Application of Electrospray Mass Spectrometry Toward Semi-Automated Kinase Inhibitor Screening

Partserniak, Ivan

08 1900

<P> Multi-site phosphorylation of protein targets by specific kinases is a common event used to propagate biological messages through signal transduction pathways in the context of the cellular environment and is a vital regulatory mechanism for many metabolic processes. Recent advances in the study of the protein glycogen synthase kinase-3 (GSK-3) have shed some light on the intricate role this enzyme plays within the framework ofmammalian cellular metabolism. Abnormal behaviour of GSK -3 profoundly impacts cellular function, and is implicated in Alzheimer's disease and the development of Type II Diabetes. A key issue in assaying the activity of GSK-3 is the ability to distinguish between singly and multiply phosphorylated substrates, as this enzyme has the ability to selectively phosphorylate a previously phosphorylated (primed) substrate. Given the serious nature of the disorders caused by the dysfunction of this kinase, high throughput screening of specific inhibitors from compound libraries is urgently needed. Unfortunately, many of the currently existing kinase screening technologies are geared towards monitoring single phosphorylation events and thus, are not be amenable to effective assaying of multiply phosphorylated substrates. In this thesis, a novel, solution-based assay method based on electrospray ionizationtandem mass spectrometry (ESI-MS/MS) is developed as a platform for inhibitor screening with full consideration being given to the specific nature of GSK-3 substrates and products. The semi-automated application of this assay is possible using an in-line autosampler, and is shown to be a potentially effective means for screening primed binding site inhibitors from compound mixtures, with subsequent deconvolution performed to isolate the effective molecule. Optimization of the MS-based assay required significant alterations in buffer conditions compared to those used in the standard GSK-3 radioassay based on y-32P ATP, owing to the inability of electrospray ionization to tolerate high buffer concentrations. Preliminary screening of mixtures was demonstrated, and expansion to screening of large compound libraries consisting of previously untested compounds and natural product extracts should be possible. </p> <p> To investigate the adaptation of the GSK-3 MS/MS assay to allow mixture deconvolution, a preliminary study was performed on the utilization of sol-gel technology for entrapment of GSK-3 to develop a solid-phase affinity assay for pull-down of bioactive ligands identified in enzyme activity assays. This method requires the preservation of enzyme function within the silica matrix, which has not been previously demonstrated for GSK-3. The sol-gel entrapment of GSK-3, however, proved to be problematic. Implementation of a flow-through assay using immobilized GSK-3 was hampered by issues such as non-specific adsorption of the cationic substrate and inhibitors, owing to electrostatic interactions with the anionic silica matrix used for enzyme entrapment. Future work aimed at further developing and optimizing the sol-gel materials and processing methods are proposed. </p> / Thesis / Master of Science (MSc)

Electrospray

Mass Spectrometry

Semi-Automated Kinase

Inhibitor Screening

The making and breaking of SAS-6 : structural insights and inhibitor search for n-terminal domain dimerisation

Busch, Julia Maria Christiane

January 2017

SAS-6 is the structural core of the forming centriole - a cylindrical protein complex, which is an essential component of the centrosome. Oligomerisation of SAS-6 is crucial for successful centriole duplication and is achieved through two dimerisation domains in the SAS-6 protein; a long C-terminal coiled-coil domain and a globular N-terminal dimerisation domain. As core components of the centrosome, centrioles help facilitate various cellular functions. They are involved in the anchoring of flagella and cilia to the membrane and in coordinating the spindle apparatus during chromosome segregation. A deeper insight into the molecular mechanisms at play in the centriole duplication process would have implications on our understanding of fundamental cell division processes and a number of related diseases. Here the involvement of an unstudied loop region in the C. elegans SAS-6 N-terminal domain dimerisation is described. Combining structural biology, biophysical and computational techniques, the molecular interactions of this loop were explored, contributing to the oligomerisation of SAS-6 at the N-terminal dimer interface. Furthermore, the screening and testing of small molecule inhibitors of the SAS-6 N-terminal domain dimerisation is described, targeting a hydrophobic pocket in the domain. Two candidate compounds are presented as a result of the screens and next steps towards structure based compound design are suggested, based on computational analysis. The search for inhibitory compounds includes a set-up of an in-house virtual screening pipeline, as well as in vitro screening efforts and a new crystallographic structure of the H. sapiens SAS-6 N-terminal domain. By investigating the making and breaking of the SAS-6 N-terminal domain dimerisation, light is shed on so far neglected details of this essential protein-protein interaction and advancements towards a SAS-6 oligomerisation inhibitor described, which could ultimately be used for new approaches in cell cycle research and might open up new avenues for medical research by binding a disease relevant target.

572

An assay for quantitative analysis of polysialic acid expression in cancer cells

Guo, Xiaoxiao, Elkashef, Sara M., Patel, Anjana, Ribeiro Morais, Goreti, Shnyder, Steven, Loadman, Paul, Patterson, Laurence H., Falconer, Robert A.

