Dissertations / Theses on the topic 'Protein interactions (PPI)'

Proteinmethylierung spielt eine immer größere Rolle in der Regulierung zellulärer Prozesse. Die Entwicklung effizienter proteomweiter Methoden zur Detektion von Methylierung auf Proteinen ist limitiert und technisch schwierig. In dieser Arbeit haben wir einen neuen Hefe-Zwei-Hybrid-Ansatz (Y2H) entwickelt, der Proteine, die miteinander wechselwirken, mit Hilfe von Sequenzierungen der zweiten Generation identifiziert (Y2H-Seq). Der neue Y2H-Seq-Ansatz wurde systematisch mit dem Y2H-Seq-Ansatz verglichen. Dafür wurde ein Bait-Set von 8 Protein-Arginin-Methyltransferasen, 17 Protein-Lysin-Methyltransferasen und 10 Demethylasen gegen 14,268 Prey-Proteine getestet. Der Y2H-Seq-Ansatz ist weniger arbeitsintensiv, hat eine höhere Sensitivität als der Standard Y2H-Matrix-Ansatz und ist deshalb besonders geeignet, um schwache Interaktionen zwischen Substraten und Protein-Methyltransferasen zu detektieren. Insgesamt wurden 523 Wechselwirkungen zwischen 22 Bait-Proteinen und 324 Prey-Pr oteinen etabliert, darunter 11 bekannte Methyltransferasen-Substrate. Netzwerkanalysen zeigen, dass Methyltransferasen bevorzugt mit Transkriptionsregulatoren, DNA- und RNA-Bindeproteinen wechselwirken. Diese Daten repräsentieren das erste proteomweite Wechselwirkungsnetzwerk über Protein-Methyltransferasen und dienen als Ressource für neue potentielle Methylierungssubstrate. In einem in vitro Methylierungsassay wurden exemplarisch mit Hilfe massenspektrometrischer Analysen die methylierten Aminosäurereste einiger Kandidatenproteine bestimmt. Von neun getesteten Proteinen waren sieben methyliert, zu denen gehören SPIN2B, DNAJA3, QKI, SAMD3, OFCC1, SYNCRIP und WDR42A. Wahrscheinlich sind viele Methylierungssubstrate im Netzwerk vorhanden. Das vorgestellte Protein-Protein-Wechselwirkungsnetzwerk zeigt, dass Proteinmethylierung sehr unterschiedliche zelluläre Prozesse beeinflusst und ermöglicht die Aufstellung neuer Hypothesen über die Regulierung Molekularer Mechanismen durch Methylierung.
Protein methylation on arginine and lysine residues is a largely unexplored posttranslational modification which regulates diverse cellular processes. The development of efficient proteome-wide approaches for detecting protein methylation is limited and technically challenging. We developed a novel workload reduced yeast-two hybrid (Y2H) approach to detect protein-protein interactions utilizing second generation sequencing. The novel Y2H-seq approach was systematically evaluated against our state of the art Y2H-matrix screening approach and used to screen 8 protein arginine methyltransferases, 17 protein lysine methyltransferases and 10 demethylases against a set of 14,268 proteins. Comparison of the two approaches revealed a higher sensitivity of the new Y2H-seq approach. The increased sampling rate of the Y2H-seq approach is advantageous when assaying transient interactions between substrates and methyltransferases. Overall 523 interactions between 22 bait proteins and 324 prey proteins were identified including 11 proteins known to be methylated. Network analysis revealed enrichment of transcription regulator activity, DNA- and RNA-binding function of proteins interacting with protein methyltransferases. The dataset represents the first proteome-wide interaction network of enzymes involved in methylation and provides a comprehensively annotated resource of potential new methylation substrates. An in vitro methylation assay coupled to mass spectrometry revealed amino acid methylation of candidate proteins. Seven of nine proteins tested were methylated including SPIN2B, DNAJA3, QKI, SAMD3, OFCC1, SYNCRIP and WDR42A indicating that the interaction network is likely to contain many putative methyltransferase substrate pairs. The presented protein-protein interaction network demonstrates that protein methylation is involved in diverse cellular processes and can inform hypothesis driven investigation into molecular mechanisms regulated through methylation.

Clarifying the physico-chemical principles of protein-protein interactions is critically important to understand the relationships between biological structures and functions in all biochemical mechanisms. In this project we aim to develop, validate and apply new computational-theoretical methods to study and predict the binding regions of proteins starting from 3D structural information and from the analysis of the conformational and physico-chemical properties of the constituting amino acids. In particular, this project entails the integrated analysis of the energetic properties of different datasets of proteins solved at high resolution. In this context, we have focused on four main subjects with different, yet highly intertwined, objectives. The first subject will address the application of an energy-based computational predictor for the identification of possible antibody-binding surfaces (epitopes) of protein antigens from the pathogen Burkholderia pseudomallei, responsible for human melioidosis. The second will focus on the expansion of the same rationale, adapting the method towards different applications, and including as a novel functionality the prediction of MHC-II coupled epitopes to elicit the intervention of T helper cells. The third objective concerns the design and characterization of peptides and peptidomimetics to optimize the properties of the identified epitopes as better vaccine candidates. The fourth one will pursue the investigation of the energetic determinants of interacting proteins in a more general context (not limited to immunogenic epitopes), aiming at the identification of an energy-based property describing the interaction event at the atomistic level of resolution. This part of the project is aimed at the development of a computational tool based on such property to help improve the understanding of the determinants of protein interactions and help predict their binding interfaces and orientation. All four subjects have been investigated in the broad spectrum of activities of an academic consortium, devoted to the identification of antigens from B. pseudomallei showing sufficient immunogenic potential to be considered as components for a vaccine against the pathogen. The computational methods developed and tested within this framework have theoretical as well as practical implications, from the physico-chemical study and characterization of protein-protein interactions, to the design of biologically active molecules.

Veränderungen in phosphorylierungsabhängigen Signalwegen, Akkumulation von Proteinaggregaten im Gehirn und neuronaler Zelltod sind Neurodegenerationskennzeichen und Indikatoren für überlappende molekulare Mechanismen. Um Einblicke in die involvierten Signalwege zu erhalten, wurde mit Hilfe eines modifizierten Hefe-Zwei-Hybrid (Y2H)-Systems für 71 Proteine, die mit neurologischen Erkrankungen assoziiert sind, proteomweit nach Protein-Protein Interaktionen (PPIs) gesucht. Für 21 dieser Proteine wurden PPIs identifiziert. Das Gesamtnetzwerk besteht aus 79 Proteinen und 90 PPIs von denen 5 phosphorylierungsabhängig sind. Ein Teil dieser PPIs wurde in unabhängigen Interaktionsassays mit einer Validierungsrate von 66 % getestet. Der netzwerkbasierte Versuch verbindet erfolgreich neurologische Erkrankungen untereinander aber auch mit zellulären Prozessen. Ser/Thr-Kinase abhängige PPIs verknüpfen zum Beispiel das Parkinson Protein 7 (PARK7, DJ1) mit den E3 Ligase Komponenten ASB3 und RNF31 (HOIP). Die Funktion dieser Proteine bekräftigt den Zusammenhang zwischen dem Ubiquitin-Proteasom-System und der Parkinson Krankheit (PD). Neurofibromin 2 (NF2, merlin) Isoformen und PARK7 interagieren mit der regulatorischen PI3K Untereinheit p55-gamma (PIK3R3). Diese PPIs basieren auf Tyr-Kinase Aktivität im modifizierten Y2H System und funktionellen PIK3R3 pTyr-Erkennungsmodulen (SH2 Domänen) in co-IP und Venus PCA Versuchen. Dies verknüpft den PI3K/AKT Überlebenssignalweg mit zwei unterschiedlichen neurologischen Erkrankungsphenotypen: dem PD assoziierten neuronalen Zelltod und der Neurofibromatose Typ 2-assoziierten Tumorentstehung. Die vergleichende Beobachtung von PIK3R3, AOF2 (KDM1A, LSD1) Interaktionen auf NF2 Isoformlevel offenbart eine Bevorzugung von Isoform 7 bei zytoplasmatischer Lokalisation, wohingegen Isoform 1 PPIs an der Membran lokalisiert sind. Das modifizierungsabhängige und isoformspezifische PPI Netzwerk ermöglichte neue Hypothesen zu molekularen Pathomechanismen.
Alterations in phosphorylation-dependent signalling pathways, accumulation of aggregated proteins in the brain and neuronal apoptosis are common to neurodegeneration and implicate overlapping molecular mechanism. To gain insight into involved pathways, a modified yeast-two hybrid (Y2H) system was applied to screen 71 proteins associated with neurological disorders in a proteome-wide manner. For 21 of these proteins interactions were identified including 5 phosphorylation-dependent ones. In total, the network connected 79 proteins through 90 protein-protein interactions (PPIs). A fraction of these Y2H PPIs was tested in secondary interaction assays with a validation rate of 66 %. The described network-based approach successfully identified proteins associated with more than one disorder and cellular functions connected to specific disorders. In particular, the network revealed Ser/Thr kinase-dependent PPIs between the Parkinson protein 7 (PARK7, DJ1) and the E3 ligase components ASB3 and RNF31 (HOIP). The function of these proteins further substantiates the established connection between Parkinson’s disease (PD) and ubiquitination-mediated proteasome (dis)functions. Neurofibromin 2 (NF2, merlin) isoforms and PARK7 were identified as PI3K regulatory subunit p55-gamma (PIK3R3) interactors. These PPIs required Tyr kinase coexpression in the modified Y2H system and functional PIK3R3 pTyr-recognition modules (SH2 domains) in co-IP and Venus PCA experiments. This finding implicates the PI3K/AKT survival pathway in PD-associated neuronal apoptosis and Neurofibromatosis type 2-associated tumour formation. Investigation of PIK3R3, AOF2 (KDM1A, LSD1) and EMILIN1 PPIs on NF2 isoform level revealed preferential isoform 7 binding and cytoplasmic or membrane localisation of these PPIs for isoform 7 or 1, respectively. The generated modification-dependent and isoform-specific PPI network triggered many hypotheses on the molecular mechanisms implicated in neurological disorders.

