Synthesis of Novel Agents for the treatment of Infectious and Neurodegenerative diseases

Eduful, Benjamin Joe

02 April 2018

Infectious and neurodegenerative diseases continue to be a major concern worldwide. In spite of the great advances in drug therapy for treating various infectious and neurodegenerative diseases, there is still an urgent need for new and improved drugs due to increasing drug resistance among pathogens, emergence of new pathogens, ease of transmission of infections, ineffective available treatments, toxicity associated with current standard of care, aging populations and the lack of better alternative treatment options. The first part of this manuscript (chapters 1 - 5) describes the synthesis of novel agents active against Leishmania donovani. According to the World Health Organization (WHO), a significant number of deaths worldwide can be attributed to infectious diseases – particularly neglected tropical diseases (NTDs), one of which is leishmaniasis - a complex and clinically diverse disease transmitted through the bite of an infected female phlebotomine sand-fly. The pathogen that causes leishmaniasis develops through a complex life cycle via different morphological changes. Its clinical presentations range from the less severe (cutaneous) to lethal/fatal (visceral) forms depending upon the level of systemic involvement, infecting species and the endemic environment. Treatments (and vaccines) must be species-specific to be particularly effective since sensitivity to commonly used drugs is largely species-specific. Heat shock protein 90 (Hsp 90) has been shown to promote the differentiation of the protozoan parasite that causes leishmaniasis from the promastigote stage to the amastigote pathogenic stages. To this end a series of compounds were prepared based on known Hsp 90 inhibitors, SNX2112 and XL888. The synthetic approach allows the probing of a hydrophobic pocket and rapid access to a collection of anti-leishmanial compounds. The most active compound, was found to be more than twice as active as the climivally used drug, miltefosine, in an infected J774 macrophage at IC50 = 0.65 µM. The second part of this manuscript (chapters 6 - 9) describes the synthesis novel anti-Alzheimer’s agents. Alzheimer’s disease is a progressive neurodegenerative disease believed to be caused by tau hyperphosphorylation and plaque aggregation in the brain. It is known to affect about 44 million people worldwide and it is marked as the 6th leading cause of death in the United States. Slingshot homology-1 (SSH1) proteins, important protein phosphatases, are promising targets for the discovery of a new generation of small molecule inhibitors as treatment for Alzheimer’s disease, since SSH1 is known to contribute to both tau hyperphosphorylation and plaque aggregation in the brain. Through structure and activity relationships (SAR) studies, two (2) series of compounds were synthesized, thiazoles and pyridones, bearing a carboxylic acid or phosphonic acid functionality as inhibitors of SSH1 enzymes. In the preliminary screening efforts against SSH1 phosphatase activity, the thiazole series were found to be more potent at inhibiting the phosphatase activity than the pyridone series. Among the active thiazole series, eight (8) analogs exhibited significant inhibitory activity over the initial hit compound, observed via phosphatase inhibition curves (using a pNPP phosphatase assay). Further investigations into the molecular target (SSH1) are currently underway.

Infectious diseases

Leishmania donovani

promastigotes

amastigotes

parasite

Chaperone proteins

Alzheimer’s disease

slingshot homology-1

Cofilin

protein phosphatases

Organic Chemistry

RNA and histone chaperone-based gene silencing in the fission yeast Schizosaccharomyces pombe / Répression de l’expression génique contrôlée par l’ARN et les histones chaperonnes chez la levure fissipare Schizosaccharomyces pombe

