers at C6. This also explain the absence of a Cotton effect even though significant hydrations has occurred. Thus we conclude (i) that the intermediate is a mixture of C6 epimers and (ii) that the more thermodynamically stable epimer predominates at long reaction times. The same studies were carried out with NADPH, deamino-NADH and NMNH to clarify the catalytic influence of the phosphate, amino, and sugar groups on the hydration and to identify the centers responsible for the positive Cotton effect at 285 nm in pyridine nucleotides. The observation that the behavior of NADPH is similar to that of β-NADH indicates that the phosphate group does not play an important role in the chemical and enzymatic catalysis. In the case of NMNH and deamino-NADH there is no significant difference between the rates of the chemical and enzymatic hydration, which implies that the presence of the amino group of adenine is important in the enzymatic catalysis of the hydration of NADH. The above derivatives also present positive Cotton effects in the later stages of the reaction. Since that mononucleotide exhibits a positive Cotton effect of intensity equal to that of the dinucleotides, it can be concluded that the sugar attached to the nicotinamide ring is responsible for the assymetry of the product. The previously unknown circular dichroic absorption spectrum of 1,6-NADH was determined in order to gain insight into its structure. From the values of the molar ellipticity it is concluded that the assymetric center of 1,6-NADH is more rigid than that of. 1,4-NADH. This is presumably due to a greater hindrance to rotation about the single bond between the pyridine and ribose rings in 1,6-NADH. A circular dichroic study of the addition of CN- to pyridine nucleotides and related compounds demonstrated the stereoselectivity of the addition. The circular dichroic absorption spectrum of the B-NAD+/CN- adduct exhibits a broad assymetric negative band with a maximum at about 330 nm. This band was interpreted in terms of two bands of similar intensity with maxima at 325 and 345 nm. By analogy with the reduction of pyridine nucleotides,which occurs at position 2,4 and 6, it is concluded that CN- addition also occurs at positions other than C4. The band at 345 nm was attributed to the 1,6-isomer. The fact that this isomer could not be detected by conventional absorption techniques indicates that it is present in low concentrations relative to the 1,4-isomer. It must have therefore has a much greater rotational strength, which is reasonable in view of the proximity of the CN- to the carbohydrate ring. The circular dichroic absorption spectrum of the α-NAD+/CN- adduct exhibited a negative band with a maximum at 342 nm and an inflection at 325 nm. This assymetry clearly demonstrated the presence of two isomers and the stereoselectivity of CN- addition at C6. Although the l,6-adduct could not be detected by conventional absorption techniques, the stereoselectivity of the addition and a large rotational strength contribute to its circular dichroic intensity. The stereoselectivity of the CN- addition corroborates the existence of a rapid conformational equilibrium between the folded and unfolded forms of pyridine nucleotides. A Cotton effect associated with the weak electronic transition attributed to the dihydronicotinamide nucleus was observed for α-NADH, β-NADH, and the corresponding CN- adducts, confirming the existence of the transition. For the β-NADH.CU++ complex, the Cotton effect was found to be 15 times more intense, thus confirming the original detection of this weak transition, which presumably has singlet-triplet character.

Coenzimas piridínicos

Dicroísmo circular

Efeito cotton

Nicotina ademina Dimedeotideo

Circular dichroism

Cotton effect

Nicotine adenine Dimedeotideo

Pyridine

Design, synthesis and mesomorphic behavior of 2,5-disubstituted pyridine liquid crystals

Getmanenko, Yulia A.

30 July 2007

No description available.

Chemistry, Organic

phenylpyridine LCs

thiophene-pyridine LCs

pyridinyl stannanes

selective Negishi coupling

liquid crystal semiconductors

smectic liquid crystals

SYNTHESIS AND DECOMPOSITION KINETICS of ESTER DERIVATIVE of PROCARCINOGEN and PROMUTAGEN, PhIP, 1-methyl-6-phenylimidazo[4,5-b]pyridine

NGUYEN DUONG, THACH-MIEN

14 February 2007

No description available.

