Functional study of the role played by nucleolar proteins in the control of neural progenitor homeostasis using zebrafish as a model / Etude fonctionnelle de gènes codants pour des protéines nucléolaires dans la biologie des cellules souches neurales chez le poisson zèbre

Brombin, Alessandro

29 September 2015

L’identité des cellules souches et des progéniteurs neuraux, comme celle de tout type cellulaire, est caractérisée par des signatures moléculaires spécifiques qui dépendent de l’environnement dans lesquelles les cellules se trouvent. Ainsi, il est primordial d’étudier ces cellules dans un contexte in vivo. Le toit optique du poisson zèbre est un modèle idéal pour ce type d’étude. En effet, c’est une large partie du cerveau moyen localisée en position dorsale et qui présente la particularité de croitre de manière orientée tout au long de la vie de l’animal grâce aux cellules neuroépitheliales présentes à sa périphérie (dans la « peripheral midbrain layer », PML). De plus, les progéniteurs neuroépithéliaux, les progéniteurs lents et les cellules post-mitotiques sont localisées dans des domaines adjacents du toit, conséquence de sa croissance orientée. Chaque population cellulaire est marquée par des profils d’expression particuliers. Ainsi, une recherche dans la base de données ZFIN nous a permis d’identifier environ 50 gènes ayant une forte expression dans les cellules de la PML (progéniteurs neuroépithéliaux). De façon intéressante, beaucoup de « gènes PML » codent pour des facteurs de la biogenèse des ribosomes. L’accumulation de ce type de transcrits dans les progéniteurs lents était surprenante. Ainsi, au cours de mon doctorat, j’ai étudié le rôle spécifique des facteurs de la biogenèse des ribosomes dans le maintien des cellules neuroepithéliales de la PML. En effet, bien qu’il soit généralement admis que la biogenèse des ribosomes est un processus essentiel dans toutes les cellules, il a été récemment démontré que plusieurs facteurs nécessaires à la synthèse des ribosomes ont un rôle tissu-spécifique. Par exemple, Notchless est requis pour la survie de la masse cellulaire interne de l’embryon préimplantatoire de souris. Récemment, des expériences de knock-out conditionnel chez la souris ont montré que Notchless était nécessaire au maintien des cellules souches hématopoïétiques et intestinales, mais pas à celui des cellules différenciées. En effet, en absence de Notchless dans les cellules souches, la grosse sous-unité ribosomique (60S) ne peut pas être exportée hors du noyau et s’accumule. Au contraire, dans les cellules différenciées, où Notchless n’est pas indispensable, cette accumulation n’est pas observée. J’ai commencé une étude fonctionnelle basée sur la surexpression conditionnelle de la forme dominante-négative du gène notchless homolog 1 (nle1, homologue poisson zèbre du gène Notchless mammifère). Selon mon hypothèse, les progéniteurs lents de la PML (Slow amplifying progenitors, SAPs) pourraient avoir besoin de Notchless pour la maturation de la sous-unité 60S, contrairement aux cellules différenciées qui pourraient survivre après la délétion de ce gène. Des expériences sont encore en cours, mais nous avons déjà pu démontrer que nle1 joue un rôle crucial dans la survie des progénitéurs neuroépithéliaux de la PML. En parallèle, j’ai étudié des lignées de poisson-zèbre mutantes pour des gènes codants pour des composants du complexe de snoRNP (box C/D small nucleolar ribonucleoprotein : Fibrillarine, Nop56, Nop58). Les trois mutants présentent des phénotypes similaires, en particulier une apoptose massive et une dérégulation du cycle cellulaire dans l’ensemble du toit optique à 48 heures de développement. Étonnamment, ces résultats sont en faveur d’un arrêt du cycle cellulaire à la transition G2/M. Ainsi, cette étude pourrait permettre de mettre en évidence de nouveaux mécanismes d’arrêt du cycle cellulaire lors de défauts de biogenèse des ribosomes. L’ensemble de ces résultats montrent comment les facteurs de la biogenèse des ribosomes (tout comme le processus) contribue à la régulation fine de l’homéostasie cellulaire, et donc à la détermination de l’identité des cellules progénitrices. / In neural stem cells (NSCs) and neural progenitors (NPs), as in other cell types, cell identity is characterized by specific molecular signatures that depend on the environment provided by neighboring cells. Thus, it is important to study progenitor cells in vivo. The zebrafish optic tectum (OT) is a suitable model for that purpose. Indeed, this large structure of the dorsal midbrain displays life-long oriented growth supported by neuroepithelial cells present at its periphery (in the peripheral midbrain layer, PML). Moreover, neuroepithelial progenitors, fast-amplifying progenitors and post-mitotic cells are found in adjacent domains of the OT, as a consequence of its oriented growth. Each cell population is marked by concentric gene expression patterns. Interestingly, a datamining of the ZFIN gene expression database allowed us to identify around 50 genes displaying biased expression in PML cells (neuroepithelial progenitors). Interestingly, many “PML genes” code for ribosome biogenesis factors. The accumulation of transcripts for such ubiquitously expressed genes in SAPs was very surprising so during my thesis I examined whether ribosome biogenesis may have specific roles in these neuroepithelial cells, while improving our knowledge. Indeed, although it is generally admitted that ribosome biogenesis is essential in all cells, it has been shown quite recently that several components of the ribosome biogenesis have tissue restricted roles. For example, Notchless is required for the survival of the inner cell mass in the preimplantation mouse embryo. More recently, conditional knock-out experiments in mice showed that Notchless is necessary for the maintenance of hematopoietic stem cells and intestinal stem cells, but not for committed progenitors and differentiated cells. Indeed in the absence of Notchless in stem cells, the immature 60S subunit cannot be exported from the nucleus and accumulates. This does not happen in differentiated cells where Notchless is dispensable. I started a functional study based on the conditional overexpression of a dominant-negative form of the gene notchless homolog 1 (nle1, the zebrafish homolog of the mammalian gene Notchless). My hypothesis was that the PML slow-amplifying progenitors (SAPs) may require Notchless for the maturation of the 60S subunit, but not the differentiated cells which could survive also after the deletion of this gene. Experiments are still underway. So far we could demonstrate that nle1 has a crucial role in SAPs. I studied zebrafish mutants for genes coding for the components of the box C/D small nucleolar ribonucleoprotein (snoRNP) complex (Fibrillarin, Nop56, Nop58). Mutants displayed a similar phenotype with massive apoptosis and a deregulation of the cell cycle in the whole tectum at 48hpf. Our data suggest a cell cycle arrest at the G2/M transition, highlighting novel possible mechanisms of cell cycle arrest upon impaired ribosome biogenesis. All together, these data highlight how ribosome biogenesis factors and the whole ribosome biogenesis contribute to the fine regulation of cell homeostasis thereby contributing to the determination of progenitor cell identity.

