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\'→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\'→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

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\'→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\'→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

New Roles for Arginine Methylation in RNA Metabolism and Cancer

Goulet, Isabelle

05 October 2011

Because it can expand the range of a protein’s interactions or modulate its activity, post-translational methylation of arginine residues in proteins must be duly coordinated and ‘decoded’ to ensure appropriate cellular interpretation of this biological cue. This can be achieved through modulation of the enzymatic activity/specificity of the protein arginine methyltransferases (PRMTs) and proper recognition of the methylation ‘mark’ by a subset of proteins containing ‘methyl-sensing’ protein modules known as ‘Tudor’ domains. In order to gain a better understanding of these regulatory mechanisms, we undertook a detailed biochemical characterization of the predominant member of the PRMT family, PRMT1, and of the novel Tudor domain-containing protein 3 (TDRD3). First, we found that PRMT1 function can be modulated by 1) the expression of up to seven PRMT1 isoforms (v1-7), each with a unique N-terminal region that confers distinct substrate specificity, and by 2) differential subcellular localization, as revealed by the presence of a nuclear export sequence unique to PRMT1v2. Second, our findings suggest that TDRD3 is recruited to cytoplasmic stress granules (SGs) in response to environmental stress potentially by engaging in methyl-dependent protein-protein interactions with proteins involved in the control of gene expression. We also found that arginine methylation may serve as a general regulator of overall SG dynamics. Finally, we uncovered that alteration of PRMT1, TDRD3, and global arginine methylation levels in breast cancer cells may be closely associated with disease progression and poor prognosis. Therefore, further studies into the pathophysiological consequences ensuing from misregulation of arginine methylation will likely lead to the development of novel strategies for the prevention and treatment of breast cancer.

Arginine methylation

Protein arginine methyltransferases

Protein arginine methyltransferase 1

Tudor domain-containing proteins

TDRD3

PRMT1

Breast cancer

RNA metabolism

Stress granules

RNA processing

Tudor domain-containing protein 3

Tudor domain

New Roles for Arginine Methylation in RNA Metabolism and Cancer

Goulet, Isabelle

05 October 2011

Because it can expand the range of a protein’s interactions or modulate its activity, post-translational methylation of arginine residues in proteins must be duly coordinated and ‘decoded’ to ensure appropriate cellular interpretation of this biological cue. This can be achieved through modulation of the enzymatic activity/specificity of the protein arginine methyltransferases (PRMTs) and proper recognition of the methylation ‘mark’ by a subset of proteins containing ‘methyl-sensing’ protein modules known as ‘Tudor’ domains. In order to gain a better understanding of these regulatory mechanisms, we undertook a detailed biochemical characterization of the predominant member of the PRMT family, PRMT1, and of the novel Tudor domain-containing protein 3 (TDRD3). First, we found that PRMT1 function can be modulated by 1) the expression of up to seven PRMT1 isoforms (v1-7), each with a unique N-terminal region that confers distinct substrate specificity, and by 2) differential subcellular localization, as revealed by the presence of a nuclear export sequence unique to PRMT1v2. Second, our findings suggest that TDRD3 is recruited to cytoplasmic stress granules (SGs) in response to environmental stress potentially by engaging in methyl-dependent protein-protein interactions with proteins involved in the control of gene expression. We also found that arginine methylation may serve as a general regulator of overall SG dynamics. Finally, we uncovered that alteration of PRMT1, TDRD3, and global arginine methylation levels in breast cancer cells may be closely associated with disease progression and poor prognosis. Therefore, further studies into the pathophysiological consequences ensuing from misregulation of arginine methylation will likely lead to the development of novel strategies for the prevention and treatment of breast cancer.