Cattaneo, Matteo

14 December 2015

Une fraction non négligeable de protéines qui contrôlent la dynamique de la chromatine et la transcription est conservée au cours de l'évolution chez les eucaryotes. Ces protéines se retrouvent dérégulées dans de nombreuses maladies, dont les cancers. Dans cette étude, nous avons exploité la purification de deux protéines associées à la chromatine pour étudier de nouveaux acteurs impliqués dans la réduction au silence (ou silencing) de la transcription au sein de l'hétérochromatine et/ou de l'euchromatine chez la levure Schizosaccharomyces pombe, un modèle de référence pour la biologie de la chromatine.Mmi1 est un facteur de liaison à l'ARN capable de guider la formation d'hétérochromatine facultative sur des gènes méiotiques. Parmi les protéines partenaires de Mmi1, nous nous sommes intéressés à Ccr4-Not, un complexe multifonctionnel, conservé de la levure à l'Homme, important pour la maturation de l'extrémité 3' des ARNs et pour le contrôle de l'expression des gènes. Nos travaux montrent que Ccr4-Not est également nécessaire pour le dépôt de la marque H3K9 méthylée aux gènes cibles de Mmi1, ainsi que pour le silencing de la transcription au sein de l'hétérochromatine constitutive, indépendamment de Mmi1.En parallèle, nous avons étudié deux nouveaux partenaires potentiels de RITS (RNA-Induced Transcriptional Silencing), un complexe nécessaire à la formation de l'hétérochromatine et l'inactivation de gène. Ces partenaires agiraient à l'interface entre la régulation de la chromatine et de la transcription. Le premier partenaire est l'histone chaperonne Spt6. Une caractérisation initiale entreprise sur Spt6 a montré son rôle crucial dans le silencing des gènes à l'hétérochromatine constitutive et facultative. Le second partenaire est Abo1, une histone chaperonne putative et homologue à la protéine humaine ATAD2, une protéine exprimée dans de nombreuses tumeurs et considérée comme une cible prometteuse pour le traitement de certains cancers, bien qu'à ce jour il n'y ait que peu d'information disponible sur sa fonction moléculaire. Nous avons dans un premier temps montré qu'Abo1 est nécessaire pour le silencing de la transcription au sein de l'hétérochromatine constitutive. Cependant, l'analyse du transcriptome des cellules abo1Δ a montré qu'Abo1 est également nécessaire au silencing transcriptionel de nombreux gènes codant et non-codant localisés dans l'euchromatine. Par la suite, nous avons purifié Abo1 et identifié par spectrométrie de masse le réseau des protéines qui lui est associé. Cette approche protéomique a montré qu'Abo1 est connectée à de nombreuses protéines impliquées dans le contrôle de la transcription, comme des histones chaperonnes et des complexes de remodelage ATP-dépendant de la chromatine. Enfin, nous avons montré que le défaut de croissance sévère observé dans les cellules abo1Δ est complètement rétabli par l'expression de ATAD2 humain. Ce dernier résultat indique que la caractérisation fonctionnelle d'Abo1, entreprise dans la levure, a le potentiel de fournir des informations importantes sur la fonction moléculaire non seulement d'Abo1, mais aussi d'ATAD2 et de son lien avec les cancers.En résumé, nos résultats permettent une meilleure compréhension de la fonction de trois acteurs impliqués dans le silencing de la transcription chez la levure fissipare. De plus, la caractérisation plus approfondie d'Abo1 pourrait grandement contribuer à élucider la fonction d'ATAD2 et de son rôle dans les cancers. / A sizeable fraction of proteins controlling chromatin dynamics and transcription are conserved throughout eukaryotes and are deregulated in many diseases, including cancer. In this study, we exploited the purification of two chromatin-associated proteins to characterize new actors in the context of euchromatic and/or heterochromatic gene silencing in Schizosaccharomyces pombe, a reference model for the biology of chromatin.Mmi1 is an RNA binding factor that can guide the formation of facultative heterochromatin assembly at meiotic genes. Among new proteins interacting with Mmi1, we examined the function of Ccr4-Not, which is a conserved multifunctional complex processing 3'ends of RNAs and regulating gene expression. We found that Ccr4-Not is also required for the deposition of H3K9 methylation mark at Mmi1 target genes and for gene silencing in a Mmi1-independent manner at constitutive heterochromatin.In parallel, we studied two new potential partners of RITS (RNA-Induced Transcriptional Silencing), a complex required for heterochromatin formation and gene silencing. Both partners are believed to act at the interface between chromatin and transcription regulation. The first one is the histone chaperone Spt6. An initial functional characterization conducted on this protein showed its implication in gene silencing, both at constitutive and facultative heterochromatin. The second one is Abo1, a putative histone chaperone which is homologue to human ATAD2 protein, a male germ factor ectopically expressed in many tumors and considered as a promising target for cancer therapy, although little is known about its molecular function. We first showed that Abo1 is necessary for proper heterochromatin gene silencing at constitutive heterochromatin. However, transcriptomic analysis of abo1∆ cells further extended Abo1's function in gene silencing to protein-coding and non-coding regions within euchromatin. In addition, we purified Abo1 and identified by mass spectrometry the network of its associated proteins. This proteomic approach showed that Abo1 is connected to several chromatin- and transcription-linked proteins, such as histone chaperones and ATP-dependent chromatin remodeling complexes. Finally, we demonstrated that the severe growth defect observed in abo1Δ is completely rescued by the expression of human ATAD2. This later finding indicates that the functional characterization of Abo1 in yeast has the potential to provide important insights into the molecular function not only of Abo1, but also of the cancer linked ATAD2 protein.Altogether, our results permitted a better understanding of three actors involved in chromatin-based gene silencing in fission yeast. In addition, a further characterization of Abo1 may contribute elucidating the function of ATAD2 and its role in cancer.

