Structural analysis of transcription factors involved in Mycobacterium tuberculosis mycolic acid biosynthesis

Tanina, ABDALKARIM

10 July 2020

Tuberculosis (TB) remains the leading cause of death due to a single infectious agent with more than 1.5 million people killed each year. In 2018, the World Health Organization (WHO) estimated that one third of the world’s population was infected with Mycobacterium tuberculosis (Mtb), the pathogen responsible for the disease.In 2000, EthR, a mycobacterial transcriptional repressor, was identified as a key modulator of ethionamide (ETH) bioactivation. ETH is one of the main second-line drugs used to treat drug-resistant strains and it is a prodrug that is activated in Mtb by the mono-oxygenase EthA and then inhibits InhA, an enzyme involved in the mycolic acid biosynthesis. In 2009, it was demonstrated that co-administration of ETH with the drug-like inhibitors of EthR was able to boost ETH activity by a factor three in a mouse-model of TB-infection, thus validating EthR protein as a target for a new therapeutic strategy. The first part of this thesis deals with the validation and deep characterization of the solved EthR-ligand structures based on all analysis of how each ligand bind to the EthR. In this section, based on the study of both co-crystal structures and the physicochemical properties of the ligands, we have rationalized the information currently available and understood the interaction of all EthR inhibitors in order to lead to more effective inhibitor design.More recently, another mycobaterial repressor, denoted EthR2, was identified as a putative target that appears to be functionally comparable to EthR (then the locus has been termed EthA2/EthR2, due to its similarity to the EthA/EthR locus). Furthermore, a spiroisoxazoline family of small-molecules, generically denoted as SMARt, has been identified as effective ligand of EthR2. However, according to the data present in the literature, this spiroisoxazoline family can also bind to the former EthR. In order to investigate this proposition, I have solved these small molecules in complex with EthR and compared their binding interactions to the EthR2 protein as well. The opportunity for the design small-molecules is capable of targeting both repressors, thereby opening the way to a dual-target approach.Finally, the third part of this thesis is devoted to the mycobacterial transcriptional factor MabR (Rv2242). Several studies identified this protein as a regulatory transcription factor of the fatty acid synthase II operon, which is mainly responsible for the mycolic acid biosynthesis in Mtb. I therefore purified to homogeneity and characterized the MabR protein as well as I determined the crystal structure of its C-terminal part. Finally, the functional role of MabR is largely discussed, and the way on how to interfere with its DNA binding ability is commented with respect to our results. / Doctorat en Sciences biomédicales et pharmaceutiques (Pharmacie) / info:eu-repo/semantics/nonPublished

Sciences bio-médicales et agricoles

Conception et synthèse de molécules à visée anti-infectieuse selon deux stratégies : le criblage à haut débit et l’approche par fragments / Design and synthesis of anti-infectious molecules using two different strategies : high throughput screening and fragment-based drug discovery approaches

Prevet, Hugues

30 September 2016

La découverte d’un candidat médicament repose sur l’identification de hits, présentant des propriétés physico-chimiques adéquates pour leur optimisation. Le criblage à haut débit et l’approche par fragments sont deux techniques couramment utilisées lors de cette étape d’identification et elles ont été mises en œuvre au cours de ma thèse dans le but de découvrir de nouveaux composés ciblant d’une part le complexe CD81/CLDN-1 pour empêcher l’entrée du virus de l’hépatite C (VHC) dans les hépatocytes et d’autre part EthR2, un régulateur transcriptionnel mycobactérien, afin de potentialiser l’activité d’un antituberculeux sur les souches résistantes de M. tuberculosis.Dans une première partie, un criblage à haut débit sur le complexe CD81/CLDN-1 a permis d’identifier des modulateurs en série thiéno[2,3-c]pyrazole. Ces composés ont été pharmacomodulés et un composé spécifique de l’étape d’entrée du VHC, non toxique et présentant une activité submicromolaire a pu être ainsi identifié. Cette sonde pharmacologique permettra de mieux comprendre les mécanismes impliqués dans le processus d’entrée virale.Dans une deuxième partie, nous nous sommes intéressés à la conception de nouveaux fragments dits privilégiés. Ainsi, le développement des voies de synthèse, sous irradiation micro-onde, de deux entités moléculaires, le noyau 1,4-benzodiazepine-2,5-dione et le noyau spirohydantoïne, nous a permis d’obtenir 34 composés originaux. Afin d’évaluer le potentiel de cette stratégie, une librairie virtuelle de fragments a été générée et son criblage in silico sur la protéine MDM2 a été effectué. La mesure in vitro de l’activité des hits identifiés permettra de valider l’intérêt de cette approche pour la découverte de nouveaux ligands ciblant les interactions protéine-protéine.Dans une troisième partie, des inhibiteurs d’un répresseur transcriptionnel mycobactérien impliqué dans la potentialisation de l’activité de l’éthionamide ont été développés. A l’issue d’un criblage de 960 fragments, l’identification d’un hit en série tropinone, et sa cocristallisation avec la protéine EthR2, a permis d’entamer une optimisation rationnelle qui a conduit à l’obtention rapide de composés présentant de meilleures activités. / The discovery of drug candidates is based on the identification of hits with appropriated physico-chemical properties for further development. High throughput screening and fragment-based drug discovery approaches are two strategies commonly used for this identification. These strategies were applied during my PhD research work for identifying not only new modulators of the CD81/CLDN-1 complex to prevent entry of the Hepatitis C virus (HCV) into hepatocytes but also inhibitors of the mycobacterial transcriptional repressor, called EthR2, to boost ethionamide antibacterial activity against resistant strains of M. tuberculosis.Firstly, a high throughput screening assay was developed to identify molecules bearing a thieno[2,3-c]pyrazole scaffold that modulate the CD81/CLDN-1 complex. The structure-activity relationships allowed us to design and synthesize one non-toxic compound that inhibits viral entry with an IC50 in the submicromolar range. This best analog will be used as pharmacological tool to understand the molecular mechanism involving the CD81/CLDN-1 interaction during virus entry.Secondary, we worked on the design and synthesis of a new generation of fragments called privileged fragments. We focused our interest on the 1,4-benzodiazepine-2,5-dione and spirohydantoin scaffolds and using microwave-assisted conditions 44 original privileged fragments have been synthesized. To further illustrate the potential of our privileged fragments, a virtual focused library has been generated and screened in silico on MDM2 protein. The in vitro evaluation of the identified hits will allow us to validate our approach and to show the potential of our privileged fragments for the discovery of new hits against protein-protein interactions.Finally, inhibitors of a new mycobacterial transcriptional repressor involved in the boosting of ethionamide activity have been developed. Screening of 960 fragments allowed us to identify a hit bearing a tropinone scaffold which was cocrystallized with EthR2. A rational design from this cocrystal structure led rapidly to more potent ligands.

Virus de l'hépatite C

CD81

Claudine-1

Inhibiteurs

Hépatocytes

HTS

Frangments privilégiés

3D

FBDD

Chimiothèque

Tuberculose

Éthionamide

EthR2

Potentialisation

Hepatitis C virus

CD81

Claudin-1

Inhibitors

Hepatocytes

HTS

Priviliged fragments

3D

FBDD

Chemical library

Tuberculosis

Ethionamide

EthR2

Boosting