O Transtorno de Déficit de Atenção e Hiperatividade (TDAH) é a doença do neurodesenvolvimento mais comum na infância, afetando cerca de 5,8% de crianças e adolescentes no mundo. Muitos estudos vêm tentando investigar a suscetibilidade genética em TDAH, mas sem muito sucesso. Este estudo teve como objetivo analisar variantes raras e comuns contribuindo para a arquitetura genética do TDAH. Foram gerados os primeiros dados de exoma de TDAH de 30 trios brasileiros em que o filho foi diagnosticado com TDAH esporádico. Foram analisados tanto variações de único nucleotídeo (ou SNVs, single-nucleotide variants) quanto variações de número de cópias (ou CNVs, copy-number variants), tanto nesses trios quanto em outros conjuntos de dados, incluindo uma amostra brasileira de 503 crianças/adolescentes controles, bem como resultados previamente publicados em quatro estudos com variação de número de cópias e uma meta-análise de estudos de associação ao longo do genoma. Tanto os trios quanto os controles fazem parte da Coorte de Escolares de Alto Risco para o desenvolvimento de Psicopatologia e Resiliência na Infância do Instituto Nacional de Psiquiatria do Desenvolvimento (INPD). Os resultados de trios brasileiros mostraram três padrões marcantes: casos com variações herdadas e somente SNVs de novo ou CNVs de novo, e casos somente com variações herdadas. Embora o tamanho amostral seja pequeno, pudemos ver que diferentes comorbidades são mais frequentes em casos somente com variações herdadas. Após explorarmos a composição de variações nos probandos brasileiros, foram selecionados genes recorrentes entre amostras do nosso estudo ou em bancos de dados públicos. Além disso, usando somente genes expressos no cérebro (amostras pós-mortem dos projetos Brain Atlas e Genotype-Tissue Expression), construímos uma rede de interação proteína-proteína \"in silico\" com interações físicas confirmadas por pelo menos duas fontes. Análises topológicas e funcionais dos genes da rede mostraram genes relacionados a sinapse, adesão celular, vias glutamatérgicas e serotonérgicas, o que confirma achados de trabalhos independentes na literatura indicando ainda novos genes e variantes genéticas nessas vias.
Attention-Deficit/Hyperactivity Disorder (ADHD) is the most common neuro-developmental disorder in children, affecting 5.8% of children and adolescents in the world. Many studies have attempted to investigate the genetic susceptibility of ADHD without much success. The present study aimed to analyze rare and common variants contributing to the genetic architecture of ADHD. We generated exome data from 30 Brazilian trios where the children were diagnosed with sporadic ADHD. We analyzed both single-nucleotide variants (SNVs) and copy-number variants (CNVs) in these trios and across multiple datasets, including a Brazilian sample of 503 children/adolescent controls from the High Risk Cohort Study for the Development of Childhood Psychiatric Disorders, and also previously published results of four CNV studies of ADHD involving children/adolescent Caucasian samples. The results from the Brazilian trios showed 3 major patterns: cases with inherited variations and de novo SNVs or de novo CNVs and cases with only inherited variations. Although the sample size is small, we could see that various comorbidities are more frequent in cases with only inherited variants. After exploring the rare variant composition in our 30 cases we selected genes with variations (SNVs or located in CNV regions) in our trio analysis that are recurrent in the families analyzed or in public data sets. Moreover, using only genes expressed in brain (post-mortem samples from Brain Atlas and The Genotype-Tissue Expression project), we constructed an in silico protein-protein interaction (PPI) network, with physical interactions confirmed by at least two sources. Topological and functional analyses of genes in this network uncovered genes related to synapse, cell adhesion, glutamatergic and serotoninergic pathways, both confirming findings of previous studies and capturing new genes and genetic variants in these pathways.

Les interactions protéine – protéine (IPP) sont essentielles à la régulation des phénomènes cellulaires. Elles impliquent deux partenaires : une protéine adaptatrice et une protéine effectrice, cette dernière étant régulée positivement ou négativement. Bien que l’inhibition des IPPs constitue une approche thérapeutique solide, la stabilisation reste encore peu étudiée, mais pourrait mener à de nouvelles modalités prometteuses. Ce projet se concentre sur la famille de protéines adaptatrices 14-3-3 qui interagit avec plus de 200 partenaires. Parmi eux, la protéine p53 est l’objet de multiples recherches dû à sa fonction régulatrice clé de nombreux processus biologiques (réparation de l’ADN, apoptose). Ces fonctions majeures sont cependant altérées dans la moitié des cancers, favorisant ainsi le développement tumoral. Des études préliminaires ont montré que la stabilisation de l’interaction entre p53 et 14-3-3 à l’aide d’une colle moléculaire permettait de restaurer l’activité antitumorale de p53. Parmi ces colles moléculaires, la fusicoccine-A (FC-A) se localise dans la vallée formée par 14-3-3 et permet d’augmenter la stabilisation du complexe protéique. Dans ce contexte, ce projet se concentre sur l’accès à des analogues simplifiés de la FC-A à travers la synthèse de squelettes tricycliques afin d’élargir la librairie de colles moléculaires. Des analogues [6-8-5] à partir d’un substrat aromatique sont envisagés, ainsi que des analogues [5-8-5] à partir d’un dérivé cyclopentane, plus proches de la structure cible. Différentes stratégies de synthèse ont été explorées afin d’accéder à ces analogues
In biological media, protein-protein interactions (PPI) are of huge importance, as they allow the regulation of many cellular events. PPI classically involve two partners: an adapter protein and its effector protein(s) regulated either in a positive or a negative manner. Inhibition of PPI has thus been considered as a solid therapeutic approach. On the other hand, stabilization of PPI remains scarcely investigated, but may lead to new promising approaches. This project focuses on the 14-3-3 family adapter protein which interacts with more than 200 protein partners. Among them, p53 protein is subjected to a lot of studies as this tumor suppressor protein regulates multiple biological processes (DNA repair, apoptosis). However, those major functions appear to be silenced in most cancer cases, thus allowing tumor cells proliferation. Some studies have shown that stabilization of the 14-3-3/p53 pair with the help of a molecular glue permitted to restore tumor suppressor activity of p53. Among the examined molecular glues, the fusicoccin-A (FC-A) natural product is shown to lodge in the valley formed by 14-3-3 and increases stabilization of the 14-3-3/p53 interaction. In this context, to enlarge the p53/14-3-3 molecular glue library, this project focuses on the access to simplified FC-A analogs through the synthesis of tricyclic scaffold. [6-8-5] analogs from an aromatic substrate are envisaged, as well as [5-8-5] analogs from a cyclopentane derivative, closer to the target structure. Various strategies have been explored in order to access these analogs

Precisely how Hephaestin (Heph) facilitate iron release from cells is poorly understood. The work in this thesis tried to establish the role of different iron metabolic proteins, Mitoferrin (Mfrn), IRPs and Heph in iron homeostasis. Analysis of 18 tagSNPs in the Mfrn gene was carried out in an AsianCaucasian population to establish any correlation between the Mfrn tagSNPs, haemoglobin levels and birth weight in the presence of covariates such as sex of the fetus, gestational age and mother's booking weight. Two-way ANCOVA analysis was carried out to check if the covariates have any influence on the dependent variable in the presence of fixed factors. From the ANCOVA analysis of Mfrn tagSN Ps it can be concluded that neither the haemoglobin levels nor the birth weight are dependent on the genotype, fetal sex, nor on their interaction. Owing to the significance in identifying the interacting partners of IRPs and Heph to understand more about their role in iron metabolism, protein-protein interaction studies were also carried out. IRPs and Heph genes were successfully cloned with One-Strep tag. Full length clones were sequence confirmed for any variation after PCR. Before carrying out immunoprecipitation to identify the interacting partners, transfection efficiency, viability and the role of magnetic particles on K562 cells was performed by using IRPs and Heph cloned with One-Strep tag. Lipofectamine-L TX plus transfection had more viable cells and higher efficiency compared with magnetic-assisted transfection . Also, this study confirms that magnetic nanoparticles do not have any adverse or significant effect on IRPs during the transfection. An unsuccessful attempt was made to identify the interacting partners of IRPs and Heph by immunoprecipitation. The current thesis work also involved identification of a potential ferroxidase . Ceruloplasmin (Cp) was used as a postive control. Non-denaturing gel eletrophoresis of the K562, MDA-MB-231 and PNT2-C2 cell fractions confirmed the presence of the extra band establishing the ubiquitous nature of the band. Mass spectrometry analysis identified the excised band as Calreticulin (CALR). This is the first report of calreticulin having ferroxidase activity.

Protein-peptide interactions play a major role in several biological processes, such as cellproliferation and cancer cell life-cycles. Accurate computational methods for predictingprotein-protein interactions exist, but few of these method can be extended to predictinginteractions between a protein and a particularly small or intrinsically disordered peptide. In this thesis, PePIP is presented. PePIP is a pipeline for predicting where on a given proteina given peptide will most probably bind. The pipeline utilizes structural aligning to perusethe Protein Data Bank for possible templates for the interaction to be predicted, using thelarger chain as the query. The possible templates are then evaluated as to whether they canrepresent the query protein and peptide using a Random Forest classifier machine learningalgorithm, and the best templates are found by using the evaluation from the Random Forest in combination with hierarchical clustering. These final templates are then combined to givea prediction of binding site. PePIP is proven to be highly accurate when testing on a set of 502 experimentally determinedprotein-peptide structures, suggesting a binding site on the correct part of the protein- surfaceroughly 4 out of 5 times.