Chromatine

Silencing des gènes

Histones chaperonnes

Schizosaccharomyces pombe

Arn

Atad2

Chromatin

Gene silencing

Histone chaperone

Schizosaccharomyces pombe

Rna

Atad2

570

Histone H3 variants and chaperones in Arabidopsis thaliana heterochromatin dynamics / Les variantes et chaperones de l'histone H3 dans la dynamique de l'hétérochromatine Arabidopsis thaliana

Benoit, Matthias

17 October 2014

Afin d’étudier la prise en charge des histones H3 jusqu’à l’ADN et pour comprendre l’influence de leur dynamique dans l’organisation d’ordre supérieur de la chromatine, une analyse des chaperonnes d’histones a été menée. Nous avons identifié et caractérisé les sous-unités du complexe HIR, impliqué dans l’assemblage de la chromatine réplication-indépendante chez Arabidopsis. La perte d’AtHIRA, la sous-unité centrale du complexe, affecte le niveau d’histone soluble, l’occupation nucléosomale des régions euchromatiniennes et héterochromatiniennes ainsi que la mise sous silence transcriptionnel des séquences d’ADN répétées. Alors que le complexe HIR ne participe pas à l’organisation d’ordre supérieur de la chromatine, j’ai montré que CAF-1, impliqué dans l’assemblage de la chromatine au cours de la réplication, joue un rôle central dans la formation des chromocentres. Lors du développement post-germinatif des cotylédons, les séquences d’ADN répétées centromériques et péricentromériques se concentrent dans les chromocentres et s’enrichissent en histone H3.1 de manière CAF-1 dépendante. Cet enrichissement, associé à des modifications post-traductionnelles d’histones associées à un état répressif de la transcription, participe à la formation des chromocentres et met en évidence l’importance de l’assemblage de la chromatine par CAF-1 dans la structure et le maintien du génome. Alors que la perte individuelle de HIR ou de CAF-1 n’affecte pas la viabilité, l’absence des deux complexes altère fortement l’occupation nucléosomale et le développement des plantes. Ceci suggère que la compensation fonctionnelle entre ces complexes de chaperonnes ainsi que la plasticité des voies de dépôt des histones restent limitées. / To understand how histones H3 are handled and how histone dynamics impact higher-order chromatin organization such as chromocenter formation in Arabidopsis, a comprehensive analysis of the different histone chaperone complexes is required. We identified and characterized the different subunits of the Arabidopsis HIR complex. AtHIRA is the central subunit and its loss affects non-nucleosomal histone levels, reduces nucleosomal occupancy not only at euchromatic but also at heterochromatic targets and alleviates transcriptional gene silencing. While the HIR complex-mediated histone deposition is dispensable for higher-order organization of Arabidopsis heterochromatin, I show that CAF-1 plays a central role in chromocenter formation. During postgermination development in cotyledons when centromeric and pericentromeric repeats cluster progressively into chromocenter structures, these repetitive elements but not euchromatic loci become enriched in H3.1 in a CAF-1- dependent manner. This enrichment, together with the appropriate setting of repressive histone post-translational marks, contributes to chromocenter formation, identifying chromatin assembly by CAF-1 as driving force in formation and maintenance of genome structure. Finally, while absence of HIR or CAF-1 complexes sustains viability, only the simultaneous loss of both severely impairs nucleosomal occupancy and plant development, suggesting a limited functional compensation between the different histone chaperone complexes and plasticity in histone variant interaction and deposition in plants.

Dynamique de l’heterochromatine

Chromocentre

Histone H3

Chaperonne d’histone

Arabidopsis thaliana

Heterochromatin dynamics

Chromocenter

Histone H3

Histone chaperone

Arabidopsis thaliana

Bri2 BRICHOS domain : Eukaryotic expression and importance of strictly conserved cysteine residues

Hemmingsson, Lovisa

January 2017

Alzheimer’s disease (AD), the most common form of dementia is associated with fibril formation of amyloid-ß peptides (Aß). Aß, proteolytically derived from Aß precursor protein (AßPP), is the major component of amyloid plaques in AD brains. Familial British and Danish dementias (FBD and FDD) share pathological and clinical characteristics with AD, and the underlying mechanisms are associated with amyloid formation of mutant peptides released from the Bri2 protein. Bri2 interacts with AßPP and its BRICHOS domain has been shown to delay Aß40 and Aß42 fibril formation and toxicity in vitro and in vivo. This makes Bri2 BRICHOS a promising anti-amyloid chaperone and a potential treatment strategy for AD. Furthermore, Bri2 BRICHOS possesses a general chaperone activity as it suppresses non-fibrillar aggregation of destabilized citrate synthase (CS). Recent findings show that Bri2 BRICHOS produced in E.coli can form different molecular weight assemblies, ranging from monomers to dimers and poly-disperse oligomers. The oligomers inhibit CS aggregation, whereas the monomers and dimers are more efficient against Aß42 fibrillation and neurotoxicity, respectively. The work in this thesis shows that similar Bri2 BRICHOS quaternary structures are formed in eukaryotic cells as in E.coli. Larger BRICHOS oligomers were found in cell media, derived from proteolytically processed endogenous Bri2 in SH-SY5Y cells, as well as in human embryonic kidney (HEK293) cells transfected with a Bri2 BRICHOS construct. Recombinant human Bri2 BRICHOS mutants with one or none of the two strictly conserved cysteine residues were studied. All mutant monomers become proteolytically degraded during purification, but form stable oligomers. Single Cys to Ser mutants form stable disulfide-dependent dimers that differ in ability to prevent Aß42 fibrillation, the most stable mutant (C164S) being even more efficient than the wildtype Bri2 BRICHOS dimer. This result suggests that intra or intermolecular disulfide(s) and oligomerization affect Bri2 BRICHOS stability and activity towards Aß42 fibril formation.