15 February 2021

Yes / Polysialic acid (polySia) is a linear polysaccharide comprised of N-acetylneuraminic acid residues and its over-expression in cancer cells has been correlated with poor clinical prognosis. An assay has been developed for quantitative analysis of cellular polySia expression. This was achieved by extracting and purifying released polySia from glycoproteins by mild acid hydrolysis and optimised organic extraction. The polySia was further hydrolysed into Sia monomers, followed by fluorescent labelling and quantitative analysis. The assay was qualified utilising endoneuraminidase-NF to remove polySia from the surface of C6-ST8SiaII cancer cells (EC50 = 2.13 ng/ml). The result was comparable to that obtained in a polySia-specific cellular ELISA assay. Furthermore, the assay proved suitable for evaluation of changes in polySia expression following treatment with a small molecule inhibitor of polysialylation. Given the importance of polySia in multiple disease states, notably cancer, this is a potentially vital tool with applications in the fields of drug discovery and glycobiology.

Polysialic acid

Sialic acid

Quantitative analysis

Cell-based method

Inhibitor screening

Intéractions avec le ribosome et changements conformationnels de la GTPase bactérienne EngA, une cible potentielle pour de nouveaux antibiotiques / Understanding ribosome binding interactions and conformational changes of the EngA bacterial GTPase, a potential target for new antibiotics

Tomé, Catarina da Silveira

05 December 2016

Au cours des dernières années, le développement de nouvelles thérapies contre les infections bactériennes a suscité un grand intérêt face à l’émergence des nombreuses souches résistantes aux antibiotiques. Le point de départ de cette recherche de nouveaux antibiotiques, pour lesquels les bactéries n’ont pas encore acquis de mécanismes de résistance, est l’identification de nouvelles cibles cellulaires. En 2000, des études génétiques ont identifié engA, un gène bactérien dont le produit est une GTPase, comme une cible pharmacologique pertinente: elle est essentielle à la survie cellulaire, conservée au sein des bactéries et absente chez les eucaryotes.Puisque EngA agit comme un facteur d’assemblage pour le ribosome bactérien, un de nos objectifs a été de développer un test de criblage pour identifier des inhibiteurs des interactions EngA-ribosome. Ces interactions sont modulées par des changements conformationnels d'EngA, qui sont eux-mêmes déclenchés par la fixation de différents nucléotides dans le domaine catalytique. Cependant, les liens entre ces différents changements restent encore méconnus. Nous avons utilisé une approche multi-technique pour étudier ces questions et obtenir des informations utiles pour l’optimisation de notre test de criblage.Des analyses de SAXS et protéolyse limitée ont démontré un changement conformationnel en solution après adition de nucléotides di- ou tri-phosphate. La comparaison des données avec des modèles cristallographiques d'EngA a confirmé la conformation de la protéine liée au GDP. Cependant, la conformation de la protéine liée au GTP ne correspond à aucune structure connue. Des essais d’interaction ont démontré que la fixation de différents nucléotides au niveau des domaines catalytiques régule l’interaction d'EngA avec le ribosome. En outre, les effets des nucléotides se produisent en utilisant des fortes concentrations, ce qui suggère que le rôle d'EngA dans la biogenèse du ribosome peut être contrôlé par la concentration intracellulaire de nucléotides. Les travaux visant la détermination de la structure d'EngA dans sa conformation liée au GTP par cristallographie nous ont permis d’obtenir la structure d’EngA dans différentes formes cristallines. Cependant, ces structures représentent la conformation liée au GDP. L’analyse de l’empilement des cristaux a montré des contacts intermoléculaires conservés qui peuvent stabiliser cette conformation pendant la nucléation. Des mutations spécifiques permettant la rupture de ces contacts peuvent éventuellement aider à promouvoir la cristallisation de conformations alternatives. Des analyses de cryo-microscopie électronique ont débuté afin d’obtenir la structure du complexe EngA:50S de chez B. subtilis. Des résultats préliminaires montrent une carte de densité électronique à 6.4 Å de résolution. L’interprétation de ces résultats est en cours. / The development of new therapeutics against bacterial infections has aroused great interest over the last years in the context of drug resistance. The starting-point in the pursuit of new antibiotics for which bacterial resistance mechanisms do not exist is the identification of novel cellular targets. Genetics studies in the early 2000s have identified engA as a conserved bacterial gene whose product is a GTPase that could represent a potential drug target: it is conserved among bacteria, essential for cell survival, and absent in humans.Since EngA acts as an assembly factor for the bacterial ribosome, one of our aims was to develop an assay to screen inhibitors of the EngA-ribosome interactions. These interactions are modulated by EngA conformational changes that are in turn triggered by the binding of different nucleotides to the catalytic G-domain. As the interplay between all these events in bacteria is still not resolved, we have used a multi-technique approach to explore these questions in order to obtain useful information for the setting up of a robust screening assay.SAXS and limited proteolysis showed a conformational change occurring in solution upon addition of either di- or tri-phosphate nucleotides. While model validation analysis confirmed the GDP-bound conformation, the GTP-bound state does not match any known EngA structure. Binding studies have revealed modulation of interactions by different nucleotide-bound states. Furthermore, response to nucleotides occurs at high concentrations, suggesting that the role of EngA in promoting ribosome assembly could be monitored by the intracellular nucleotide concentration. Efforts on identifying the GTP-bound state 3D structure by crystallography have resulted in EngA structures in different crystal forms. Although all the obtained structures represent the GDP-bound state, packing analysis has revealed conserved crystal contacts that can potentially stabilise this conformation during nucleation. Specific mutations aiming at disrupting these contacts may help to promote crystallisation of alternative conformations. Cryo-EM investigation has been initiated in order to obtain the structure of the B. subtilis EngA:50S complex. So far, an electron density map at 6.4 Å resolution has been obtained and its interpretation is underway.

