Etude de facteurs impliqués dans le contrôle-qualité de l'expression des gènes, chez Saccharomyces cerevisiae / Proteins involved in the quality-control of gene expression, in Saccharomyces cerevisiae

Zhang, Elodie

09 November 2017

La régulation et le contrôle-qualité de l'expression génique permettent respectivement de maintenir un équilibre entre synthèse et dégradation des ARNm répondant aux besoins cellulaires et d'empêcher l'expression d'ARNm ou protéines aberrants potentiellement toxiques. Pour mieux comprendre ces processus cytoplasmiques, je me suis intéressée à Jlp2, Tac4 et Ska1, trois protéines ayant des liens physiques ou fonctionnels avec des acteurs du contrôle-qualité des ARNm et peptides appartenant aux complexes RQC et SKI. Jlp2 montre des liens de létalité synthétique avec les complexes RQC et SKI mais son absence n'altère pas le " NonStop mRNA Decay ". Elle pourrait donc être impliquée dans une autre voie de contrôle dépendante des complexes RQC et SKI. Tac4 est une ARN hélicase putative associée aux ribosomes, au niveau de l'hélice H16 de l'ARNr 18S comme son homologue putatif mammifère DHX29. Elle interagit également au niveau de régions 3'UTR d'ARNm. Ces observations suggèrent que Tac4 pourrait être impliquée dans la réinitiation de la traduction et le sauvetage de ribosomes non-dissociés récemment identifiés dans la région 3'UTR d'ARNm. Enfin, nous avons identifié Ska1, une protéine appartenant à une nouvelle sous-population de complexes SKI. Nos données suggèrent que ce complexe SKI-Ska1 est impliqué dans la dégradation de transcrits dépourvus de ribosome. Nous proposons un modèle selon lequel ce complexe SKI-Ska1 agirait durant la dégradation de 3'UTR avec l'exosome, puis en arrivant dans la région codante et en rencontrant un ribosome, Ska1 se dissocierait du complexe pour lui permettre d'interagir directement avec le ribosome et poursuivre la dégradation 3'-5' de l'ARN. / Mechanisms responsible for the regulation of gene expression and its quality-control are required, respectively for maintaining an equilibrium between mRNA synthesis and degradation and to prevent synthesis of aberrant mRNAs and proteins potentially toxic for the cells. To better understand these quality-control processes, I studied three factors, Jlp2, Tac4 and Ska1, with physical or functional links described with factors involved in mRNA and protein quality-control, the RQC and SKI complexes. Jlp2 shows synthetic lethality with the RQC and SKI complexes but its deletion has no effect on the NonStop mRNA Decay, suggesting that Jlp2 could be implicated in another control pathway linked to the RQC and SKI complexes. Tac4 is a putative RNA helicase bound to ribosomes, on the 18S rRNA H16 helix, as its mammalian putative homolog DHX29. DHX29 plays a role in translation initiation but surprisingly, Tac4 interacts, in addition to ribosomes, with mRNA 3’UTRs. These observations suggest that Tac4 could be implicated in translation reinitiation and rescue of non-dissociated-ribosomes, recently described within mRNA 3’UTRs. Finally, we identified Ska1, a new factor associated to a SKI complex subpopulation. Our observations suggest that the SKI-Ska1 complex is implicated in the degradation of transcripts devoid of ribosomes. It suggests a model by which the SKI complex would proceed in two steps. First, the SKI-Ska1 complex could assist the exosome to degrade 3’UTR regions of RNAs and then, when its reaches the coding region and encounter a ribosome, Ska1 would leave the complex and allow it to interact directly with ribosomes to proceed further in the 3’-5’ RNA degradation.