Bri2 BRICHOS

Aß

Chaperone

Amyloid fibril formation

Alzheimer disease

Eukaryotic expression

Cysteine residues

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Le système CupE de la voie chaperonne - "usher" de Pseudomonas aeruginosa : assemblage, fonction et régulation. Identification du système à deux composants PprA-PprB et caractérisation de son régulon

Giraud, Caroline

13 July 2011

La bactérie à Gram négatif Pseudomonas aeruginosa est un pathogène opportuniste possédant de nombreux systèmes moléculaires contribuant à sa pathogénicité et à son développement selon un mode de vie en biofilm, qui permet une meilleure résistance aux défenses de l’hôte et aux antibiotiques. Parmi ces systèmes, on retrouve les fimbriae assemblés par la voie chaperonne – « usher » (CU). La voie CU implique une protéine formant un pore dans la membrane externe, la protéine « usher », une chaperonne périplasmique et au moins une sous unité piline qui va être assemblée en fimbriae à la surface de la bactérie.Mon travail de thèse a principalement porté sur l’étude du cluster de gènes cupE, qui code pour un système CU du clade σ-fimbriae. Ce système est différent des quatre autres systèmes CU cupA – cupD déjà caractérisés chez P. aeruginosa et appartenant au clade γ4-fimbriae. Indépendamment des gènes codant la protéine « usher » et la chaperonne, ce cluster comprend quatre autres gènes qui codent pour des sous unités pilines atypiques (une piline majeure, deux pilines mineures et une adhésine). Nous avons montré que le système CupE est fonctionnel et permet l’assemblage de fimbriae à la surface de la cellule, assemblage (oligomérisation de la sous unité majeure en fimbirae) pour lequel nous avons montré que l’adhésine est essentielle, au contraire des deux sous unités mineures. Ces fimbriae jouent un rôle important dans la formation et la structuration du biofilm, tant à des étapes précoces que lors des étapes tardives. Excepté une piline mineure, tous les éléments de la fibre sont importants pour la formation du biofilm. Ce cluster de gènes est spécifiquement exprimé en conditions de formation du biofilm et par une approche de mutagenèse aléatoire par transposition, le système à deux composants (TCS) PprA – PprB a été identifié comme un régulateur positif potentiel de ce cluster. L’implication de ce TCS dans la régulation de cupE a été vérifiée et nous avons pu démontrer par des techniques de retard sur gel que ce contrôle est direct et que PprB se lie sur des boites putatives en amont du +1 de transcription de cupE défini par 5’-RACE PCR.Ce TCS ayant été identifié au préalable comme un régulateur positif de pili de type IVB Flp, eux-mêmes acteurs du biofilm chez P. aeruginosa, nous avons caractérisé le régulon du régulateur de réponse PprB. Parmi les nouvelles cibles régulées positivement par PprB, nous avons identifié deux cibles nouvelles dont nous avons débuté la caractérisation. La première est un opéron de quatre gènes codant pour un transporteur ABC impliqué dans la résistance aux antibiotiques spécifiquement en conditions de biofilm et pour une protéine de haut poids moléculaire, substrat potentiel de ce transporteur ABC. Cette protéine, que nous avons renommé AdhA, est effectivement sécrétée par le transporteur ABC et est impliquée dans la cohésion des cellules au cours de la formation du biofilm. Il s’agit d’une nouvelle adhésine participant à la structuration du biofilm chez P. aeruginosa. La seconde cible est un gène codant pour une protéine que nous avons renommée Hvn, homologue aux halovibrines HvnA et HvnB de Vibrio fischeri. Le sécrétome d’une souche délétée du gène hvn est considérablement modifié et son absence d’effet sur la morphologie des cellules eucaryotes par rapport au sécrétome de la souche PAO1 suggère que la protéine Hvn pourrait jouer un rôle dans la virulence de P. aeruginosa.Au travers de ce travail, nous avons caractérisé le système CupE de la voie CU chez P. aeruginosa et montré qu’il assemblait des fimbriae atypiques pouvant avoir un rôle dans les différentes phases de la formation du biofilm et qu’il était sous la régulation directe et positive du TCS PprA – PprB. [...] / The Gram negative opportunistic pathogen Pseudomonas aeruginosa is equipped with molecular systems that contribute to bacterial pathogenesis and biofilm development, this latter being associated with increased resistance to host defenses and antibiotics. Among them, are the fimbriae assembled by the chaperone usher (CU) pathway. The CU pathway involves a protein called the usher that forms a pore in the outer membrane, a periplasmic chaperone and at least one fimbrial subunit assembled into fimbriae at the cell surface.My PhD study mainly focuses on the cupE gene cluster, encoding a CU system from the σ-fimbrial clade. This system is different from all the CU systems cupA – cupD already characterized in P. aeruginosa, all belonging to the γ4-fimbrial clade. Independently from the genes encoding the usher and the chaperone, this cluster comprises four other genes encoding atypical pilins (one major pilin, two minor pilins and one adhesin). We showed that this CupE system is functional and allows the assembly of fimbriae at the cell surface. Unlike the two minor pilins, the adhesin is necessary for the fimbriae assembly (oligomerisation of the major subunit into the fiber). These fimbriae play an important role in biofilm formation and structuration, at early and late steps. Except one minor pilin, all subunits are important for the CupE-dependent biofilm formation. This gene cluster is specifically expressed in biofilm conditions and a random transposon mutagenesis allowed us to identify the two component system (TCS) PprA-PprB as an activator of cupE genes. We verified the implication of this TCS in cupE regulation and, using EMSA, we showed that the PprB control on cupE is direct, with PprB binding onto putative boxes upstream the transcription start of cupE, defined by 5’-RACE PCR.As this TCS was identified before as a positive regulator for the type IVB Flp pilus, another actor in the biofilm formation, we defined the PprB regulon. Among the new targets positively controlled by PprB, we found two new targets that we started to characterize. The first one is a four gene operon encoding an ABC transporter involved in antibiotic resistance specifically in biofilm conditions and a high molecular weight protein, a potential substrate for this ABC transporter. This protein that we renamed AdhA is indeed secreted by this ABC transporter and is implicated in the cohesion between cells during the biofilm formation. It is a new adhesin participating into the biofilm structuration of P. aeruginosa. The second target is a gene encoding a protein that we renamed Hvn, and homologous to HvnA and HvnB halovibrins from Vibrio fischeri. Secretome from an hvn mutant is highly modified and the lack of effect on eukaryotic cell’s morphology in comparison to the PAO1 secretome suggests the Hvn protein can play a role in P. aeruginosa virulence.Through this work, we characterized the cupE system from the CU pathway and showed that this system can assemble atypical fimbriae having a role in the different phases of biofilm formation. This system is under the positive and direct regulation of the TCS PprA – PprB.[...]

