Spectrométrie de masse des modifications induites ou post-traductionnelles de protéines : méthodologie et application à des protéines d’intérêt thérapeutique / Mass spectrometry for induced or post-translational modifications : methodology and application to proteins of therapeutic interest

Gabant, Guillaume

17 December 2014

Les modifications de protéines, qu’elles soient post-traductionnelles (PTMs) ou induites chimiquement, ont une influence considérable sur l'activité des protéines. Des méthodes de spectrométrie de masse (MS) HRMS, MS/MS CID et ETD, et de biochimie ont été développées pour la caractérisation structurale et cinétique de complexes protéine-ligand et de PTMs, dans le but de disséquer leur mécanisme et de concevoir des médicaments covalents contre des protéines liant des protéases, des kinases, ou l'ADN. La MS combinée avec des outils biochimiques a permis de séquencer l'inhibiteur de protéases grégline, et de détecter une PTM originale. De même, la transposase MOS1, modèle de l'intégrase du VIH pour la conception d'inhibiteurs, s'avère être à la fois acétylée et phosphorylée. Pour la lyase Abf2, une stratégie de piégeage, purification, protéolyse et hydrolyse ADN du complexe covalent Abf2-ADN, couplée à l’analyse MS, a été développée. Enfin, l’interaction entre le surpresseur de métastase hPEBP1 et la locostatine a été disséquée sur la protéine entière et par approche bottom-up. La locostatine s’hydrolyse en butyrate après fixation. Afin d’identifier le site ciblé par la locostatine, les conditions de réaction et de protéolyse ont été optimisées. La présence de réactions non spécifiques a conduit au développement 1) d'un modèle mathématique permettant de déterminer la fraction de liaison optimale pour discriminer le site spécifique des sites non-spécifiques, et 2) d'une méthode pour la quantification parallèle et exhaustive du degré de modification de tous les sites modifiés d'une protéine. Ces outils sont applicables aux ligands covalents de protéines et/ou à leurs PTMs. / Protein modifications, whether post-translational (PTMs) or chemically induced, play a crucial role on the activity of proteins. Mass spectrometry (MS) techniques such as HRMS, CID/ETD MS/MS, and biochemistrybased methods for structural and kinetic characterization of protein-ligand complexes and PTMs have been developed. MS combined with several biochemical tools has been used to sequence the proteinase inhibitor gregline and to detect a novel PTM. A similar approach shows that the transposase MOS1, a model for the design of HIV integrase inhibitors, is both phosphorylated and acetylated. For the lyase Abf2, a strategy of trapping, purification, proteolysis, and DNA hydrolysis of the Abf2-DNA covalent complex, coupled to MS analysis, has been developed. Finally, the interaction between the metastasis suppressor hPEBP1 and locostatin was dissected. Upon binding to hPEBP1, locostatin undergoes hydrolysis. To identify the site targeted by locostatin, the conditions of reaction and proteolysis were optimized. The qualitative approach reveals the presence of non-specific reactions, leading to the development of 1) a mathematical model to determine the optimum bound fraction for discriminating the specific site from non-specific sites, and 2) a method for the parallel and exhaustive quantification of the degree of modification of all modified sites of a protein. These tools are widely applicable to covalent protein ligands and/or PTMs.

Modification de protéine

PTM

Ligand covalent

Quantification

Protein modification

PTM

Covalent ligand

Quantification

Mass spectrometry

572.6

Integrative Approaches to Decode the Co-translational Role of the Phage Vp16 Peptide Deformylase and how it Compromises Host Viability / Approches intégratives visant à décoder le rôle de co-traduction de la peptide déformylase du phage Vp16 et comment il compromet la viabilité de l'hôte