Using computational methods to identify protein-protein interactions (PPIs) supports experimental techniques by using less time and less resources. Identifying PPIs can be made through a template-based approach that describes how unstudied proteins interact by aligning a common structural template that exists in both interacting proteins. A pipeline that uses this is InterPred, that combines homology modelling and massive template comparison to construct coarse interaction models. These models are reviewed by a machine learning classifier that classifies models that shows traits of being true, which can be further refined with a docking technique. However, InterPred is dependent on using complex structural information, that might not be available from unstudied proteins, while it is suggested that PPIs are dependent of the shape and interface of proteins. A method that aligns structures based on the interface attributes is InterComp, which uses topological and sequence-order independent structural comparison. Implementing this method into InterPred will lead to restricting structural information to the interface of proteins, which could lead to discovery of undetected PPI models. The result showed that the modified pipeline was not comparable based on the receiver operating characteristic (ROC) performance. However, the modified pipeline could identify new potential PPIs that were undetected by InterPred.

Doenças complexas são caracterizadas por serem poligênicas e multifatoriais, o que representa um desafio em relação à busca de genes relacionados a elas. Com o advento das tecnologias de sequenciamento em larga escala do genoma e das medições de expressão gênica (transcritoma), bem como o conhecimento de interações proteína-proteína, doenças complexas têm sido sistematicamente investigadas. Particularmente, baseando-se no paradigma Network Medicine, as redes de interação proteína-proteína (PPI -- Protein-Protein Interaction) têm sido utilizadas para priorizar genes relacionados às doenças complexas segundo suas características topológicas. Entretanto, as redes PPI são afetadas pelo viés da literatura, em que as proteínas mais estudadas tendem a ter mais conexões, degradando a qualidade dos resultados. Adicionalmente, métodos que utilizam somente redes PPI fornecem apenas resultados estáticos e não-específicos, uma vez que as topologias destas redes não são específicas de uma determinada doença. Neste trabalho, desenvolvemos uma metodologia para priorizar genes e vias biológicas relacionados à uma dada doença complexa, através de uma abordagem integrativa de dados de redes PPI, transcritômica e genômica, visando aumentar a replicabilidade dos diferentes estudos e a descoberta de novos genes associados à doença. Após a integração das redes PPI com dados de expressão gênica, aplicamos as hipóteses da Network Medicine à rede resultante para conectar genes sementes (relacionados à doença, definidos a partir de estudos de associação) através de caminhos mínimos que possuam maior co-expressão entre seus genes. Dados de expressão em duas condições (controle e doença) são usados separadamente para obter duas redes, em que cada nó (gene) dessas redes é pontuado segundo fatores topológicos e de co-expressão. Baseado nesta pontuação, desenvolvemos dois escores de ranqueamento: um que prioriza genes com maior alteração entre suas pontuações em cada condição, e outro que privilegia genes com a maior soma destas pontuações. A aplicação do método a três estudos envolvendo dados de expressão de esquizofrenia recuperou com sucesso genes diferencialmente co-expressos em duas condições, e ao mesmo tempo evitou o viés da literatura. Além disso, houve uma melhoria substancial na replicação dos resultados pelo método aplicado aos três estudos, que por métodos convencionais não alcançavam replicabilidade satisfatória.
Complex diseases are characterized as being poligenic and multifactorial, so this poses a challenge regarding the search for genes related to them. With the advent of high-throughput technologies for genome sequencing and gene expression measurements (transcriptome), as well as the knowledge of protein-protein interactions, complex diseases have been sistematically investigated. Particularly, Protein-Protein Interaction (PPI) networks have been used to prioritize genes related to complex diseases according to its topological features. However, PPI networks are affected by ascertainment bias, in which the most studied proteins tend to have more connections, degrading the quality of the results. Additionally, methods using only PPI networks can provide just static and non-specific results, since the topologies of these networks are not specific of a given disease. In this work, we developed a methodology to prioritize genes and biological pathways related to a given complex disease, through an approach that integrates data from PPI networks, transcriptomics and genomics, aiming to increase replicability of different studies and to discover new genes associated to the disease. The methodology integrates PPI network and gene expression data, and then applies the Network Medicine Hypotheses to the resulting network in order to connect seed genes (obtained from association studies) through shortest paths possessing larger coexpression among their genes. Gene expression data in two conditions (control and disease) are used to obtain two networks, where each node (gene) in these networks is rated according to topological and coexpression aspects. Based on this rating, we developed two ranking scores: one that prioritizes genes with the largest alteration between their ratings in each condition, and another that favors genes with the greatest sum of these scores. The application of this method to three studies involving schizophrenia expression data successfully recovered differentially co-expressed gene in two conditions, while avoiding the ascertainment bias. Furthermore, when applied to the three studies, the method achieved a substantial improvement in replication of results, while other conventional methods did not reach a satisfactory replicability.

RNA:protein interactions are central in many cellular processes, including activation of innate immune responses against microbial infection. Their study is essential to better understand the diverse biological events that occur within cells. However, isolation of RNA:protein complexes is often laborious and requires specialized techniques. This thesis is concerned with attempts to develop an improved purification protocol to isolate specific RNA:protein complexes. Taking advantage of the specific interaction of the Pseudomonas aeruginosa PP7 protein with its cognate RNA binding site, termed the PP7 recognition sequence (PRS), the aim was to identify cellular proteins involved in activating cell-signalling pathways, including the interferon-induction cascade, following viral infection with stocks of parainfluenza virus 5 (PIV5) rich in copyback defective interfering (DI) particles. Copyback DI genomes are powerful inducers of IFN and, here, I show they also activate the induction of IL-6, IL-8 and TNFα; cytokines that also have antiviral properties. Following the successful cloning of the PRS into a copyback DI genome, we investigated conditions for optimal in vitro capture of DI-PRS:protein complexes by PP7 on Dynabeads. When tested, the protocol led to the successful capture of ILF3 and PKR, two dsRNA binding proteins induced by IFN. We further developed a tap-tagging system to minimize the presence of non-specifically bound proteins to Dynabeads that may interfere with future mass spectrometry analysis. To isolate DI-PRS RNA:protein complexes from infected cells, attempts were made to rescue replicating DI-PRS genomes in the context of wild type PIV5. Similarly, efforts were made to isolate influenza A virus RNPs that contained the PRS in the neuraminidase (NA) gene from infected cells using the PP7-based protocol developed. However, for reasons discussed, unfortunately RNA:proteins complexes were not successfully purified from infected cells in either case.