Dégradation des ARN et protéines

Nsd/ngd

Ribosome

Complexe SKI

Exosome

Saccharomyces cerevisiae

Rna and protein degradation

Ski complex

Ribosome

571.6

572.8

Isolierung und Charakterisierung funktioneller Exosomen durch sequentielle Filtration

Heinemann, Mitja Leonard

30 August 2016

Exosomen aus Zellen nehmen eine immer größere Rolle in aktuellen Erkenntnissen zu Tumorwachstum und Metastasierung ein. Die Funktionen dieser circa 40-100 nm großen, aktiv sezernierten Vesikel sind bisher noch weitesgehend ungeklärt. Für die Untersuchung von Exosomen sind optimierte und schonende Isolierungsmethoden notwendig. Zur Zeit gibt es jedoch weder eine standardisierte Methode zur routinemäßigen Isolation von Exosomen noch zur Isolation von funktionell intakten Exosomen für die anschließende Funktionsanalyse. Ziel dieser Arbeit war es, eine vereinfachte, größenbasierte und standardisierbare Methode zur Isolation von funktionell intakten Exosomen zu entwickeln und die isolierten Exosomen qualitativ und quantitativ zu charakterisieren. Die Ergebnisse dieser Arbeit konnten in einer internationalen Fachzeitschrift publiziert werden. Die Publikation liegt dieser Arbeit bei (Heinemann et al. 2014).

info:eu-repo/classification/ddc/610

ddc:610

Význam exosomů a ektosomů pro virulenci Trichomonas vaginalis. / Role of exosomes and ectosomes in Trichomonas vaginalis virulence

Göblová, Rebeka

January 2020

Trichomonas vaginalis is a causative agent of the most common non-viral sexually transmitted disease with approximately 275 mil new cases annually. Virulence of this parasitic depends on at least four factors: cell shape transformation, cytoadherence, secretion of cysteine proteases, and presence of endosymbionts. Over the past decades, extracellular vesicles appeared being another important player in the host-parasite interaction. It was discovered that T. vaginalis is one of the protists that can shed the extracellular vesicles such as exosomes and ectosomes. These vesicles are possibly involved in host-parasite communications, however limited information is available about their function. To investigate a possible role of exosomes in T. vaginalis virulence, we first selected suitable strain, which is free of endosymbionts (TV 17-2MI). Next we prepared six clones of TV 17-2MI strain to test whether the strain is homogenous concerning the virulence, or there are differences in virulence among individual cells. Mouse intraperitoneal virulence tests revealed that the clones displayed significant differences in virulence level, particularly in abscess formation and mortality of infected animals. Thus, for the first time we demonstrated heterogeneity of cells derived from a single T. vaginalis strain...

Adaptation de la levure à la suite des perturbations du mécanisme de contrôle de qualité de l'ARN

Gendron, Louis

09 1900

The life-cycle of RNA is determined by several processing steps, which allow the cell to export and translate a coding transcript. The cell has developed an astonishingly complex mechanism to ensure the integrity of RNA processing steps. The quality control mechanism of RNA balances the biosynthesis and degradation of various transcripts, adding another layer of gene regulation to the complex system of gene expression. The exosome is a central piece of the RNA quality control mechanism as it degrades many of the aberrant or non-functional RNAs in the nucleus and the cytoplasm. This project characterizes and highlight a response to mutation of components from the RNA quality control mechanism in Saccharomyces cerevisiae. These perturbations include functional components of the exosome (Csl4 and Dis3), a cofactor of the nuclear exosome (Rrp6), an essential protein for pre-rRNA processing (Enp1) and a component of RNA export machinery (Srm1). Here, I present bioinformatics approaches to characterize the cellular response at a level of transcript expression and polyadenylation size. The stress response embedded in the gene expression profile is highly similar between the mutants. This work suggests a generic response to a failure in different components of the RNA quality control machinery. / Le cycle de vie des ARN est déterminé par différentes étapes permettant à la cellule d’exporter et de traduire un transcrit codant. La cellule a développé un mécanisme incroyablement complexe pour s’assurer de l’intégrité des étapes de maturation de l’ARN. Le mécanisme de contrôle de qualité balance la biosynthèse et la dégradation de différents transcrits, ce qui ajout un niveau de régulation au système de l’expression génique. L’exosome est une pièce centrale du mécanisme de contrôle de qualité de l’ARN alors qu’elle dégrade une grande partie des transcrits aberrants ou non-fonctionnels dans le noyau et le cytoplasme. Ce projet caractérise et souligne la réponse cellulaire à la suite de la mutation de composantes du mécanisme de contrôle de qualité de l’ARN chez Saccharomyces cerevisiae. Ces perturbations comportent des composantes fonctionnelles du complexe de l’exosome (Csl4 et Dis3), un cofacteur de l’exosome nucléaire (Rrp6), une protéine essentielle pour la maturation des pré-ARNr (Enp1) et une composante de la machinerie d’export de l’ARN (Srm1). Ici, je présente des approches bio-informatiques pour caractériser la réponse cellulaire au niveau de l’expression des transcrits et de la taille des segments polyadénylés. La réponse au stress cellulaire intégré dans le profil d’expression du génome est très similaire entre les mutants. Ce travail suggère une réponse générique à la suite de la perturbation de différentes composantes du mécanisme de contrôle de qualité de l’ARN.