Lavecchia, Francesco

31 January 2019

L'excision de la méthionine N-terminale (NME) est la première modification se produisant au N-terminal des protéines (NPM). Les peptides déformylases (PDF) sont les enzymes impliquées dans ce processus co-traductionnel essentiel et conservé. Les PDFs suppriment le groupe formyle lié à la méthionine initiatrice (iMet) présente au début de toutes les chaînes procaryotes naissantes. Les PDFs agissent au niveau du tunnel de sortie des ribosomes, plaque tournante de nombreux facteurs de biogénèse des protéines associées aux ribosomes (PRB), impliqués non seulement sur les MNP, mais également dans le repliement et la translocation des protéines. La déformylation N-terminale implique 95% du protéome bactérien et contribue directement à la stabilité des protéines. Le récent séquençage à haut débit de milliers de génomes a révolutionné notre perception de la distribution des PDFs dans les différents règnes, révélant des PDFs putatives dans tous les organismes, y compris les virus. En particulier, les études concernant les virus présents dans les échantillons microbiens océaniques ont permis d’identifier des gènes inhabituels de PDF chez les phages, constituant la famille la plus abondante de protéines auxiliaires conservées de ces génomes. La comparaison des séquences identifiées révèle que les PDF virales présentent une forte conservation des trois motifs constituant le site catalytique. Cependant, ces PDFs virales ne présentent pas d'extension C-terminale, région réputée importante des PDFs des autres organismes. Sachant que cette extension est impliquée dans la liaison de la PDF d’E. coli au ribosome et est requise pour son activité déformylase in vivo, il était incertain que les PDFs de phage découvertes avaient une activité déformylase classique. Ainsi, la découverte de ces PDFs virales soulève un certain nombre de questions parmi lesquelles: a) Ces PDFs virales présentent-elles une activité déformylase classique? b) Ces PDFs sont-elles capables de se lier aux ribosomes ? c) Pourquoi autant de virus portent-ils une ou plusieurs déformylases ? Dans ce contexte, l’objectif de ma thèse a été d’entreprendre la caractérisation de ces PDFs de phages marins et en particulier la PDF de Vp16 provenant de bactériophages isolés à l’origine de la souche 16 de Vibrio parahaemolyticus. Nos études révèlent que ces PDFs de phages présentent une activité déformylase à la fois in vitro et in vivo, avec une spécificité de substrat similaire à celle des autres PDFs bactériennes. D'autre part, nous avons montré par des études biochimiques et structurales, combinées à des analyses par mutagenèse dirigée, que les propriétés de la PDF de Vp16 diffèrent significativement de celle des autres PDFs caractérisées précédemment. Il faut aussi noter que l'expression de la PDF Vp16 dans les souches d'E. Coli, même à de faibles concentrations, montre un effet bactéricide marqué à une température inférieure à 37 °C. L’effet bactéricide de la PDF Vp16 est indépendant de la présence de la PDF endogène bactérienne et repose strictement sur son activité déformylase. La caractérisation de ce phénotype a révélé que la létalité induite par Vp16 PDF montrait un lien génétique fort avec des gènes codants pour des facteurs cellulaires impliqués dans le ciblage et le repliement précoce des protéines (Trigger Factor et Sec). Contrairement à ce qui a été montré pour les PDFs bactériennes, Vp16 PDF a une forte affinité pour le ribosome bactérien d’E. coli en cours de traduction, interagissant avec une région ribosomale chevauchant celles des facteurs impliqués dans le transit des protéines vers les voies de sécrétion. Une compétition au niveau du ribosome entre Vp16 PDF et ces RPBs pourrait contribuer à la lyse cellulaire de l’hôte. Mon travail suggère un nouveau mécanisme utilisé par les bactériophages permettant de contrôler la viabilité de l'hôte. / N-terminal Methionine Excision (NME) is the first occurring N-terminal Protein Modification (NPMs). Peptide deformylases (PDFs) are the enzymes involved in this essential and conserved co-translational process. PDFs remove the formyl group bound to the iMet present at the beginning of all prokaryotic nascent chains. PDFs act on the nascent chain at the level of the ribosome exit tunnel, a central hub for a number of Ribosome-associated Protein Biogenesis factors (RPBs) involved not only on NPMs but also in protein folding and translocation. Deformylation involves 95% of bacterial proteome and it is suggested to directly contribute to protein stability. Recent high-throughput sequencing of thousands of genomes has strongly contributed to revolutionizing our perception of the distribution of PDFs among kingdoms, revealing putative PDFs in all organisms, including viruses. In particular, studies of viruses within oceanic microbial samples retrieved unusual PDFs genes as the most abundant family in most of phage genomes. Sequence comparisons reveal that viral PDFs show high conservation in the three motifs that build the catalytic site; however, viral PDFs do not display a C-terminal extension when compared to the different active PDFs from other organisms. Since this C-terminal extension was shown to be important for PDF-ribosome binding and is required for the in vivo deformylase activity of E. coli PDF, it was unclear whether the discovered phage PDFs might support a classical deformylase activity. Thus, the discovery of these viral PDFs raises a number of questions among which: a) Have these viral PDFs a classical deformylase activity? b) Are these PDFs able to still bind to the ribosomes? c) Why so many viruses carry a peptide deformylase? In this context, the objective of my thesis was to undertake the characterization of these marine phage PDFs and particularly Vp16 PDF derived from the bacteriophages originally isolated from Vibrio Parahaemolyticus strain 16. Our studies reveal that phage PDFs display deformylase activity both in vitro and in vivo with a substrate specificity similar to that of other bacterial PDFs. On the other hand, we showed by biochemical and structural data, combined with site-directed mutagenesis analyses, that Vp16 PDF significantly differs from previously characterized PDFs in terms of their properties, which can be related to its few uncommon peculiarities. Interestingly, expression of Vp16 PDF in E. coli strains, even at low concentrations, exhibited a severe bactericidal effect at temperature lower than 37 °C. This bactericidal effect of Vp16 PDF was independent of the presence of the bacterial endogenous PDF and strictly relied on its PDF activity. Characterization of this phenotype revealed that Vp16 PDF-induced lethality showed a strong genetic link with genes encoding cellular factors involved in nascent pre-secretory protein targeting and folding (Trigger Factor and Sec). Differently from bacterial PDF, I could show that Vp16 PDF has strong affinity for ribosomes with a specific nascent chain, interacting with a ribosomal region overlapping that of factors involved in pre-secretory protein targeting. A competition between Vp16 PDF and these RPBs at the level of the ribosome may contribute to the host lysis, revealing a possible new unrecognized mechanism developed by viruses to control host viability.