Biologie structurale

GTPases bactériennes

Ribosome bactérien

Test de criblage

Interactions protéine–protéine

Structural biology

Bacterial GTPases

Bacterial ribosome

Inhibitor screening

Protein-Protein interactions

530

Etude des réactions enzymatiques par électrophorèse capillaire / The study of enzymatic reactions by capillary electrophoresis

Nehme, Hala

17 December 2013

Les enzymes sont les catalyseurs de toutes les réactions biochimiques. Leur dérégulation peut être impliquée dans de nombreuses pathologies graves. L’étude de ces réactions est importante pour dépister les anomalies, mieux comprendre le fonctionnement des enzymes et rechercher des modulateurs de leur activité. Le présent travail de thèse présente différents types d’essais enzymatiques basés sur l’électrophorèse capillaire pour étudier la cinétique d’enzymes variées. Le mode pré-capillaire où la réaction enzymatique est effectuée à l’extérieur du capillaire et les essais homogènes en-ligne en mode discontinu où la réaction est réalisée dans le capillaire, sont appliqués. Les méthodes développées sont optimisées pour assurer un mélange optimal des réactifs et une bonne séparation électrophorétique. Les constantes cinétiques et d’inhibition (Vmax, Km et IC50) de la réaction enzymatique sont déterminées et comparées à celles obtenues par les techniques classiques. Pour les essais en-ligne, plusieurs types de mélange (par application d’un champ électrique, par diffusion longitudinale ou diffusion transversale) des créneaux de réactifs sont utilisés selon le système enzymatique étudié. Finalement, jusqu’à quatre réactifs injectés successivement dans le capillaire sont mélangés avec succès. De nombreux essais sont effectués sur des matrices complexes (cellules, extraits de plantes). Le criblage d’inhibiteurs de référence et de synthèse est réalisé sur plusieurs kinases humaines : CDK1/cycline B, CDK5/p25, DYRK1A, GSK3!, PI3K, Akt et mTOR. Les essais développés se sont avérés être simples, rapides, quantitatifs, économes en réactifs et répétables. / Enzymes catalyze all enzymatic reactions. Their deregulation can be involved in several severe diseases. The study of these reactions is important to detect anomalies, to better understand enzyme functioning and to seek modulators of their activity. This thesis presents capillary electrophoresis based enzymatic assays developed to study kinetics of various enzymes. The pre-capillary mode in which the enzymatic reaction occurs outside the capillary and the incapillary plug-plug mode of homogenous assays where the reaction is performed inside the capillary are applied. The methods developed are optimized to ensure optimum reactant mixing and a good electrophoretic separation. The kinetic and inhibition constants (Vmax, Km and IC50) of the enzymatic reaction are determined by these assays and compared to the results obtained using conventional techniques. For in-capillary assays, several mixing types (by application of an electric field, by longitudinal diffusion or transverse diffusion) of the reactant plugs are used depending on the enzymatic system studied. Finally, up to four reactants injected successively in the capillary are successfully mixed. Many assays are performed on complex matrices (cells, plant extracts). Screening of referenced and synthesized inhibitors on several human kinases: CDK1/cyclin B, CDK5/p25, DYRK1A, GSK3!, PI3K, Akt and mTOR are performed. Developed assays proved to be quantitative, simple, economic, fast and robust.

Electrophorèse capillaire

Essais enzymatiques pré-capillaire

Essais enzymatiques en-ligne

Cinétique enzymatique

Criblage d’inhibiteurs

Kinases

Cellules

Extraits de plantes

Capillary electrophoresis

Pre-capillary enzymatic assays

In-capillary enzymatic assays

Kinetics

Inhibitor screening

Kinases

Cells

Plant extracts