Uma abordagem integrativa usando dados de interação proteína-proteína e estudos genéticos para priorizar genes e funções biológicas em transtorno de déficit de atenção e hiperatividade / An integrative approach using protein-protein interaction data and genetic studies to prioritize genes and biological functions in attention-deficit/hyperactivty disorder

Leandro de Araujo Lima

22 July 2015

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.

CNV

PPI

Redes de interação proteína-proteína

SNV

TDAH

Variação de número de cópias

Variação de único nucleotídeo

ADHD

CNV

Copy-number variant

PPI

Protein-protein interactions network

Single-nucleotide variant

SNV

Imagerie quantitative de l'assemblage de la NADPH oxydase des phagocytes en cellules vivantes par des approches FRET-FLIM / Imaging the assembly of the phagocyte NADPH oxidase in live cells - a quantitative FRET-FLIM approach

Ziegler, Cornelia

14 March 2016

La NADPH oxydase des phagocytes (NOX2) est responsable de la production d’anions superoxydes qui sont les précurseurs des autres formes réactives de l’oxygène. NOX2 est une enzyme majeure de la réponse immunitaire. Les dysfonctionnements de NOX2 sont associés à de nombreuses pathologies et donc il convient d’en comprendre les détails de la régulation. Cette oxydase est composée de cinq sous-unités : deux protéines membranaires, gp91phox et p22phox et 3 protéines cytosoliques p47phox, p67phox et p40phox. D’après les études in vitro avec des protéines purifiées, les protéines cytosoliques sont supposées former un complexe ternaire qui se déplace à la membrane avec une petite protéine G, Rac, au moment l’activation.L’objectif de ce projet est de caractériser les interactions spécifiques entre les sous-unités cytosoliques de NOX2 en cellules vivantes en utilisant le phénomène de transfert résonant d’énergie de type Förster (FRET) entre deux fluorophores, un donneur et un accepteur. Ici les fluorophores seront des protéines fluorescentes de la famille de la GFP. Elles sont fusionnées à deux sous-unités. L’efficacité du FRET dépend de la distance entre les fluorophores et permet ainsi de caractériser les interactions entre les protéines d’intérêt. Une méthode rapide d’identification des situations où le FRET est positif a été mise au point par cytométrie en flux. Des études détaillées et quantitatives ont ensuite été réalisées en utilisant l’imagerie de durée de fluorescence (FLIM) du donneur. Le FLIM, combiné à l’utilisation de donneurs présentant une durée de vie mono-exponentielle, permet de déterminer directement des efficacités de FRET apparentes et moléculaires, qui contiennent, toutes les deux, des informations qualitatives et quantitatives sur l’interaction et la structure des protéines impliquées. De ces données, il est possible d’extraire la fraction des donneurs interagissant avec un accepteur. Les informations obtenues à partir des données de FRET-FLIM permettent une meilleure compréhension de l’organisation et de la régulation de NOX2 tout en permettant une estimation des constantes de dissociation (Kd). Afin de confirmer ces résultats, des expériences de spectroscopie de corrélation de fluorescence à deux couleurs (FCCS) ont été réalisées. Cette méthode complétement indépendante n’est pas basée sur la distance entre fluorophores comme le FRET mais sur leur co-diffusion à travers un petit volume d’observation dans le cytoplasme cellulaire.L’approche FRET-FLIM nous a tout d’abord permis d’observer les interactions entre hétéro-dimères formés de deux sous-unites différentes en cellules vivantes et d’exclure la formation d’homo-dimères entre deux sous-unités identiques. Etant donné la bonne précision des mesures de FLIM, nous avons pu comparer les informations structurales obtenues en cellules avec les données structurales issues d’études sur les protéines purifiées in vitro et nous avons constaté qu’elles sont en bon accord. Nous avons ensuite aligné les structures disponibles pour proposer un premier modèle 3D du complexe cytosolique de la NADPH oxydase au repos dans le cytosol cellulaire.Les fractions de protéines en interaction sont pour tous les hétéro-dimères autour de 20% ce qui n’est pas en accord avec l’hypothèse courante qui propose que toutes les sous-unités cytosoliques soient sous forme de complexe. Toutefois nos premiers résultats de FCCS confirment ce résultat extrait des données de FRET-FLIM. Nous proposons donc que la