Doutoramento em Bioquímica
The work presented in this Thesis investigates the dynamics and molecular interactions of p22HBP and the p22HBP-tetrapyrrole complex. Specifically, the key residues involved when a tetrapyrrole binds to p22HBP were sought. Previous molecular modelling studies identified three possible charged residues R56, K64 and K177 as possibly being important in tetrapyrrole binding via electrostatic interactions with the propionate groups of the tetrapyrrole. A number of variants of murine p22HBP were therefore prepared and fluorescence quenching and NMR used to verify the integrity of the variants and their interaction with tetrapyrrole. The same molecular modelling studies identified a mobile loop Y171-R180 in p22HBP that decreased in mobility on tetrapyrrole binding, therefore to confirm this mobility change dynamics studies based on NMR relaxation experiments were carried out. Finally in order to obtain a non heme-binding form of human p22HBP a chimeric p22HBP was designed and constructed. This construct, and the resulting protein, will be important for future siRNA knockdown studies where rescue or recovery of function experiments are required to prove the knockdown results. Chapter one discusses the current state of the art in terms of the biological, structural and functional aspects of p22HBP. The main objectives of the Thesis are also introduced here. Chapter two presents a detailed description of the different expression vectors (pNJ2 and pet28-a) and procedures used for overexpression and purification of murine p22HBP and its variants and human p22HBP. All expression and purification systems used gave good yields and allowed isotopic labeling to be carried out. The fluorescence quenching results for tetrapyrrole binding to murine p22HBP and variants are presented in chapter three along with the dissociation constants that were found to be in the nanomolar range for wild type murine and human p22HBP. The same studies were performed for murine p22HBP variants, with hydrophobic and polar changes being introduced at R56, K64 and K177. The dissociation constants were found to double in some cases but no significant changes in the strength of hemin-protein interactions were observed. The tetrapyrrole interaction with p22HBP was also followed by NMR spectroscopy, where chemical shift mapping was used to identify binding pocket location. All the variants and wild type human p22HBP were found to bind at the same location. Chapter 4 contains the data from 2D and 3D experiments carried out on 15N/13C labelled human p22HBP that was used to obtain backbone assignments. Comparison with wild type murine p22HBP assignments, PPIX titrations and theoretical calculations based on chemical shifts (Talos+) allowed 82% of the backbone resonances to be assigned. The results from the relaxation experiments used to probe the dynamics of the mobile loop in p22HBP on binding to tetrapyrrole are presented in chapter 5. The overall protein was found to tumble isotropically in the free and bound forms however the results to probe mobility changes in the 171-180 loop on tetrapyrrole binding proved inconclusive as only residue could be assigned and this did not seem to become significantly less mobile. The final chapter describes the design and construction of a chimeric p22HBP. For these purpose, the alfa1-helix sequence of human p22HBP in the phHBP1 plasmid was replaced by its homologous sequence in hSOUL, a non heme-binding protein with identical 3D structure. The results however indicated that either the incorrect sequence was introduced into the plasmid or the purification procedure was inadequate.
O trabalho apresentado nesta Tese focou-se na dinâmica e nas interações moleculares da p22HBP e do complexo p22HBP-tetrapirrol, nomeadamente nos resíduos chave envolvidos nesta interação. Estudos prévios de modelação molecular identificaram três possíveis resíduos chave R56, K64 e K177 como sendo importantes na interação com os tetrapirróis, através de interações eletrostáticas com os grupos propionato do tetrapirrol. Foram desenhados e construídos variantes da p22HBP murina e foram desenvolvidos estudos de extinção de fluorescência e RMN para avaliar a integridade dos variantes e a sua interação com os tetrapirróis. Os mesmos estudos de modelação molecular identificaram ainda uma zona flexível (Y171-R180) na p22HBP que diminui a mobilidade com a interação do tetrapirrol. Para confirmar esta alteração de mobilidade, foram realizados estudos de dinâmica, baseados em RMN. Por fim, com o intuito de obter uma versão não funcional da p22HBP humana, foi planeada e construída uma versão quimérica da p22HBP humana. No futuro, esta nova versão da p22HBP quimérica, será importante para os estudos de knockdown envolvendo siRNA. O capítulo um introduz uma revisão dos aspetos biológicos da p22HBP nomeadamente os estudos estruturais e as possíveis funções que foram identificadas. Os principais objetivos da tese são também apresentados neste capítulo. No capítulo dois é apresentada uma descrição detalhada dos diferentes vectores de sobreexpressão (pNJ2 e pet28-a) e dos métodos de sobreexpressão e purificação da p22HBP murina e respectivos variantes, bem como da p22HBP humana. Todos os sistemas de sobreexpressão e purificação utilizados obtiveram bons rendimentos e permitiram a marcação isotópica das proteínas. No capítulo 3 são apresentados os resultados de extinção de fluorescência para a interação da p22HBP murina e humana com hemina através das constantes de dissociação determinadas na ordem dos nanomolar. Os mesmos estudos foram realizados para os variantes da p22HBP murina, com alterações hidrofóbicas e de polaridade nos resíduos R56, K64 e K177. Em alguns casos, as constantes de dissociação determinadas são mais elevadas, embora não se tenham verificado alterações significativas na força da interação proteína-hemo. As interações tetrapirrólicas com a p22HBP foram também estudadas por espectroscopia de RMN, onde foram mapeadas as diferenças nos desvios químicos para identificar a localização da zona de interação. A localização da zona de interação dos variantes da p22HBP e a p2HBP humana mantém-se igual à p22HBP murina. No capítulo 4 encontram-se os resultados das experiências 2D e 3D realizadas na p22HBP humana, isotopicamente marcada com 15N/13C, para identificar as ressonâncias da cadeia principal. 82% dos sistemas de spin da cadeia principal foram identificados através da comparação com a p22HBP murina, das titulações com PPIX e de cálculos teóricos baseados nos desvios químicos (Talos+). No capítulo 5 são apresentados os resultados das experiências de relaxação, usados para comprovarem a dinâmica do loop na p22HBP aquando da interação com o tetrapirrol. A proteína no seu todo move-se de uma forma isotrópica na forma livre e ligada. No entanto os resultados para comprovar as alterações de mobilidade no loop 171-180 na presença de hemo, foram inconclusivos uma vez que só a um resíduo foi atribuído um sistema de spin, e não foi indicativo da perda significativa de mobilidade. O último capítulo descreve o planeamento e a construção da p22HBP quimérica. Para tal, a sequência que codifica a hélix alfa 1 da p22HBP humana, no plasmídeo phHBP1, foi substituída pela sequência homóloga da SOUL humana, uma proteína com uma estrutura 3D semelhante mas não liga ao hemo. Os resultados no entanto demonstraram que ou a sequência não foi introduzida corretamente no plasmídeo ou o sistema de purificação não foi adequado.

Tackling protein interfaces with small molecules capable of modulating protein-protein interactions remains a challenge in structure-based ligand design. Particularly arduous are cases in which the epitopes involved in molecular recognition have a non-structured and discontinuous nature. Here, the basic strategy of translating continuous binding epitopes into mimetic scaffolds cannot be applied, and other innovative approaches are therefore required. We present a structure-based rational approach involving the use of a regular expression syntax inspired in the well established PROSITE to define minimal descriptors of geometric and functional constraints signifying relevant functionalities for recognition in protein interfaces of non-continuous and unstructured nature. These descriptors feed a search engine that explores the currently available three-dimensional chemical space of the Protein Data Bank (PDB) in order to identify in a straightforward manner regular architectures containing the desired functionalities, which could be used as templates to guide the rational design of small natural-like scaffolds mimicking the targeted recognition site. The application of this rescaffolding strategy to the discovery of natural scaffolds incorporating a selection of functionalities of interleukin-10 receptor-1 (IL-10R1), which are relevant for its interaction with interleukin-10 (IL-10) has resulted in the de novo design of a new class of potent IL-10 peptidomimetic ligands.

Tackling protein interfaces with small molecules capable of modulating protein-protein interactions remains a challenge in structure-based ligand design. Particularly arduous are cases in which the epitopes involved in molecular recognition have a non-structured and discontinuous nature. Here, the basic strategy of translating continuous binding epitopes into mimetic scaffolds cannot be applied, and other innovative approaches are therefore required. We present a structure-based rational approach involving the use of a regular expression syntax inspired in the well established PROSITE to define minimal descriptors of geometric and functional constraints signifying relevant functionalities for recognition in protein interfaces of non-continuous and unstructured nature. These descriptors feed a search engine that explores the currently available three-dimensional chemical space of the Protein Data Bank (PDB) in order to identify in a straightforward manner regular architectures containing the desired functionalities, which could be used as templates to guide the rational design of small natural-like scaffolds mimicking the targeted recognition site. The application of this rescaffolding strategy to the discovery of natural scaffolds incorporating a selection of functionalities of interleukin-10 receptor-1 (IL-10R1), which are relevant for its interaction with interleukin-10 (IL-10) has resulted in the de novo design of a new class of potent IL-10 peptidomimetic ligands.

Parkinson’s Disease (PD) is the second most common neurodegenerative disease in the Western world. It shows a high degree of genetic and phenotypic complexity with many implicated factors, various disease manifestations but few clear causal links. Ongoing research has identified a growing number of molecular alterations linked to the disease. Dopaminergic neurons in the substantia nigra, specifically their synapses, are the key-affected region in PD. Therefore, this work focuses on understanding the disease effects on the synapse, aiming to identify potential genetic triggers and synaptic PD associated mechanisms. Currently, one of the main challenges in this area is data quality and accessibility. In order to study PD, publicly available data were systematically retrieved and analysed. 418 PD associated genes could be identified, based on mutations and curated annotations. I curated an up-to-date and complete synaptic proteome map containing a total of 6,706 proteins. Region specific datasets describing the presynapse, postsynapse and synaptosome were also delimited. These datasets were analysed, investigating similarities and differences, including reproducibility and functional interpretations. The use of Protein-Protein-Interaction Network (PPIN) analysis was chosen to gain deeper knowledge regarding specific effects of PD on the synapse. Thus I generated a customised, filtered, human specific Protein-Protein Interaction (PPI) dataset, containing 211,824 direct interactions, from four public databases. Proteomics data and PPI information allowed the construction of PPINs. These were analysed and a set of low level statistics, including modularity, clustering coefficient and node degree, explaining the network’s topology from a mathematical point of view were obtained. Apart from low-level network statistics, high-level topology of the PPINs was studied. To identify functional network subgroups, different clustering algorithms were investigated. In the context of biological networks, the underlying hypothesis is that proteins in a structural community are more likely to share common functions. Therefore I attempted to identify PD enriched communities of synaptic proteins. Once identified, they were compared amongst each other. Three community clusters could be identified as containing largely overlapping gene sets. These contain 24 PD associated genes. Apart from the known disease associated genes in these communities, a total of 322 genes was identified. Each of the three clusters is specifically enriched for specific biological processes and cellular components, which include neurotransmitter secretion, positive regulation of synapse assembly, pre- and post-synaptic membrane, scaffolding proteins, neuromuscular junction development and complement activation (classical pathway) amongst others. The presented approach combined a curated set of PD associated genes, filtered PPI information and synaptic proteomes. Various small- and large-scale analytical approaches, including PPIN topology analysis, clustering algorithms and enrichment studies identified highly PD affected synaptic proteins and subregions. Specific disease associated functions confirmed known research insights and allowed me to propose a new list of so far unknown potential disease associated genes. Due to the open design, this approach can be used to answer similar research questions regarding other complex diseases amongst others.

Proteins in Escherichia coli were compared in terms of essentiality, centrality, and conservation. The hypotheses of this study are: for proteins in Escherichia coli, (1) there is a positive, measureable correlation between protein conservation and essentiality, (2) there is a positive relationship between conservation and degree centrality, and (3) essentiality and centrality also have a positive correlation. The third hypothesis was supported by a moderate correlation, the first with a weak correlation, and the second hypotheis was not supported. When proteins that did not map to orthologous groups and proteins that had no interactions were removed, the relationship between essentality and conservation increased to a strong relationship. This was due to the effect of proteins that did not map to orthologus groups and suggests that protein orthology represented by clusters of orthologus groups does not accurately dipict protein conservation among the species studied.

