Examining the Inhibition Mechanism of EPAC / Inhibition Mechanism of EPAC

Shao, Hongzhao

January 2019

A novel partial agonist of the exchange protein activated by cAMP isoform 1 (EPAC1), I942, was recently discovered and shown to reduce the guanine exchange factor activity of cAMP-bound EPAC1 to approximately 10% relative to cAMP activation. However, the inhibition mechanism of I942 remains unknown. Here, we utilize NMR spectroscopy to probe the inhibitory I942 - EPAC1 interactions at atomic resolution. The EPAC1 - I942 interface was mapped through intermolecular NOEs measured by 15N and 13C filtered NOESY-HSQC experiment. Intermolecular NOE mapping combined with other protein NMR methods, such as saturation transfer difference, transfer Nuclear Overhauser Effect spectroscopy and chemical shift mapping, we revealed that I942 interacts with the phosphate binding cassette (PBC) and base binding region (BBR) of the EPAC1 cyclic nucleotide binding (CNB) domain, similar to cAMP. The PBC controls the conformation of the hinge region, and subsequently, allosterically shifts the hinge region between its active/inactive states. Molecular dynamics simulation based on the NMR spectroscopy data revealed that EPAC1-CNB adopts an intermediate conformation between its inactive and active states, which explains the partial agonist nature of I942. / Thesis / Master of Science (MSc) / The exchange protein activated by cAMP (EPAC) is a receptor for the classical secondary messenger cAMP. EPAC is present in multiple human systems and plays a pivotal role in the development of a wide range of diseases. In this study, we aim to establish the inhibition mechanism of a novel small molecule EPAC inhibitor/partial agonist I942 using NMR spectroscopy with the goal of achieving a better understanding of EPAC inhibition and paving the way for new small molecule EPAC inhibitors that can potentially treat EPAC-related diseases such as heart failure and diabetes.

EPAC

competitive inhibitor

inhibition mechanism

NMR Spectroscopy

Modulation of TGF‐β Receptor 1 signalling in Live Cells

Driscoll, Brandon

07 August 2009

TGF-β negatively affects the maintenance and expansion of hematopoietic stem cells ex vivo and its inhibition has been widely studied as a treatment for numerous hematopoietic disorders and cancers. Current inhibitory strategies (small molecule ATP competitors and neutralizing antibodies) are compared to a novel cell-permeable peptide-based inhibitor of TGF-β RI. Multiple levels of assay from biochemical to functional are utilized with the aim of applying the most successful inhibitor to hematopoietic stem cell culture. The neutralizing antibody proved ineffective in the short-term biochemical assay but was extremely effective at neutralizing TGF-β signalling in proliferation and hematopoietic colony-forming cell assays with no evidence of toxicity. The small molecule inhibitors (SD-208 and Pyrazole TGF-β RI inhibitor) were equally effective at micromolar levels in all forms of assay, with SD-208 being slightly more potent. The novel peptide inhibitor proved ineffective in all assays, which is likely a result of its rapid degradation in live cells.

TGF-β Inhibition

Peptide

ATP competitive inhibitor

neutralzing antibody

0541

Modulation of TGF‐β Receptor 1 signalling in Live Cells

Driscoll, Brandon

07 August 2009

TGF-β negatively affects the maintenance and expansion of hematopoietic stem cells ex vivo and its inhibition has been widely studied as a treatment for numerous hematopoietic disorders and cancers. Current inhibitory strategies (small molecule ATP competitors and neutralizing antibodies) are compared to a novel cell-permeable peptide-based inhibitor of TGF-β RI. Multiple levels of assay from biochemical to functional are utilized with the aim of applying the most successful inhibitor to hematopoietic stem cell culture. The neutralizing antibody proved ineffective in the short-term biochemical assay but was extremely effective at neutralizing TGF-β signalling in proliferation and hematopoietic colony-forming cell assays with no evidence of toxicity. The small molecule inhibitors (SD-208 and Pyrazole TGF-β RI inhibitor) were equally effective at micromolar levels in all forms of assay, with SD-208 being slightly more potent. The novel peptide inhibitor proved ineffective in all assays, which is likely a result of its rapid degradation in live cells.