complexation des sous-unités cytosolique pourrait être impliquée dans la régulation de la NADPH oxydase. Des études complémentaires seront nécessaires pour valider cette nouvelle hypothèse. Les constantes de dissociation Kd estimées à partir de nos résultats sont micromolaires et donc un ordre de grandeur plus élevé que les valeurs nanomolaires déterminées in vitro. Des mesures plus détaillées de FCCS pourront compléter et valider ces résultats. / The phagocyte NADPH oxidase (NOX2) is a key enzyme of the immune system generating superoxide anions, which are precursors for other reactive oxygen species. Any dysfunctions of NOX2 are associated with a plethora of diseases and thus detailed knowledge about its regulation is needed. This oxidase is composed of five subunits, the membrane-bound gp91phox and p22phox and the cytosolic p47phox, p67phox, and p40phox. The latter are assumed to be in a ternary complex that translocates together with the small GTPase Rac to the membranous subunits during activation.Our aim was to discover and to characterize specific interactions of the cytosolic subunits of NOX2 in live cells using a Förster Resonance Energy Transfer (FRET) based approach: Since FRET depends on the distance between two fluorophores, it can be used to reveal protein-protein interactions non-invasively by studying fluorescent protein tagged subunits. To have a rapid method on hand to reveal specific interactions, a flow cytometer based FRET approach was developed. For more detailed studies, FRET was measured by fluorescence lifetime imaging microscopy (FLIM), because it allows a direct determination of the apparent and molecular FRET efficiency, which contains both qualitative and quantitative information about the interaction and the structure of the interacting proteins. Furthermore, the FRET-FLIM approach enables an estimation of the fraction of bound donor. This information itself is important for a better understanding of the organisation and regulation of the NOX2, but it is also necessary for the calculation of the dissociation constant Kd from the FRET-FLIM data. To confirm the findings obtained by FRET-FLIM fluorescence cross correlation spectroscopy (FCCS) experiments were performed. This completely independent method is not based on distances like FRET but on the observation of the co diffusion of the fluorescently labelled samples when they move across a small observation volume inside the cells.The FRET-FLIM approach allowed us in a first step to discover heterodimeric interactions between all cytosolic subunits in live cells. Due to the good precision of the results, we were able to extract structural information about the interactions and to compare them with available structural data obtained from in vitro studies. The information from FRET-FLIM was coherent with in vitro data. We then aligned the available structures leading to the first 3D model of the cytosolic complex of the NADPH oxidase in the resting state in live cells.Additionally, the bound fraction for all heterodimeric interactions derived by FRET-FLIM is around 20 %, which is in contrast to the general belief that all cytosolic subunits are bound in complex. The first FCCS results support our findings. Therefore, we believe that the complexation of the cytosolic subunits could be involved in the regulation of the NADPH oxidase and should be investigated further. The estimated Kd derived from the FRET-FLIM approach is in the low micomolar range, which is an order of a magnitude higher than the nanomolar range of in vitro studies.In conclusion, we showed that our quantitative FRET-FLIM approach is not only able to distinguish between specific and unspecific protein-protein interactions, but gives also information about the structural organisation of the interacting proteins. The high precision of the FRET-FLIM data allow the determination of the bound fraction and an estimation of the Kd in live cells. FCCS is a complementary method, which can verify these quantitative findings. However, it cannot replace FRET-FLIM completely as it does not give any structural information.With respect to the biological outcome of this project, we can propose for the first time a 3D-model of the cytosolic complex of the NADPH oxidase covering the in vitro as well as the live cell situation. Additionally, the small bound fraction found here may raise new ideas on the regulation of this vital enzyme.