Peptide déformylase (PDF)

Phage

Interaction ribosomal

Peptide deformylase (PDF)

Phage

Ribosomal interaction

N-terminal protein modification

Proteomická a bioinformatická charakterizace N-terminálních sekvencí proteinů modifikovaných po importu do hydrogenosomu Trichomonas vaginalis. / Proteomická a bioinformatická charakterizace N-terminálních sekvencí proteinů modifikovaných po importu do hydrogenosomu Trichomonas vaginalis.

Zákoucká, Eva

January 2014

Trichomonas vaginalis is a human pathogen causing trichomoniasis, one of the most common non-viral sexually transmitted diseases in both men and women. Trichomoniasis is currently treated with metronidazole, but the pathogen is known to develop resistance against this drug. However as the pathogen is eukaryotic, the targets for the pathogen elimination without seriously affecting the host are limited. Throughout the evolution Trichomonas vaginalis adapted to anaerobic environments by developing an alternative metabolism resulting in a reduced form of mitochondria named hydrogenosome. Hydrogenosomes lack genetic information, therefore all its proteins are nucleus-encoded and need to be transported inside the hydrogenosome using a targeting N-terminal presequence. The peptidase recognizing and cleaving those presequences at the entrance of the organelle, the hydrogenosomal processing peptidase (HPP), is unique for hydrogenosomes and therefore represents a potential drug target against the pathogen. In this work the HPP's substrate specificity towards the targeting presequences was investigated. To do so a proteomic analysis of the proteome of Trichomonas vaginalis hydrogenosomes was performed using a novel optimized protocol for N-terminal peptide sequencing. N-terminal peptides were captured using a...

Selective Fusion-Tag-Catalyzed Protein Immobilizations for Microarray and Biosensor Applications

Voelker, Alden Earl

23 August 2013

No description available.

Chemistry

Organic Chemistry

Biochemistry

microarrays

GST-tag

fusion proteins

SjGST

CDNB

protein modification

protein immobilization

protein biochip

PART I: FORMATION, PROTEIN MODIFICATION, AND CELLULAR METABOLISM OF 4-HYDROXY-7-OXOHEPT-5-ENOIC ACID LACTONE (HOHA-LACTONE)PART II: DETECTION AND BIOLOGICAL ACTIVITIES OF CARBOXYETHYLPYRROLE (CEP)-PHOSPHATIDYL-ETHANOLAMINE AND METABOLISM OF CEP-LYSINE

Wang, Hua

21 February 2014

No description available.

