Global ETD Search

21	β-CATENIN REGULATION OF ADULT SKELETAL MUSCLE PLASTICITY Wen, Yuan 01 January 2018 (has links) Adult skeletal muscle is highly plastic and responds readily to environmental stimuli. One of the most commonly utilized methods to study skeletal muscle adaptations is immunofluorescence microscopy. By analyzing images of adult muscle cells, also known as myofibers, one can quantify changes in skeletal muscle structure and function (e.g. hypertrophy and fiber type). Skeletal muscle samples are typically cut in transverse or cross sections, and antibodies against sarcolemmal or basal lamina proteins are used to label the myofiber boundaries. The quantification of hundreds to thousands of myofibers per sample is accomplished either manually or semi-automatically using generalized pathology software, and such approaches become exceedingly tedious. In the first study, I developed MyoVision, a robust, fully automated software that is dedicated to skeletal muscle immunohistological image analysis. The software has been made freely available to muscle biologists to alleviate the burden of routine image analyses. To date, more than 60 technicians, students, postdoctoral fellows, faculty members, and others have requested this software. Using MyoVision, I was able to accurately quantify the effects of β-catenin knockout on myofiber hypertrophy. In the second study, I tested the hypothesis that myofiber hypertrophy requires β-catenin to activate c-myc transcription and promote ribosome biogenesis. Recent evidence in both mice and human suggests a close association between ribosome biogenesis and skeletal muscle hypertrophy. Using an inducible mouse model of skeletal myofiber-specific genetic knockout, I obtained evidence that β-catenin is important for myofiber hypertrophy, although its role in ribosome biogenesis appears to be dispensable for mechanical overload induced muscle growth. Instead, β-catenin may be necessary for promoting the translation of growth related genes through activation of ribosomal protein S6. Unexpectedly, we detected a novel, enhancing effect of myofiber β-catenin knockout on the resident muscle stem cells, or satellite cells. In the absence of myofiber β-catenin, satellite cells activate and proliferate earlier in response to mechanical overload. Consistent with the role of satellite cells in muscle repair, the enhanced recruitment of satellite cells led to a significantly improved regeneration response after chemical injury. The novelty of these findings resides in the fact that the genetic perturbation was extrinsic to the satellite cells, and this is even more surprising because the current literature focuses heavily on intrinsic mechanisms within satellite cells. As such, this model of myofiber β-catenin knockout may significantly contribute to better understanding of the mechanisms of satellite cell priming, with implications for regenerative medicine. skeletal muscle image analysis ribosome biogenesis β-catenin plasticity Cellular and Molecular Physiology Exercise Physiology
22	The role of Bud23 in the biogenesis of the small ribosomal subunit in Saccharomyces cerevisiae White, Joshua Paul, 1977- 16 February 2011 (has links) Ribosomes are the cellular structures responsible for the synthesis of protein in all branches of life. All ribosomes are made from a large and small subunit that in turn are composed of protein and RNA. The synthesis of eukaryotic ribosomes is a complex process involving more than 200 factors and spans three cellular compartments: the nucleolus, the nucloplasm, and the cytoplasm. The precise function of most of these ribosome biogenesis factors remains unknown. The RNA component of ribosomes is in part processed from a large RNA transcript that yields most of the RNA present in mature ribosomes. Part of the maturation process involves modification of this ribosomal RNA as processing is carried out. Recent work constructing protein interaction networks in Saccharomyces cerevisiae suggested the methyltransferase Bud23 was involved in ribosome biogenesis (1). This thesis describes my work to characterize Bud23 and place it within the ribosome biogenesis pathway. Bud23 is a SAM methyltransferase important for the proper biogenesis of the small ribosomal subunit. Here I will demonstrate that Bud23 methylates G1575 of the small subunit ribosomal RNA (SSU rRNA), and its absence delays export of the SSU rRNA from the nucleolas, and the nucleus, and results in the delayed maturation of the SSU rRNA. Finally, I will show that Bud23 function is connected to small subunit processome factor Utp14 through identification of a Utp14 mutant that suppresses the bud23[Delta] deletion phenotype. / text Ribosome biogenesis Small subunit 40s Bud23 Utp14 Export Methylation 90S RNA