Pseudomonas aeruginosa

Biofilm

Chaperonne

Protéine usher

Système à deux composants

Fimbirae

Pseudomonas aeruginosa

Biofilm

Chaperone

Usher protein

Two component system

Fimbirae

Structure de l'ARN au sein des ribonucléoprotéines des Influenzavirus A / Structure of the RNA in Influenza A virus ribonucleoproteins

Ferhadian, Damien

28 September 2018

Le génome des Influenzavirus A est constitué de huit segments d’ARN de polarité négative formant des ribonucléoprotéines virales (RNPv). La segmentation du génome complique l’empaquetage du génome, puisqu’un jeu complet de segments est nécessaire à l’infectiosité des virus. Il est aujourd’hui admis que le mécanisme d’empaquetage est sélectif et fait intervenir des interactions entre les ARN des différentes RNPv, qui dépendent vraisemblablement de la structure de l’ARN. Notre but a été de caractériser la fixation de la protéine virale NP, composant majeur des RNPv, sur l’ARN in vitro. Nous avons également mis en place une stratégie expérimentale afin de déterminer la structure de l’ARN au sein des particules virales. Ces deux aspects du projet ont été abordés par la cartographie chimique qui permet d’interroger la flexibilité de chaque nucléotide de l’ARN. Nos résultats démontrent une activité chaperone de la protéine NP ainsi que des sites préférentiels de fixation. Notre approche in viro a démontré que l’utilisation de deux sondes chimiques permet de discriminer les interactions ARN-ARN des interactions ARN-NP. / The Influenzavirus genome comprises eight segments of single-stranded RNA of negative polarity packaged in viral ribonucleoproteins (vRNP). Genome segmentation complicates packaging as a full set of vRNPs is required needed for virus infectivity. It is now accepted that packaging is selective and involves interactions between the RNA components of vRNPs that likely depend on the RNA structure. Our goal was to characterize the binding of the viral protein NP, the major component of the vRNP, on in vitro transcribed RNA. We also developed an experimental strategy to determine the RNA structure inside the viral particles. Both parts of the project were addressed with chemical mapping experiments, that interrogates the flexibility of each nucleotide in the RNA structure. Our results show that NP possess an RNA chaperone activity and binds preferential sites. Our in viro approach demonstrate that using two chemical probes allow us to discriminate between RNA-RNA and RNA-NP interactions.

