Exploration des modifications post-traductionnelles des protéines : nouvelles approches et nouveaux modèles biologiques / Exploration of protein post-translational modifications : new approaches and novel biological models

Dedieu, Alain

26 November 2014

L'étude des modifications post-traductionnelles a connu au cours des dernières années un regain d'intérêt notable. Tout d'abord car elle s'effectue aujourd'hui au travers d'approches basées sur la spectrométrie de masse, technique qui pendant cette période a connu de profonds bouleversements, conduisant à des études plus aisées et systématiques.Mais aussi car tant par leur variété que par le rôle qu'elles jouent dans la vie et la régulation cellulaire, ces modifications ne peuvent plus être négligées. Par ailleurs au cours de ces quinze dernières années, nous avons assisté concernant les procaryotes à un changement total de paradigme. En effet à la fin des années 90, l'idée dominante était que ces modifications pouvaient exister chez ceux-ci mais de façon très partielle et/ou très particulière.Dans ce travail, les divers degrés d'iodation de la tyrosine ont été sondés par une approche de type «shotgun » sur un organe entier, la thyroïde de souris. L'efficacité de ce type d'approche démontrée, les modifications post-traductionnelles potentiellement présentes dans des organismes modèles radiorésistants, la bactérie Deinococcus deserti et l'archée Thermococcus gammatolerans ont été analysées. Dans le premier cas, les données de protéomique montrent que de nombreuses acétylations N-terminales portent sur un motif spécifique (essentiellement des thréonines et sérines), cas très atypique pour une bactérie. Chez Thermococcus gammatolerans les acétylations N-terminales sont rares, mais la présence d'acétylations sur les chaînes latérales des lysines est notable. La présence de phosphorylations sur ces mêmes protéines, laisse entrevoir un possible phénomène de « cross talk » entre les lysines acétylées et les sérines et/ou thréonines phosphorylées.Ici, nous démontrons que la complexité du protéome chez les procaryotes par le biais des MPT est bien réelle et que de possibles interdépendances entre MPT mériteraient un regard nouveau. / Recently, the study of post-translational modifications has greatly evolved, mainly because of crucial progresses in mass spectrometry methodology which have allowed high-throughput, high resolution analysis. Their variety and their role in the regulation of key molecular mechanisms are increasingly documented. In this work, the different degrees of iodination of tyrosine were probed with a "shotgun" approach carried out from an entire organ, the mice thyroid. Post-translational modifications present in two radioresistant organism models, the bacterium Deinococcus deserti and the archaeon Thermococcus gammatolerans, were analyzed. The large scale exploration of N-terminal acetylation in D. deserti indicates a specific pattern of this modification on serine and threonine, as well as an atypical, high propension to acetylation with 50% of modified N-termini. In T. gammatolerans, N-terminal acetylation is rare, but the presence of acetylation on lysine side chains is significant. The presence of phosphorylation on these proteins suggests a potential "cross talk" between the acetylated lysine and phosphorylated serine or threonine residues. This work demonstrates that the complexity of the proteome in prokaryotes through post-translational modifications is higher than expected when extremophiles are scrutinized compared to classical prokaryote models. Interdependencies between post-translational modifications definitively deserve a fresher look.

Modifications post-Traductionnelles MPT

Spectrométrie de masse

Procaryote

Radio-Résistant

Acétylations N-Terminales

Acétylations des lysines

Post-Translational modifications PTM

Mass spectrometry

Prokaryote

Radio-Resistant

N-Terminal acetymations

Lysine acetylations

577

Molekulární mechanismy signalizace Wnt v savčích buňkách / Molecular mechanisms of Wnt signalling in mammalian cells

Lukáš, Jan

January 2013

Wnt signalling represents an important mechanism participating in control of cellular and developmental processes, including establishment of cell polarity, cell fate specification, stem cell self-renewal, tissue patterning and organogenesis, homeostasis maintenance and regeneration. Misregulation of the Wnt signalling during embryogenesis leads to developmental defects while aberrant activation later in development is associated with degenerative diseases and a number of cancers. The presented PhD thesis is based on four original publications that deal with the post-translational modifications of Wnt ligands and molecular mechanisms contributing to the regulation of a transcriptional profile of the so-called canonical Wnt pathway. Wnt signalling pathway is used repetitively both in time and different cellular contexts throughout development of multicellular organisms. Inevitably, in each single situation -catenin/TCF complexes, the downstream effectors, induce only subsets of all potential target genes. How this differential tissue- and stage-specific control over various subsets of target genes is achieved with such a limited number of nuclear effectors is not fully understood. Along with the expression of specific LEF/TCF family members or their variants containing different functional domains...