Poisson zèbre

Toit optique

Biogenèse des ribosomes

Fibrillarin

Notchless

Zebrafish

Optic Tectum

Ribosome biogenesis

Fibrillarin

Notchless

STRUCTURAL AND FUNCTIONAL STUDIES OF H. VOLCANII BOX C/D PROTEINS AND ROLES FOR HUMAN PUS10 BEYOND PSEUDORURIDINE SYNTHESIS

Bosmeny, Michael Stephen

01 May 2022

RNA in all forms of life contain a myriad of post-transcriptional modifications. These modifications are important for processing and structural reasons, and includes 2’-O-methylation and pseudouridylation. Some of these modifications are the product of stand-alone proteins and others are the product of RNA-protein complexes.In eukaryotic and archaeal cells, the Box C/D ribonucleoprotein complex is one of the complexes responsible for 2’-O-methylation activity. In Archaea, this complex consists of the enzymatic protein, Fibrillarin, plus two other structural proteins, Nop5 and L7Ae, along with a guide RNA, which all come together to modify a specific target RNA sequence. A methyl group is added to the 2’ hydroxyl of the nucleotide’s ribose sugar. These modifications are found both in ribosomal RNA and tRNAs. This work focuses on the interactions between Nop5, Fibrillarin, and the guide RNA used in this complex. The objective was to identify important amino acid sequences in these proteins which are essential for the operation of the complex. The size of the archaeal Box C/D complex is also investigated using size chromatography.Similarly, Pus10 is one protein responsible for pseudouridylation in Archaea and eukaryotes. Pseudouridylation is the isomerization of uridine (U) to pseudouridine (Ψ). Pus10 is known to produce Ψ54 and Ψ55 in the TΨC loop of some archaeal and eukaryotic tRNAs. However, current research suggests it could have additional jobs in the cellular lifecycle, such as roles in apoptosis and the regulation of eukaryotic cell cycle. During mammalian cell apoptosis, Pus10 translocates from the nucleus to the cytoplasm and is believed to be involved in cytochrome c release. This is suspected to be related to Caspase-3’s role in apoptosis. Caspase-3 is activated in both the extrinsic and intrinsic apoptotic pathways. It has been shown that activation of the extrinsic apoptotic pathway via TRAIL affects the localization of Pus10. Here we test Pus10’s actions in cells under the effect of intrinsic apoptotic pathway compounds.Pus10 has also shown to have an effect on cell proliferation. Cells in which Pus10 has been depleted show increased growth rates. Here we investigate expression levels of proteins involved in cell cycle regulation, in both wild-type and Pus10-depleted cells, and attempt to compile a model of how Pus10 could be interacting with this system, using RNA-Seq, qPCR, and ChIP.SARS-CoV-2, also known as COVID-19, is a coronavirus that quickly became a pandemic in late 2019, early 2020. In the two years since then, the virus has undergone many mutations. By tracking the spread of these mutations at a national or regional level, by studying the spread pattern, we can make predictions, and possibly even prevent the next pandemic.