Chemistry, Organic

PhIP

2-OH-PhIP

nitrenium ion

tetrazole

Synthèse et étude des relations structure-activité de nouvelles 3-nitroimidazo (1,2-a) pyridines anti-kinétoplastidés / Synthesis and structure-activity relationships study of new anti-kinetoplastid 3-nitroimidazo[1,2-a]pyridines

Fersing, Cyril

11 July 2018

Les maladies tropicales négligées causées par les protozoaires kinétoplastidés du genre Leishmania et Trypanosoma représentent une menace pour près d’un demi-milliard de personnes en zone intertropicale, entrainant jusqu’à 50 000 décès par an. Parmi les molécules en développement clinique pour traiter ces pathologies, le fexinidazole est une prodrogue appartenant à la famille des 5-nitroimidazoles et qui exerce son action anti-infectieuse via une étape de bioactivation catalysée par des nitroréductases (NTR) parasitaires, enzymes dont le co-facteur est une flavine. Afin d’identifier de nouveaux nitrohétérocycles antiparasitaires substrats des NTR, une petite chimiothèque d’imidazo[1,2-a]pyridines synthétisées au laboratoire a subi un criblage in vitro ayant conduit à l’identification d’une molécule Hit, à la fois active sur Leishmania donovani et Trypanosoma brucei brucei. Ce composé a servi de point de départ à un travail de pharmacomodulation, dans un premier temps en position 8 du cycle imidazo[1,2-a]pyridine : l’introduction de groupements variés à l’aide de réactions de couplage pallado-catalysées de Suzuki-Miyaura, Sonogashira et Buchwald-Hartwig ou des réactions de SNAr, a permis de mettre en lumière plusieurs composés « tête de série » au profil biologique nettement amélioré. Dans un second temps, le travail de pharmacomodulation entrepris a été étendu aux positions 2, 3 et 6 du cycle imidazo[1,2-a]pyridine en vue de compléter les données de relations structure-activité, d’étudier en particulier l’impact du potentiel rédox et d’optimiser les paramètres physico-chimiques et pharmacocinétiques in vitro des meilleurs composés. / The kinetoplastids of the Leishmania and Trypanosoma genus are the causative agents of neglected tropical diseases that threaten nearly half a billion people in the intertropical zone, resulting in 50 000 deaths per year. Among the molecules in clinical development to treat these pathologies, fexinidazole is a prodrug belonging to the 5-nitroimidazoles family, which exerts its anti-infectious action via a bioactivation step catalyzed by parasitic nitroreductases (NTR), enzymes whose cofactor is a flavin. In order to identify novel nitroheterocycles as parasitic NTR substrates, a small chemical library of imidazo[1,2-a]pyridines synthesized by our laboratory was screened in vitro, leading to the identification of a Hit molecule active both on Leishmania donovani and Trypanosoma brucei brucei. This compound served as a starting point for a pharmacomodulation work, initially in position 8 of the imidazo[1,2-a]pyridine ring: the introduction of various chemical groups using the pallado-catalyzed coupling reactions of Suzuki-Miyaura, Sonogashira and Buchwald-Hartwig, or SNAr reactions, highlighted several "lead" compounds with a significantly improved biological profile. In a second step, the pharmacomodulation work was extended to positions 2, 3 and 6 of the imidazo[1,2-a]pyridine ring in order to complete the structure-activity relationship data, to study in particular the impact of the redox potential and to optimize the physicochemical and in vitro pharmacokinetic parameters of the best compounds in order to initiate the study of their in vivo activity on a trypanosomiasis mouse model.

Nitrohétérocycles

Nitroréductases

Couplages pallado-Catalysés

Relations structure-Activité

Leishmania sp

Trypanosoma sp.

Imidazo[1;2-A]pyridine

Anti-Kinetoplastids pharmacomodulation

Nitroheterocycles

Nitroreductases

Imidazo[1

2-A]pyridine

Structure-Activity relationships

Leishmania spp

Trypanosoma spp.

Imidazo[1;2-A]pyridine

Supramolecular studies with functionalised group 15 ligands

Sanchez-Ballester, Noelia M.