23	Bystin in human cancer cells : intracellular localization and function in ribosome biogenesis MIYOSHI, Masaya, OKAJIMA, Tetsuya, MATSUDA, Tsukasa, FUKUDA, Michiko N., NADANO, Daita 06 1900 (has links) No description available. BYSL cancer embryo implantation nucleolar stress ribosomal RNA processing ribosome biogenesis
24	Unraveling variations in ribosome biogenesis activity in the mouse hematopoietic system at homeostasis in vivo / Mise en évidence de variations de l'activité de biogenèse des ribosomes dans le lignage hématopoïétique murin in vivo à l'homéostasie Jarzebowski, Léonard 11 October 2016 (has links) Les cellules souches (CS) se démarquent des progéniteurs et cellules différenciées à de nombreux égards. Notamment, les CS présentent des caractéristiques particulières dans des processus cellulaires fondamentaux, et il a été récemment proposé que la biogenèse des ribosomes (BiRi) participe à la régulation des CS. Pendant ma thèse, j’ai utilisé diverses approches pour étudier le rôle et la régulation de la BiRi dans des populations de CS, in vivo et ex vivo dans des modèles murins.Grâce à un modèle d’inactivation génétique du facteur de BiRi Notchless (Nle), j’ai participé à l’étude de son rôle dans le lignage hématopoïétique et l’épithélium intestinal adultes, et cours du développement embryonnaire précoce. In vivo, la perte constitutive de Nle entraîne une létalité embryonnaire, et j’ai montré ex vivo que l’inactivation de Nle dans des CS embryonnaires induit une réponse au stress ribosomique médiée par le suppresseur de tumeur p53, et des défauts de prolifération/survie. L’induction de la perte de Nle chez l’adulte active également p53 dans les CS hématopoïétiques et intestinale, entraînant leur rapide élimination.En parallèle, j’ai utilisé plusieurs méthodes pour mesurer l’activité de BiRi des progéniteurs immatures et CS hématopoïétiques (CSH) à l’homéostasie, in vivo chez la souris adulte. J’ai ainsi mis en évidence des variations de l’activité de BiRi dans ces populations, révélant notamment une activité de BiRi des CSH jusqu’ici insoupçonnée du fait de leur quiescence.Dans l’ensemble, mon travail renforce l’idée d’un rôle de la BiRi dans la régulation des CS, et apporte une meilleure compréhension de la régulation de ce processus dans le lignage hématopoïétique. / Stem cells (SCs) differ from progenitors and differentiated cells on many aspects. Notably, SCs display particular characteristics in fundamental cellular processes, and ribosome biogenesis (RiBi) has recently been proposed to play an important role in the regulation of SCs. During my thesis, I have used various approaches to study the role and regulation of RiBi in SC populations, using in vivo and ex vivo mouse models.Using genetic inactivation of the RiBi factor Notchless (Nle), I have participated to the analysis of its role in the adult hematopoietic system and intestinal epithelium, and in the establishment of the first cell lineages during early embryogenesis. In vivo, constitutive Nle deficiency causes early embryonic lethality, and I showed ex vivo that Nle inactivation in embryonic SCs induces a ribosomal stress response mediated by the tumor suppressor p53, and proliferation/survival defects. Conditional Nle inactivation in the adult mouse also induces activation of p53 in hematopoietic and intestinal SCs in vivo, leading to their rapid elimination.In parallel, I have used different methods to analyze the RiBi activity of hematopoietic SCs (HSCs) and immature progenitors at homeostasis, in vivo in the adult mouse. Thus, I have unraveled variations in the RiBi activity of these populations, and notably uncovered previously unsuspected RiBi activity in HSCs despite their quiescent state.Altogether, my work supports the hypothesis of a role for RiBi in the regulation of SCs and provides better understanding of the activity of this process during hematopoietic differentiation. Hématopoïèse Cellule souche hématopoïétique Biogenèse des ribosomes Souris Hematopoiesis Hematopoietic stem cell Ribosome biogenesis 571.6