bio-informatique

bioinformatic

transcriptomique

transcriptomic

contrôle de qualité de l'ARN

RNA quality control

exosome

polyadenylation

Membrane vesicle trafficking of immune modulatory stimuli during <i>Mycobacterium tuberculosis</i> infection

Athman, Jaffre Joseph

07 February 2017

No description available.

Immunology

Molecular Biology

Microbiology

tuberculosis

Mycobacterium tuberculosis

T-cells

bacterial vesicle

exosome

immune evasion

LAM

lipoarabinomannan

membrane vesicle

anergy

Cardiac and Skeletal Muscle Dysfunction in Diabetic Dyslipdemic mice is Mitigated by Stem Cell Derived Exosomes

Banerjee, Abha

01 January 2024

Hyperglycemia and dyslipidemia are common comorbidities that often coincide and have a significant impact on the severity of diabetes. This current study investigates the pathology and mechanism behind skeletal muscle cachexia and cardiac dysfunction in diabetic dyslipidemia. Stem cells continue to be critical as a regenerative strategy to restore damaged tissue, however, several drawbacks have been observed with use of stem cells including thrombogenesis, low survival, and tumorigenicity. Therefore, we isolated exosomes from stem cells and assessed their ability to attenuate diabetes-induced sarcopenia and cardiomyopathy. Exosomes are nanosized particles released by cells, containing proteins and nucleic acids that allow it to exhibit similar properties to the cell type of origin. To model diabetic dyslipidemia, we utilized ApoE knockout mice (10±2 weeks) and divided them into 4 groups consisting of control (saline intraperitoneal (IP) injection), diabetic (STZ IP injection), treatment group administered intravenous (IV) exosomes derived from miR-1 ES-Exos (microRNA-1 enriched Embryonic Stem Cells) or MSC-Exos (Mesenchymal Stem Cells), and negative control treatment MEF-Exos (Mouse Embryonic Fibroblasts). Heart and soleus tissue samples were analyzed for inflammation, inflammatory cell death expression, and adverse tissue remodeling using histology, immunohistochemistry, western blotting, RT-PCR, cytokine, and luciferase-based arrays. In summary we found diabetic dyslipidemic mice acquire cardiac and skeletal muscle dysfunction. Administration of miR-1 ES-Exos and MSC-Exos significantly mitigated inflammation and cell death marker expression, resulting in improved cardiac and skeletal muscle function. In conclusion our data shows that miR-1 ES-Exos and MSC-Exos are effective therapeutic agents in attenuating diabetes-induced sarcopenia and cardiomyopathy.

apoptosis

atrophy

myopathy

sarcopenia

diabetes

sterile inflammation

necroptosis

diabetic cardiomyopathy

MSC

exosome therapy

Estudo do exossomo de Archaea e de sua interação com a proteína reguladora PaNip7 / Study of Archaeal exosome and its interaction with the PaNip7 regulatory protein.