Arginine methylation

Protein arginine methyltransferases

Protein arginine methyltransferase 1

Tudor domain-containing proteins

TDRD3

PRMT1

Breast cancer

RNA metabolism

Stress granules

RNA processing

Tudor domain-containing protein 3

Tudor domain

New Roles for Arginine Methylation in RNA Metabolism and Cancer

Goulet, Isabelle

05 October 2011

Because it can expand the range of a protein’s interactions or modulate its activity, post-translational methylation of arginine residues in proteins must be duly coordinated and ‘decoded’ to ensure appropriate cellular interpretation of this biological cue. This can be achieved through modulation of the enzymatic activity/specificity of the protein arginine methyltransferases (PRMTs) and proper recognition of the methylation ‘mark’ by a subset of proteins containing ‘methyl-sensing’ protein modules known as ‘Tudor’ domains. In order to gain a better understanding of these regulatory mechanisms, we undertook a detailed biochemical characterization of the predominant member of the PRMT family, PRMT1, and of the novel Tudor domain-containing protein 3 (TDRD3). First, we found that PRMT1 function can be modulated by 1) the expression of up to seven PRMT1 isoforms (v1-7), each with a unique N-terminal region that confers distinct substrate specificity, and by 2) differential subcellular localization, as revealed by the presence of a nuclear export sequence unique to PRMT1v2. Second, our findings suggest that TDRD3 is recruited to cytoplasmic stress granules (SGs) in response to environmental stress potentially by engaging in methyl-dependent protein-protein interactions with proteins involved in the control of gene expression. We also found that arginine methylation may serve as a general regulator of overall SG dynamics. Finally, we uncovered that alteration of PRMT1, TDRD3, and global arginine methylation levels in breast cancer cells may be closely associated with disease progression and poor prognosis. Therefore, further studies into the pathophysiological consequences ensuing from misregulation of arginine methylation will likely lead to the development of novel strategies for the prevention and treatment of breast cancer.

Arginine methylation

Protein arginine methyltransferases

Protein arginine methyltransferase 1

Tudor domain-containing proteins

TDRD3

PRMT1

Breast cancer

RNA metabolism

Stress granules

RNA processing

Tudor domain-containing protein 3

Tudor domain

Etudes de la biogenèse du ribosome chez l'Homme / Understanding human ribosome biogenesis

Zorbas, Christiane

26 June 2015

Les ribosomes sont des macrocomplexes ribonucléoprotéiques sophistiqués, essentiels pour décoder l’information génétique et la traduire en protéines fonctionnelles. Chez les organismes eucaryotes, le ribosome est constitué de deux sous-unités, la petite (40S) et la grande (60S). Leur biogenèse est un processus fondamental, très complexe, qui mène à la synthèse et l’assemblage de 4 ARNr et 80 protéines ribosomiques (79 chez la levure). La biogenèse du ribosome a longtemps été étudiée chez Saccharomyces cerevisiae. Près de 20 ans de recherches ont été nécessaires à la communauté scientifique pour identifier les quelques 200 facteurs de synthèse du ribosome levurien. Alors que le schéma global de cette voie de biosynthèse semble conservé chez les organismes eucaryotes, de nombreux éléments suggèrent qu’elle serait plus élaborée chez l’homme et nécessiterait un plus grand nombre de facteurs que chez la levure. De plus, la caractérisation de nombreuses ribosomopathies, ou maladies du ribosome prédisposant aux cancers, a suscité un intérêt accru pour l’étude de la voie de biosynthèse du ribosome dans le paradigme expérimental le plus approprié, la cellule humaine.<p><p>Au cours de ma thèse de doctorat, j’ai contribué à un projet systématique d’identification de facteurs d’assemblage (FA) du ribosome chez l’homme. Pratiquement, nous avons identifié 286 FA humains, dont beaucoup sont homologues aux facteurs levuriens connus, et 74 sont sans équivalent chez la levure. Par ailleurs, j’ai caractérisé en détail certains facteurs. En particulier, Trm112 pour lequel j’ai montré qu’il agit comme un stabilisateur de la méthyltransférase (MTase) Bud23, spécifique à l’ARNr 18S de la sous-unité levurienne 40S. J’ai également participé à la caractérisation de mutations à l’interface du complexe Bud23-Trm112. Enfin, j’ai contribué à l’étude de trois FA que nous avons identifiés chez l’homme, DIMT1L et WBSCR22-TRMT112. J’ai montré que ces protéines sont les orthologues des MTases levuriennes Dim1 et Bud23-Trm112, qu’elles sont requises pour la synthèse et la modification de l’ARNr mature de la petite sous-unité ribosomique, et qu’elles seraient impliquées dans un mécanisme conservé contrôlant la qualité de la voie de biosynthèse du ribosome.<p><p>La totalité des FA que nous avons identifiés en cellule humaine sont à la disposition de la communauté scientifique dans une base de données en ligne accessible sur la page www.RibosomeSynthesis.com. Nous espérons que cette ressource contribuera à une meilleure compréhension des mécanismes moléculaires sous-jacents au développement des ribosomopathies et à l’élaboration d’agents thérapeutiques efficaces.<p> / Doctorat en sciences, Spécialisation biologie moléculaire / info:eu-repo/semantics/nonPublished