Biochemistry

Analytical Chemistry

Chemistry

Creation of a Site-Directed Mutant of Hen Egg White Lysozyme Working Toward Site-Specific Oxidation as it Relates to Protein Structure

Mensah, Eric

05 September 2009

No description available.

Biochemistry

Organic Chemistry

protein expression

site-specific oxidation

site-directed mutagenesis

protein purification

protein modification

Studium vlastností minoritních strukturních proteinů myšího polyomaviru / Studies of properties of the minor structural proteins of the Murine polyomavirus

Bílková, Eva

January 2014

Murine polyomavirus (MPyV) is a member of the Polyomaviridae family. Its capsid is composed of the major capsid protein, VP1, and the minor proteins, VP2 and VP3. The minor capsid proteins probably assure delivery of the viral genome through the endoplasmic reticulum membrane to the nucleus during early phase of infection. However, precise mechanism is not known. Expression plasmids encoding mutated VP2 or VP3 fused with EGFP have been constructed to study the interaction of VP2 and VP3 with membranes. The mutated proteins have deletions in the predicted hydrophobic domains. In this thesis, cell localisation of mutated proteins was followed. The study revealed that the hydrophobic domain 2 is the most important for association of VP2 and VP3 with membranes, while domains 1 and 3 are rather expendable. Further, nature of VP2 and VP3 isoforms has been studied. Isoforms with different electrophoretic mobility were separated on SDS-PAGE. Consequent mass spectrometry analysis showed that they differ in deamidation of asparagine, present at both minor proteins (position 253 of VP2 and 137 of VP3). Previously, acetylation of VP3 N-terminal alanine has been identified. To elucidate the function of these modifications, mutated viruses were constructed with substitution of these amino acids. Pilot...

INTERACTIONS OF HIGH VOLTAGE ATMOSPHERIC COLD PLASMA WITH MICROORGANISM AND PROTEIN IN FOOD SYSTEMS

Lei Xu (5930420)

12 February 2019

<p>Multiple studies have demonstrated atmospheric cold plasma (ACP) as an effective non-thermal technology for microbial decontamination, surface modification, and functionality alteration in food processing and packaging. ACP constitutes charged particles, such as positive and negative ions, electrons, quanta of electromagnetic radiation, and excited and non-excited molecules, which corresponds to its predominant reactive properties. However, in many of these applications, the interactions between plasma and the components in food matrix are not well-understood. The <b>overall goals</b> of this dissertation were to 1) evaluate the interactions between high voltage atmospheric cold plasma (HVACP) and microbes in liquid and semi-solid food; 2) investigate plasma transfer into semi-solid foods and determine the relationship between microbial inactivation and plasma transfer; 3) explore the interactions between plasma and proteins. </p> <p>The first study explored the microbial (<i>Salmonella</i> <i>enterica</i> serovar Typhimurium, <i>S</i>. <i>enterica</i>) inactivation efficacy of HVACP. The physicochemical interactions between HVACP and biomolecules, including an enzyme (pectin methylesterase, PME), vitamin C and other components in orange juice (OJ) under different conditions was also evaluated. Both direct and indirect HVACP treatment of 25 mL OJ induced greater than a 5 log reduction in <i>S</i>. <i>enterica</i> following 30 s of treatment with air and MA65 gas with no storage. For 50 mL OJ, 120 s of direct HVACP treatment followed by 24 h storage achieved <i>S</i>. <i>enterica</i> reductions of 2.9 log in air and 4.7 log in MA65 gas. An indirect HVACP treatment of 120 s followed by 24 hours storage resulted in a 2.2 log reduction in air and a 3.8 log reduction in MA65. No significant (<i>P </i>< 0.05) Brix or pH change occurred following 120 s HVACP treatment. HVACP direct treatment reduced vitamin C content by 56% in air and PME activity by 74% in air and 82% in MA65. These results demonstrated that HVACP can significantly reduce <i>Salmonella</i> in OJ with minimal quality degradation.</p> <p>The second study in this dissertation examined the penetration process of plasma into semi-solid food and the resulting microbial inactivation efficacy. Agar gels of various densities (0.25, 0.5, 1.0, and 2%) with a pH indicator were inoculated with <i>S</i>. <i>enterica</i> (10⁷>CFU) and exposed directly (between the electrode) or indirectly (adjacent to the plasma field created between the two electrodes) to 90 kV at 60 Hz for up to 1.5 h. A long treatment time (1.5 h) caused sample temperature to increase 5~10 °C. The microbial analysis indicated a greater than 6 log₁₀ (CFU) reduction (both with air and MA65) in the zone with a pH change. Inactivation of bioluminescence cells in the plasma penetrated zone confirmed that the plasma, and its generated reactive species, inactivate microbial as it penetrates into the gel. A two-minute HVACP direct treatment with air at 90 kV induced greater than 5 log₁₀ (CFU)<i> S</i>. <i>enterica </i>reduction in applesauce. <em></em></p> <p>The third study investigated the interactions between HVACP and protein, using bovine serum albumin (BSA) as a model protein. The physicochemical and structural alteration of BSA and its reaction mechanism, when subjected to HVACP, were investigated. After treating 10 mL of BSA solution (50 mg/mL) at 90 kV for 20, 40, or 60 min, we characterized structural alteration and side-group modification. FTIR spectroscopy, Raman spectroscopy, and circular dichroism analysis indicated protein unfolding and decreased secondary structure (25 % loss of α-helix, 12% loss of β-sheet) in HVACP treated BSA. Average particle size in the protein solutions increased from 10 nm to 113 µm, with a broader distribution after 60 min HVACP treatment indicating protein aggregation. SDS-PAGE and mass spectrometer analysis observed a formation of new peptides of 1 to 10 kDa, indicating that the plasma triggered peptide bond cleavage. Chemical analysis and mass spectrometer results confirmed the plasma modifications on the side chains of amino acids. This study reveals that HVACP treatment may effectively introduce structural alteration, protein aggregation, peptide cleavage, and side-group modification to proteins in aqueous conditions, through several physicochemical interactions between plasma reactive species (reactive oxygen species and reactive nitrogen species) and the proteins. This finding can be readily applied to other plasma-protein studies or applications in the food system, such as enzyme inactivation or protein-based film modifications.</p>