NADPH oxidase

Fret

Spectro microscopie quantive

Interactions proteine-Proteine

Flim

Imagerie

NADPH oxydase

Fret

Quantitative spectro microscopy

Protein-Protein interactions

Flim

Imaging

Fluorescence-based nanofluidic biosensor platform for real-time measurement of protein binding kinetics / Développement d'une plateforme nanofluidique de biodétection en fluorescence pour la mesure de cinétiques d'interaction de protéines en temps-réel

Teerapanich, Pattamon

10 November 2015

L'analyse cinétique d'interactions de protéines offre une multitude d'informations sur les fonctions physiologiques de ces molécules au sein de l'activité cellulaire, et peut donc contribuer à l'amélioration des diagnostics médicaux ainsi qu'à la découverte de nouveaux traitements thérapeutiques. La résonance plasmonique de surface (SPR) est la technique de biodétection optique de référence pour les études cinétiques d'interaction de molécules biologiques. Si la SPR offre une détection en temps réel et sans marquage, elle nécessite en revanche des équipements coûteux et sophistiqués ainsi que du personnel qualifié, limitant ainsi son utilisation au sein de laboratoires de recherche académiques. Dans ces travaux de thèse, nous avons développé une plateforme de biodétection basée sur l'utilisation de nanofentes biofonctionnalisées combinées avec une détection par microscopie à fluorescence. Ce système permet l'observation en temps réel d'interactions protéines-protéines et la détermination des constantes cinétiques associées, avec des temps de réponse optimisés et une excellente efficacité de capture. La fonctionnalité du système a été démontrée par l'étude des cinétiques d'interaction de deux couples modèles de différentes affinités : le couple streptavidine/biotine et le couple IgG de souris/anti-IgG de souris. Une très bonne cohérence entre les constantes cinétiques extraites, celles obtenues par des expériences similaires réalisées en SPR et les valeurs rapportées dans la littérature montre que notre approche pourrait être facilement applicable pour l'étude cinétique d'interactions de protéines avec une sensibilité allant jusqu'au pM, sur une large gamme de constantes de dissociation. De plus, nous avons intégré un générateur de gradient de concentrations microfluidique en amont de nos nanofentes, permettant ainsi des mesures simultanées de cinétiques d'interactions à différentes concentrations d'analyte en une seule expérience. Ce système intégré offre de nombreux avantages, tels qu'une réduction de la consommation des réactifs et des temps d'analyse par rapport aux approches séquentielles classiques. Cette technologie innovante pourrait ainsi être un outil précieux non seulement pour les domaines du biomédical et de la médecine personnalisée mais aussi pour la recherche fondamentale en chimie et biologie. / Kinetic monitoring of protein-protein interactions offers fundamental insights of their cellular functions and is a vital key for the improvement of diagnostic tests as well as the discovery of novel therapeutic drugs. Surface plasmon resonance (SPR) is an established biosensor technology routinely used for kinetic studies of biomolecular interactions. While SPR offers the benefits of real-time and label-free detection, it requires expensive and sophisticated optical apparatus and highly trained personnel, thus limiting the accessibility of standard laboratories. In this PhD project, we have developed an alternative and cost-effective biosensor platform exploiting biofunctionalized nanofluidic slits, or nanoslits, combined with a bench-top fluorescence microscope. Our approach enables the visualization of protein interactions in real-time with the possibility to determine associated kinetic parameters along with optimized response times and enhanced binding efficiency. We have demonstrated the effectiveness of our devices through kinetic studies of two representative protein-receptor pairs with different binding affinities: streptavidin-biotin and mouse IgG/anti-mouse IgG interactions. Good agreement of extracted kinetic parameters between our device, SPR measurements and literature values indicated that this approach could be readily applicable to study kinetics of protein interactions with sensitivity down to 1 pM on a large scale of dissociation constants. In addition, we have incorporated a microfluidic gradient generator to our validated nanoslit device, which has allowed one-shot parallel kinetic measurements to be realized in a single-experiment. This integrated system provides advantages of diminished material consumption and analysis time over the conventional kinetic assays. We believe that this innovative technology will drive future advancements not only in the discipline of biomedical and personalized medicine, but also in basic chemical/biological research.

Etudes cinétiques

Interactions protéine-protéine

Biocapteurs

Microscopie à fluorescence

Nanofluidique

Gradient de concentration

Kinetic studies

Protein-protein interactions

Biosensors

Fluorescence microscopy

Nanofluidics

Concentration gradient

Establishment of interaction partners of Plasmodium falciparum heat shock protein 70-x(PfHsp 70-x)