Contribution à l’étude de la régulation des complexes respiratoires par la phosphorylation chez Saccharomyces cerevisiae : -Etude générale du protéome et du phosphoprotéome mitochondrial selon le métabolisme -Cas particulier de deux sous-unités du complexe cytochrome c oxydase / Contribution to the Study of Regulation of Respiratory Complexes by Phosphorylation in Saccharomyces cerevisiae : -General Proteomic and Phosphoproteomic Analysis of Mitochondria According to Metabolism -Particular Study of two Subunits of Complex Cytochrome c Oxidase

Renvoisé, Margaux

13 October 2014

La phosphorylation oxydative est un processus majeur du métabolisme énergétique qui est catalysée par les enzymes de la chaîne respiratoire (OXPHOS), localisées dans la membrane interne des mitochondries. Sa dérégulation est souvent associée à des pathologies, par exemple aux maladies mitochondriales et neurodégénératives. La régulation de la phosphorylation oxydative par la phosphorylation reste encore peu comprise et peu étudiée. Pourtant, la phosphorylation est une des modifications post-traductionnelles les plus répandues dans la cellule, régulant de nombreux aspects de la vie cellulaire et dont l’altération est associée à des pathologies au niveau cellulaire (Alzheimer, Parkinson, cancer). Concernant la phosphorylation oxydative, il est à noter que quelques sites de phosphorylation des complexes respiratoires, en particulier du complexe IV, ont été montrés comme ayant un effet sur leur stabilité et/ou leur activité. Toutefois la connaissance du phosphoprotéome mitochondrial n’est pas suffisamment documentée à ce jour pour identifier les différents rôles que pourraient jouer la phosphorylation au niveau de la mitochondrie et en particulier, de la chaîne respiratoire. Dans la première partie de la thèse, nous nous sommes intéressés à l’analyse du phosphoprotéome mitochondrial de Saccharomyces cerevisiae dans trois conditions de culture : respiratoire (YLAC), respiro-fermentaire (YPGalA) et fermentaire (YPGA). Nous avons quantifiés près de 300 sites de phosphorylation dans la mitochondrie, dont 90 ont un niveau de phosphorylation variable selon le substrat. Les données que nous avons obtenues constituent une base pour l’analyse de la phosphorylation mitochondriale et de la compréhension de son mécanisme. Les sites de phosphorylation de la voie métabolique énergie sont ceux présentant le plus de variation de leur niveau de phosphorylation. La localisation des résidus phosphorylés sur la structure des complexes respiratoires nous a permis d’émettre des hypothèses sur le rôle de ces résidus. Afin de normaliser la quantité des résidus phosphorylés dans les trois conditions de culture, nous avons aussi quantifié le protéome mitochondrial dans les trois conditions de culture. Ceci nous a permis d’argumenter en faveur d’un métabolisme respiro-fermentaire en YPGalA, question encore largement discutée à ce jour. Enfin, cette première étude quantitative du protéome et phosphoprotéome mitochondrial constitue une avancée dans l’étude de la régulation de la mitochondrie par la phosphorylation. Elle peut notamment apporter des informations applicables à l’étude du cancer : en effet, les cellules saines ont un métabolisme respiratoire tandis que les cellules tumorales, dérégulées, ont un métabolisme fermentaire. La seconde partie de la thèse concerne l’analyse du rôle de deux sous-unités du complexe IV de la chaîne respiratoire : les sous-unités Cox12p et Cox13p, encore peu étudiées à ce jour. De plus, deux sites de phosphorylation ont été identifiés sur la sous-unité Cox12p. Dans un premier temps, nous nous sommes intéressés au rôle de ces sous-unités, notamment au niveau de l’assemblage et de l’activité du complexe IV, en analysant des mutants Δcox12, Δcox13 et Δcox12Δcox13. Dans un deuxième temps, nous nous sommes intéressés au rôle des deux sites de phosphorylation de Cox12p : Ser7 et ser82. Nous avons généré les mutants phosphomimétiques de ces deux résidus et étudié leurs effets sur la stabilité et/ou l’activité du complexe IV. Cette seconde étude nous a notamment permis d’identifier un rôle de Cox12p sur la stabilité du complexe et un rôle de Cox13p dans sa dimérisation. La phosphorylation de Cox12p au niveau de