Biologie

Ribosomes

Nucleoproteins

Gene expression

RNA -- Metabolism

Ribosomes

Nucléoprotéines

Expression génique

ARN -- Métabolisme

cancer

ribosomopathies

human cells

yeast

nucleolus

pre-rRNA modification

pre-rRNA processing

ribonucleoprotein (RNP) particles

translation gene expression

ribosome assembly

ribosome biogenesis

Etude de la protéine CIRP et sa fonction dans le métabolisme des ARN messagers

De Leeuw, Frédéric

15 January 2008

La protéine CIRP (Cold Induced RNA binding Protein) est une petite protéine de liaison à l’ARN de 172 acides aminés, qui est constituée du côté amino-terminal d’un domaine de liaison à l’ARN de type RRM (RNA recognition motif), et d’une partie carboxy-terminale riche en glycine et arginine qui comprend plusieurs motifs RGG. Elle a été identifiée comme étant inductible par hypothermie mais aussi par irradiation aux UV et par hypoxie. Nous avons analysé son expression et sa localisation en réponse à différents stress cellulaires. Nous avons montré qu’un traitement à l’arsénite qui induit un stress oxydant n’altère pas l’expression de CIRP provoque sa localisation dans les granules de stress (SG). Les SG sont des structures ribonucléoprotéiques cytoplasmiques contenant des complexes de pré-initiation incompétents pour la traduction, et qui s’accumulent dans les cellules exposées à un stress. Ces structures constituent des sites de triages des ARNm, dans lesquels les ARNm sont soit stockés en attente d’une réinitiation de la traduction une fois le stress surmonté, soit destinés à être dégradés. La protéine CIRP se localise dans les SG que ce soit suite à un stress cytoplasmique ou du réticulum endoplasmique. Nous avons montré également que la localisation de la protéine CIRP dans les SG se déroule indépendamment de la présence de la protéine TIA-1 qui a été décrite comme responsable de l’assemblage des SG. De plus la surexpression de la protéine CIRP conduit à la formation de SG. Nous suggérons donc qu’il existe plusieurs voies qui mènent à l’assemblage de ces structures. En outre, nous avons analysé la localisation de mutants par délétion de la protéine CIRP et avons montré que le domaine RRM et le domaine RGG peuvent indépendamment localiser la protéine dans les SG. Par contre, la méthylation des résidus arginine du domaine RGG est une modification nécessaire à la localisation de CIRP dans les SG. Ensuite, nous avons étudié la fonction de la protéine CIRP dans le métabolisme des ARN messagers. Nous avons montré par une méthode d’adressage, que CIRP est un répresseur de la traduction des ARNm et que le domaine carboxy-terminal est nécessaire et suffisant à cette fonction. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Biologie

