Pharmacochimie des aurones pour la modulation d'enzymes

Aurones, a subclass of flavonoids, present a favorable pharmacological profile and a wide, promising spectrum of biological activites. During this work, we used this potential for the modulation of two major therapeutic targets. Firstly, since several hepatitis C virus protease NS3/4A inhibitors were recently marketed, the inhibition of the polymerase NS5B is now the focus of research efforts in the fight against HCV. The use of aurones against the HCV polymerase is here reported for the first time. Four generations of compounds were synthesized and evaluated, and several bioactive derivatives were found, including some natural products, with an IC50 below 5 μM. Furthermore, additional investigations regarding inhibitor – receptor interactions allowed to identify the aurones binding site, which is Thumb Site I. Secondly, although the modulation of tyrosinase in a therapeutic aim remains a matter of discussion, a number of studies considers this enzyme as a potential target for future treatments against some hardly curable diseases, such as cancer or Parkinson's disease. During this work, aurones showed a great versatility toward tyrosinase. According to their substitution pattern, the compounds embraced very different behaviours, i.e. alternative substrate, hyperbolic activator or mixed inhibitor behaviour. However a consistent model was proposed, which gathers and explains all of these behaviours. During this study, a large number of widely substituted or modified aurone derivatives were prepared, according to structure-dependant adaptative synthetic methods.Les aurones, qui constituent une sous-classe des flavonoïdes, présentent un profil pharmacologique et un spectre d'activités biologiques prometteurs. Au cours de ce travail, nous avons mis à profit ce potentiel pour la modulation de deux cibles thérapeutiques majeures. En premier lieu, depuis la mise sur le marché d'inhibiteurs de la protéase NS3/4A, l'inhibition de la polymérase NS5B du virus de l'hépatite C représente un enjeu primordial dans la lutte contre cette maladie. L'utilisation des aurones contre cette polymérase trouve ici ses premiers développements. L'évaluation de quatre générations de composés a mené à l'identification de plusieurs dérivés actifs, dont certains produits naturels, présentant un IC50 inférieur à 5 μM. L'étude des interactions ligand – récepteur a en outre permis de déterminer que les aurones se fixent probablement sur le site « Thumb I ». En second lieu, si la modulation de la tyrosinase dans un cadre thérapeutique reste actuellement hypothétique, de nombreuses études voient en cette enzyme une cible pour le traitement futur de pathologies difficilement curables, comme le cancer ou la maladie de Parkinson. Les aurones ont fait preuve lors de ce travail d'une grande versatilité face à la tyrosinase, adoptant au gré des substitutions des comportements très différents de substrat alternatif, d'activateur hyperbolique ou d'inhibiteur mixte. Un modèle cohérent a cependant été proposé, qui regroupe et explique ces comportements. Au cours de ce travail, de nombreux dérivés d'aurone diversement substitués ou modifiés ont été préparés, par le biais de méthodes de synthèse adaptées à la structure de chaque produit formé