Le paludisme, première endémie parasitaire mondiale ayant engendré près d’un demi-million de morts en 2017 (d’après l’OMS), est due à une infection par un parasite du genre Plasmodium. Cet apicomplexe infecte, au cours de son cycle de vie, un hôte définitif, un moustique femelle du genre Anopheles, et un hôte intermédiaire homéotherme (l’Homme pour au moins 6 espèces). Chez ce dernier, après une phase de développement hépatique, le parasite envahit puis lyse les érythrocytes. L’accroissement exponentiel de la parasitémie engendre les symptômes du paludisme et permet la production de formes sexuées (gamétocytes) qui seront transmises au vecteur arthropode, permettant ainsi la complétion du cycle de vie du parasite.Plasmodium a co-évolué avec ses hôtes et mis en place divers modes de régulation de l’expression de ses gènes. La phosphorylation est l’une des modifications post-traductionnelles majeures et rapides qu’il utilise pour répondre aux changements environnementaux auxquels il est confronté au cours de son cycle de vie. Nombre de ses kinases et phosphatases jouent un rôle essentiel dans l’invasion de cellules hôtes, la croissance et la division cellulaires, ainsi que la motilité de certains stades. En revanche, le rôle des cinq pseudokinases de Plasmodium dans son développement n’a jusqu’ici pas été exploré.Durant ma thèse, j’ai caractérisé l’unique pseudo-Tyrosine Kinase-like (pTKL) de Plasmodium et étudié son rôle au cours du cycle intra-érythrocytaire du parasite.L’annotation de la pTKL de P. falciparum (PfpTKL) m’a permis d’identifier différents domaines et motifs, et notamment un domaine SAM (Sterile Alpha Motif), deux motifs RVxF (connus pour leur capacité d’interaction avec la Protéine Phosphatase de type 1, PP1) et un pseudo-domaine kinase appartenant à la famille des Tyrosine Kinases-like (TKL). Nous avons montré que ce pseudo-domaine kinase est capable de lier l’ATP de manière cation-indépendante, mais est dépourvu d’activité enzymatique. Des études d’interaction in vitro couplées à l’utilisation de modèles hétérologues (Levure, ovocytes de Xénope) m’ont permis d’identifier deux protéines parasitaires partenaires de PfpTKL : le domaine SAM de PfpTKL interagit directement avec la pseudo-protéase PfSERA5 (SErine Repeat Antigen 5), alors que les deux régions de la protéine contenant les motifs RVxF de PfpTKL interagissent avec PfPP1c (phosphatase majeure de Plasmodium). De façon intéressante, le deuxième motif RVxF est directement impliqué dans l’interaction avec PP1c et serait capable de moduler l’activité de cette dernière de manière allostérique.La localisation de la pTKL de P. berghei (PbpTKL) a ensuite été étudiée par immunofluorescence et confirmée par des expériences de fractionnement cellulaire. Nous avons ainsi observé que PbpTKL est exportée dans l’érythrocyte infecté au stade trophozoïte, puis retenue dans le parasite et la vacuole parasitophore au stade schizonte. L’étude de l’interactome de PbpTKL par IP/MS au stade trophozoïte a montré que PbpTKL s’associe à diverses protéines impliquées dans l’organisation du cytosquelette de l’érythrocyte, ainsi que dans l’érythropoïèse et l’homéostasie cellulaire. Ces observations suggèrent que pTKL joue un rôle, direct ou via ses partenaires, à l’interface entre le parasite et sa cellule hôte.Enfin, afin d’approcher la fonction de pTKL chez le parasite, nous avons généré différentes lignées génétiquement modifiées. L’étude phénotypique des souches de P. berghei KO et iKD pour pTKL a montré qu’elle était dispensable pour la complétion du cycle intra-érythrocytaire, l’expression des gamétocytes ainsi que l’activation des gamétocytes mâles. Ces données suggèrent que pTKL est dispensable pour ces stades de développement ou que l’expression de gènes redondants compense son absence. Quoi qu’il en soit, il est important de poursuivre les recherches sur le rôle de cette protéine aux autres stades de développement du parasite, notamment du zygote aux stades hépatiques
Malaria is the first endemic parasitic disease in the world with nearly half million deaths in 2017 according to the WHO. This disease is the result of an infection by an agent belonging to the Plasmodium genus. This apicomplexan parasite infects two hosts over its complex life cycle: a definitive one – a mosquito belonging to the Anopheles genus – and a homoeothermic intermediate host. At least six Plasmodium species can infect humans. In its intermediate host, Plasmodium first replicates in hepatocytes before releasing erythrocyte-infectious stages in the bloodstream. Once there, parasites invade and replicate within erythrocytes, before lysing them to release other infectious stages. This triggers an exponential rise in the parasitemia, as well as malaria symptoms. Sexual stages, called gametocytes, are produced over this intra-erythrocytic cycle to be transmitted to the arthropod vector, thus allowing the completion of the parasite life cycle.Plasmodium co-evolved with its hosts and set up diverse gene expression regulation pathways accordingly. Phosphorylation is one of the major and fastest post-translational modifications used by the parasite to respond to environmental changes. Many of its kinases and phosphatases play key roles in host cell invasion, cellular growth and division, as well as motility of specific developmental stages. However, the role of the five pseudo-kinases expressed by Plasmodium has not been explored yet.During my PhD project, I have performed the characterization of the unique Plasmodium pseudo-Tyrosine Kinase-like (pTKL) and explored its role over the parasite intra-erythrocytic cycle.P. falciparum pTKL (PfpTKL) in silico annotation allowed the delineation of the protein domains. Notably, a SAM (Sterile Alpha Motif) domain, two RVxF motifs (known for their binding potential with the major protein phosphatase type 1, PP1) and a pseudo-kinase domain belonging to Tyrosine Kinase-like (TKL) family were found. This pseudo-kinase domain was found to be able to bind ATP in a cation-independent way although devoid of kinase activity. Two parasite protein partners of PfpTKL have been identified using in vitro protein-protein interaction studies together with heterologous models (yeast, Xenopus ovocytes). First, PfSERA5 (SErine Repeat Antigen 5) specifically and strongly interacts with PfpTKL SAM domain and second, PfPP1c binds the two RVxF-containing regions of PfpTKL. Interestingly, the second RVxF motif, which is located within the pseudo-kinase domain, directly binds PfPP1c and seems to be involved in the allosteric regulation of the phosphatase activity. The subcellular localization of P. berghei pTKL (PbpTKL) was studied by IFA as well as sequential lysis of erythrocytes followed by immunoprecipitation assays. PbpTKL was shown to be exported to the host cell cytosol at the trophozoite stage, but retained in the parasitophorous vacuole and the parasite cytosol at the schizont stage. Furthermore, our interactome analysis conducted at the trophozoite stage by IP/MS showed that PbpTKL binds many host cell proteins involved in erythrocyte cytoskeleton organization, as well as erythropoiesis and cell homeostasis. These data suggest that pTKL plays a role at the parasite/host interface, either directly or via its protein partners.Finally, in an attempt to understand the role of pTKL for the parasite development, we generated genetically modified P. berghei strains. The phenotypic study of PbpTKL KO and iKD strains did not show any difference between the defective parasites and the parental wild type ones during the intra-erythrocytic cycle, gametocyte expression and male gametocyte activation. These data suggest the dispensability of pTKL or the expression of redundant gene(s) with similar functions in these parasite stages. Whatever the explanation, it is still important to follow up this investigation in other parasite stages, from zygotes to hepatic stages

Nous avons caractérisé cinq protéines bovines qui sont potentiellement impliquées dans la reproduction.Un travail de clonage a été initié qui permettra à terme de purifier les GPA2 et GPB5 recombinantes puis naturelles pour étudier leurs structures. GPA2 et GPB5 sont considérés comme les ancêtres moléculaires des sous-unités α et β des hormones glycoprotéiques. Nous avons montré la relative fragilité thermique de la structure quaternaire de la FSH bovine par rapport aux FSH ovine et humaine et nous avons étudié les propriétés enzymatiques de la PDI (Protein Disulfide Isomerase) en préalable à l’étude de l’activité PDI de GPA2/GPB5. Nous avons aussi purifié la phosphatidyl-ethanolamine-binding protein (PEBP) et l’ubiquitine testiculaires par chromatographie hydrophobe à très haute concentration de sulfate d’ammonium. A partir de la PEBP purifiée, on a produit des anticorps spécifiques chez le lapin qui nous ont permis d’être les premiers à développer un dosage ELISA fiable pour cette protéine
We characterized five bovine proteins that are potentially involved in reproduction. We started with the cloning of gpa2 and gpb5 cDNAs in order to eventually purify recombinant and natural GPA2 and GPB5 to study their possible quaternary structure. GPA2 and GPB5 are the evolutionary ancestors of Glycoprotein hormones α and β subunits respectively. Meanwhile, we have shown the relative quaternary structure fragility of bovine FSH compared to human and sheep FSH. We also studied the effect of endocrine disruptors on PDI (Protein Disulfide Isomerase) before addressing GPA2/GPB5 PDI activity of GPA2/GPB5 once purified.We succeeded to purify the phosphatidyl-ethanolamine-binding protein (PEBP) and ubiquitin from bovine testis by hydrophobic interaction chromatography at very high ammonium sulfate concentration and we produced specific antibodies (anti-PEBP) in rabbits that allowed us to be the first to develop a reliable Elisa assay for this protein