January 2010

This thesis has been divided into five sections. The first chapter introduces the main themes of this thesis, including the description of the concepts of supramolecular chemistry, crystal engineering, hydrogen bonding and graph set analysis. The final section of chapter one describes a typical X-ray experiment used to determine the structures of the compounds presented in this thesis. Chapter two describes the synthesis and single crystal structures of copper(I) complexes with pyridine- and pyrazine-carboxylic acids. A series of novel solvent inclusion compounds of copper(I) complexes with pyridine- and pyrazine-carboxylic acids and the hydrogen bonding patterns adopted are also discussed. Chapter three reports the potential uses of boronic acids as building blocks for the design of novel solid-state architectures utilising hydrogen bonds. Novel copper(I) pyridine-/pyrazine-carboxylate complexes with boronic acid co-crystals are presented in which the heterodimeric boronic carboxylate R22(8) ring motif is present in all cases. Chapter four discusses the synthesis of novel ditertiary phosphines bearing functional groups with hydrogen bonding potential either via a three-step or single step synthetic route which involves a well known method of reductive amination followed by an efficient Mannich-based condensation. Complexation studies of these P,P-bidentate ligands with various transition metal centres such as Pt(II), Mo(0), Ru(II) and Au(I) are also presented. The effect on the structural motifs observed in these series of compounds by the regioselective incorporation of functional groups with potential hydrogen bonding capability such as hydroxyl and amide is also given. Finally, chapter five contains the synthesis and coordination studies of new phosphorus donor ligands leading to ideas for further work.

547.05

Synthèse totale de la lépadine B : plate-forme pour la découverte de nouvelles tranformations chimiques

Barbe, Guillaume

07 1900

Dans ce document, serons détaillées les résultats de mes travaux de recherche d’études doctorales. Tout d’abord, nous discuterons de la synthèse totale de la lépadine B, la plus courte à paraître dans la littérature à ce jour. Cette synthèse, en plus de valoriser la synthèse asymétrique de pipéridines poly-substituées développée par l’équipe du professeur Charette, mettra à profit une utilisation originale d’une séquence de fermeture-ouverture de cycle par la réaction de métathèse d’alcènes. De plus, nous détaillerons une brève étude mécanistique de cette dernière nous ayant permis la proposition d’un mécanisme peu commun de ce type de séquence réactionnel et dont les conséquences expérimentales sont impressionnantes. Au cours de cette synthèse, nous avons identifié un synthon d’une grande valeur synthétique. En effet, ne comportant pas moins que quatre centres chiraux, ce synthon pouvait être obtenu énantiopure en seulement trois étapes à partir de la pyridine. Ainsi, nous avons effectué une analyse structurale de ce synthon et avons envisagé une valorisation supplémentaire par une utilisation originale de la fragmentation de Grob. Dans ce contexte, nous avons développé une toute nouvelle synthèse de pipéridines 2,3,6-trisubstituées hautement régio- et diastéréosélective. Afin de pouvoir réaliser la précédente méthodologie, nous avons dû étudier la réduction d’une amide en présence de groupements fonctionnels sensibles dans les conditions usuelles. Heureusement, l’année précédente nous avions développée une réaction hautement chimiosélective d’amides tertaires. Cette nouvelle réaction, qui a été fondamentalement inspiré par une méthodologie du professeur Charette sur l’activation d’amides, a permis la réduction d’amides tertiaires en présence de fonctions telles les cétone, ester, nitrile, époxyde, insaturations, etc. Enfin, l’ensemble des connaissances acquises au cours de ces projets a permis l’élaboration d’une toute nouvelle stratégie de synthèse pour la préparation d’indolizidines et quinolizidines. Plus spécifiquement, nous avons développé la première séquence d’activation intramoléculaire et déaromatization asymétrique de la pyridine. Ceci permet d’avoir un accès aux squelettes indolizidine et quinolizidine avec des stéréosélectivités élevées, la nature insaturée de ces derniers laissant également place à une grande flexibilité synthétique. Dans ce contexte, nous allons détailler une très courte synthèse de trans-indolizidines. / In this document, the results of Ph.D. thesis will be detailed. First, we will discuss the synthesis of alkaloid lepadin B, the shortest to appear in the literature to date. This synthesis, in addition to validating the asymmetric synthesis of polysubstituted piperidines developed earlier by the group of Professor Charette, will highlight an original use of a ring-closing ring-opening alkene metathesis sequence. Also, a brief mechanistic study of the latter reaction will be detailed, a study which led us to propose an unusual mechanism for this reaction sequence and for which the experimental concequences are impressive. During the total synthesis of lepadin B, we identified a synthon of great synthetic value. Indeed, containing not less than four chiral centres, that synthon could be obtained enantiopure through a short three-step synthesis from pyridine. We performed a structural analysis of this synthon and we envisaged an additional validating through an original use of the Grob fragmentation. Consequently, we developed a new highly regio- and diastereoselective synthesis of 2,3,6-trisubstituted piperidines. To succesfully realize the latter methodology, it was required to perform an amide reduction in the presence of sensitive functionnalities under usual reduction conditions. Fortunatly, we had recently developed a set of conditions for the highly chemoselective reduction of tertiary amides. This new reaction, fundamentaly inspired by an amide activation methodology from Charette’s group, allowed the reduction of amides in the presence of functionalities such as ketone, ester, nitrile, epoxide, unsaturations, etc. Finaly, the knowledge acquired by conducting this research allowed for the elaboration of a new methodology for the synthesis of indolizidines and quinolizidines. Specifically, we developed the first intramolecular pyridine activation-asymmetric dearomatization reaction of the pyridine. This led us to the highly stereoselective access to indolizidine and quinolizidine backbone, the unsaturated nature of which permitting a good degree of synthetic flexibility. In that context, we will detail a short synthesis of trans-indolizidines.