Apoptosis

Box C/D

Cell Cycle

Fibrillarin

Nop5

Pus10

Analysis of the effects of Leptomycin B on Cells Exiting Mitosis

Liu, Gin-Yun

20 September 2006

No description available.

Biology, Cell

Nucleologenesis

nucleolus

LMB

C23

B23

and Fibrillarin

Structure / Function Relationship of Archaeal Box C/D and H/ACA Proteins

Bosmeny, Michael

01 May 2016

Ribonucleoprotein complexes are responsible for some of the post-transcriptional modifications of RNA that occur within the cell, including 2'-O-methylation and pseudouridylation. These modifications contribute, among other things, to RNA folding, inhibition of degradation, and general cellular viability. In this study, we identify residues within the proteins of these complexes that are important to the functioning of the Box C/D and Box H/ACA complexes. Candidates were selected based on previous work and mutant versions of the proteins were introduced in-vivo. Assays were done to determine the functionality of the mutant complex. This work is divided into three parts, focused on the three proteins investigated. The first part is concerned with Nop5, a protein in the Box C/D RNP complex. Nop5 is known to interact with all other proteins and RNAs in the complex, and is believed to serve a primarily structural role, aligning the other components. Mutagenesis study of suspected significant amino acids in this protein showed that it is difficult to disrupt the operation of Nop5 with single changes, but is possible with more extensive mutation. The second part concerns Fibrillarin, the catalytic protein of the Box C/D ribonucleoprotein complex. Previous mutagenesis work identified several important amino acids involved with AdoMet transfer and complex formation. The methylation ability of these mutant complexes were further examined in this work by confirming that the same modification, or lack thereof, occurred at a second rRNA position. The final part of this work is about Nop10, part of the Box H/ACA complex. This work is only preliminary, but begins the process of testing suspected essential amino acids in the structure.

Box C/D

Box H/ACA

Fibrillarin

Nop10

Nop5

RNA Modification

Dinâmica nucleolar e a herança epigenética dos genes ribossomais / Nucleolar dinamics and the epigenetic inheritance of ribosomal genes