Nuclear Engineering

Food Engineering

Food Packaging, Preservation and Safety

Food Processing

Atmospheric Cold Plasma

Microbial Inactivation

Plasma Penetration

Protein Modification

Physiochemical Interactions

Salmonella enterica serovar Typhi

Metal mediated mechanisms of drug release

Stenton, Benjamin James

January 2018

In this thesis will be described research towards the development of bioorthogonal bond-cleavage reactions, and their applications in targeted drug delivery (Figure 1). The first project relates to the development of a palladium mediated bond-cleavage or "decaging" reaction which can cause a propargyl carbamate to decompose and release an amine. This was further developed by the incorporation of a protein modification handle which allowed an amine-bearing drug to be covalently ligated to a protein by a palladium-cleavable linker. This chemistry was demonstrated by the conjugation of the anticancer drug doxorubicin to a tumour targeted anti-HER2 nanobody. The drug could then be delivered to cancer cells upon addition of a palladium complex. The second project relates to the development of a platinum mediated bond-cleavage reaction. This was developed with the aim of using platinum-containing anticancer drugs - such as cisplatin - as a catalyst to cause drug release reactions in tumours. In this reaction an alkyne-containing amide can decompose to release an amine upon addition of platinum complexes, and was applied to the release of prodrugs of the cytotoxins monomethylauristatin E and 5-fluorouracil in cancer cells. A cisplatin-cleavable antibody-drug conjugate was designed and synthesised, and progress towards its biological evaluation will be discussed.

Post-translational generation of Cá-formylglycine in Prokaryotic Sulfatsases by Radical SAM-Proteins / Posttranslationale Bildung von Cá-formylglycine in Prokaryotischen bakterieller Sulfatasen durch Radikal-SAM-Proteine

Fang, Qinghua

22 January 2004

No description available.

Mathematics and Computer Science

Formylglycine

Proteine Modifikation

Radikal-SAM-Proteine

Sulfatasen

S-adenosylmethionine

570 Biowissenschaften

Biologie

Formylglycine

protein modification

radical-SAM-protein

sulfatase

S-adenosylmethionine

42

WA