Human cytomegalovirus (HCMV) is a leading cause of congenital defects in humans. Currently available antivirals utilized for the therapy against HCMV infections have a series of contraindications due to their high cost, low bioavailability, high toxicity and the uprising of resistant viral strains. Furthermore no vaccine is available and no drugs are approved to prevent vertical transmission during pregnancy, therefore new, effective antiviral are highly needed. HCMV DNA polymerase accessory protein UL44 plays an essential role in viral replication, conferring processivity to the DNA polymerase catalytic subunit UL54 by tethering it to the DNA. Binding of UL44 to dsDNA occurs in the absence of ATP and clamp loaders, and depends on UL44 homodimerization. Indeed, our research group recently demonstrated that the protein can dimerize in cells and point mutations disrupting protein self-interaction also prevent DNA binding and abolish viral oriLyt-dependent DNA replication in transient transcomplementation assays. Therefore, disruption of UL44 homodimerization represents an attractive target for the development of new anti-virals. Based on these observations, using the recently published crystal structure of UL44 homodimers our research group previously performed a virtual screening with the Glide software in combination with a library of 1.3 x 10^6 small molecules (SMs) to identify SMs potentially interfering with UL44 homodimerization. After three rounds of screening (HTVS: high-throughput virtual screening, SP: standard precision, XP: extra precision), followed by an in depth analysis of compounds chemical properties, 18 SMs were selected for further analysis. Selected compounds were obtained from a commercial supplier, to be tested in a variety of assays for their ability to inhibit UL44 homodimerization both in cells and in vitro, as well as on HCMV replication. To this end, we applied a number of in cells and in vitro assays to monitor the effect of the SMs on UL44 dimerization. In cells methods included Fluorescent Resonant Energy Transfer (FRET) and Bioluminescence Resonant Energy Transfer (BRET), while as GST pull-down assays was chosen as the in vitro method. FRET acceptor photobleaching was capable of detecting both UL44 homodimerization and UL44 binding to the catalytic subunit C-terminal domain (residues 1125-1242). Such interactions were sensitive to point mutations specifically impairing the two processes, highlighting the specificity of this technique. Therefore, we were able to confirm that UL44 forms dimers in cells. However, data acquisition and analysis proved quite time consuming and dependent on high fusion proteins expression levels. BRET assays allowed to quickly and precisely quantitatively monitor UL44 self-interaction and binding to UL54 in living cells, and through saturation experiments allowed to precisely calculate Bmax and B50 values, relative to homodimerization or binding to UL54 for a number of single amino acids substitution derivatives of UL44 impaired for dimerization, binding to UL54 or to dsDNA, as well as for nuclear targeting. These data allowed gaining insights relative to the formation of HMCV DNA polymerase holoenzyme, suggesting conformational changes within UL44 upon DNA binding in complex to UL54. Furthermore, calculation of Bmax and B50 values was used to establish three different cellular systems expressing ideal amount of UL44 for screening purposes, in that they generated a BRET ratio similar to half of the Bmax. These included a fully stable expression system, whereby both RLuc-UL44 and YFP-UL44 are stably expressed in HEKA derived cells, a stable/transient system whereby YFP-UL44 is stably expressed and RLuc-UL44 is transiently expressed, or a fully transient system whereby both fusion proteins are transiently expressed. Competition assays performed overexpressing increasing amounts of FLAG-tagged UL44 as a competitor revealed that no inhibition could be obtained for the fully stably expressing system. This result highlighted the difficulty in disrupting a pre-existing protein complex and suggested to focus our attention on transient systems. Keeping this in mind, a first small-scale screening was performed to study the impact of 18 SMs on UL44 dimerization by BRET using the stable/transient system. The 18 selected SMs were resuspended in DMSO and their toxicity was evaluated in cell culture, before being added at sub-toxic concentration to the YFP-UL44 cell line, six hours post-transfection with RLuc-UL44. Our analysis identified only compounds slightly inhibiting the BRET ratio relative to UL44 homodimerization. Based on these disappointing results, we revaluated the BRET assays setup, by decreasing the time of SM incubation before assaying their effect from 42 to 18h, by switching to a completely transient system, and by decreasing the amount of expressed proteins. The last modification required a change in the substrate used for generation of bioluminescent signal from RLuc-fusion proteins from CTZ to hCTZ. A new screening was performed, which resulted in very similar results to those obtained using the original setup. Furthermore when hit candidates were re-evaluated for their effect using a negative control, their effect on BRET ratio of UL44 proved unspecific. Additionally, BRET - similarly to FRET - failed to detect a specific effect on the UL54/UL44 interaction by a SM known to disrupt such interaction. Therefore we conclude that, with our current settings, BRET and FRET are not the ideal techniques to search for SM inhibitors of protein-protein interactions We then focused on in vitro methods, starting with a GST pull-down assay, which was performed using UL44 C-terminal domain (residues 1-290), either fused to GST of a 6His-tag. Our results indicated that GST pull-down was capable of detecting differences in binding between wild-type UL44 and a dimerization-impaired mutant, suggesting a possible application for the screening of SMs. GST pull-down is currently being implemented for this purpose, and preliminary data suggest that a number of tested SMs could impair UL44 dimerization. In summary, we have developed a number of assays to monitor UL44 dimerization. Whereas in cells RET based assays confirmed that UL44 form dimers in living cells, they proved suboptimal for screening proposes. On the other hand, in vitro methods such as GST pull-down might prove more sensitive and are currently being implemented for the identification of SMs inhibitors of UL44 dimerization
Cytomegalovirus (CMV) è un importante patogeno di interesse umano. Al momento gli antivirali disponibili ed utilizzati per la terapia contro l’infezione da CMV presentano una serie di controindicazioni dovute all’alto costo, bassa biodisponibilità, alta tossicità ed il presentarsi di ceppi virali resistenti. Inoltre non è disponibile un vaccine ed ancora non è ancora stato approvato l’uso di alcun farmaco per prevenire la trasmissione verticale durante la gravidanza. Per questi motivi, sono necessari nuovi ed efficaci farmaci antivirali. La proteina accessoria UL44 della DNA polimerasi di CMV, svolge un ruolo essenziale nella replicazione virale, conferendo processività alla subunità catalitica UL54 ancorando il complesso oloenzimatico al DNA. Il legame di UL44 al dsDNA avviene in assenza di ATP e dei clamp loaders, e dipende dalla omodimerizzazione di UL44. Infatti, il nostro gruppo di ricerca ha recentemente dimostrato che la proteina può dimerizzare in cellule e che mutazioni puntiformi in grado di inficiare tale dimerizzazione prevengono il legame con il DNA ed aboliscono la replicazione del DNA virale oriLyt-dipendente in saggi di transcomplementazione transiente. Perciò, la distruzione dell’omodimerizzazione UL44 rappresenta un potenziale allettante bersaglio per lo sviluppo di nuovi anti-virali. Partendo da queste osservazioni ed usando la struttura cristallografica recentemente pubblicata degli omodimeri UL44, il nostro gruppo di ricerca ha eseguito un virtual screening con il software Glide in combinazione con una libreria di 1.3 x 10^6 piccole molecole (SMs) per identificare SMs che potenzialmente potessero interferire con l’omodimerizzazione di UL44. Dopo tre rounds di screening (HTVS: high-throughput virtual screening, SP: standard precision, XP: extra precision), seguiti da un’analisi delle proprietà chimiche dei composti, sono state selezione 18 SM per ulteriori analisi. I composti selezionati sono stati acquistati presso un fornitore commerciale, per essere testati in diversi saggi per valutare le loro abilità di inibire l’omodimerizzazione di UL44, sia in cellule che in vitro. A questo scopo, abbiamo utilizzato diversi saggi in cellule e in vitro per monitorare l’effetto delle SMs sulla dimerizzazione di UL44. Nei saggi cellulari, le tecniche utilizzate includono Fluorescent Resonant Energy Transfer (FRET) e Bioluminescence Resonant Energy Transfer (BRET), mentre per saggi in vitro è stato utilizzato il saggio GST-pull down. I nostri dati indicano che la metodica FRET acceptor photobleaching è in grado di rilevare sia l’omodimerizzazione di UL44, sia il legame con il dominio C-terminale della subunità catalitica (residui 1125-1242). Queste interazioni sono sensibili all’introduzione di mutazioni puntiformi che alterano i due processi, evidenziando la specificità di questa tecnica. Siamo stati quindi in grado di confermare che UL44 forma dimeri in un contesto cellulare. Purtroppo, l’acquisizione dei dati e la loro analisi richiedono un lungo tempo e dipendono da alti livelli di espressione delle proteine di fusione. Per contro, il saggio BRET permette un rapido e preciso monitoraggio quantitativo dell’omodimerizzazione di UL44 e il legame con UL54 in cellule viventi. Inoltre, attraverso esperimenti di saturazione, che permettono di calcolare in modo preciso i valori di Bmax e B50 relative all’omodimerizzazione o al legame con UL54 per varianti di UL44 che contengono singole sostituzioni amminoacidiche che affliggono la dimerizzazione di UL44, il suo legame a UL54 o il DNA, nonché il trasporto al nucleo della proteina. I dati ottenuti possono aiutare a comprendere il processo di formazione dell’oloenzima della DNA polimerasi di CMV, suggerendo cambiamenti conformazionali nel complesso olenzimatico in seguito a legame con il DNA. Inoltre, il calcolo di Bmax e B50 è stato usato per sviluppare tre differenti sistemi cellulari esprimenti un’ideale quantità di UL44 da utilizzare come piattaforma per lo screening di SM, poiché sono in grado di generare valori di BRET ratio simili al 50% della Bmax .Questi includono un sistema di espressione completamente stabile, in cui sia RLuc-UL44 che YFP-UL44 sono stabilmente espresse in cellule derivate da HEK293 A, un sistema ibrido stabile/transiente, in cui YFP-UL44 è stabilmente espressa e RLuc-UL44 è espressa in transiente, o un sistema completamente transiente in cui entrambe le proteine sono espresse transientemente. Saggi di competizione eseguiti sovra-esprimendo quantità crescenti di UL44 fusa a un FLAG tag hanno evidenziato che nessun inibizione può essere ottenuta per il sistema completamente stabile, probabilmente per la difficoltà di distruggere un complesso proteico preformato piuttosto che prevenirne la formazione. Per questo motive ci siamo focalizzati su sistemi transienti di espressione piuttosto che sul sistema interamente stabile. Sulla base di questi dati, un primo screening su piccolo scala è stato eseguito per studiare l’effetto di 18 SMs sulla dimerizzazione di UL44 usando il sistema BRET stabile/transiente. Le 18 piccole molecole sono state risospese in DMSO e la loro tossicità è stata valutata in coltura cellulare, prima di essere aggiunte a concentrazioni subtossiche alla linea YFP-UL44, sei ore dopo la trasfezione per esprimere RLuc-UL44. La nostra analisi ha identificato solo composti che inibivano blandamente il BRET ratio relativo alla dimerizzazione di UL44. Per questo motivo abbiamo ri-valutato il set up del saggio BRET, diminuendo il tempo d’incubazione delle SM prima di testare i valori BRET da 42 a 18 ore, utilizzando un saggio completamente transiente e diminuendo la quantità di proteine espresse. Per quest’ultima è stato necessario cambiare il substrato utilizzato per generare il segnale bioluminescente da CTZ a hCTZ. È stato eseguito un nuovo screening, con risultati molto simili a quelli ottenuti utilizzando il setup originale. Inoltre, quando i candidati migliori sono stati rivalutati usando un controllo negativo, il loro effetto sul BRET ratio è risultato aspecifico. Ulteriormente, la BRET, come la FRET, non è riuscita a rilevare uno specifico effetto nell’interazione UL44/UL54 di una SM in grado di distruggere questa interazione. Possiamo quindi concludere che BRET e FRET non sono tecniche ideali per la ricerca di SM inibitrici dell’interazione tra le proteine. Ci siamo poi focalizzati su metodi in vitro, partendo dal saggio GST-pull down, il quale è stato effettato utilizzando il dominio C-terminale (residui 1-290) di UL44, fuso o con GST o con 6His-tag. I risultati ottenuti mostrano che la tecnica GST-pull down è in grado di rilevare differenze nel legame tra UL44 wild-type e i mutanti con mutazioni nel sito di dimerizzazione, suggerendo una possibile applicazione di GST-pull down per lo screening delle SMs. Questa tecnica è stata implementata per questo studio, e i dati preliminari suggeriscono che il numero di SMs testate potrebbe portare all’inibizione della dimerizzazione di UL44. In conclusione, abbiamo sviluppato diversi saggi per monitorare la dimerizzazione di UL44. I saggi cellulari basati su RET confermano che UL44 forma dimeri in cellule viventi, e dimostrano di essere subottimali per lo screening. D’altro canto, i metodi in vitro come GST-pull down dimostrerebbero un maggiore sensibilità e sono stati implementati per l’identificazione degli inibitori della dimerizzazione di UL44.