25	Protein factors involved in the biogenesis of the mitochondrial ribosome D'Souza, Aaron Raynold January 2018 (has links) The mammalian mitochondria contain their own genome which encodes thirteen polypeptide components of the oxidative phosphorylation (OxPhos) system, and the mitochondrial (mt-) rRNAs and tRNAs required for their translation. The maturation of the mitochondrial ribosome requires both mt-rRNAs to undergo post-transcriptional chemical modifications, folding of the rRNA and assembly of the protein components assisted by numerous biogenesis factors. The post-transcriptional modifications of the mt-rRNAs include base methylations, 2’-O-ribose methylations and pseudouridylation. However, the exact function of these modifications is unknown. Many mitoribosome biogenesis factors still remain to be identified and characterised. This work aims to broaden our understanding of two proteins involved in mitoribosome biogenesis through the study of the function of an rRNA methyltransferase and a novel biogenesis factor. Firstly, we characterised MRM1 (mitochondrial rRNA methyltransferase 1), a highly conserved 2’-O-ribose methyltransferase. We confirmed that MRM1 modifies a guanine in the peptidyl (P) transferase region of the 16S mt-rRNA that specifically interacts with the 3’ end of the tRNA at the ribosomal P-site. In bacteria, the modification is dispensable for ribosomal biogenesis and cell viability under standard conditions. However, in yeast mitochondria, Mrm1p is vital for ribosomal assembly and function. We generated knockout cells lines using programmable nuclease technology, and characterised the possible effects of MRM1 depletion on mitochondrial translation and mitoribosome biogenesis. We demonstrated that neither the enzyme nor the modification is required for human mitoribosomal assembly and translation in our experimental setup. Secondly, we identified a novel mitochondrially-targeted putative RNA endonuclease, YbeY. Using YbeY knockout cell lines, we showed that depletion of YbeY leads to loss of cell viability and OxPhos function as a consequence of a severe decrease in mitochondrial translation. Northern blotting and transcriptomic analysis using next generation RNA-Seq revealed transcript-specific changes to steady state levels. This analysis identified mt-tRNASer as a potential target of YbeY. We investigated the effect of YbeY deficiency on mitoribosomal assembly by quantitative sucrose gradient fractionation and mass spectrometry. This analysis showed that the mt-SSU is depleted in YbeY knockout cells. Further, immunoaffinity purification identified MRPS11 as a key interactor of YbeY. We propose that YbeY is a multifunctional protein that performs endonucleolytic functions in the mitochondria and also acts as a mitochondrial ribosome biogenesis factor, assisting small subunit assembly through its interaction with MRPS11.
26	Localisation membranaire de la RNase E : rôle dans la dégradation des ARN et la biogenèse des ribosomes / RNase E membrane-localization : role in RNA degradation and ribosome biogenesis Hadjeras, Lydia 12 November 2018 (has links) La RNase E chez Escherichia coli est une endoribonucléase essentielle qui joue un rôle important dans la maturation des ARN stables, dans le contrôle qualité des ribosomes, ainsi que dans la dégradation constitutive et régulée des ARN messagers. La séquence de ciblage à la membrane (MTS pour Membrane Targeting Sequence), qui forme une hélice α-amphipatique, ancre la RNase E à la membrane cytoplasmique interne des cellules. La conservation absolue du MTS chez l'ensemble des -protéobactéries suggère un rôle important de la localisation membranaire RNase E dans le métabolisme de l'ARN. Pour élucider la fonction cellulaire de l'association membranaire de la RNase E, nous avons caractérisé la souche rne∆MTS qui exprime une RNase E cytoplasmique. Les résultats de cette étude nous amènent à proposer que l'association membranaire de la RNase E est nécessaire à la stabilité de la RNase E, est impliquée dans des interactions fonctionnelles avec des régulateurs associés à la membrane et protège les transcrits présents dans le nucléoïde