la Ser7 semble aussi déstabiliser le complexe IV. De plus, la phosphorylation de la Ser7 et de la Ser82 semblent influencer l’interaction du cytochrome c avec le complexe IV. Cette hypothèse reste à vérifier mais est pertinente du fait de la proximité de Cox12p avec Cox2p, qui porte le lieu de fixation du cytochrome c. / Mitochondria are the powerhouses of cells, providing energy in the form of adenosine triphosphate (ATP). The synthesis of ATP is achieved by oxidative phosphorylation (OXPHOS), a process catalyzed by the respiratory chain, which is located in the inner membrane of mitochondria. Deregulation of OXPHOS is often associated to diseases. Deregulation is particularly observed in mitochondrial diseases and neurodegenerative diseases, but regulation of respiration by phosphorylation is still poorly understood.However, phosphorylation is one of the most frequent post-translational modifications in the cell, modulating most processes, and defects at a cellular level are observed in some diseases (Alzheimer, Parkinson, cancer). Moreover, some phosphorylation sites have been identified in the respiratory complexes, particularly in the complex IV; some of them have an effect on the stability and/or activity of the complex, but we still lack a comprehensive study about mitochondrial phosphoproteome. Such analysis would be necessary to extend the role of phosphorylation in the regulation of mitochondrial functions in general, and in the regulation of the respiratory chain in particular.In the first part of this thesis, we focused on the analysis of the mitochondrial phosphoproteome of Saccharomyces cerevisiae. We studied the mitochondrial phosphoproteome in three growth conditions: in the respiratory condition (YLAC), in the fermentable condition (YPGA) and in an intermediate one (YPGalA). We quantified around 300 mitochondrial phosphorylation sites in which 90 displayed a different level of phosphorylation according to the substrate. This study is a first step towards understanding mitochondrial phosphorylation and its mechanism. Phosphorylation sites with varying levels of phosphorylation according to their conditions are mostly located on proteins involved in energy metabolism. We localized the phosphosites on the structure of the respiratory complexes when it was possible. This allowed us to make hypotheses on the role of these residues. In order to normalize the quantity of phosphorylation sites in the three growth conditions, we also studied the mitochondrial proteome in the three conditions. These results helped us to understand the energetic metabolism of galactose, which is surely intermediate between respiration and fementation, a question still debated nowadays.Finally this proteomic and phosphoproteomic study is a step forward in the comprehension of regulation of mitochondria by phosphorylation. These results can be used as a model to study cancer cells because they display a deregulation in the energetic metabolism: normal cells display respiratory metabolism whereas cancer cells exhibit fermentable metabolism.The second part of this thesis was the study of two subunits of complex IV of the respiratory chain: Cox12p and Cox13p, which had been poorly studied. Moreover, two phosphorylation sites had been identified in the subunit Cox12p. First we were interested in the role of these two proteins, thus we compared the mitochondria of mutants Δcox12, Δcox13 et Δcox12Δcox13 with wild-type mitochondria. We particularly focused on the assembly and the activity of complex IV. Secondly, we analyzed the role of the two phosphosites of Cox12p: Ser7 and Ser82. We generated phosphomimetic mutants of these two residues and observed their effects on the stability and/or activity of complex IV.All of these results allowed us to identify a role of Cox12p in the stability of complex IV and a role of Cox13p in the dimerization of complex IV. Phosphorylation of Ser7 of Cox12p seemed to destabilize the complex. Moreover phosphorylation of both Ser7 and Ser82 of Cox12p seemed to modify the interaction between cytochrome c and complex IV; this hypothesis remains to be tested but is relevant according to the proximity between Cox12p and the subunit Cox2p, where the cytochrome c interacts.