Silva, Natalia de Sousa Teixeira e

25 June 2014

O nucléolo é uma organela subnuclear formada pela atividade transcricional dos genes ribossomais 18S-5.8S-26S (rDNA 45S) e consequente biogênese dos ribossomos. A atividade destes genes resulta na região organizadora do nucléolo (NOR), na forma de uma constrição secundária em cromossomos metafásicos. As constrições secundárias se condensam progressivamente durante a mitose e se descondensam ao final da telófase quando a reestruturação do nucléolo se inicia. Genomas que apresentam mais de um locus de rDNA 45S deve apresentar, obrigatoriamente, pelo menos um par de NORs, enquanto os demais loci poderão ou não serem expressos. O controle da expressão dos genes ribossomais e a formação da cromatina nucleolar são modulados por eventos epigenéticos. Embora alguns pontos sobre o funcionamento dos genes ribossomais e a formação do nucléolo estejam bem estabelecidos, questões como o padrão de condensação da cromatina nucleolar durante a mitose, o padrão de funcionamento de sítios adicionais de genes ribossomais, o papel das modificações epigenéticas na dinâmica da cromatina nucleolar e na expressão do rDNA 45S e o mecanismo de herança dos genes ativos, permanecem abertas. A espécie Crotalaria juncea (Leguminosae-Papilionoideae), com 2n=2x=16 cromossomos, que possui um locus de rDNA 45S no braço curto do cromossomo 1, que sempre forma constrição secundária, e um sítio adicional com atividade facultativa no braço curto do cromossomo 4, é um excelente modelo para o estudo destas questões. No contexto apresentado, foram estudadas a dinâmica de condensação das NORs durante o ciclo celular e sua correlação com a atividade dos genes ribossomais, incluindo o locus adicional, e ainda o papel da metilação da citosina do DNA durante estes processos. Os resultados demonstram que a cromatina da região organizadora do nucléolo segrega em um estado descondensado durante a mitose, na forma de constrição secundária, ou seja, tal estrutura não se condensa durante a metáfase e não volta a se distender no início da telófase. Aparentemente, o que causa correlações equivocadas entre a atividade nucleolar e a observação morfológica da constrição secundária na metáfase é a contração forçada da cromatina da NOR causada por agentes antimitogênicos. Este modelo de segregação em um estado aberto pode ser explicado pela descrição de diversas proteínas que permanecem diretamente ligadas ou indiretamente associadas à região da NOR durante a mitose, funcionando como uma barreira física para a compactação. Ambos os sítios, principais e adicionais, do rDNA 45S presentes em Crotalaria juncea apresentam atividade transcricional, embora o locus do cromossomo 4 mostre atividade facultativa. Ao contrário do que foi anteriormente proposto, uma vez ativo, o locus adicional permanece descondensado durante todo o ciclo mitótico, seguindo o mesmo comportamento dos sítios principais. As constrições secundárias e a cromatina nucleolar são hipermetiladas em nível citológico, independentemente de sua atividade. A aparente hipometilação observada no rDNA 45S em cromossomos mitóticos e núcleos interfásicos se deve ao menor grau de compactação da região organizadora do nucléolo e, consequentemente, à baixa densidade de cromatina. / The nucleolus is a subnuclear organelle formed as a result of transcriptional activity of ribosomal RNA genes 18S-5.8S-26S (45S rDNA) and subsequent ribosome biogenesis. This activity forms the nucleolar organizing region (NOR) as a secondary constriction in metaphase chromosomes. The secondary constrictions progressively condense during mitosis and decondense at the end of telophase, when nucleoli start to reassemble. Genomes presenting more than one 45S rDNA locus must have at least one pair of NOR bearing chromosomes, while other loci may be expressed or not. Ribosomal gene expression and nucleolar chromatin assembly are modulated by specific epigenetic events. Although some topics related to rDNA gene activity and nucleolus formation are well understood, questions such as the behavior of nucleolar chromatin condensation during mitosis, standard functions associated with rDNA additional sites, role of epigenetic modifications in nucleolar chromatin and 45S rDNA expression processes, and inheritance mechanism of active genes, remain to be solved. Crotalaria juncea (Leguminosae - Papilionoideae) has 2n=2x=16 chromosomes and carries a 45S rDNA locus at the short arm of chromosome 1, always presenting a secondary constriction, and an additional site with facultative activity at the short arm of chromosome 4, being an excellent model to resolve these questions. Thus, this study aimed to study NOR condensation dynamics during the cell cycle and its correlation with ribosomal gene activity, including the additional locus, while analyzing the role of rDNA cytosine methylation during this process. The results show that NOR chromatin segregate in a decondensed way throughout mitosis, as a secondary constriction. In other words, this structure does not condense during metaphase and the NOR is not reassembled at the beginning of telophase. Misinterpretations relating nucleolar activity with morphological observations of secondary constrictions, appear to be induced by the artificial contraction of NOR chromatin caused by antimitotic drugs. This segregation model in an open state may be supported by strong diversity of proteins that are maintained attached to NORs during mitosis, serving as a physic barrier for condensation. Both principal and additional 45S rDNA sites of C. juncea are transcriptionally active, although the additional locus in chromosome 4 presented facultative activity depending upon ribosomal request. Unlike what was previously proposed, once the additional site is activated, it remains in an open configuration throughout the cell cycle, similarly to principal site behavior. Secondary constrictions and nucleolar chromatin are hypermethylated at cytological level, regardless of their activity. The seeming hipomethylated state of 45S rDNA in interphase nucleus and mitotic chromosomes is due to a lower compaction level of nucleolar organizing regions and subsequent low chromatin density.