TGF-β Inhibition

Peptide

ATP competitive inhibitor

neutralzing antibody

0541

Synthèse et évaluation biologique d’hétérocycles à cinq chaînons, inhibiteurs de la protéine farnésyltransférase / Synthesis and biological evaluation of five-membered heterocycles, inhibitors of protein farnesyltransferase

Bosc, Damien

14 October 2011

La protéine farnésyltransférase (FTase) est une métalloenzyme à zinc catalysant le transfert d’une chaîne farnésyle provenant du pyrophosphate de farnésyle (FPP) sur le résidu cystéine de certaines protéines possédant un motif CaaX C-terminal où C est la cystéine farnésylée, a est un acide aminé aliphatique et X est Ser, Ala, Gln ou Met. Une fois additionné, le groupement farnésyle fait office de point d’ancrage rendant possible la fixation des protéines à la membrane cellulaire et de guide moléculaire facilitant la liaison de ces protéines prénylées à d’autres protéines. D’abord étudiée en oncologie, la FTase constitue aujourd’hui une cible potentielle pour la thérapie antiparasitaire qui manque cruellement de médicaments suite à l’apparition de phénomènes de résistance. La nécessité d’améliorer les thérapies existantes ouvre la voie de recherches innovantes pour trouver de nouvelles molécules bioactives.Lors de ces travaux de thèse, les deux stratégies de recherche pratiquées en chimie médicinale ont été utilisées.La première approche a consisté à synthétiser des analogues bisubstrats 1,2,3-triazoles pouvant se lier à la fois sur le site de liaison de la protéine et sur celui du FPP. Cette approche rationnelle a aussi permis d’ébaucher une synthèse monotope de triazoles 1,5-disubstitués à partir d’amines primaires. L’approche par criblage constitue la deuxième méthode de recherche de nouveaux inhibiteurs. Dans ce contexte, la chimiothèque de l’ICSN a été criblée et deux composés de type 3-arylthiophène ont révélé de bonnes activités et une structure originale dans l’inhibition de la FTase. Ainsi, des travaux de relations structure-activité ont été réalisés pour moduler les différentes positions du thiophène et la nature de l’hétérocycle central.Ce travail nous a permis d’élaborer une librairie de plus d’une centaine de composés. L’évaluation biologique de ces analogues sur FTases isolées humaine et de T. brucei et sur parasites T. brucei et P. falciparum a révélé des molécules particulièrement intéressantes et prometteuses. / Protein farnesyltransferase (FTase) is a zinc metalloenzyme which catalyzes the transfer of a farnesyl chain from farnesyl pyrophosphate (FPP) to the cysteine residue of some proteins possessing a C-terminal CaaX moiety where C is the farnesylated cysteine, a is an aliphatic amino-acid and X is Ser, Ala, Gln or Met. Once attached, the farnesyl group serves as anchors for fixing proteins to cell membrane and as molecular handles for facilitating binding of these prenylated proteins to other proteins.First studied in oncology, FTase constitutes nowadays a potential target for antiparasitic therapies, where drugs are missing due to the appearance of resistance phenomena. The necessity to improve the existing therapies paves the way of innovating researches to find new bioactive molecules.During this Ph.D work, two strategies of research used in medicinal chemistry were performed.The first approach consisted in the synthesis of bisubstrate analogues with a 1,2,3-triazole core deviced to tie up both to the protein and the FPP binding sites. This rational approach also allowed to draft a one-pot synthesis of 1,5-disubstituted triazoles from primary amines.The screening approach was the second strategy to search for new inhibitors. For this purpose, ICSN chemical library was screened and two 3-arylthiophene compounds disclosed good activities and an original scaffold for FTase inhibition. Therefore, a structure-activity relationship study was carried out to modulate the different positions of the thiophene and the nature of the central heterocycle.This work allowed us to create a above-hundred-molecule library. The biological evaluation of these analogues on human and T. brucei isolated FTase and on T. brucei and P. falciparum parasites revealed particularly interesting and promising molecules.

Protéine farnésyltransférase

Inhibiteur bisubstrat

Inhibiteur compétitif

Antiparasitaire

Relations structure-activité

Thiophène

Triazole

Synthèse monotope

Protein farnesyltransferase

Bisubstrat inhibitor

Competitive inhibitor

Antiparasitic

Structure-activity relationships

Thiophene

Triazole

One-pot synthesis

Biochemical Characterization of β-galactosidase from Enterobacter sp. YSU

Motari, Fred Ondabu

02 May 2023

No description available.

Biochemistry

Biology

Biomedical Research

Chemistry

Food Science

Health Sciences

Molecules

o-NPGal

Galactose as a competitive inhibitor

Glucose as an uncompetitive inhibitor

Galactooligosaccharides

Galactosylation

hydrolysis of lactose