Protéome

Phosphoprotéome

Métabolisme carboné

Saccharomyces cerevisiae

Mitochondrie

OXPHOS

Cytochrome c oxydase

Modifications post-traductionnelles

Phosphorylation

Proteome

Phosphoproteome

Carbon metabolism

Saccharomyces cerevisiae

Mitochondria

OXPHOS

Cytochrome c oxidase

Post-translational modifications

Phosphorylation

Multi-Level Regulation Of Argininosuccinate Synthase: Significance For Endothelial Nitric Oxide Production

Corbin, Karen Davidowitz

17 November 2008

The citrulline-nitric oxide (NO) cycle, comprised of the enzymes argininosuccinate synthase (AS), argininosuccinate lyase (AL) and endothelial nitric oxide synthase (eNOS), is responsible for the regulated production of endothelial NO. Although most studies have focused on eNOS to uncover important regulatory mechanisms, we and others have determined that AS is an essential and regulated step in endothelial NO production. AS is rate limiting for endothelial NO production and is the primary source of arginine, the substrate for eNOS-mediated NO production, despite saturating intracellular levels of arginine and available arginine transport systems. AS is essential for endothelial cell viability and its expression is regulated coordinately with eNOS by TNF and thiazolidenediones with concomitant effects on NO production. Given the importance of AS for endothelial health, we explored three independent regulatory mechanisms. In Chapter One, the functional consequences of altered AS expression due to overexpression, insulin, VEGF and ceramide were studied. We demonstrated that overexpression of AS leads to enhanced NO production and that insulin, VEGF and ceramide coordinately regulate the expression of AS and eNOS. In Chapter Two, the first post-translational modifications of AS in the endothelium were characterized. We determined that AS is an endogenous phosphoprotein in the endothelium, described several levels of biological significance of AS phosphorylation, identified 7 sites of AS phosphorylation and began to uncover the direct impact of phosphorylation on AS function. Finally, in Chapter Three, endothelial AS subcellular localization was defined and important protein interactions were identified including caveolin-1 and HSP90. The work presented in this dissertation demonstrates that multiple mechanisms regulate the function of AS, often coordinately with eNOS, and have a direct impact on nitric oxide production. Our findings suggest that the global understanding of the citrulline-NO cycle as a metabolic unit will unravel new paradigms that will re-define our understanding of the regulation of vascular function by NO.

insulin

vascular endothelial growth factor

bradykinin

ceramide

kinase

phosphorylation

post-translational modifications

heat shock protein 90

caveolin

endothelial nitric oxide synthase

subcellular localization

protein interactions

American Studies

Arts and Humanities

Visualization of Protein Activity Status in situ Using Proximity Ligation Assays

Jarvius, Malin

January 2010

In 2001 the human proteome organization (HUPO) was created with the ambition to identify and characterize all proteins encoded in the human genome according to several criteria; their expression levels in different tissues and under different conditions; the sub-cellular localization; post-translational modifications; interactions, and if possible also the relationship between their structure and function.When the knowledge of different proteins and their potential interactions increases, so does the need for methods able to unravel the nature of molecular processes in cells and organized tissues, and ultimately for clinical use in samples obtained from patients. The in situ proximity ligation assay (in situ PLA) was developed to provide localized detection of proteins, post-translational modifications and protein-protein interactions in fixed cells and tissues. Dual recognition of the target or interacting targets is a prerequisite for the creation of a circular reporter DNA molecule, which subsequently is locally amplified for visualization of individual protein molecules in single cells. These features offer the high sensitivity and selectivity required for detection of even rare target molecules. Herein in situ PLA was