en évitant des interactions prématurées avec la RNase E. En particulier, garder la RNase E à la membrane est critique pour la spécificité de la RNase E dans le contrôle qualité des ribosomes. Cette association membranaire est une nouvelle couche de régulation qui permet d’expliquer comment la RNase E, une enzyme avec peu de spécificité de séquence et avec beaucoup de substrat, peut remplir les fonctions de «maturase» et de «dégradase». / RNase E in Escherichia coli is an essential endoribonuclease with important roles in stable RNA maturation, in ribosome quality control and in constitutive and regulated mRNA degradation. The Membrane Targeting Sequence (MTS), which forms an amphipathic α-helix, anchors RNase E on the inner cytoplasmic membrane. The absolute conservation of the MTS among -Proteobacteria suggests an important role for RNase E membrane association in RNA metabolism. To elucidate the cellular function of the membrane association of RNase E, we characterized the rne∆MTS strain expressing cytoplasmic RNase E. The results of this study lead us to propose that RNase E membrane association is necessary for RNase E stability, for functional interactions with membrane-associated regulatory factors and for protecting nascent transcripts in the nucleoid from premature interactions with RNase E. In particular, keeping RNase E to the membrane is critical for the specificity of RNase E in ribosome quality control. Membrane association is a new layer of regulation that can explain how RNase E, an enzyme with little sequence specificity and many substrates, can fulfill both ‘maturase’ and ‘degradase’ functions. RNase E Biogenèse des ribosomes Métabolisme de l'ARN E. coli Organisation cellulaire RNase E Ribosome biogenesis RNA metabolism E. coli Cell organization
27	Study of ribosome biogenesis factors in zebrafish neural progenitors / Étude des facteurs de la biogenèse des ribosomes dans les progéniteurs neuraux de poisson zèbre Bouffard, Stéphanie 22 September 2017 (has links) Alors que la biogénèse des ribosomes a étéconsidérée comme un mécanisme ubiquiste, lesétapes de ce processus ont récemment étédémontrées comme étant tissu-spécifiques. Letoit optique (OT) du poisson-zèbre est un modèleapproprié pour étudier la prolifération cellulairepuisque les cellules à différents états dedifférenciation se trouvent dans des domainesséparés.Au cours de mon doctorat, j'ai examiné si lesgènes de la biogenèse des ribosomes peuventavoir des rôles spécifiques dans les cellulesprogénitrices neuroépithéliales (CPNe). Profitantd'une analyse transcriptomique antérieure, j'aid'abord examiné les nouveaux candidatsaccumulés dans les CPNe. J'ai décidé de meconcentrer sur proliferation-associated 2G4(pa2G4/ebp1) qui est exprimé de manièrepréférentielle dans les CPNe.Ce gène favorise ou réprime la proliférationcellulaire dans des organismes normaux oupendant la tumorigénèse. J'ai conçu une stratégiepour l'expression inductible et cellule-spécifiquede ce gène.Fibrillarin (Fbl), une méthyltranférasenucléolaire est également préférentiellementexprimée dans CPNe. Ce gène joue un rôleimportant dans le cancer. J'ai montré que lesmutants fbl présentaient des défauts OTspécifiques,en lien avec une apoptose massive etune absence de différenciation neurale. J'aiégalement démontré une diminution de l'activitéde traduction des ribosomes. En outre, lesmutants fbl montrent une progression de la phaseS altérée. Nos données suggèrent que fbl estessentiel à la prolifération des progéniteursneuronaux du poisson-zèbre. / While ribosome biogenesis has been consideredas an ubiquitous mechanism, steps of thisprocess have recently been shown to be tissuespecific. Zebrafish optic tectum (OT) is asuitable model to study cell proliferation sincecells at different differentiation states arespatially partitioned.During my PhD, I examined whether ribosomebiogenesis genes may have specific roles inneuroepithelial progenitor cells (NePCs).Taking advantage of a previous transcriptomicanalysis, I first screened for new candidatesaccumulated in NePCs. I decided to focus onproliferation-associated 2G4 (pa2g4/ebp1),which was expressed preferentially in NePCs.This gene promotes or represses cellproliferation in normal organisms or duringtumorigenesis. I designed a strategy for theinducible expression and cell specificexpression of this gene.Fibrillarin (Fbl), a small nucleolarmethyltransferase is also preferentiallyexpressed in NePCs. It plays an important rolein cancer. I showed that fbl mutants displayedspecific OT defects linked to a massiveapoptosis and an absence of neuraldifferentiation. I also demonstrated deficienciesin the ribosome translational activity.Additionally, fbl mutants showed impaired Sphaseprogression. Our data suggest that fbl isessential for the proliferation of zebrafishneuronal progenitors. Biogenèse des ribosomes Cellules neuroépithéliales Poisson zèbre Ribosome biogenesis Neuroepithelial cells Zebrafish