Pharmacochemistry of aurones for modulation of enzymes

Les aurones, qui constituent une sous-classe des flavonoïdes, présentent un profil pharmacologique et un spectre d'activités biologiques prometteurs. Au cours de ce travail, nous avons mis à profit ce potentiel pour la modulation de deux cibles thérapeutiques majeures. En premier lieu, depuis la mise sur le marché d'inhibiteurs de la protéase NS3/4A, l'inhibition de la polymérase NS5B du virus de l'hépatite C représente un enjeu primordial dans la lutte contre cette maladie. L'utilisation des aurones contre cette polymérase trouve ici ses premiers développements. L'évaluation de quatre générations de composés a mené à l'identification de plusieurs dérivés actifs, dont certains produits naturels, présentant un IC50 inférieur à 5 μM. L'étude des interactions ligand – récepteur a en outre permis de déterminer que les aurones se fixent probablement sur le site « Thumb I ». En second lieu, si la modulation de la tyrosinase dans un cadre thérapeutique reste actuellement hypothétique, de nombreuses études voient en cette enzyme une cible pour le traitement futur de pathologies difficilement curables, comme le cancer ou la maladie de Parkinson. Les aurones ont fait preuve lors de ce travail d'une grande versatilité face à la tyrosinase, adoptant au gré des substitutions des comportements très différents de substrat alternatif, d'activateur hyperbolique ou d'inhibiteur mixte. Un modèle cohérent a cependant été proposé, qui regroupe et explique ces comportements. Au cours de ce travail, de nombreux dérivés d'aurone diversement substitués ou modifiés ont été préparés, par le biais de méthodes de synthèse adaptées à la structure de chaque produit formé.Aurones, a subclass of flavonoids, present a favorable pharmacological profile and a wide, promising spectrum of biological activites. During this work, we used this potential for the modulation of two major therapeutic targets. Firstly, since several hepatitis C virus protease NS3/4A inhibitors were recently marketed, the inhibition of the polymerase NS5B is now the focus of research efforts in the fight against HCV. The use of aurones against the HCV polymerase is here reported for the first time. Four generations of compounds were synthesized and evaluated, and several bioactive derivatives were found, including some natural products, with an IC50 below 5 μM. Furthermore, additional investigations regarding inhibitor – receptor interactions allowed to identify the aurones binding site, which is Thumb Site I. Secondly, although the modulation of tyrosinase in a therapeutic aim remains a matter of discussion, a number of studies considers this enzyme as a potential target for future treatments against some hardly curable diseases, such as cancer or Parkinson's disease. During this work, aurones showed a great versatility toward tyrosinase. According to their substitution pattern, the compounds embraced very different behaviours, i.e. alternative substrate, hyperbolic activator or mixed inhibitor behaviour. However a consistent model was proposed, which gathers and explains all of these behaviours. During this study, a large number of widely substituted or modified aurone derivatives were prepared, according to structure-dependant adaptative synthetic methods

Multitasking Water-Soluble Synthetic G-Quartets: From Preferential RNA-Quadruplex Interaction to Biocatalytic Activity

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Pharmacochimie des aurones pour la modulation d'enzymes

Les aurones, qui constituent une sous-classe des flavonoïdes, présentent un profil pharmacologique et un spectre d'activités biologiques prometteurs. Au cours de ce travail, nous avons mis à profit ce potentiel pour la modulation de deux cibles thérapeutiques majeures. En premier lieu, depuis la mise sur le marché d'inhibiteurs de la protéase NS3/4A, l'inhibition de la polymérase NS5B du virus de l'hépatite C représente un enjeu primordial dans la lutte contre cette maladie. L'utilisation des aurones contre cette polymérase trouve ici ses premiers développements. L'évaluation de quatre générations de composés a mené à l'identification de plusieurs dérivés actifs, dont certains produits naturels, présentant un IC50 inférieur à 5 M. L'étude des interactions ligand récepteur a en outre permis de déterminer que les aurones se fixent probablement sur le site Thumb I . En second lieu, si la modulation de la tyrosinase dans un cadre thérapeutique reste actuellement hypothétique, de nombreuses études voient en cette enzyme une cible pour le traitement futur de pathologies difficilement curables, comme le cancer ou la maladie de Parkinson. Les aurones ont fait preuve lors de ce travail d'une grande versatilité face à la tyrosinase, adoptant au gré des substitutions des comportements très différents de substrat alternatif, d'activateur hyperbolique ou d'inhibiteur mixte. Un modèle cohérent a cependant été proposé, qui regroupe et explique ces comportements. Au cours de ce travail, de nombreux dérivés d'aurone diversement substitués ou modifiés ont été préparés, par le biais de méthodes de synthèse adaptées à la structure de chaque produit formé.Aurones, a subclass of flavonoids, present a favorable pharmacological profile and a wide, promising spectrum of biological activites. During this work, we used this potential for the modulation of two major therapeutic targets. Firstly, since several hepatitis C virus protease NS3/4A inhibitors were recently marketed, the inhibition of the polymerase NS5B is now the focus of research efforts in the fight against HCV. The use of aurones against the HCV polymerase is here reported for the first time. Four generations of compounds were synthesized and evaluated, and several bioactive derivatives were found, including some natural products, with an IC50 below 5 M. Furthermore, additional investigations regarding inhibitor receptor interactions allowed to identify the aurones binding site, which is Thumb Site I. Secondly, although the modulation of tyrosinase in a therapeutic aim remains a matter of discussion, a number of studies considers this enzyme as a potential target for future treatments against some hardly curable diseases, such as cancer or Parkinson's disease. During this work, aurones showed a great versatility toward tyrosinase. According to their substitution pattern, the compounds embraced very different behaviours, i.e. alternative substrate, hyperbolic activator or mixed inhibitor behaviour. However a consistent model was proposed, which gathers and explains all of these behaviours. During this study, a large number of widely substituted or modified aurone derivatives were prepared, according to structure-dependant adaptative synthetic methods.SAVOIE-SCD - Bib.électronique (730659901) / SudocGRENOBLE1/INP-Bib.électronique (384210012) / SudocGRENOBLE2/3-Bib.électronique (384219901) / SudocSudocFranceF