first established and then employed as a tool for detection of both interactions and post-translational modifications in cultured cells and tissue samples. In situ PLA was also adapted to high content screening (HCS) for therapeutic effects, where it was applied for cell-based drug screening of inhibitors influencing post-translational modifications. This was performed using primary cells, paving the way for evaluation of drug effects on cells from patient as a diagnostic tool in personalized medicine. In conclusion, this thesis describes the development and applications of in situ PLA as a tool to study proteins, post-translational modifications and protein-protein interactions in genetically unmodified cells and tissues, and for clinical interactomics.

proximity ligation

in situ

high content screening

platelet-derived growth factor receptor

rolling circle amplification

protein interactions

in situ PLA

post-translational modifications

drug screening

Molecular biology

Molekylärbiologi

Pou5f1 Post-translational Modifications Modulate Gene Expression and Cell Fate

Campbell, Pearl

20 December 2012

Embryonic stem cells (ESCs) are characterized by their unlimited capacity for self-renewal and the ability to contribute to every lineage of the developing embryo. The promoters of developmentally regulated loci within these cells are marked by coincident epigenetic modifications of gene activation and repression, termed bivalent domains. Trithorax group (TrxG) and Polycomb Group (PcG) proteins respectively place these epigenetic marks on chromatin and extensively colocalize with Oct4 in ESCs. Although it appears that these cells are poised and ready for differentiation, the switch that permits this transition is critically held in check. The derepression of bivalent domains upon knockdown of Oct4 or PcG underscores their respective roles in maintaining the pluripotent state through epigenetic regulation of chromatin structure. The mechanisms that facilitate the recruitment and retention of Oct4, TrxG, and PcG proteins at developmentally regulated loci to maintain the pluripotent state, however, remain unknown. Oct4 may function as either a transcriptional activator or repressor. Prevailing thought holds that both of these activities are required to maintain the pluripotent state through activation of genes implicated in pluripotency and cell-cycle control with concomitant repression of genes required for differentiation and lineage-specific differentiation. More recent evidence however, suggests that the activator function of Oct4 may play a more critical role in maintaining the pluripotent state (Hammachi et al., 2012). The purpose of the studies described in this dissertation was to clarify the underlying mechanisms by which Oct4 functions in transcriptional activation and repression. By so doing, we wished to contextualize its role in pluripotent cells, and to provide insight into how changes in Oct4 function might account for its ability to facilitate cell fate transitions. As a result of our studies we find that Oct4 function is dependent upon post-translational modifications (PTMs). We find through a combination of experimental approaches, including genome-wide microarray analysis, bioinformatics, chromatin immunoprecipitation, functional molecular, and biochemical analyses, that in the pluripotent state Oct4, Akt, and Hmgb2 participate in a regulatory feedback loop. Akt-mediated phosphorylation of Oct4 facilitates interaction with PcG recruiter Hmgb2. Consequently, Hmgb2 functions as a context dependent modulator of Akt and Oct4 function, promoting transcriptional poise at Oct4 bound loci. Sumoylation of Oct4 is then required to maintain Hmgb2 enrichment at repressed loci and to transmit the H3K27me3 mark in daughter progeny. The expression of Oct4 phosphorylation mutants however, leads to Akt inactivation and initiates the DNA Damage Checkpoint response. Our results suggest that this may subsequently facilitate chromatin reorganization and cell fate transitions. In summary, our results suggest that controlled modulation of Oct4, Akt, and Hmgb2 function is required to maintain pluripotency and for the faithful induction of transcriptional programs required for lineage specific differentiation.