Monyai, Florina Semakaleng

18 May 2018

MSc (Biochemistry) / Department of Biochemistry / Plasmodium falciparum is a unicellular protozoan parasite that causes malaria in humans. The parasite is passed to humans through mosquito bites and migrates to the liver before it infects host erythrocytes. It is at the erythrocytic stage of development that the parasite causes malaria pathology. Malaria is characterized by the modification of host erythrocytes making them cytoadherent. This is as a result of formation of protein complexes (knobs) on the surface of the erythrocyte. The knobs that develop on the surface of the erythrocyte are constituted by proteins of host origin as well as some proteins that the parasite ‘exports’ to the host cell surface. Nearly 550 parasite proteins are thought to be exported to the infected erythrocyte. Amongst the exported proteins is P. falciparum heat shock protein 70-x (PfHsp70-x). Hsp70 proteins are known to maintain protein homeostasis. Thus, the export of PfHsp70-x may be important for maintaining protein homeostasis in the host cell. PfHsp70-x is not essential for parasite survival although is implicated in the development of parasite virulence. This is possibly through its role in facilitating the trafficking of parasite proteins to the erythrocyte as well as supporting the formation of protein complexes that constitute the knobs that develop on the surface of the infected erythrocyte. The main objective of the current study was to investigate protein interaction partners of PfHsp70-x. It is generally believed that PfHsp70-x interacts with various proteins of human and parasite origin. Potential candidate interactors include its protein substrates, Hsp70 co-chaperones such as Hsp40 members, and human Hsp70-Hsp90 organizing protein (hHop). The establishment of the PfHsp70-x interactome would highlight the possible role of PfHsp70-x in the development of malaria pathogenicity. Based on bioinformatics analysis, PfHsp70-x was predicted to interact with some exported P. falciparum Hsp40s, hHop and human Hsp90 (hHsp90). Recombinant forms of PfHsp70-x (full length and a truncated form that lacks the C-terminal EEVN motif implicated in co-chaperone binding) were expressed in E. coli BL21 Star (DE3) cells. Recombinant hHop and hHsp70 were expressed in E. coli JM109 (DE3) cells. The proteins were successfully purified using nickel affinity chromatography. Co-affinity chromatography using recombinant PfHsp70-x and immuno-affinity chromatography using PfHsp70-x specific antibody did not confirm the direct interaction of PfHsp70-x with human Hop. However, the direct interaction of hHop and PfHsp70-x has previously been validated in vitro and the current bioinformatics data support ii the existence of such a complex. PfHsp70-x was not stable in the cell lysate that was prepared and this could explain why its interaction with hHop could not be ascertained. However, taken together the evidence from a previous independent study, and the predicted interaction of PfHsp70-x with human chaperones suggests cooperation of chaperone systems which possibly facilitates the folding and function of parasite proteins that are exported to the infected erythrocyte. / NRF

Malaria

P. falciparum

PfHsp70-x

Human chaperones human Hop

Chaperone networks

Interaction partners

Protein-protein interactions

616.9362

Malaria -- Prevention

Malaria -- Immunological aspects

Plasmodium falciparum

Protozoan diseases

Fever

Malaria

Fyzické interakce sestřihového faktoru Prp45 / Physical interactions of the splicing factor Prp45

Kratochvílová, Eliška

January 2015

It is well known that chromatin posttranslational state, transcription and splicing influence each other. Nevertheless, the details of this coupling are not fully understood. In S. cerevisiae, it is possible to induce conditions, in which splicing is uncoupled from transcription. Such situation occurred in cells expressing a mutated splicing factor Prp45, whose human homolog has been proved to participate in transcription regulation and also in splicing reactions. Based on previously indicated interactions in high throughput two-hybrid screens, we have been looking for physical links between Prp45 and proteins involved in chromatin posttranslational modifications. Finding of such a link would provide insight into the relationships of gene expression processes. Using coimmunoprecipitation and affinity purification, we were unable to detect physical interactions between Prp45 and our candidate chromatin regulators. Alternative approaches are discussed. Using the precipitation techniques, we mapped the interaction of Prp46 with truncated variants of Prp45. This observation contributes to our knowledge of protein-protein interactions within the spliceosome.