Menino, Glaucia Freitas

28 January 2016

O exossomo é um complexo multiproteico conservado evolutivamente de archaea a eucariotos superiores que desempenha funções celulares essenciais tais como: atividade exoribonucleolítica 3\'&#8594;5\', regulação dos níveis de mRNA, maturação de RNAs estruturais e controle de qualidade de RNAs durante os vários estágios do mecanismo de expressão gênica. Em Archaea, o exossomo é composto por até quatro subunidades diferentes, duas com domínios de RNase PH, aRrp41 e aRrp42, e duas com domínios de ligação a RNAs, aCsl4 e aRrp4. Três cópias das proteínas aRrp4 e/ou aCsl4 se associam com o núcleo hexamérico catalítico do anel de RNase PH e completam a formação do complexo. A proteína PaNip7 é um cofator de regulação do exossomo da archaea Pyrococcus abyssi e atua na inibição do complexo enzimático ligando-se simultaneamente ao exossomo e a RNAs. Neste projeto, a reconstituição in vitro do exossomo da archaea Pyrococcus abyssi formado pela proteína de topo PaCsl4 foi obtida. Para tanto foram realizadas análises de interação proteica usando as técnicas de cromatografia de afinidade, gel filtração e SDS-PAGE. Em adição à formação da isoforma PaCsl4-exossomo, um fragmento peptídico correspondente à região C-terminal da PaNip7 foi sintetizado pelo método da fase sólida, purificado por RP-HPLC e o purificado foi caracterizado por LC/ESI-MS almejando realizar futuros experimentos de interação com o exossomo. / The exosome is a multiprotein complex evolutionarily conserved from archaea to higher eukaryotes that performs essential cellular functions such as: 3\'&#8594;5\' exoribonucleolytic activity, regulation of mRNA levels, maturation of structural RNAs and quality control of RNAs during the various stages of the gene expression mechanism. In Archaea, the exosome is composed of up to four different subunits, two with RNase PH domains, aRrp41 and aRrp42, and two with RNAs binding domains, aCsl4 and aRrp4. Three copies of the aRrp4 and/or aCsl4 proteins associate with the hexameric catalytic core of the RNase PH ring and complete the formation of the complex. The PaNip7 protein is a regulating cofactor of the Pyrococcus abyssi archaeal exosome and acts in the inhibition of the enzyme complex by binding simultaneously to the exosome and RNAs. In this project, the reconstitution in vitro of the Pyrococcus abyssi archaeal exosome formed by the PaCsl4 top protein was achieved. To this end protein interaction analyses were performed using affinity chromatography, gel filtration and SDS-PAGE techniques. In addition to the formation of the PaCsl4-exosome isoform, a peptide fragment corresponding to the C-terminal region of PaNip7 was synthesized by solid-phase method, purified by RP-HPLC and the purified peptide was characterized by LC/ESI-MS aiming to perform future binding experiments with the exosome.

Archaeal exosome

Chromatography

Cromatografia

Estrutura de proteína

Exossomo de archaea

Expressão gênica

Gene expression

Metabolismo de RNA

PaNip7

PaNip7

Peptide synthesis

Protein purification

Protein structure

Purificação de proteína

RNA metabolism

Síntese de peptídeo

Endothelial HSPA12B is a Novel Protein for the Preservation of Cardiovascular Function in Polymicrobial Sepsis via Exosome MiR-126