Influenza

ARN

Cartographie chimique

SHAPE

Activité chaperonne

Structure ARN

Influenza

RNA

Chemical mapping

SHAPE

Chaperone activity

RNA structure

579.2

572.8

REGULATION OF INTRACELLULAR ARYL HYDROCARBON RECEPTOR PROTEIN LEVELS

Chen, Jinyun

01 January 2020

The aryl hydrocarbon receptor (AHR) is a ligand-activated signaling molecule which controls tumor growth and metastasis, T cell differentiation, and liver development. Expression levels of this receptor protein are sensitive to the cellular p23 protein levels in immortalized cancer cell lines. As little as 30% reduction of the p23 cellular content can suppress the AHR function. Here we reported that down-regulation of the p23 protein content in normal, untransformed human bronchial/tracheal epithelial cells to 48% of its content also suppresses the AHR protein levels to 54% of its content. This p23-mediated suppression of AHR is responsible for the repression of (1) the ligand-dependent induction of the cyp1a1 gene transcription; (2) the benzo[a]pyrene- or cigarette smoke condensate-induced CYP1A1 enzyme activity, and (3) the benzo[a]pyrene and cigarette smoke condensate-mediated production of reactive oxygen species. Reduction of the p23 content does not alter expression of oxidative stress genes or production of PGE2. Down-regulation of p23 suppresses the AHR protein levels in two other untransformed cell types, namely human breast MCF-10A and mouse immune regulatory Tr1 cells. Collectively, down-regulation of p23 suppresses the AHR protein levels in normal and untransformed cells and can in principle protect our lung epithelial cells from AHR-dependent oxidative damage caused by exposure to agents from environment and cigarette smoking. The AHR is expressed in triple-negative and non-triple-negative breast cancer cells. It affects breast cancer growth and crosstalk with the estrogen receptor signaling. Normally the AHR is degraded shortly after ligand activation via the action of 26S proteasome. Here we report that the piperazinylpyrimidine compound Q18 triggers AHR protein degradation which is mediated through chaperone-mediated autophagy in triple-negative breast cancer cells (MDA-MB-468 and MDA-MB-231). This lysosomal degradation of AHR exhibits the following characteristics: (1) not observed in non-triple-negative breast cancer cells (MCF-7, T47D, and MDA-MB-361); (2) inhibited by progesterone receptor B but not estrogen receptor alpha; (3) reversed by chloroquine but not MG132; (4) required LAMP2A; (5) triggered by 6 amino-nicotinamide and starvation and (6) involved AHR-LAMP2A interaction mediated by 6 amino-nicotinamide and starvation. The NEKFF sequence localized at amino acid 558 of human AHR is a KFERQ-like motif of chaperone-mediated autophagy, essential for the LAMP2A-mediated AHR protein degradation.

aryl hydrocarbon receptor

chaperone-mediated autophagy

p23

protein degradation

Pharmaceutical sciences; Pharmacology

Medicine and Health Sciences

Pharmacy and Pharmaceutical Sciences

Rôle des chaperons d’histones dans la réplication et la réparation de l’ADN / Role of histone chaperones in the replication and repair of DNA