Mécanisme moléculaire de l'endonucléase Mlh1-Mlh3 dans la voie de réparation des mésappariements de l’ADN et dans les processus de recombinaison en méiose / Molecular basis of the dual role of the Mlh1-Mlh3 endonuclease in MMR and in crossover formation during meiosis

Dai, Jingqi

24 September 2019

La méiose est un processus de ségrégation des chromosomes essentiel pour la gamétogenèse chez tous les organismes qui présentent une reproduction sexuée. Ce mécanisme nécessite des connections entre chromosomes homologues et des structures intermédiaires d’ADN appelées Jonction de Holliday. Ces jonctions sont résolues principalement par complexe MutLγ (Mlh1-Mlh3). Des mutations sur les gènes impliqués en méiose s’accompagnent chez l’homme de problèmes allant de la stérilité à des réarrangements chromosomiques comme la trisomie. Mlh1-Mlh3 joue aussi un rôle dans la voie de réparation des mésappariements de l’ADN (MisMatch Repair - MMR). Notre laboratoire a révélé la première structure cristalline de la région C-terminale du complexe MutLα (Mlh1-Pms1) qui est l’endonucléase majeure de la voie MMR. Mon projet de thèse s’insère dans le cadre de l’étude des différentes fonctions des MutL eucaryotes et plus particulièrement sur le mécanisme moléculaire de MutLγ (Mlh1-Mlh3). Au cours de ma thèse, nous avons déterminé la structure cristalline du domaine C-terminale du complexe Mlh1-Mlh3 qui contient le site d’endonucléase et caractérisé 3 états du site actif. Nous avons montré le rôle de Mlh1 dans le site endonucléase. Nous avons caractérisé la spécificité de ce domaine pour les Jonctions de Holliday et proposé un modèle du site de fixation de l’ADN sur le complexe entier. Ce modèle a permis de proposer un nouveau mutant de séparation de fonction de Mlh1-Mlh3, appelé KERE, qui a été analysé par gel retard et génétique. / Meiosis is key process in sexual reproduction, where chromosomes are segregated. During this process, a parental diploid cell divides into haploid gametes. This mechanism requires connections between homologous chromosomes and intermediate DNA structures called Holliday Junctions. These junctions are mainly resolved by MutLγ (Mlh1-Mlh3) complex. Mutations of genes involved in meiosis are associated with human diseases including sterility and chromosomal rearrangements such as trisomy. Mlh1-Mlh3 plays also a role in DNA mismatch repair (MMR). Our laboratory has characterized the first crystal structure of the C-terminal region of the MutLα complex (Mlh1-Pms1) which is the major endonuclease in MMR. My thesis aims at understanding the molecular mechanism of MutLγ (Mlh1-Mlh3) mainly involved in meiosis and to compare it with Mlh1-Pms1 mainly involved in MMR.We determined the crystal structure of the C-terminal domain of the MutLγ complex which contains the endonuclease site. We characterized the structure of three different states of the active site. We showed how Mlh1 is an integral part of the Mlh3 endonuclease site. We characterized the specificity of this domain for Holliday Junctions and proposed a model of the full-length complex and its DNA binding sites. Finally, we design new separation of function allele of Mlh1-Mlh3, called KERE, which was analyzed by EMSA and genetic experiments.

Réparation des mésappariement de l'ADN

Meiose

Cristallographie

Biologie Stucturale

Interactions des Protéines

Santé Humaine

DNA mismatch repair

Meiosis

Crystallography

Structural Biology

Protein-Protein Interactions

Human Diseases

Etudes des fonctions du facteur de transcription YB-1, de l'ADN glycosylase hNTH1 et de la topoisomerase humaine I dans le contexte de la résistance aux drogues et en relation avec les voies de réparation de l'ADN / Evaluation of YB-1 transcriptional factor, DNA glycosylase hNTH1 and human topoisomerase I functions in relation to drug resistance and DNA repair mechanisms