Zhang, Xia

01 August 2016

Sepsis is the most frequent cause of mortality in most intensive care units. Cardiovascular dysfunction is a major complication associated with sepsis, with high mortality rates up to 70%. Currently, there is no effective treatment approach for sepsis. The integrity of the endothelium is fundamental for the homeostasis of the cardiovascular system. Sepsis induces endothelial cell injury which is the key factor for multiple organ failure. The increased expression of adhesion molecules and chemokines in endothelial cell promotes leukocytes infiltration into the tissue. The loss of tight junction proteins and increased permeability of the endothelial cells will provoke tissue hypoxia and subsequent organ failure. Therefore, preservation of endothelial function is a critical approach for improving sepsis-induced outcome. Here, we showed that endothelial specific protein HSPA12B plays a critical role in the preservation of cardiovascular function in polymicrobial sepsis. HSPA12B is the newest member of HSP70 family which predominantly expresses in endothelial cells. We observed that HSPA12B deficiency (HSPA12B-/-) exaggerated polymicrobial sepsis-induced endothelial dysfunction, leading to worse cardiac dysfunction. HSPA12B-/- significantly increases the expression of adhesion molecules, decreases tight junction protein levels and enhances vascular permeability. HSPA12B-/- alsomarkedly promotes the infiltration of inflammatory cells into the myocardium and inflammatory cytokine production. We investigated the cardioprotective mechanisms of HSPA12B in sepsis induced cardiovascular dysfunction. Exosomes play a critical role in intercellular communication. Exosome is a natural vehicle of microRNAs. We found that exosomes isolated from HSPA12B-/- septic mice induced more expression of adhesion molecules in endothelial cells and inflammation in macrophages. Interestingly, the levels of miR-126 in serum exosomes isolated from HSPA12B-/- septic mice were significantly lowers than in WT septic mice. Importantly, delivery of miR-126 carried exosomes significantly improved cardiac function, suppressed the expression of adhesion molecules, reduced immune cell infiltration in the myocardium, and improved vascular permeability in HSPA12B-/- septic mice. The data suggests that HSPA12B is essential for endothelial function in sepsis and that miR-126 containing exosomes plays a critical role in cardiovascular-protective mechanisms of endothelial HSPA12B in polymicrobial sepsis.

sepsis

endothelial cell

heat shock protein

exosome

microRNA

cardiac function

Bacterial Infections and Mycoses

Cardiovascular Diseases

Cell Biology

Disease Modeling

Immunology and Infectious Disease

Immunology of Infectious Disease

The genetic regulation and subcellular dynamics of secretory and endolysosomal organelles of Drosophila secondary cells

Kroeger, Benjamin Robert

January 2017

Secretory processes underpin the emergence of cellular diversity in complex multicellular organisms. However, our understanding of the basic mechanisms controlling the different secretory and endosomal compartments involved remains surprisingly incomplete. During my DPhil I have studied a specialised epithelial cell type in the male Drosophila accessory glands, the secondary cell, which contains unusually large intracellular compartments that are accessible to detailed morphological study. I characterise the organisation, ultrastructure and molecular composition of this cell's secretory and endosomal compartments, and I employ specific Rab GTPases, conserved coordinators of membrane trafficking and identity, to define multiple compartmental subtypes. By developing super-resolution and time-lapse microscopy approaches in these cells, I show that numerous intraluminal vesicles (ILVs) are formed within Rab11-labelled secretory compartments and released into the accessory gland lumen as exosomes, the first clear demonstration in eukaryotic cells of exosome biogenesis within a non-late endosomal compartment. Biogenesis of these ILVs is dependent on evolutionarily conserved Endosomal Sorting Complexes Required for Transport (ESCRT) 0-III genes and involves loading of compartment-specific cargoes. Work by others, some in collaboration with me, has shown that these novel mechanisms are conserved in human cells. I show that dense-core granules, the structures employed to package proteins and other molecules destined for regulated secretion, form within large non-cored Rab6- positive compartments, in a process that seems to involve inputs from both the Golgi and recycling endosomal pathways. Further analysis has revealed roles for specific Rabs, for ILVs, and for the conserved fibrillar protein Mfas/TGFBI in different aspects of DCG formation. I also show that DCGs are not only secreted, but can also be degraded by fusion to acidic endosomal compartments. Remarkably, there is evidence that mammalian cells may employ all of these mechanisms and defects in these processes may be linked to diseases like cancer, diabetes and neurodegenerative disorders. Hence my work has established a new system to study complex secretory mechanisms, which can now be developed to model specific disease processes in the future. In summary, I have discovered several novel cell biological mechanisms controlling exosome biology, dense-core granule biogenesis, regulated secretion, and endolysosomal trafficking. Some of these already appear relevant to human health and disease, suggesting that the secondary cell system has considerable further potential for unravelling the fundamental processes underlying eukaryotic secretion in the future.