Oct4

pluripotency

stem cells

Akt

Polycomb Group Proteins

Trithorax Group Proteins

transcriptional regulation

transcriptional regulatory network

cancer

cell cycle checkpoint function

cell fate transitions

cell cycle

SET complex

Hmgb2

post-translational modifications

Pou5f1

Signal Transduction

embryonic stem cells

Set

The influence of post-translational modifications on biology of the linker histone HIS-24 in Caenorhabditis elegans / Der Einfluss posttranslationaler Modifikationen auf die Biologie des Linker-Histons HIS-24 in Caenorhabditis elegans

Studencka, Maja

11 June 2012

No description available.

570 Biowissenschaften, Biologie

WF 200

Biology (incl. Psychology)

Linker-Histon

Heterochromatin Proteine 1

posttranslationaler Modifikationen

Hox-Gene

C. elegans

linker histone

heterochromatin protein 1

post-translational modifications

Hox genes

C. elegans

42

Analytical strategies for the comprehensive profiling of histone post translational modifications by mass spectrometry and implications for functional analyses

Drogaris, Paul

11 1900

Le long bio-polymère d'ADN est condensé à l’intérieur du noyau des cellules eukaryotes à l'aide de petites protéines appelées histones. En plus de leurs fonctions condensatrices,ces histones sont également la cible de nombreuses modifications post-traductionnelles(MPT), particulièrement au niveau de leur section N-terminale. Ces modifications réversibles font partie d’un code d’histones épi-génétique transmissible qui orchestre et module dynamiquement certains événements impliquant la chromatine, tels l’activation et la désactivation de gènes ainsi que la duplication et la réparation d’ADN. Ces modifications sont impliquées subséquemment dans la signalisation et la progression de cancers, tels que la leucémie. En conséquence, l'élucidation des modifications d’histones est importante pour comprendre leurs fonctions biologiques. Une méthodologie analytique a été mise au point en laboratoire pour isoler, détecter, et quantifier les MPT d’histones en utilisant une approche rapide à deux volets à l’aide d’outils bioinformatiques spécialisés. La méthodologie développée en laboratoire a été validée en utilisant des histones de souche sauvage ainsi que deux types d’histones mutants déficients en enzymes acétyltransferase. Des trois sources d’histones utilisées, la seule MPT qui a démontré un changement significatif est l’acétylation de l’histone H3 à lysine 56 (H3K56ac). L’expression et la stoechiométrie de cette MPT, issue de cellules de souche sauvage et de cellules mutantes, ont été déterminées avec précision et comparées. Les fonctions de balayage polyvalentes d'un instrument à trappe ionique quadrupôle linéaire hybride ont été utilisées pour améliorer la détection de protéines intactes. Le mode de balayage « enhanced multiply charged » (EMC) a été modifié pour contenir et détecter les ions de protéines intactes situées dans la trappe ionique linéaire. Ce mode de balayage nommé « targeted EMC » (tEMC) a permis de quadrupler le niveau de sensibilité (signal/interférence), et quintupler la résolution du mode de balayage conventionnel. De plus, la capacité de séparation des charges du tEMC a réduit de façon significative les effets de « space charge » dans la trappe ionique linéaire. La résolution supérieure du mode tEMC a permis de différencier plusieurs isoformes modifiées, particulièrement pour l’histone H3. L’analyse des peptides d’histones trypsiques à l’aide du mode de balayage « MRM » a permis le séquençage et la quantification de MPT avec un haut degré de précision. La seule MPT qui était sous-exprimée entre l’histone de souche sauvage et le mutant DOT1L fut la méthylation de l’histone H3 lysine 79(H3K79me1). Les effets de deux inhibiteurs d’enzymes HDAC (HDACi) sur l’expression de MPT d’histone ont été évalués en utilisant la méthodologie analytique mentionnée. Les histones extraites de cellules normales et cancéreuses ont été exposées à du Vorinostat(SAHA) ou du Entinostat (MS-275) pour une période de 24 à 72 heures. Deux histones furent principalement affectées, soit H3 et H4. Étonnamment, les mêmes effets n'ont pas été détectés lorsque les cellules normales ont été traitées avec le HDACi pour une période de 48 à 72 heures. Une méthode absolue de quantification avec une courbe d’étalonnage a été développée pour le peptide H3K56ac. Contrairement à certaines publications, nos résultats démontrent que cette MPT est présente dans les cellules mammifères avec une stoechiométrie très basse (< 0,1%) et n'est pas surexprimée de façon significative après le traitement au HDACi. / In eukaryotic cells, the lengthy DNA biopolymer is condensed into the cell nucleus with the aid of small packaging proteins called histones. In addition to their packing functions,histones are also targets of numerous post translational modifications (PTMs), especially on their N-terminus. These reversible modifications are believed to be constituents of a heritable epigenetic “histone code” that dynamically orchestrate and modulate chromatin based events such as gene activation and silencing, DNA replication and repair, and are also involved in the downstream signaling and progression of cancers, such as leukemia. Thus, the elucidation of histone PTMs is important in understanding their biological function. An analytical workflow was designed and set-up in the laboratory to isolate, detect, and quantitate histone PTM, using a two-pronged, unbiased, and rapid approach with specialized bioinformatic tools. The workflow was validated using histones from wildtype, and 2 mutants deficient in acetyltransferase activity. Between the three histone sources, the only PTM that demonstrated any change was acetylation at histone H3 lysine 56 (H3K56ac). The down-regulation and stoichiometry of this PTM was accurately assessed between wild-type and mutant cells. The versatile scan functions of a hybrid quadrupole-linear ion trap instrument were exploited to enhance the detection of intact histone proteins. The enhanced multiply charged (EMC) scan was modified in order to contain and detect intact protein ions within the linear ion trap. This targeted EMC (or tEMC) resulted in not only a 4-fold increase in signal-to-noise, but also a 5-fold increase in resolution. Furthermore, the charge separation capability of the tEMC dramatically reduced space charge effects within the linear ion trap. The superior resolution of the tEMC mode allowed for the discimination of many modified histone isoforms, especially for histone H3. Using the bottom-up strategy with multiple reaction monitoring (MRM), histone peptides were quantified and sequenced with a high degree of precision. The only PTM that was down-regulated between wild-type and DOT1L mutant histones was methylation at histone H3 lysine 79 (H3K79me1). The effects of two clinically relevant small molecule HDAC inhibitors (HDACi) on histone PTMs patterns were assessed using the analytical workflow developed. Histones derived from both normal and cancer cells were exposed to either Vorinostat (SAHA) or Entinostat (MS-275) over a 24- to 72 hour period. The two core histones primarily affected were H3 and H4. Surprisingly, the same effects were not observed when normal cells were treated with three doses of SAHA at 24-hour intervals over a 72-hour period. An absolute quantitation method using a calibration curve was developed for H3K56ac. In opposition to other published literature, our findings demonstrate that this PTM is present in very low stoichiometry (< 0.1%) in mammalian cells, and exhibits no significant up-regulation in different cell lines treated with several types of HDACi.