Senarisoy, Muge

27 September 2018

La résistance acquise aux traitements anticancéreux représente un problème clinique majeur. Les voies de réparation de l'ADN fournissent un mécanisme de résistance, mais celle-ci peut aussi résulter de mutations ou d'une expression réduite de la protéine ciblée. La surexpression ou la localisation nucléaire de la Y-Box binding (YB-1) protéine est considérée comme un marqueur pronostique de chimiorésistance de la tumeur. YB-1 interagit avec plusieurs partenaires ; dans cette étude, nous nous sommes concentrés sur son interaction avec l'enzyme de réparation de l'ADN NTH1 (hNTH1) et l'ADN topoisomérase I (hTopoI), deux enzymes stimulées par YB-1. L'abondance du complexe hNTH1/YB-1 est accrue dans les cellules tumorales résistantes au cisplatine. La TopoI humaine est une enzyme essentielle impliquée dans la régulation cellulaire du surenroulement de l'ADN et est la cible de plusieurs agents anticancéreux. YB-1 augmente la sensibilité à l'inhibiteur de TopoI, la camptothécine, dans les tumeurs. Nous avons caractérisé les complexes YB-1/hNTH1 et YB-1/hTopoI in vitro et in vivo en utilisant des mesures de transfert d'énergie par résonance en fluorescence (ou FRET) pour identifier et développer de nouvelles stratégies pour le traitement de tumeurs chimio-résistantes. Nous avons développé et optimisé un biosenseur original basé sur le FRET pour cribler deux chimiothèques de taille moyenne afin d’identifier des inhibiteurs potentiels du complexe hNTH1/YB-1. Plusieurs «hits» ont été identifiés qui réduisent de façon significative le niveau de FRET de notre biosenseur. Pour certains de ces composés, nous avons reproduit ces résultats à partir de poudres, effectué des courbes dose-réponse et validé leurs actions en tant qu'inhibiteurs de l'interface hNTH1/YB-1 en utilisant d'autres tests d’interactions. Ensemble nos résultats démontrent que YB-1 interagit directement et stimule des enzymes de la réparation de l'ADN et du relaxation de l’ADN, et que cibler l’interface YB-1/hNTH1 représente une nouvelle stratégie intéressante pour le développement de traitements anticancéreux. / Acquired resistance to anti-cancer therapy is common and is a major clinical issue. Functional DNA repair pathways provide a common mechanism for drug resistance, but it can also result from mutations or reduced expression of the targeted protein. The overexpression or nuclear localisation of the multifunctional Y-box binding protein (YB-1) is considered as a prognostic marker for drug resistance in tumours. YB-1 has several interaction partners in cells; in this study, we have focused on its interaction with the human DNA repair enzyme NTH1 (hNTH1) and human DNA topoisomerase I (hTopoI), two enzymes that have been shown to be stimulated by YB-1. The abundance of the hNTH1/YB-1 complex was shown to increase in cisplatin-resistant tumour cells. Human TopoI is an essential enzyme involved in cellular regulation of DNA supercoiling and is the target of several anti-cancer agents. YB-1 enhances the activity of hTopoI and its sensitivity to hTopoI inhibitor, camptothecin in tumour cells. We have characterised the YB-1/hNTH1 and YB-1/hTopoI complexes in vitro and in vivo using Fluorescence Resonance Energy Transfer (FRET) measurements to identify and develop new strategies for the treatment of drug-resistant tumours. We also designed and optimised an original FRET-based biosensor to screen two medium-sized chemical libraries in order to find potential inhibitors of the hNTH1/YB-1 complex. Several “hits” were identified that significantly reduced the FRET level of our biosensor. For some of these compounds, we have reproduced these results starting from powders, have performed dose-response curves and have validated their actions as inhibitors of the hNTH1/YB-1 interface using alternative binding assays. Taken together, our results demonstrate that YB-1 directly interacts and stimulates a DNA repair and a DNA relaxing enzyme and targeting the YB-1/hNTH1 interface represents an interesting new strategy for the development of anti-cancer drugs.