Liu, Danni

23 February 2018

La chromatine chez les eucaryotes, porte des informations génétiques et épigénétiques. Les mécanismes garantissant le maintien de ces informations lors de la division cellulaire ou la réparation de l’ADN sont encore mal connus et ils constituent l’enjeu principal du projet de thèse. Plus particulièrement, l’objectif du projet de thèse est de chercher à comprendre comment les chaperons d’histones coordonnent leur action avec des partenaires associés à la fourche de réplication pour conserver les marques épigénétiques portées par les histones parentales et les reporter sur les histones nouvellement synthétisées. Cette thèse décrit précisément comment ASF1 (Anti Silencing Function 1) coopère avec le complexe CAF-1 (Chromatin Assembly Factor 1) et la sous-unité de l’hélicase réplicative MCM2 (Mini Chromosome Maintenance 2), pour la prise en charge des H3-H4 dans la réplication et la réparation de l’ADN.La thèse s’intéresse également à la régulation de l’activité de ces chaperons d’histones par des kinases activées suite à des stress réplicatifs ou des dommages de l’ADN. En particulier nous avons cherché à mieux comprendre comment l’ajout de groupements phosphate sur ASF1 par une enzyme appelée TLK (Tousled Like Kinase) module son activité au cours du cycle cellulaire et en réponse aux dommages de l’ADN. La caractérisation de l'importance des sites phosphorylés sur les propriétés de liaison du chaperon, permet de mieux comprendre le rôle joué par différent forme d’ASF1 dans l’assemblage des histones sur l’ADN et le maintien des informations épigénétiques. Le travail de thèse contient d’analyses biochimiques et structurales par une combinaison de techniques (SEC-MALS, AUC, ITC, RMN, cristallographie des rayons X) et d’analyses fonctionnelles sur des modèles cellulaires. / In eukaryotes, chromatin carries both, the genetic and epigenetic information. Mechanisms implicated in maintenance of these information during cell division or DNA repair remain poorly understood and they constitute the main issue of this thesis project. More specifically, the goal of the project is to understand how histone chaperones coordinate their action with partners associated with the replication fork to recognize and preserve the epigenetic marks carried by parental histones and to copy on the newly synthesized histones. The work unravels how ASF1 (Anti-Silencing Function 1) cooperates with the CAF-1 complex (Chromatin Assembly Factor 1) and with the replicative helicase subunit MCM2 (Mini Chromosome Maintenance 2), for the management of H3-H4 histones in DNA replication and repair.Moreover, this thesis investigates the regulation of histone chaperones activities by kinases activated after a replicative stress or DNA damage. In particular, we analyzed the consequences of ASF1 phosphorylation by the enzyme called TLK (Tousled like kinase). The activity of TLK is modulated during the cell cycle and after DNA damage. Characterization of the importance of phosphorylated sites on the chaperone binding properties, allows a better understanding of the role played by different forms of ASF1 in the assembly of histones on DNA and maintenance of epigenetic information. The thesis work included biochemical and structural analysis with a combination of different techniques (SEC-MALS, AUC, ITC, NMR, X-ray crystallography) and functional analysis in cellular models.

Chaperon d'histone

RMN et Cristallographie

Kinase phosphorylation

Réplication et Réparation de l'ADN

Histone chaperone

NMR and Crystallography

Kinase phosphorylation

DNA Replication and Repair

Characterization of heat shock protein 70-z (PfHsp70-z) from plasmodium falciparium

Zininga, Tawanda

January 2015

PhD (Biochemistry) / Department of Biochemistry / Malaria is a parasitic disease that accounts for more than 660 thousand deaths annually, mainly in children. Malaria is caused by five Plasmodium species P. ovale, P. vivax, P. malariae, P. falciparum and P. knowlesi. The most lethal cause of cerebral malaria is P. falciparum. The parasites have been shown to up-regulate some of their heat shock proteins (Hsp) in response to stress. Heat shock protein 70 (called DnaK in prokaryotes) is one of the most prominent groups of chaperones whose role is central to protein homeostasis and determines the fate of proteins. Six Hsp70 genes are represented on the genome of P. falciparum. The Hsp70 genes encode for proteins that are localised in different sub-cellular compartments. Of these two occur in the cytosol, PfHsp70-z and PfHsp70-1; two occur in the endoplasmic reticulum, PfHsp70-2 and PfHsp70-y; one in the mitochondria, PfHsp70-3 and one exported to the red blood cell cytosol, PfHsp70-x. PfHsp70-1 is a well characterized canonical Hsp70 involved in prevention of protein aggregation and facilitates protein folding. Little is known about PfHsp70-z. PfHsp70-z was previously shown to be an essential protein implicated in the folding of proteins possessing asparagine rich repeats. However, based on structural evidence PfHsp70-z belongs to the Hsp110 family of proteins and is thought to serve as a nucleotide exchange factor (NEF) of PfHsp70-1. The main aim of this study is to elucidate the functional roles of PfHsp70-z as a chaperone and its interaction with PfHsp70-1. In the current study, PfHsp70-z was cloned and expressed in E. coli JM109 cells. This was followed by its purification using nickel chromatography. The expression of PfHsp70-z in parasites cultured in vitro was investigated and its association with PfHsp70-1 was explored using a co-immuno precipitation assay. PfHsp70-z expression in malaria parasites is up regulated by heat stress and the protein is heat stable based on investigations conducted using Circular Dichroism. Furthermore, the direct interaction between recombinant forms of PfHsp70-z and PfHsp70-1 were investigated using slot blot and surface plasmon resonance assays. PfHsp70-z was observed to exhibit ATPase activity. In addition, the direct interaction between PfHsp70-z and PfHsp70-1 is promoted by ATP. Based on limited proteolysis and tryptophan fluorescence analyses, PfHsp70-z binds ATP to assume a unique structural conformation compared to the conformation of the protein bound to ADP or in nucleotide-free state. PfHsp70-z was able to suppress the heat-induced aggregation of malate dehydrogenase and luciferase in vitro. Interestingly, while ATP appears to modulate the conformation of PfHsp70-z, the chaperone function of PfHsp70-z was not influenced by ATP. Altogether, these findings suggest that Characterization of Heat Shock Protein 70-z (PfHsp70-z) from Plasmodium falciparum iii PfHsp70-z serves as an effective peptide substrate holding chaperone. In addition, PfHsp70-z may also serve as the sole nucleotide exchange factor of PfHsp70-1. The broad spectrum of functions of this protein, could explain this PfHsp70-z is an essential protein in malaria parasite survival. This is the first study to show that PfHsp70-z possess independent chaperone activity and that it interacts with its cytosolic counterpart, PfHsp70-1 in a nucleotide dependent fashion. Furthermore, the study shows that PfHsp70-z is a heat stable molecule and that it is capable of forming high order oligomers.