45S rDNA

Constrição secundária

DNA Methylation

Epigenética

Epigenetics

Fibrilarina

Fibrillarin

Metilação de DNA

NOR

Nucléolo

Nucleolus

rDNA 45S

RON

Secondary Constriction

Dinâmica nucleolar e a herança epigenética dos genes ribossomais / Nucleolar dinamics and the epigenetic inheritance of ribosomal genes

Natalia de Sousa Teixeira e Silva

25 June 2014

O nucléolo é uma organela subnuclear formada pela atividade transcricional dos genes ribossomais 18S-5.8S-26S (rDNA 45S) e consequente biogênese dos ribossomos. A atividade destes genes resulta na região organizadora do nucléolo (NOR), na forma de uma constrição secundária em cromossomos metafásicos. As constrições secundárias se condensam progressivamente durante a mitose e se descondensam ao final da telófase quando a reestruturação do nucléolo se inicia. Genomas que apresentam mais de um locus de rDNA 45S deve apresentar, obrigatoriamente, pelo menos um par de NORs, enquanto os demais loci poderão ou não serem expressos. O controle da expressão dos genes ribossomais e a formação da cromatina nucleolar são modulados por eventos epigenéticos. Embora alguns pontos sobre o funcionamento dos genes ribossomais e a formação do nucléolo estejam bem estabelecidos, questões como o padrão de condensação da cromatina nucleolar durante a mitose, o padrão de funcionamento de sítios adicionais de genes ribossomais, o papel das modificações epigenéticas na dinâmica da cromatina nucleolar e na expressão do rDNA 45S e o mecanismo de herança dos genes ativos, permanecem abertas. A espécie Crotalaria juncea (Leguminosae-Papilionoideae), com 2n=2x=16 cromossomos, que possui um locus de rDNA 45S no braço curto do cromossomo 1, que sempre forma constrição secundária, e um sítio adicional com atividade facultativa no braço curto do cromossomo 4, é um excelente modelo para o estudo destas questões. No contexto apresentado, foram estudadas a dinâmica de condensação das NORs durante o ciclo celular e sua correlação com a atividade dos genes ribossomais, incluindo o locus adicional, e ainda o papel da metilação da citosina do DNA durante estes processos. Os resultados demonstram que a cromatina da região organizadora do nucléolo segrega em um estado descondensado durante a mitose, na forma de constrição secundária, ou seja, tal estrutura não se condensa durante a metáfase e não volta a se distender no início da telófase. Aparentemente, o que causa correlações equivocadas entre a atividade nucleolar e a observação morfológica da constrição secundária na metáfase é a contração forçada da cromatina da NOR causada por agentes antimitogênicos. Este modelo de segregação em um estado aberto pode ser explicado pela descrição de diversas proteínas que permanecem diretamente ligadas ou indiretamente associadas à região da NOR durante a mitose, funcionando como uma barreira física para a compactação. Ambos os sítios, principais e adicionais, do rDNA 45S presentes em Crotalaria juncea apresentam atividade transcricional, embora o locus do cromossomo 4 mostre atividade facultativa. Ao contrário do que foi anteriormente proposto, uma vez ativo, o locus adicional permanece descondensado durante todo o ciclo mitótico, seguindo o mesmo comportamento dos sítios principais. As constrições secundárias e a cromatina nucleolar são hipermetiladas em nível citológico, independentemente de sua atividade. A aparente hipometilação observada no rDNA 45S em cromossomos mitóticos e núcleos interfásicos se deve ao menor grau de compactação da região organizadora do nucléolo e, consequentemente, à baixa densidade de cromatina. / The nucleolus is a subnuclear organelle formed as a result of transcriptional activity of ribosomal RNA genes 18S-5.8S-26S (45S rDNA) and subsequent ribosome biogenesis. This activity forms the nucleolar organizing region (NOR) as a secondary constriction in metaphase chromosomes. The secondary constrictions progressively condense during mitosis and decondense at the end of telophase, when nucleoli start to reassemble. Genomes presenting more than one 45S rDNA locus must have at least one pair of NOR bearing chromosomes, while other loci may be expressed or not. Ribosomal gene expression and nucleolar chromatin assembly are modulated by specific epigenetic events. Although some topics related to rDNA gene activity and nucleolus formation are well understood, questions such as the behavior of nucleolar chromatin condensation during mitosis, standard functions associated with rDNA additional sites, role of epigenetic modifications in nucleolar chromatin and 45S rDNA expression processes, and inheritance mechanism of active genes, remain to be solved. Crotalaria juncea (Leguminosae - Papilionoideae) has 2n=2x=16 chromosomes and carries a 45S rDNA locus at the short arm of chromosome 1, always presenting a secondary constriction, and an additional site with facultative activity at the short arm of chromosome 4, being an excellent model to resolve these questions. Thus, this study aimed to study NOR condensation dynamics during the cell cycle and its correlation with ribosomal gene activity, including the additional locus, while analyzing the role of rDNA cytosine methylation during this process. The results show that NOR chromatin segregate in a decondensed way throughout mitosis, as a secondary constriction. In other words, this structure does not condense during metaphase and the NOR is not reassembled at the beginning of telophase. Misinterpretations relating nucleolar activity with morphological observations of secondary constrictions, appear to be induced by the artificial contraction of NOR chromatin caused by antimitotic drugs. This segregation model in an open state may be supported by strong diversity of proteins that are maintained attached to NORs during mitosis, serving as a physic barrier for condensation. Both principal and additional 45S rDNA sites of C. juncea are transcriptionally active, although the additional locus in chromosome 4 presented facultative activity depending upon ribosomal request. Unlike what was previously proposed, once the additional site is activated, it remains in an open configuration throughout the cell cycle, similarly to principal site behavior. Secondary constrictions and nucleolar chromatin are hypermethylated at cytological level, regardless of their activity. The seeming hipomethylated state of 45S rDNA in interphase nucleus and mitotic chromosomes is due to a lower compaction level of nucleolar organizing regions and subsequent low chromatin density.