Le virus de l’hépatite C (VHC) est un agent causateur de maladies du foie important responsable d’une pandémie affectant près de 180 millions d’individus mondialement. L’absence de symptômes dans les premières années d’infection entraîne des diagnostics tardifs qui empêchent la prise en charge rapide des patients avant l’apparition d’une fibrose et, dans près de 16 % des cas d’infection, d’une cirrhose. En exploitant les interactions protéine-protéine membranaires, des essais utilisant la technologie BRET, dans les cellules vivantes, ont été précédemment optimisés afin d’établir le réseau complet des interactions du VHC. En utilisant les fondements de cette étude, un essai à haut débit dans les cellules vivantes a été réalisé pour identifier de nouveaux composés anti-VHC ciblant une nouvelle interaction NS3/4A-NS3/4A. Approximativement 110,000 petites molécules ont été criblées pour leurs effets sur l’homodimérization de NS3/4A et ont été classées par rapport à leur spécificité et à leur puissance contre le VHC. Au terme de cette étude, UM42811 a été identifié comme un activateur potentiel de l’interaction NS3/4A-NS3/4A offrant une activité antivirale prometteuse dotant une excellente fenêtre thérapeutique. Par la suite, un séquençage exhaustif des virus, soumis à un traitement de UM42811, a permis d’établir le profil de résistance du VHC contre ce composé. Grâce à cette fine cartographie, il a été possible d’identifier un nouveau mécanisme d’inhibition de NS3/4A qui est indépendant de son activité protéase. En utilisant les données de notre groupe sur les interactions VHC-hôte, il a été possible de continuer la caractérisation fonctionnelle du composé UM42811 en étudiant son effet sur les interactions potentiellement bénéfiques à la persistance virale. Pour ce faire, les protéines associées au transport nucléaire et mitochondriale qui sont des interactants de choix de NS3/4A ont été priorisées. Parmi ces facteurs de l’hôte, l’étude de karyopherin subunit beta 1 (KPNB1) et de heat shock protein 60 (HSP60) a été priorisée. De façon intéressante, les expériences de co-immunoprécipitation ont démontré que UM42811 était capable de prévenir l’interaction KPNB1-NS3/4A ainsi que l’interaction HSP60-NS3/4A. De plus, les études ii fonctionnelles et les analyses d’immunobuvardage de type western ont démontré que l’interaction KPNB1-NS3/4A avait des effets délétères sur l’induction des gènes stimulés par l’interféron (ISG). Finalement, il a été démontré que KPNB1 est possiblement clivé par NS3/4A suggérant la présence potentielle d’un mécanisme de subversion ou d’échappement. En bref, cette étude démontre la puissance des stratégies impliquant les interactions protéine-protéine dans les cellules vivantes pour l’identification de nouveaux composés inhibiteurs, caractérise un nouveau mécanisme d’inhibition anti-VHC et révèle la possibilité d’un nouveau mécanisme d’évasion du système immunitaire.
Hepatitis C virus (HCV) is an important causative agent for liver diseases and is responsible for a worldwide pandemic affecting roughly 180 million individuals worldwide. Late diagnosis following the progression to fibrosis and to cirrhosis, in nearly 16% of chronic infections, is attributed to the absence of symptoms in the first years of infection. By exploiting membrane protein-protein interactions (PPI), live cell assays using bioluminescence resonance energy transfer (BRET) technology have previously been optimized to complete a comprehensive hepatitis C virus (HCV) protein interaction network. Using the groundwork laid by this network study, a high-throughput assay (HTS) cell-based assay was implemented to identify novel inhibitory compounds targeting an unreported NS3/4A-NS3/4A interaction. Approximately 110,000 compounds from a small-molecule collection were screened to monitor modulation of NS3/4A homodimerization and were discriminated based on specificity and potency. UM42811 was identified as a potential NS3/4A-NS3/4A interaction activator and found to have a promising antiviral activity boasting an excellent therapeutic window. Combined deep sequencing and mutation mapping have yielded a resistance profile based on statistical and functional probability pointing towards a novel inhibitory mechanism targeting the HCV NS3/4A independent from protease activity inhibition. Data from an HCV to host protein interaction network generated by our group was used to analyze alternative effects of UM42811 on interactions which potentially benefit viral persistence. NS3/4A-specific host interactors were heavily associated with nuclear and mitochondrial transport based on Gene Ontology (GO). Among these specific interactors, karyopherin subunit beta 1 (KPNB1) and heat shock protein 60 (HSP60) were selected for further study. Interestingly, co-immunoprecipitation experiments revealed that UM42811 was able to prevent both KPNB1-NS3/4A and HSP60-NS3/4A interactions. Moreover, functional and western analysis revealed the KPNB1-NS3/4A interaction to have deleterious effects on iv interferon stimulated gene (ISG) induction. Unexpectedly, analysis revealed a putative NS3/4A mediated cleavage of KPNB1. Overall, this study demonstrates the strength of cell-based PPI strategies in the identification of novel HCV antiviral compounds, characterizes a novel inhibitory mechanism for HCV and reveals a potentially novel viral immune evasion mechanism.

Finding reliable gene markers for accurate disease classification is very challenging due to a number of reasons, including the small sample size of typical clinical data, high noise in gene expression measurements, and the heterogeneity across patients. In fact, gene markers identified in independent studies often do not coincide with each other, suggesting that many of the predicted markers may have no biological significance and may be simply artifacts of the analyzed dataset. To nd more reliable and reproducible diagnostic markers, several studies proposed to analyze the gene expression data at the level of groups of functionally related genes, such as pathways. Given a set of known pathways, these methods estimate the activity level of each pathway by summarizing the expression values of its member genes and using the pathway activities for classification. One practical problem of the pathway-based approach is the limited coverage of genes by currently known pathways. As a result, potentially important genes that play critical roles in cancer development may be excluded. In this thesis, we first propose a probabilistic model to infer pathway/subnetwork activities. After that, we developed a novel method for identifying reliable subnetwork markers in a human protein-protein interaction (PPI) network based on probabilistic inference of subnetwork activities. We tested the proposed methods based on two independent breast cancer datasets. The proposed method can efficiently find reliable subnetwork markers that outperform the gene-based and pathway-based markers in terms of discriminative power, reproducibility and classification performance. The identified subnetwork markers are highly enriched in common GO terms, and they can more accurately classify breast cancer metastasis compared to markers found by a previous method.

碩士
國立中正大學
分子生物研究所
90
Inhobitor-2 (I2) is the regulatory subunit of the catalytic subunit of protein phosphatase-1 (PP1) and inhibits the enzyme activity via multiple sites. Our previous studies have demonstrated that the region encompassing residues 9-13 (PIKGI) plays critical role in inhibition of PP1. However, no obvious evidence indicated the sequence Lys144-Leu-His-Tyr147 corresponding to the BB(V/I)XF PP1-binding motif, involved in this action. In the presentation, we have characterized in detail the function of this sequence to test whether it has such activity. Biacore analysis demonstrated that deletion of C-terminal sequence after the residue 120 of I2 did not significantly affect the binding constant between PP1 and I2. In comparison with I2(WT), mutation of Tyr-147 【I2-(Y147A)】 also showed no significant difference on affinity with PP1. These findings suggested that this sequence Lys144-Leu-His-Tyr147 is probably not involved in the inhibition with PP1.