Estudo do exossomo de Archaea e de sua interação com a proteína reguladora PaNip7 / Study of Archaeal exosome and its interaction with the PaNip7 regulatory protein.

Glaucia Freitas Menino

28 January 2016

O exossomo é um complexo multiproteico conservado evolutivamente de archaea a eucariotos superiores que desempenha funções celulares essenciais tais como: atividade exoribonucleolítica 3\'&#8594;5\', regulação dos níveis de mRNA, maturação de RNAs estruturais e controle de qualidade de RNAs durante os vários estágios do mecanismo de expressão gênica. Em Archaea, o exossomo é composto por até quatro subunidades diferentes, duas com domínios de RNase PH, aRrp41 e aRrp42, e duas com domínios de ligação a RNAs, aCsl4 e aRrp4. Três cópias das proteínas aRrp4 e/ou aCsl4 se associam com o núcleo hexamérico catalítico do anel de RNase PH e completam a formação do complexo. A proteína PaNip7 é um cofator de regulação do exossomo da archaea Pyrococcus abyssi e atua na inibição do complexo enzimático ligando-se simultaneamente ao exossomo e a RNAs. Neste projeto, a reconstituição in vitro do exossomo da archaea Pyrococcus abyssi formado pela proteína de topo PaCsl4 foi obtida. Para tanto foram realizadas análises de interação proteica usando as técnicas de cromatografia de afinidade, gel filtração e SDS-PAGE. Em adição à formação da isoforma PaCsl4-exossomo, um fragmento peptídico correspondente à região C-terminal da PaNip7 foi sintetizado pelo método da fase sólida, purificado por RP-HPLC e o purificado foi caracterizado por LC/ESI-MS almejando realizar futuros experimentos de interação com o exossomo. / The exosome is a multiprotein complex evolutionarily conserved from archaea to higher eukaryotes that performs essential cellular functions such as: 3\'&#8594;5\' exoribonucleolytic activity, regulation of mRNA levels, maturation of structural RNAs and quality control of RNAs during the various stages of the gene expression mechanism. In Archaea, the exosome is composed of up to four different subunits, two with RNase PH domains, aRrp41 and aRrp42, and two with RNAs binding domains, aCsl4 and aRrp4. Three copies of the aRrp4 and/or aCsl4 proteins associate with the hexameric catalytic core of the RNase PH ring and complete the formation of the complex. The PaNip7 protein is a regulating cofactor of the Pyrococcus abyssi archaeal exosome and acts in the inhibition of the enzyme complex by binding simultaneously to the exosome and RNAs. In this project, the reconstitution in vitro of the Pyrococcus abyssi archaeal exosome formed by the PaCsl4 top protein was achieved. To this end protein interaction analyses were performed using affinity chromatography, gel filtration and SDS-PAGE techniques. In addition to the formation of the PaCsl4-exosome isoform, a peptide fragment corresponding to the C-terminal region of PaNip7 was synthesized by solid-phase method, purified by RP-HPLC and the purified peptide was characterized by LC/ESI-MS aiming to perform future binding experiments with the exosome.

Cromatografia

Estrutura de proteína

Exossomo de archaea

Expressão gênica

Metabolismo de RNA

PaNip7

Purificação de proteína

Síntese de peptídeo

Archaeal exosome

Chromatography

Gene expression

PaNip7

Peptide synthesis

Protein purification

Protein structure

RNA metabolism