Alcaloïdes

Fragmentation de Grob

Réduction d’amide

Déaromatisation de pyridines

Synthèse chimiosélective

Synthèse asymétrique

Alkaloids

Grob fragmentation

Amide reduction

Pyridine dearomatization

Chemoselective synthesis

Asymetric synthesis

Récepteurs P2Y et Cardioprotection : implication du récepteur P2Y11-like dans le préconditionnement pharmacologique induit par le NAADP extracellulaire / P2Y receptors and cardioprotection : involvement of P2Y11-like receptor in pharmacological preconditioning induced by extracellular NAADP

Djerada, Zoubir

22 May 2013

L’infarctus du myocarde (IC) représente plus de 15 % de la mortalité mondiale liés aux maladies cardiovasculaires (MC). En absence d’une rapide reperfusion des coronaires occluses, aucune intervention thérapeutique n’est capable de limiter les effets délétères de l’IC. Un des moyens les plus efficaces de la cardioprotection, étudié en recherche, est le préconditionnement cardiaque ischémique (PCI). L’adénosine libérée au cours du PCI active via ces récepteurs P1 les voies de cardioprotection. Des études mettent en évidence également l’implication des purinorécepteurs P2Y dans la cardioprotection. Les récepteurs P2Y2, 4 et 6 sont les plus étudiés dans la cardioprotection. Les récepteurs P2Y sont sensibles aux nucléotides comme l’ATP et l’UTP libérés au cours de l’ischémie. Parmi les récepteurs P2Y seul le récepteur P2Y11 est doublement couplé à l’adénylate cyclase et à la phospholipase C (PLC). Il est également le seul récepteur dont le polymorphisme génétique, induisant une perte du signal métabotropique, prédispose à plus de risques d’IC et d’inflammation dans toutes les catégories d’âge indépendamment des facteurs de risques variables de l’IC (Amisten et al., 2007). Ceci suggère un important rôle du récepteur P2Y11 dans la prévention primaire et comme cible thérapeutique de l’infarctus du myocarde. Le β-NAD, nucléotide à base de pyridine, est libéré au cours de l’ischémie comme les médiateurs de cardioprotection notamment l’adénosine, l’ATP et l’UTP. Cependant, aucune étude ne s’est intéressée spécifiquement aux rôles du P2Y11 et des nucléotides pyridiniques, comme médiateurs, dans la cardioportection alors que le NAADP, un métabolite du β-NAD, est rapporté comme agoniste (Moreschi et al., 2008) du récepteur P2Y11. Dans ce travail, nous avons mis en évidence pour la première fois l’augmentation des concentrations interstitielles des métabolites du β-NAD comme le NAADP au cours de l’ischémie. L’augmentation des concentrations du NAADP décrit une cinétique comparable à celle de l’adénosine. Le NAADP extracellulaire ([NAADP]e), appliqué avant un cycle d’ischémie/reperfusion (I/R), déclenche une cardioprotection envers les effets délétères de l’I/R. En effet, le [NAADP]e améliore les fonctions contractiles, réduit les contractures, les arythmies de reperfusion et la taille de l’infarctus, dans un modèle d’I/R cardiaque chez le rat. Ce préconditionnement pharmacologique induit par le [NAADP]e implique les récepteurs P2Y11-like. Dans un modèle de cardiomyocytes, nous mettons en évidence l’activité métabotropique spécifique du récepteur P2Y11-like déclenché par le [NAADP]e. Le [NAADP]e déclenche via le récepteur P2Y11-like l’activation de la PKCε, ERK1/2, AKT et GSK-3β, des protéines kinases de prosurvie cellulaire, ce qui explique ses effets cardioprotecteurs. La phosphorylation des protéines de prosurvie cellulaire nécessite la médiation de la PKA, de la PLC et de la src. Le NF546, un nouvel agoniste sélectif du récepteur P2Y11, déclenche une activité métabotropique semblable à celle du [NAADP]e, confirmant ainsi l’existence fonctionnelle du récepteur P2Y11-like au niveau des cardiomyocytes de rat. L’activation du récepteur P2Y11-like, que ce soit par le [NAADP]e ou le NF546, induit une augmentation des