Constrição secundária

Epigenética

Fibrilarina

Metilação de DNA

NOR

Nucléolo

rDNA 45S

45S rDNA

DNA Methylation

Epigenetics

Fibrillarin

Nucleolus

RON

Secondary Constriction

Studium mechanizmu regulace genové exprese na úrovni funkční organizace chromatinových domén. / Study of the mechanism of gene expression regulation at the level of functional organization of chromatin domains.

Hornáček, Matúš

January 2018

- 1 - ABSTRACT Nucleoli are formed on the basis of genes of ribosomal DNA (rDNA) clusters called Nucleolus Organizer Regions (NORs). The essential structural components of the nucleoli, Fibrillar Centers (FC) and Dense Fibrillar Components (DFC), together compose FC/DFC units. These units are centers of rDNA transcription by RNA polymerase I (pol I), as well as the early processing events, in which an essential role belongs to fibrillarin. Each FC/DFC unit probably corresponds to a single transcriptionally active gene. In our work we study changes of FC/DFC units in the course of cell cycle. Correlative light and electron microscopy analysis showed that the pol I and fibrillarin positive nucleolar beads correspond to individual FC/DFC units. In vivo observations showed that at early S phase, when transcriptionally active ribosomal genes were replicated, the number of the units in each cell increased by 60 to 80 %. During that period the units transiently lost pol I, but not fibrillarin. Then, until the end of interphase, number of the units did not change, and their duplication was completed only after the cell division, by mid G1 phase. This peculiar mode of reproduction suggests that a considerable subset of ribosomal genes remain transcriptionally silent from mid S phase to mitosis but become again active...

Altérations de composition des ribosomes dans les cancers du sein : analyses de cohortes humaines et modèles cellulaires / Alterations of ribosomes composition in breast cancers : analyses of human cohorts and cellular models