Messenger RNA -- Metabolism

Proteins -- Synthesis

Genetic translation

Cytoplasmic granules

ARN messager -- Métabolisme

Protéines -- Synthèse

Traduction génétique

Granulations cytoplasmiques

traduction/translation

granules de stress/stress granules

CIRP

New Roles for Arginine Methylation in RNA Metabolism and Cancer

Goulet, Isabelle

January 2011

Because it can expand the range of a protein’s interactions or modulate its activity, post-translational methylation of arginine residues in proteins must be duly coordinated and ‘decoded’ to ensure appropriate cellular interpretation of this biological cue. This can be achieved through modulation of the enzymatic activity/specificity of the protein arginine methyltransferases (PRMTs) and proper recognition of the methylation ‘mark’ by a subset of proteins containing ‘methyl-sensing’ protein modules known as ‘Tudor’ domains. In order to gain a better understanding of these regulatory mechanisms, we undertook a detailed biochemical characterization of the predominant member of the PRMT family, PRMT1, and of the novel Tudor domain-containing protein 3 (TDRD3). First, we found that PRMT1 function can be modulated by 1) the expression of up to seven PRMT1 isoforms (v1-7), each with a unique N-terminal region that confers distinct substrate specificity, and by 2) differential subcellular localization, as revealed by the presence of a nuclear export sequence unique to PRMT1v2. Second, our findings suggest that TDRD3 is recruited to cytoplasmic stress granules (SGs) in response to environmental stress potentially by engaging in methyl-dependent protein-protein interactions with proteins involved in the control of gene expression. We also found that arginine methylation may serve as a general regulator of overall SG dynamics. Finally, we uncovered that alteration of PRMT1, TDRD3, and global arginine methylation levels in breast cancer cells may be closely associated with disease progression and poor prognosis. Therefore, further studies into the pathophysiological consequences ensuing from misregulation of arginine methylation will likely lead to the development of novel strategies for the prevention and treatment of breast cancer.

Arginine methylation

Protein arginine methyltransferases

Protein arginine methyltransferase 1

Tudor domain-containing proteins

TDRD3

PRMT1

Breast cancer

RNA metabolism

Stress granules

RNA processing

Tudor domain-containing protein 3

Tudor domain

Transcriptional regulation of ATF4 is critical for controlling the Integrated Stress Response during eIF2 phosphorylation

Dey, Souvik

29 October 2012

Indiana University-Purdue University Indianapolis (IUPUI) / In response to different environmental stresses, phosphorylation of eIF2 (eIF2P) represses global translation coincident with preferential translation of ATF4. ATF4 is a transcriptional activator of the integrated stress response, a program of gene expression involved in metabolism, nutrient uptake, anti-oxidation, and the activation of additional transcription factors, such as CHOP/GADD153, that can induce apoptosis. Although eIF2P elicits translational control in response to many different stress arrangements, there are selected stresses, such as exposure to UV irradiation, that do not increase ATF4 expression despite robust eIF2P. In this study we addressed the underlying mechanism for variable expression of ATF4 in response to eIF2P during different stress conditions and the biological significance of omission of enhanced ATF4 function. We show that in addition to translational control, ATF4 expression is subject to transcriptional regulation. Stress conditions such as endoplasmic reticulum stress induce both transcription and translation of ATF4, which together enhance expression of ATF4 and its target genes in response to eIF2P. By contrast, UV irradiation represses ATF4 transcription, which diminishes ATF4 mRNA available for translation during eIF2∼P. eIF2P enhances cell survival in response to UV irradiation. However, forced expression of ATF4 and its target gene CHOP leads to increased sensitivity to UV irradiation. In this study, we also show that C/EBPβ is a transcriptional repressor of ATF4 during UV stress. C/EBPβ binds to critical elements in the ATF4 promoter resulting in its transcriptional repression. The LIP isoform of C/EBPβ, but not the LAP version is regulated following UV exposure and directly represses ATF4 transcription. Loss of the LIP isoform results in increased ATF4 mRNA levels in response to UV irradiation, and subsequent recovery of ATF4 translation, leading to enhanced expression of its target genes. Together these results illustrate how eIF2P and translational control, combined with transcription factors regulated by alternative signaling pathways, can direct programs of gene expression that are specifically tailored to each environmental stress.

Transcriptional regulation

ATF4

Gene expression

Gene regulatory networks

Genetic translation

Stress (Physiology)

Transcription factors

RNA-protein interactions

Cell receptors -- Research

RNA -- Metabolism

Proteins -- Metabolism -- Regulation

Proteins -- Synthesis

Proteomics -- Methodology

Cellular signal transduction

Eukaryotic cells

The E3 ubiquitin ligase SPL11 regulates both programmed cell death and flowering time in rice

Vega-Sanchez, Miguel E.

10 September 2008

No description available.

Botany

Molecular Biology

Plant Pathology

Ubiquitination

programmed cell death

flowering time

RNA metabolism

<i>Spl11</i>

<i>Spin1</i>

<i>Rbs1</i>