碩士
國防醫學院
生物化學研究所
89
PIP is a novel p53-interacting protein. It has been well known that p53-binding proteins play important roles in either mediating or modulating the activity of p53, and consequently affect its tumor suppression function. In normal cells, p53 mainly localizes in nucleus, whereas the cytoplasmic distribution of p53 was found in certain type of cancers in which p53 is wild-type. The focus of this research is to identify the cellular localization of p53 and PIP in various cell lines, and to determine their distribution after exposing to DNA damage agents such as UV or IR. Our data indicate that the localization of singly transfected fluorescent p53 and PIP fusion proteins is primarily in nucleus and cytosol, respectively, and UV or IR did not affect their cellular localization. When cells were co-expressed the fluorescent p53 and PIP fusion proteins, three different results were obtained from a series of independent experiments in both MCF-7 and H1299: first, the prescence of p53-DsRed fusion protein was sufficient to translocate EGFP-PIP fusion protein from its original place, cytosol, to nucleus, second, both the expression of p53-DsRed and the stimulation of IR were require for changing the cellular localization of EGFP-PIP, and third, the localization of EGFP-PIP did not change upon the expression of p53-DsRed and IR stimulation. Besides the fluorescent fusion proteins, we also used immunohistochemistry to determine the localization of endogenous PIP and transfected PIP with different sizes. The results showed that the endogenous PIP and the transfected PIP with ring-finger motif are localized in nucleus, whereas the cytoplasmic localization was observed when cells were transfected with the other PIP constructs including the PIP fragments derived from the longest ORF and the usage of the fourth ATG as initiation codon. In consistent with the third observation mentioned above, the localization of endogenous and transfected PIP remains in the cytosol regardless the expression of p53 and/or the treatment of DNA damaging agents. Overall, the results in this thesis, although with certain conflicting observations, show that we are fail to demonstrate the colocalization of p53 and PIP, and indicate that these two proteins do not interact with each other in the conditions which we employed. However, this conclusion is contradictory to what we obtained from in vivo binding assay, in which the interaction between p53 and PIP can be measured in irradiated mouse tissues. The results in my thesis might provide some clues and information in pursuing the interaction of p53 and PIP in the future.

Indiana University-Purdue University Indianapolis (IUPUI)
Excitotoxicity, a major hallmark of neurodegeneration associated with cerebral ischemia, is a result of accumulation of extracellular glutamate. This excess glutamate leads to hyperactivation of glutamate receptors such as the N-methyl-D-asparate (NMDA) receptors (NMDARs) following the activation of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor (AMPARs). Excessive activation of NMDARs causes an influx of calcium, which can eventually activate apoptotic pathways and lead to death of neurons. Regulation of NMDAR subunit composition, localization, surface expression, and activity can balance cell survival via activation of either pro-death or pro-survival pathways after a course of an ischemic insult. Specifically, phosphorylation of different NMDAR subunits defines their activity and downstream signaling pathways. NMDARs are phosphorylated by multiple kinases and dephosphorylated by different phosphatases. Besides phosphatases and kinases, per se, phosphorylation of synaptic proteins that regulate kinase or phosphatase targeting and activity also mediate NMDAR phosphorylation. Spinophilin, a major synaptic scaffolding and protein phosphatase 1 (PP1) targeting protein, mediates substrate phosphorylation via its ability to bind PP1. Our studies focus on delineating the role of spinophilin in the regulation of phosphorylation and function of the GluN2B subunit of the NMDA receptor as well as the role of spinophilin in modulating glutamate-induced neurotoxicity. Interestingly, our data demonstrate that spinophilin sequesters PP1 away from GluN2B thereby enhancing phosphorylation of GluN2B at Ser-1284. These changes impact GluN2B protein interactions, subcellular localization, and surface expression, leading to alterations in the amount of calcium entering the neuron via GluN2B-containing NMDARs. Our data show that spinophilin biphasically regulates GluN2B function. Specifically, Ser-1284 phosphorylation enhances calcium influx through GluN2B containing NMDA receptors, but spinophilin leads to dramatic decreases in the surface expression of the receptor independent of Ser-1284 phosphorylation. Moreover, in spinophilin knockout mice, we observe less PP1 binding to GluN2B and less phosphorylation of Ser-1284, but more surface expression of GluN2B and greater levels of caspase activity. Together, these observations suggest a potential neuroprotective role for spinophilin by decreasing GluN2B-containing NMDA receptor-dependent surface expression and thereby decreasing intracellular calcium and neuronal cell death.

Excitotoxicity, a major hallmark of neurodegeneration associated with cerebral ischemia, is a result of accumulation of extracellular glutamate. This excess glutamate leads to hyperactivation of glutamate receptors such as the N-methyl-D-asparate (NMDA) receptors (NMDARs) following the activation of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor (AMPARs). Excessive activation of NMDARs causes an influx of calcium, which can eventually activate apoptotic pathways and lead to death of neurons. Regulation of NMDAR subunit composition, localization, surface expression, and activity can balance cell survival via activation of either pro-death or pro-survival pathways after a course of an ischemic insult. Specifically, phosphorylation of different NMDAR subunits defines their activity and downstream signaling pathways. NMDARs are phosphorylated by multiple kinases and dephosphorylated by different phosphatases. Besides phosphatases and kinases, per se, phosphorylation of synaptic proteins that regulate kinase or phosphatase targeting and activity also mediate NMDAR phosphorylation. Spinophilin, a major synaptic scaffolding and protein phosphatase 1 (PP1) targeting protein, mediates substrate phosphorylation via its ability to bind PP1. Our studies focus on delineating the role of spinophilin in the regulation of phosphorylation and function of the GluN2B subunit of the NMDA receptor as well as the role of spinophilin in modulating glutamate-induced neurotoxicity. Interestingly, our data demonstrate that spinophilin sequesters PP1 away from GluN2B thereby enhancing phosphorylation of GluN2B at Ser-1284. These changes impact GluN2B protein interactions, subcellular localization, and surface expression, leading to alterations in the amount of calcium entering the neuron via GluN2B-containing NMDARs. Our data show that spinophilin biphasically regulates GluN2B function. Specifically, Ser-1284 phosphorylation enhances calcium influx through GluN2B containing NMDA receptors, but spinophilin leads to dramatic decreases in the surface expression of the receptor independent of Ser-1284 phosphorylation. Moreover, in spinophilin knockout mice, we observe less PP1 binding to GluN2B and less phosphorylation of Ser-1284, but more surface expression of GluN2B and greater levels of caspase activity. Together, these observations suggest a potential neuroprotective role for spinophilin by decreasing GluN2B-containing NMDA receptor-dependent surface expression and thereby decreasing intracellular calcium and neuronal cell death.

Les domaines de transactivation (TAD) acides sont présents dans plusieurs protéines oncogéniques, virales et dans des facteurs de différenciation de cellules souches. Ces domaines acides contrôlent la transcription à travers une myriade d’interactions avec divers partenaires ce qui provoque l’activation de la transcription ou leur propre élimination. Cependant, dans la dernière décennie, de plus en plus de recherches ont démontré que les TAD possédaient un sous-domaine activation/dégradation (DAD) responsable pour une fonction d'activation de la transcription dépendante de la dégradation de la protéine. Un tel phénomène peut être accompli par plusieurs moyens tels que des modifications post-traductionnelles, l’association à des cofacteurs ou la formation d’un réseau d’interaction complexe en chaînes. Or, aucune preuve concrète n’a pu clairement démontrer le fonctionnement de la dépendance paradoxale entre ces deux fonctions sur un activateur de transcription. Le DAD, a été observé dans plusieurs facteurs de transcription incluant la protéine suppresseur de tumeur p53 et le facteur de différenciation érythrocyte EKLF. Un aspect particulier des DAD est que la composition de leur séquence d’acide aminé est fortement similaire à celle des domaines de liaison à l’ubiquitine (UBD) qui jouent un rôle clé dans le contrôle de la transcription à travers leur interaction non-covalente avec l’ubiquitine. Ainsi, dans ce mémoire, nous avons étudié la possibilité que les TAD acides soient capables d’agir comme UBD pour réguler leur fonction paradoxale à travers des interactions non-covalentes avec l’ubiquitine. L’analyse est faite en utilisant la résonnance magnétique nucléaire (RMN) ainsi qu’avec des essais fonctionnels de dégradation. En somme, cette étude amène une plus grande compréhension des protéines impliquées dans le contrôle des TAD et caractérise le tout premier exemple de TAD capable d’interagir avec l’ubiquitine.
Acidic transactivating domains have been shown to be potential targets for a number of different therapies but their dynamic nature and their ability to bind many interacting partners has made it difficult to fully understand their functioning mechanisms. What we do know about these domains is that they readily control transcription through a myriad of interactions capable of either activating specific aspects of their function or simply, signal for their own demise. Within the acidic TADs lies an unusual degradation/activation domain (DAD) capable of activating transcription at the cost of its degradation. In other words, DAD transcriptional activation is dependent on the degradation of the protein. Such a phenomenon could be explained by a wide variety of hypotheses like the play of post-translational modifications, co-factors, or maybe just a really sophisticated time scaled network of interactions. However, no concrete explanation of how this dual dependent functioning domain works has yet to surface. The DAD has been observed within acidic TADs of several transcription factors including the tumor suppressor p53 and the red blood cell differentiation factor EKLF. Interestingly though, the amino acid sequence composition of DADs share a strong similarity with several types of sequences from domains that bind ubiquitin (UBDs). These domains have been shown in the past to, in addition to their role in degradation, play a key role in regulating transcription through non-covalent interaction with ubiquitin. Hence, in this project, we investigated weather acidic TADs had the ability to function as UBDs and form non-covalent interactions with ubiquitin and also to determine the functional significance of this interaction in regards to the dual function of acidic TADs.