Histones

Modifications post-traductionnelles

Spectrométrie de masse

nanoLC-MS/MS

Trappe ionique linéaire

Protéomique quantitative

Histones

Post-translational modifications

Mass spectrometry

nanoLC-MS/MS

Linear ion trap

Quantitative proteomics

Pou5f1 Post-translational Modifications Modulate Gene Expression and Cell Fate

Campbell, Pearl

20 December 2012

Embryonic stem cells (ESCs) are characterized by their unlimited capacity for self-renewal and the ability to contribute to every lineage of the developing embryo. The promoters of developmentally regulated loci within these cells are marked by coincident epigenetic modifications of gene activation and repression, termed bivalent domains. Trithorax group (TrxG) and Polycomb Group (PcG) proteins respectively place these epigenetic marks on chromatin and extensively colocalize with Oct4 in ESCs. Although it appears that these cells are poised and ready for differentiation, the switch that permits this transition is critically held in check. The derepression of bivalent domains upon knockdown of Oct4 or PcG underscores their respective roles in maintaining the pluripotent state through epigenetic regulation of chromatin structure. The mechanisms that facilitate the recruitment and retention of Oct4, TrxG, and PcG proteins at developmentally regulated loci to maintain the pluripotent state, however, remain unknown. Oct4 may function as either a transcriptional activator or repressor. Prevailing thought holds that both of these activities are required to maintain the pluripotent state through activation of genes implicated in pluripotency and cell-cycle control with concomitant repression of genes required for differentiation and lineage-specific differentiation. More recent evidence however, suggests that the activator function of Oct4 may play a more critical role in maintaining the pluripotent state (Hammachi et al., 2012). The purpose of the studies described in this dissertation was to clarify the underlying mechanisms by which Oct4 functions in transcriptional activation and repression. By so doing, we wished to contextualize its role in pluripotent cells, and to provide insight into how changes in Oct4 function might account for its ability to facilitate cell fate transitions. As a result of our studies we find that Oct4 function is dependent upon post-translational modifications (PTMs). We find through a combination of experimental approaches, including genome-wide microarray analysis, bioinformatics, chromatin immunoprecipitation, functional molecular, and biochemical analyses, that in the pluripotent state Oct4, Akt, and Hmgb2 participate in a regulatory feedback loop. Akt-mediated phosphorylation of Oct4 facilitates interaction with PcG recruiter Hmgb2. Consequently, Hmgb2 functions as a context dependent modulator of Akt and Oct4 function, promoting transcriptional poise at Oct4 bound loci. Sumoylation of Oct4 is then required to maintain Hmgb2 enrichment at repressed loci and to transmit the H3K27me3 mark in daughter progeny. The expression of Oct4 phosphorylation mutants however, leads to Akt inactivation and initiates the DNA Damage Checkpoint response. Our results suggest that this may subsequently facilitate chromatin reorganization and cell fate transitions. In summary, our results suggest that controlled modulation of Oct4, Akt, and Hmgb2 function is required to maintain pluripotency and for the faithful induction of transcriptional programs required for lineage specific differentiation.

Oct4

pluripotency

stem cells

Akt

Polycomb Group Proteins

Trithorax Group Proteins

transcriptional regulation

transcriptional regulatory network

cancer

cell cycle checkpoint function

cell fate transitions

cell cycle

SET complex

Hmgb2

post-translational modifications

Pou5f1

Signal Transduction

embryonic stem cells

Set

Etudes structurales et fonctionnelles des interactions de SUMO avec des proteines d'echafaudage modeles: TIF1beta, PIAS1 et PML

Mascle, Xavier H.

