TAR-RNA Recognition by a Novel Cyclic Aminoglycoside Analogue / TAR-RNA Recognition by a Novel Cyclic Aminoglycoside Analogue

Raghunathan, Devanathan

02 May 2007

No description available.

540 Chemie

Mathematics and Computer Science

Aminoglycoside

TAR RNA

NMR

Bindungsmodus

Aminoglycoside

TAR RNA

NMR

binding mode

35.25

S

Conception, synthèse et étude de nouvelles molécules bioactives. Propriétés antivirales et antimélanome

Joly, Jean-Patrick

19 December 2013

Malgré des progrès importants réalisés ces dernières années, la lutte contre les infections virales (SIDA, hépatites etc.) et les cancers demeurent un problème de santé mondiale. Ce bref bilan met en évidence la nécessité de développer de nouvelles molécules pour contourner les limites des traitements disponibles actuellement. Cette thèse, articulée autour de trois grands thèmes, s’inscrit dans ce contexte. Nous avons d’abord mis au point de manière rationnelle de nouveaux ligands d’ARN capables de se lier sélectivement à certaines structures secondaires de type tige-boucle ou tige-renflement de l’ARN TAR du VIH-1. Ces ligands interagissent avec l’ARN grâce à l’action coopérative de deux motifs de reconnaissance : (i) une nucléobase modifiée qui peut reconnaitre spécifiquement une paire de base de l’ARN et (ii) des acides aminés qui agissent avec les bases non appariées de l’ARN. Ces deux motifs sont reliés grâce à une matrice aliphatique (ligands non nucléosidiques) ou une matrice 2-désoxyribose (ligands nucléosidiques). Des études biophysiques et biologiques ont été menés en collaboration avec l’équipe du Dr. L. Briant (CEAPBS, UMR5236-CNRS) pour connaitre leur activité antivirale et leur site d’interaction sur la cible. Nous avons ensuite développé des molécules de type benzènesulfonamide thiazoles pour cibler le mélanome résistant aux inhibiteurs de B-Raf. Des modulations effectuées sur ce squelette nous ont permis d’établir des relations structure/activité, en collaboration avec l’équipe de Dr. S. Rocchi (C3M, INSERM U895). Enfin, nous avons développé une stratégie de modification post-synthétique d’oligonucléotides en position anomérique par réaction clic. / Despite significant progress made in recent years, the fight against viral infections (AIDS, Hepatitis, etc.) and cancer remains a global health problem. This brief summary underlines the need for new compounds in order to overcome the limitations of currently available drugs. To this end, the main objective of this thesis is to address these issues by the investigation of three major research projects. We first developed new RNA ligands that selectively bind to RNA secondary structures such as the stem-loop or the stem-bulge of HIV-1 TAR RNA. These ligands interact with RNA thanks to the presence of two RNA binding domains acting in a cooperative manner: (i) a modified nucleobase that can specifically recognize an RNA base pair and (ii) basic amino acids that interact with strong affinity with surrounding free RNA nucleobases. These two patterns are connected by an aliphatic matrix (non-nucleoside ligands) or a 2-desoxyribose matrix (nucleoside-based ligands). Biophysical and biological studies were conducted in collaboration with the team of Dr. L. Briant (CEAPBS, UMR5236-CNRS) in order to study their antiviral activity and their mode of action. We next developed new bioactive molecules featuring a thiazole benzenesulfonamide scaffold to target melanoma cells resistant to B-Raf inhibitors. The modular synthesis of a large number of analogs allowed us to establish the structure/activity relationships, in collaboration with the team of Dr. S. Rocchi (C3M, INSERM U895). Finally, we developed a straightforward and convenient strategy for post-synthetic modification of oligonucleotides at the anomeric position using click chemistry.

Nucléosides

Ligands d’ARN

Triplet de bases

ARN TAR VIH

Mélanome

Benzènesulfonamide thiazole

Oligonucléotides

Modification post-synthétique

Nucleosides

RNA ligands

HIV TAR RNA

Thiazole benzenesulfonamide

Oligonucleotides

Post-synthetic modification

Targeting HIV-1 RNAs with Medium Sized Branched Peptides Featuring Boron and Acridine-Branched Peptide Library Design, Synthesis, High-Throughput Screening and Validation

Zhang, Wenyu

14 April 2014

RNAs have gained significant attention in recent years because they can fold into well-defined secondary or tertiary structures. These three dimensional architectures provide interfaces for specific RNA-RNA or RNA-protein interactions that are essential for biological processes in a living system. These discoveries greatly increased interest in RNA as a potential drug target for the treatment of diseases. Two of the most studied RNA based regulatory systems are HIV-1 trans-activating response element (TAR)/Tat replication pathway and Rev response element (RRE)/Rev export pathway. To efficiently target TAR and RRE RNA, we designed and synthesized three generations of branched peptide libraries that resulted in medium sized molecules. The first generation of BPs were discovered from screening a one-bead one-compound library (4,096 compounds) against HIV-1 TAR RNA. One peptide FL4 displayed a binding affinity of 600 nM to TAR RNA, which is tighter than its native protein counterpart, Tat. Biophysical characterization of these BP demonstrated that "branches" in BPs impart multivalency, and they are cell permeable and non-toxic. The second generation peptides were discovered from an on-bead high-throughput screening of a 3.3.4 branched peptide boronic acids (BPBAs) library that bind selectively to the tertiary structure of RRE IIB. The library comprised of 46,656 unique sequences. We demonstrate that our highest affinity BPBA (BPBA1) selectively binds RRE IIB in the presence of competitor tRNAs as well as against six RRE IIB structural variants. Further, we show that the boronic acid moieties afford a novel binding mode towards RNA that is tunable; their Lewis acidity has critical effects on binding affinity. In addition, biophysical characterizations provide evidence that "branching" in these peptides is a key structural motif for multivalent interactions with the target RNA. Finally, RNA footprinting studies revealed that the BPBA1 binding site encompasses a large surface area that spans both the upper stem as well as the internal loop regions of RRE IIB. BPBA1 is cell permeable and non-toxic. In the next generation of branched peptides, a 3.3.4 branched peptide library composed of 4,096 unique sequences that featured boronic acid and acridine moieties was designed. We chose acridine as the amino acid side chain due to its potential for π-stacking interaction that provides high binding affinity to RNA target. The library was screened against HIV-1 RRE IIB RNA. Fifteen peptides were sequenced and four contained acridine alone and/or in conjunction with boronic acid moieties displayed dissociation constants lower than 100 nM. The ribonuclease protection assays of A7, a sequence that contains both boronic acid and acridine residues, showed a similar protection pattern compared to previous peptide BPBA1, suggesting that the 3.3.4 branched peptides shared similar structural elements and contacted comparable regions of the RRE IIB RNA. The results from this research indicated that "branching" in peptides imparts multivalent interactions to the RNA, and that functional groups such as boronic acid and acridine are key structural features for efficient binding and selectivity for the folded RNA target. We demonstrated that the branched peptides are cell permeable and non-toxic. / Ph. D.

HIV-1

TAR RNA

RRE RNA

Branched Peptide Library

High-throughput Screening

Branched Peptide Boronic Acids

Acridine Branched Peptides

Unnatural Amino Acids