Nguyen Van Long, Flora

26 June 2019

Les ribosomes sont responsables de la traduction des ARNm en protéines. Des modifications de la composition des ribosomes altèrent son activité de traduction et favorisent la tumorigenèse. L’identification des altérations de composition des ribosomes dans les cancers du sein pourrait être un nouveau mécanisme de tumorigenèse mammaire et ouvrir de nouvelles perspectives thérapeutiques. En effet, les cancers du sein restent la première cause de mortalité liés aux cancers chez la femme et leur hétérogénéité induit un problème thérapeutique important. Dans ce contexte, les altérations de composition des ribosomes dans les cancers du sein ont été abordées dans des cohortes humaines et dans des modèles cellulaires de l’EMT (Transition Epithélio-Mésenchymateuse), un processus impliqué dans la tumorigenèse mammaire. Ces travaux ont permis d’identifier : i) deux facteurs impliqués dans la biogenèse des ribosomes, FBL (fibrillarine) et NCL (nucléoline) dont les variations d’expression sont associées à un mauvais pronostic chez les patientes ; et ii) des variations de composition du ribosome et de son activité traductionnelle dans l’EMT. L’ensemble de ces résultats soutient l’existence d’altérations de composition des ribosomes dans les cancers du sein / Ribosomes are responsible of translating mRNAs to proteins. Alterations of ribosome composition modify its translation activity and favour tumourigenesis. Identification of ribosomes composition alterations in breast cancers might correspond to a new mechanism responsible of mammary tumourigenesis and might open up novel therapeutic approaches. Indeed breast cancers represent the first cause of women mortality due to cancers and their heterogeneity induces an important therapeutic problem.In this context, alterations of ribosomes composition were determined in human cohorts and in EMT (Epithelial to Mesenchymal Transition) cellular models, the EMT being a process involved in mammary tumourigenesis. This studies identify : (i) two factors involved in ribosome biogenesis, FBL (fibrillarin) and NCL (nucleolin) whose expression variations are associated with poor prognosis in patients and (ii) variations of ribosome composition and its translational activity in EMT. Altogether, this data support the presence of ribosomes composition alterations in breast cancers

Ribosome

Méthylation 2’-O-ribose des ARNr

Biogénèse des ribosomes

Traduction

Fibrillarine

Nucléoline

Biomarqueurs pronostiques

Cancer du sein

Ribosome

RRNA 2’-O-ribose methylation

Ribosome biogenesis

Translation

Fibrillarin

Nucleolin

Prognostic biomarkers

Breast cancer

570

DNA Methylation, Cellular Stress Response and Expression of Inner Nuclear Membrane Proteins

Levesque, Steve

04 May 2011

Hutchinson-Gilford Progeria Syndrome is described as a series of mutations within the lamin A gene leading to the accumulation of progerin in the nucleus, contributing to premature aging and affecting the epigenetic control. Epigenetic control, such as DNA methylation, relies on DNA methyltransferase enzymes. In human cells, heat shock (HS) leads to the formation of nuclear stress bodies (nSBs); ribonucleoprotein aggregates of Sat III RNA and RNA-binding proteins. The objectives of this study were to determine if epigenetic status induces varying responses to HS and assess the variability of nuclear proteins in similar conditions. Results show epigenetic modifications do not prevent a stress response; however the extent may be affected. In addition the functions of most nuclear antigens were not affected. It is most likely the sum of interactions at the inner nuclear membrane and nuclear lamina interface that result in nuclear strength pertaining to lamin A.

Epigenetics

DNA methylation

Nuclear stress bodies

Inner nuclear membrane (INM)

Lamin A

Lamin B

Emerin

Satellite III (Sat III)

Stress response

Heat shock (HS)

2H12

Lamina associated polypeptide 2 (Lap2)

Fibrillarin

Laminopathies

DNA Methylation, Cellular Stress Response and Expression of Inner Nuclear Membrane Proteins

Levesque, Steve

04 May 2011

Hutchinson-Gilford Progeria Syndrome is described as a series of mutations within the lamin A gene leading to the accumulation of progerin in the nucleus, contributing to premature aging and affecting the epigenetic control. Epigenetic control, such as DNA methylation, relies on DNA methyltransferase enzymes. In human cells, heat shock (HS) leads to the formation of nuclear stress bodies (nSBs); ribonucleoprotein aggregates of Sat III RNA and RNA-binding proteins. The objectives of this study were to determine if epigenetic status induces varying responses to HS and assess the variability of nuclear proteins in similar conditions. Results show epigenetic modifications do not prevent a stress response; however the extent may be affected. In addition the functions of most nuclear antigens were not affected. It is most likely the sum of interactions at the inner nuclear membrane and nuclear lamina interface that result in nuclear strength pertaining to lamin A.

Epigenetics

DNA methylation

Nuclear stress bodies

Inner nuclear membrane (INM)

Lamin A

Lamin B

Emerin

Satellite III (Sat III)

Stress response

Heat shock (HS)

2H12

Lamina associated polypeptide 2 (Lap2)

Fibrillarin

Laminopathies