12 1900

L’adaptation des cellules à leur environnement externe repose sur la transduction adéquate de signaux régulés par une pléthore d'événements moléculaires. Parmi ces événements moléculaires, les modifications post-traductionnelles (MPT) de protéines aident à intégrer, à traduire et à organiser de façon spatiotemporelle ces signaux pour que les cellules puissent réagir aux stimuli externes. Parmi les modifications post-traductionnelles, les petites protéines de la famille de l’Ubiquitine (Ublps, Ubiquitin-like proteins) jouent un rôle majeur dans presque toutes les voies de signalisation. Cette thèse rapporte des études fonctionnelles et structurales des interactions covalentes et non covalentes entre SUMO (Small Ubiquitin related MOdifier), un membre de la famille des Ublps, et trois protéines d'échafaudage, TIF1beta, le corépresseur universel des protéines KRAB-multidoigt de zinc, PIAS1, une ligase E3 pour SUMO et PML, un suppresseur de tumeur. La première étude rapporte l'identification et la caractérisation biochimique des sites de SUMOylation de TIF1beta. Nous avons déterminé que la modification covalente de six résidus lysine par SUMO est essentielle à l’activité de répression de la transcription induit par TIF1beta. En outre, nous présentons des évidences indiquant que la SUMOylation de TIF1 exige non seulement sa capacité à homo-oligomériser, mais est aussi positivement régulée par son interaction avec le domaine KRAB des protéines à doigts de zinc. Partant de ce constat, nous postulons que les protéines KRAB-multidoigt de zinc recrutent leur corépresseur TIF1betaà des gènes cibles, mais aussi accentuent son activité répressive grâce à l'augmentation de sa SUMOylation. Notre seconde étude révèle qu’en plus de réprimer la transcription en tant que MPT covalente, SUMO joue aussi un rôle important dans la répression en tant que partenaire non covalent d’interactions protéine-protéine. Nous avons montré que SUMO interagit simultanément avec deux enzymes de la machinerie de SUMOylation, l’unique enzyme de conjugaison E2, UBC9, et la ligase E3 PIAS1 au sein d’un complexe ternaire répresseur. En outre, nous révélons que la formation du complexe ternaire PIAS1:SUMO:UBC9 est modulée par le niveau de phosphorylation de résidus sérine juxtaposés à un motif d’interaction avec SUMO (SIM) dans PIAS1. Ainsi, SUMO agit comme un adaptateur spécifique qui stabilise les interactions UBC9 E2: E3 PIAS1. Partant de ce constat, nous proposons que les enzymes E2 et E3 des autres systèmes Ublps exploitent des mécanismes similaires dans le cadre de leur fonction Enfin, notre troisième étude explore la régulation des interactions non covalentes de SUMO par la phosphorylation. En utilisant une combinaison d'études in vivo et in vitro, nous démontrons que l'interaction entre SUMO1 et PML est régi par la phosphorylation dépendant de CK2 sur quatre résidus sérine de PML. Les structures cristallographiques des complexes PML-SIM:SUMO1 révèlent que les phospho-sérines de PML contactent des résidus de la région basique de SUMO1. Sachant que la kinase CK2 peut être induite par des kinases activables par le stress, ces résultats suggèrent que les interactions non-covalentes avec SUMO sont modulées par le stress cellulaire. Sur la base de cette constatation, nous postulons que des événements analogues affectent des protéines contenant des séquences SIM ciblées par CK2. En résumé, cette étude révèle qu’en plus de son rôle de MPT, SUMO peut fonctionner comme un adaptateur permettant des interactions spécifiques entre protéines tel que pour les enzymes E3 et E2. / Cell adaption to the external environment relies on proper signal transduction that is orchestrated by a plethora of molecular events. Among these molecular events, post-translational modifications (PTMs) of proteins help to spatiotemporally integrate, translate and dispatch signals so cells can respond to external stimuli. Among these post-translational modifications, the Ubiquitin-like proteins (Ublps) play a major role in almost all signaling pathways. This thesis reports functional and structural studies of the covalent and non-covalent interactions between the Small Ubiquitin-related MOdifier (SUMO), a member of the Ublps family, and three scaffold proteins, TIF1beta, the corepressor of KRAB-Multifinger proteins, PIAS1, a SUMO E3 ligase and the Promyleocytic leukemia (PML) tumor suppressor protein. The first study reports the identification and the biochemical characterization of TIF1betaSUMOylation sites. We mapped six SUMOylation sites in TIF1beta and determined that the covalent modification of these sites by SUMO is essential for its transcriptional repression activity. In addition, we present evidence indicating that SUMOylation of TIF1beta requires not only its ability to homo-oligomerize, but is positively regulated through its interaction with KRAB domains found in zinc-finger proteins. Based on this finding, we postulate that these KRAB domain containing multifinger proteins not only recruit TIF1beta co-repressor to target genes but also increase its repressive activity through enhancement of its SUMOylation. The work in the second study reveals that in addition to suppressing transcription as a covalent PTM, SUMO plays an important role in repression as a non-covalent protein-protein interaction partner. We determine that SUMO can form a repressive complex by simultaneously forming non-covalent interactions with UBC9 and PIAS1, the E2 and E3 enzymes in the SUMOylation system. In addition, we report that the formation of the PIAS1:SUMO:UBC9 ternary complex is modulated by the phosphorylation of serine residues juxtaposed to a SUMO-Interacting Motif (SIM) found in PIAS1. Thus SUMO acts as a specific adaptor that stabilizes UBC9 E2: PIAS1 E3 interactions. Based on this finding, we propose that the E2 and E3 enzymes from other Ublps systems exploit similar mechanisms as part of their function Finally, our third study explores the regulation of SUMO non-covalent interactions by phosphorylation. Using a combination of in vivo and in vitro studies we demonstrate that the interaction between SUMO1 and PML is governed by CK2-dependent phosphorylation of four serine residues in PML. Crystal structures of PML-SIM:SUMO1 complexes reveal that these PML phospho-serine specifically contact SUMO1 basic patch residues. Since CK2 kinase is induced by stress activated kinases pathways, this indicates that SUMO non-covalent interactions are regulated by cellular stress. Based on this finding, we postulated that analogous events influence other CK2-targeted SIM-containing proteins. In summary, this study reveals that in addition to its well described function as PTM, SUMO can function as an adaptor enabling specific proteins interactions such as functional E3:E2 enzymes pairs.

Modifications post-traductionnelles

TIF1beta

PIAS1

UBC9

PML

phosphorylation

Kinase CK2

Enzyme de conjugaison E2

Enzyme de ligation E3

SUMOylation

Post-translational modifications

E2-conjugating enzyme

E3 ligase

TIF1beta

phosphorylation

CK2 kinase

SUMOylation