A Model of Smart G-Quadruplex Ligand

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β-Carboline as a Privileged Scaffold for Multitarget Strategies in Alzheimer's Disease Therapy

International audienceThe natural β-carboline alkaloids display similarities with neurotransmitters that can be favorably exploited to design bioactive and bioavailable drugs for Alzheimer's Disease (AD) therapy. Several AD targets are currently and intensively being investigated, divided in different hypotheses: mainly the cholinergic, the Amyloid β (Aβ) and the Tau hypotheses. To date, only symptomatic treatments are available involving acetylcholinesterase and NMDA inhibitors. Based on plethoric single-target structure-activity relationship studies, the βcarboline scaffold was identified as a powerful tool for fostering activity and molecular interactions with a wide range of AD-related targets. This knowledge can undoubtedly be used to design multitarget-directed ligands (MTDL), a highly relevant strategy preferred in the context of multifactorial pathology with intricated etiology such as AD. In this review, we first individually discussed the AD targets of the β-carbolines and then we focused on the multitarget strategies dedicated to the deliberate design of new efficient scaffolds

Bioactive Aurones, Indanones, and Other Hemiindigoid Scaffolds: Medicinal Chemistry and Photopharmacology Perspectives

International audienceHemiindigoids comprise a range of natural and synthetic scaffolds that share the same aromatic hydrocarbon backbone as well as promising biological and optical properties. The encouraging therapeutic potential of these scaffolds has been unraveled by many studies over the past years and uncovered representants with inspiring pharmacophoric features such as the acetylcholinesterase inhibitor donezepil and the tubulin polymerization inhibitor indanocine. In this review, we summarize the last advances in the medicinal potential of hemiindigoids, with a special attention to molecular design, structure–activity relationship, ligand-target interactions, and mechanistic explanations covering their effects. As their strong fluorogenic potential and photoswitch behavior recently started to be highlighted and explored in biology, giving rise to the development of novel fluorescent probes and photopharmacological agents, we also discuss these properties in a medicinal chemistry perspective

Bioactive Aurones, Indanones, and Other Hemiindigoid Scaffolds: Medicinal Chemistry and Photopharmacology Perspectives

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Design and synthesis of 4-amino-2’,4’-dihydroxyindanone derivatives as potent inhibitors of tyrosinase and melanin biosynthesis in human melanoma cells

Melanogenesis inhibition constitutes a privileged therapeutic solution to treat skin hyperpigmentation, a major dermatological concern associated with the overproduction of melanin by human tyrosinase (hsTYR). Despite the existence of many well-known TYR (tyrosinase) inhibitors commercialized in skin formulations, their hsTYR-inhibition efficacy remains poor since most of them were investigated over mushroom tyrosinase (abTYR), a model with low homology relative to hsTYR. Considering the need for new potent hsTYR inhibitors, we designed and synthesized a series of indanones starting from 4-hydroxy compound 1a, one of the two most active derivatives reported to date against the human enzyme, together with marketed thiamidol. We observed that analogues featuring 4-amino and 4-amido-2’,4’-dihydroxyindanone motifs showed two- to ten-fold increase in activity over human melanoma MNT-1 cell lysates, and a ten-fold improvement in a 4-days whole-cell experiment, compared to parent analogue 1a. Molecular docking investigation was performed for the most promising 4-amido derivatives and suggested a plausible interaction pattern with the second coordination sphere of hsTYR, notably through hydrogen bonding with Glu203, confirming their impact in the binding mode with hsTYR active site

A Model of Smart G‑Quadruplex Ligand

An unprecedented strategy to control the quadruplex- vs duplex-DNA selectivity of a ligand is reported. We designed a compound whose structure can rearrange when it interacts with a G-quadruplex, thereby controlling its affinity. Thus, the first “smart G-quadruplex ligand” is reported, since this ligand experiences a structural change in the presence of quadruplexes but not in the presence of duplexes, ensuring a high level of quadruplex selectivity