Cancer

Réparation de l'ADN

Topoisomérase I

Interactions protéines-Protéines

Fret

Inhibiteurs

Cancer

DNA repair

Topoisomerase I

Protein-Protein Interactions

Fret

Inhibitors

570

Design and Synthesis of Small-Molecule Protein-Protein Interaction Antagonists

Han, Xu

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Protein-protein interactions play a crucial role in a wide range of biological processes. Research on the design and synthesis of small molecules to modulate these proteinprotein interactions can lead to new targets and drugs to modulate their function. In Chapter one, we discuss the design and synthesis of small molecules to probe a proteinprotein interaction in a voltage-gated Ca2+ channel. Virtual screening identified a compound (BTT-3) that contained a 3,4-dihydro-3,4’-pyrazole core. This compound had modest biological activity when tested in a fluorescence polarization (FP) assay. The synthetic route to BTT-3 consisted of six steps. In addition, analogs of BTT-3 were made for a structure-activity study to establish the importance of a carboxylate moiety. We also synthesized a biotinylated benzophenone photo-affinity probe and linked it to BTT-3 to identify additional protein targets of the compound. In Chapter two, small-molecule antagonists targeting uPA-uPAR protein-protein interaction are presented. A total of 500 commercially-available compounds were previously identified by virtual screening and tested by a FP assay. Three classes of compounds were found with biological activity. The first class of compounds contains pyrrolidone core structures represented by IPR- 1110, the second class has a novel pyrrolo[3,4-c]pyrazole ring system, represented by xv IPR-1283 and the last series had compounds with a 1,2-disubstituted 1,2- dihydropyrrolo[3,4-b]indol-3(4H)-one core structure, represented by IPR-540. Each of these three compounds were synthesized and assessed by FP and ELISA assays. A binding mode of IPR-1110 with uPA was subsequently proposed. Based on this binding mode, another 61 IPR-1110 derivatives were synthesized by us to illustrate the SAR activity. Analogs of the other two series were also synthesized.

Molecular association -- Antagonists

Urokinase -- Research

Fluorescence spectroscopy -- Analysis

Calcium channels -- Research

Plasminogen activators

The impact of mTOR, TFEB and Bid on non-alcoholic fatty liver disease and metabolic syndrome

Zhang, Hao

18 May 2015

Indiana University-Purdue University Indianapolis (IUPUI) / Non-alcoholic fatty liver disease and metabolic syndrome induced by high nutrient status have increasingly become a global health concern as it cause multiple complications. The mTOR complex is central in regulating anabolic reactions within cells under growth factors or under high nutrients stimulation. Constitutive and persistent activation of mTOR can impair cellular functions. In the first part of this study, we demonstrate a damping oscillation of mTOR activity during a long-term treatment of high fat diet. TFEB translocation and lysosomal enzyme activity also oscillate, but in an opposite direction. TFEB controls the lysosomal activity, autophagic degradation and lipid metabolism. Overexpression of wild type and mutant TFEB could inhibit NAFLD development in mice. In addition, TFEB location in nucleus inversely correlates with NAFLD severity in patients. mTOR activation under hypernutrition status suppresses TFEB translocation, inhibits lysosomal functions and autophagic degradation of lipid droplets. Inhibition of mTOR activity by rapamycin reverse the above phenotypes. Because mTOR activation also requires normal lysosomal function, the inhibition of TFEB by mTOR leads to decreased lysosomal function and mTOR downregulation. This negative feedback may explain the oscillation pattern of mTOR activation in long term high fat diet regimen and is a novel mechanism for inhibition of mTOR. In the second part of study, we report that Bid protein, previously known for its pro-apoptosis function in promoting mitochondrial permeability, plays an unexpected role in regulating fatty acid beta oxidation. Deletion of Bid in mice reprograms the body's response to hyper-nutrition caused by high fat diet, leading to the resistance to the development of obesity, liver steatosis and metabolic syndrome. These mice present a higher oxygen consumption, a lower respiratory quotient, and an increased beta-oxidation rate. Mechanistically, the high fat diet regimen triggers translocation of the full length Bid molecule to mitochondrial membrane. Genetic deletion of Bid also affects the stability of its binding protein, MTCH2 in the mitochondrial membrane. In summary, we describe in this study a mTOR-TFEB-lysosome feedback loop, which can regulate NAFLD development, and a novel Bid-mediated regulatory mechanism in beta-oxidation, which limits energy expenditure and promotes obesity development.

Liver -- Diseases

Fatty liver

Hepatology

Metabolism -- Disorders

Metabolic syndrome

Nutrition

Cellular signal transduction

Adipose tissues

Fat

Protein-protein interactions

Mice as laboratory animals

Targeting Anti-apoptotic Bcl-2 Proteins with Scyllatoxin-based BH3 Domain Mimetics

Berugoda Arachchige, Danushka M.

01 June 2020

No description available.

Biochemistry

Biology

Biomedical Engineering

Biophysics

Biomedical Research

Chemistry

peptide synthesis

B cell lymphoma

scyllatoxin

apoptosis

protein-protein interactions

direct binding assay

competitive binding assay