concentrations intracellulaires du β-NAD et de ses métabolites, le NADP, le NAADP, le NAAD et l’ADP ribose cyclique. Le β-NAD, le NAADP comme le NAAD, ont été impliqués dans le déclenchement au niveau intracellulaire des voies de cardioprotection comme la voie des sirtuines et de l’autophagie. Ces mécanismes peuvent être complementaires de l’effet cardioprotecteur du [NAADP]e. L’ensemble de nos données conforte le rôle cardioprotecteur du récépteur P2Y11 et suggère que le NAADP interstitiel accumulé au cours de l’ischémie pourrait avoir un rôle de facteur paracrine de survie cellulaire améliorant la survie des cardiomyocytes au cours des évènements ischémiques. / Myocardial infarction (MI) accounts for more than 15 % of global deaths related to cardiovascular diseases (CD). In the absence of a prompt reperfusion of occluded coronary arteries, none of therapeutic interventions is able to limit the deleterious effects of MI. One of the most effective means of cardioprotection, studied in research, is the ischemic cardiac preconditioning (ICP). Adenosine released during ICP triggers, via P1 receptors, cardioprotective effects. Involvement of the purinoceptors (P2Y) in cardioprotective effects has been also reported. P2Y2,4,6 receptors, the most studied P2Y receptors in cardioprotection, are activated by the nucleotides released during ischemia such as ATP and UTP. Among the P2Y receptors, P2Y11 is dually coupled to Gs and Gq proteins and is the single P2Y receptor which has been linked, via a genetic polymorphism, to an increased risk of acute myocardial infarction and elevated levels of C-reactive protein in humans in all age groups (Amisten et al., 2007). This suggests for the P2Y11 receptor an important role in primary prevention and as a therapeutic target of the P2Y11 receptor for myocardial infarction. β-NAD, a pyridine nucleotide, is released during ischemia like adenosine, ATP and UTP. However, no study has focused on the roles of P2Y11 receptor and pyridine nucleotide in mediating cardioprotective effects while NAADP, a β-NAD metabolite, has been reported as an agonist (Moreschi et al., 2008) of the P2Y11 receptor. In this work, we show, for the first time, increased interstitial concentrations of NAADP during ischemia. Interstitial kinetics of NAADP is similar to adenosine. Using a pharmacological preconditioning protocol, triggered by extracellular NAADP ([NAADP]e) before a prolonged ischemia/reperfusion (I/R), rat hearts rapidly recovered post-ischemic contractile function and displayed attenuated contracture, infarct size and arrhythmogenesis. This pharmacological preconditioning involves the P2Y11-like receptor. In cardiomyocytes culture, [NAADP]e induces specific metabotropic response of the P2Y11-like receptor. [NAADP]e triggers via the P2Y11-like receptor prosurvival protein kinases activation such as PKCε, ERK1/2, AKT and GSK-3β which explains its protective effects. Phosphorylation of prosurvival protein kinases requires the mediation of PKA, PLC and src. As with [NAADP]e, the NF546, a new selective agonist of P2Y11 receptor, triggers a metabotropic activity, thus confirming the functional existence of P2Y11-like receptor in rat cardiomyocytes. Activation of the P2Y11-like receptor, either by [NAADP]e or NF546 induced an increase in intracellular concentrations of β-NAD and its metabolites, NADP, NAADP, NAAD and cyclic ADP ribose. More, β-NAD, NAADP as well as NAAD have been involved in activation of cardioprotective pathways such as sirtuine pathways and autophagy. Taken together, our data demonstrate for the first time that the P2Y11 receptor mediates cardioprotective effects induced by [NAADP]e. NAADP is released during ischemia suggesting that [NAADP]e may act as a paracrine survival factor, prolonging cardiomyocytes lifespan during ischemic events.