Malaria

Plasmodium falciparum

Chaperone

Nucleotide

Exchange factor

PfHsp70-z

616.9362 ZIN

Malaria

Malaria -- Prevention

Heat shock proteiins

Malaria -- Immunology aspects

Investigation of the role of the GGMP motif of Plasmodium falciparum Hsp70-1 on the chaperone function of the protein and its interaction with a co-chaperone, PfHop

Makumire, Stanley

20 September 2019

PhD (Biochemistry) / Department of Biochemistry / The main malaria agent, Plasmodium falciparum expresses an Hsp70 (PfHsp70-1) which plays a significant role in parasite survival. PfHsp70-1 is distinct in that it possesses glycine-glycine-methionine-proline (GGMP) tetrapeptide repeats in its C-terminal domain. To date, the GGMP motif of PfHsp70-1 has not been studied. The motif is positioned within the C-terminal lid segment of PfHsp70-1. The motif is also about seven residues upstream the terminal EEVD residues that are responsible for the interaction of PfHsp70-1 with its functional regulators (co-chaperones). P. falciparum Hsp70/Hsp90 organizing protein (PfHop) constitutes one of the functional regulators of PfHsp70-1. PfHop allows PfHsp70-1 and its chaperone partner, PfHsp90 to form a functional partnership. Given the proximity of the GGMP repeats to the C-terminus of PfHsp70-1, it was postulated in this study that the GGMP repeat residues may regulate attachment of PfHop to PfHsp70-1. Hence, this study hypothesized that the GGMP repeat motif is important for the interaction between PfHop and PfHsp70-1 as well as the chaperone activity of PfHsp70-1. Two variants in which the N-terminal and the C-terminal GGMP repeats were conservatively substituted were generated. E. coli Hsp70 (DnaK) lacks a GGMP motif. Thus, the GGMP motif of PfHsp70-1 was introduced into E. coli DnaK in order to generate a third GGMP variant. Recombinant forms of PfHsp70-1, DnaK, and their GGMP variants were heterologously expressed in E. coli XL1 Blue cells. The proteins were purified to homogeneity by using a combination of Ni-NTA affinity chromatography, ion exchange, and size exclusion chromatography. Purified proteins were then biophysically characterized using CD spectroscopy and tryptophan fluorescence. Findings from this study revealed that there were minimal secondary structural differences between PfHsp70-1, DnaK and their GGMP variants. In order to investigate the chaperone function of PfHsp70-1, DnaK and the GGMP variants, a complementation assay in E. coli dnak756 cells whose Hsp70 is functionally compromised was conducted. The PfHsp70-1 GGMP variants were able to suppress the thermosensitivity of the E. coli cells. However, the Investigation of the role of GGMP motif of Plasmodium falciparum Hsp70-1 on the chaperone function of the protein and its interaction with a co-chaperone, PfHop ii DnaK-G variant failed to confer cytoprotection to the E. coli dnak756 cells. To further validate the findings from the complementation assay, the ability of the recombinant proteins to suppress aggregation of heat stressed Malate dehydrogenase (MDH) was elucidated. PfHsp70-1 had better MDH aggregation suppression capabilities than its GGMP variants. Overall, findings from the MDH aggregation suppression assay suggest that the GGMP repeats may contribute towards substrate binding. Substrate binding might be dependent on the specific positioning of a particular repeat in the GGMP motif of PfHsp70-1. Furthermore, the ATPase activity of PfHsp70-G632 and PfHsp70-G648 was significantly reduced compared to PfHsp70-1 (wild type). However, PfHsp70-G632 had the lowest ATPase activity. Interestingly, the ATPase activity of PfHsp70-G632 was enhanced in the presence of synthetic Hsp70 model peptide substrates. Slot blot and ELISA approaches confirmed that the GGMP mutations partially abrogated the interaction of PfHsp70-1 with PfHop. Altogether, the findings suggest that the GGMP motif of PfHsp70-1 has marginal effects on the structure of PfHsp70-1. In conclusion, this study provides the first direct evidence that the GGMP motif is important for the chaperone function of PfHsp70-1 as well as its interaction with PfHop. / NRF

Malaria

Plasmodium falciparum

Chaperone

GGMP motif

Hsp70

Hop

616.9362

Malaria

Malariotherapy

Plasmodium falciparum

Malaria -- Immunological aspects

Malaria -- Prevention

Protozoan diseases