28	Molecular insights into the roles of RNA helicases during large ribosomal subunit assembly Aquino, Gerald Ryan 13 February 2022 (has links) No description available. 570 572 RNA helicases Ribosome biogenesis ribosomal protein small nucleolar RNA RNA modifications Biologie (PPN619462639)
29	Novel Functions of Erythropoietin Receptor Signaling Hidalgo, Daniel 15 March 2022 (has links) Erythroid terminal differentiation couples sequential cell divisions with progressive reductions in cell size. The erythropoietin receptor (EpoR) is essential for erythroblast survival, but its other functions are not well characterized. I used Epor−/− mouse erythroblasts endowed with survival signaling to identify novel non-redundant EpoR functions. I found that, paradoxically, EpoR signaling increases red cell size while also increasing the number and speed of erythroblast cell cycles. Specifically, I found that high levels of EpoR signaling increase the size and shorten the cycle of early erythroblasts, which are amongst the fastest cycling somatic cells. I confirmed the effect of erythropoietin (Epo) on red cell size in human volunteers, whose mean corpuscular volume (MCV) increases following Epo administration. Our work shows that EpoR signaling alters the expected inverse relationship between cell cycle length and cell size. Further, diagnostic interpretations of increased MCV should now include high Epo levels and hypoxic stress. The ability of EpoR signaling to increase cell size in rapidly cycling early erythroblasts suggests that these cells have exceptionally efficient EpoR-driven mechanisms for growth. I found evidence for this in ongoing work, where Epor−/− and Stat5−/− single-cell transcriptomes show dysregulated expression of ribosomal proteins and rRNA transcription and processing genes. Global rates of ribosomal rRNA transcription and protein synthesis increase in an EpoR dependent manner during a narrow developmental window in early ETD, coincident with the time of cell cycle shortening. Our work therefore suggests EpoR-driven regulation of ribosome biogenesis and translation orchestrating rapid cycling and cell growth during early ETD. Erythropoietin (Epo) Erythropoietin Receptor (EpoR) MCV Erythroid Terminal Differentiation (ETD) Ribosome Biogenesis Cell and Developmental Biology
30	Silencing Defective 2 is an essential gene required for ribosome biogenesis and the regulation of alternative splicing Floro, Jess 02 February 2022 (has links) RNA provides the framework for the assembly of some of the most intricate macromolecular complexes within the cell, including the spliceosome and the mature ribosome. The assembly of these complexes relies on the coordinated association of RNA with hundreds of trans-acting protein factors. While some of these trans-acting factors are RNA binding proteins (RBPs), others are adaptor proteins, and others still, function as both. Defects in the assembly of these complexes results in a number of human pathologies including neurodegeneration and cancer. Here, we demonstrate that Silencing Defective 2 (SDE2) is both an RNA binding protein and also a trans-acting adaptor protein that functions to regulate RNA splicing and ribosome biogenesis. SDE2 depletion leads to widespread changes in alternative splicing, defects in ribosomal biogenesis, and ultimately complete loss of cell viability. Our data highlight SDE2 as a previously uncharacterized essential gene required for the assembly and maturation of some of the most fundamental processes in mammalian cells. Molecular biology Alternative splicing Intron retention Ribosome biogenesis RNA binding proteins Silencing Defective 2 snoRNA

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