Nucleotides pyridiniques

Récepteur P2Y11-like

Préconditionnement pharmacologique

Cardioprotection

Ischémie/reperfusion

Pyridine nucleotide

P2Y11-like receptor

Pharmacological preconditioning

Cardioprotection

Ischemia/reperfusion

610

Effect of ascorbic acid on 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine-induced toxicity in the brain of balb/c mouse. / CUHK electronic theses & dissertations collection

January 2004

by Chan Tak Yee Bonita. / "July 2004." / Thesis (Ph.D.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (p. 121-137). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web. / Abstracts in English and Chinese.

Vitamin C--Therapeutic use

Mice--Diseases

Pyridine

Ascorbic Acid--therapeutic use

Mice, Inbred BALB C

Líquidos iônicos tensoativos: correlação entre estrutura molecular e propriedades micelares de cloretos de 1,3-dialquilimidazólio / Surface-active ionic liquids: correlation between molecular structure and micellar properties of 1,3-dialkylimidazolium chlorides

Galgano, Paula Decot

31 October 2012

Este trabalho tem como objetivo a síntese e a determinação de propriedades micelares de líquidos iônicos tensoativos (LITs) catiônicos. Dentre as características importantes desses compostos destacamos: alta deslocalização da carga e caráter ácido no hidrogênio H2 do anel heterocíclico e a grande flexibilidade estrutural, estas são relevantes para as propriedades de soluções desses tensoativos, e, consequentemente, para suas aplicações. A influência da variação estrutural nas suas propriedades é importante para modular as propriedades micelares e, por consequência suas aplicações. A síntese de LITs foi realizada por aquecimento convencional e irradiação por micro-ondas, o último método foi o mais eficiente. Inicialmente, estudamos a influência do comprimento da cadeia carbônica (fator importante para a energia de formação de micelas), de cloretos de 1-alquil-3-metilimidazólio, tendo a cadeia n-alquílica 10 a 16 átomos de carbonos. Em seguida, comparamos as propriedades dos LITs acima mencionados com as de tensoativos convencionais, cloretos de 1-alquilpiridínio e cloretos 1-alcanoil-amidoetil benzildimetilamônio. Por fim, estudamos a influência do volume da cabeça-polar, utilizando cloretos de 1-alquil-3-hexadecilimidazólio, tendo a cadeia alquílica secundária 1 a 5 átomos de carbono. As propriedades micelares foram investigadas por tensão superficial, condutividade, calorimetria, espalhamento de luz e ressonância magnética nuclear. Os resultados mostraram que ligações de hidrogênio (devido ao H2 ácido do anel imidazólio) e as interações hidrofóbicas são relevantes para a formação de micelas e que o aumento do volume da cabeça-polar favorece a micelização e a formação de agregados pré-micelares / The objective of this work is the synthesis and determination of the micelar properties of cationic surface-active ionic liquids (SAILs). Among the important characteristics of these compounds are: high charge delocalization and acid character of hydrogen H2 of the heterocyclic ring and large structural flexibility, the latter is relevant to solution properties of these surfactants, hence to their applications. Synthesis of SAILs was carried out by conventional heating or by microwave irradiation, the later method was more efficient. Initially, we studied the influence of the chain length of the alkyl group (an important factor for the energy of micelle formation) of 1-alkyl-3-methylimidazolium chlorides, n-alkyl group having 10 to 16 carbon atoms. Then, we compared the properties of the above mentioned SAILs with conventional surfactants, 1-alkylpyridinium chlorides and 1-alkanoyl-amidoethyl benzyldimethylammonium chlorides. Finally, we studied the influence of the head-group volume, by studying 1-alkyl-3-hexadecylimidazolium chlorides, with secondary n-alkyl group having 1 to 5 carbon atoms. The micelar properties were investigated by surface tension, conductivity, calorimetry, light scattering and nuclear magnetic resonance. Our results have shown that hydrogen bonding (due to the acidic H2 of the imidazolium ring) and hydrophobic interactions are relevant to micelle formation; increasing the head-group volume favors micellization and the formation of pre-micellar aggregates

Agregados micelares

Derivados de imidazol

Derivados de piridina

Imidazole derivatives

Ionic liquids

Líquidos iônicos

Líquidos iônicos tensoativos

Micellar aggregates

Pyridine derivatives

Surface-active ionic liquids

Synthèse de ligands du récepteu de l'Urotensine II et des récepteurs de la Mélatonine. Composés à noyau pyrido[2,3-d]pyrimidine ou imidazo[1,2-a]pyridine

Griffon Du Bellay, Amaury

05 December 2008

L'Urotensine II est un peptide vasoactif que l'on retrouve chez toutes les espèces étudiées. Elle présente une partie N-terminale linéaire variable selon l'espèce et une partie C-terminale hexocyclique constante et responsable de l'activité. Parmi les ligands développés, le Palosuran, un inhibiteur sélectif du récepteur de l'Urotensine II, présente un intérêt dans le traitement de l'insuffisance rénale du patient diabétique voire dans certaines pathologies ischémiques. Dans la première partie de ce travail de thèse, une série de composés à noyau pyrido[2,3-d]pyrimidine a été développée, tout d'abord, par analogie aux structures brevetées par Takeda puis sur le modèle du Palosuran.<br />La Mélatonine est une hormone à noyau indolique produite pendant la nuit par la glande pinéale et qui présente de nombreuses propriétés dont la plus importante est la synchronisation de l'horloge biologique avec le cycle jour-nuit. L'Agomélatine, analogue mélatoninergique à noyau naphtalénique développé par les Laboratoires Servier pour le traitement de la dépression, est un agoniste des récepteurs MT1 et MT2 et un antagoniste du récepteur 5HT2c. C'est sur ce modèle, qu'ont été développés des ligands à noyau pyrido[2,3-d]pyrimidine par substitution des sommets 2, 4 et 6, soit par alkylation, soit par couplages palladiés. La ramification de la chaîne latérale de l'Agomélatine ayant conduit à des composés actifs, il a été envisagé la synthèse d'analogues possédant la même chaîne en série pyrido[2,3-d]pyrimidine d'une part puis imidazo[1,2-a]pyridine d'autre part.

[CHIM:OTHE] Chemical Sciences/Other

Urotensine II

Palosuran

pyrido[2

3-d]pyrimidine

Mélatonine

Agomélatine

imidazo[1

2-a]pyridine

alkylation

couplages palladiés