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Understanding the role of assembly factors in 30S subunit biogenesis / The role of assembly factors in 30S subunit biogenesisThurlow, Brett Thomas January 2016 (has links)
Our understanding regarding the function of YjeQ, RbfA, RimM and Era in ribosome biogenesis has been derived in part from the study of immature 30S particles that accumulate in bacteria strains lacking one of these factors. However, their mechanistic details are still unknown. Here, we demonstrate that the 30SΔyjeQ and 30SΔrimM immature particles are not dead-end products of assembly, but progress into mature 30S subunits. Mass spectrometry analysis revealed that in vivo the occupancy level of these factors in these immature 30S particles is below 10% and that the concentration of factors does not increase when immature particles accumulate in cells. Analysis of the binding interactions of these assembly factors with mature 30S subunits and the immature particles demonstrated that YjeQ and Era bind to the mature 30S subunit with high affinity, however binding of these factors to the immature particles and of RimM and RbfA to mature or immature particles is weak. This indicates that binding of the assembly factors to the immature particles is not occurring at physiological concentrations. These results suggest that in the absence of these factors, the immature particles evolve into a thermodynamically stable intermediate that exhibits low affinity for the assembly factors and that the true substrates of YjeQ, RbfA, RimM and Era are immature particles that precede the ribosomal particles accumulating in the knockouts strains. We also developed an Era-depletion and ΔrbfA strain, which exhibited slow-growth, cold-sensitivity and an aberrant ribosome profile, which are all characteristic of ribosome assembly defects. Cryo-EM structural analysis of the 30SEra-depleted particles revealed that multiple classes at various stages in the assembly process accumulate upon depletion of Era, suggesting that Era may have a global effect on biogenesis. Ultimately, this thesis provides new insights into the nature of 30S particles that accumulate during assembly factor perturbation and advances our understanding of ribosome biogenesis as a whole. / Dissertation / Doctor of Philosophy (PhD) / One of the most fundamental processes in all living cells is the synthesis of proteins by the ribosome. The ribosome is a massive macromolecular complex that consists of both proteins and RNA, which must be manufactured from its individual components before it can perform its function. There is a myriad of protein factors that assist in the assembly of ribosomes to ensure that biogenesis proceeds rapidly and efficiently. The purpose of this thesis was to gain a better understanding of how the assembly factors YjeQ, Era, RbfA and RimM work by studying the intermediates that accumulate when they are removed or depleted from the cell. Specifically, the fate, binding interactions and structure of the immature particles that accumulate in the assembly factor knockout or depletion strains were investigated. The work here brings new insights into the nature of these immature ribosomal particles and the maturation reactions catalyzed by these factors.
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Impairment of Ribosomal Subunit Synthesis in Aminoglycoside-Treated Ribonuclease Mutants of Escherichia coliFrazier, Ashley D., Champney, W. S. 01 December 2012 (has links)
The bacterial ribosome is an important target for many antimicrobial agents. Aminoglycoside antibiotics bind to both 30S and 50S ribosomal subunits, inhibiting translation and subunit formation. During ribosomal subunit biogenesis, ribonucleases (RNases) play an important role in rRNA processing. E. coli cells deficient for specific processing RNases are predicted to have an increased sensitivity to neomycin and paromomycin. Four RNase mutant strains showed an increased growth sensitivity to both aminoglycoside antibiotics. E. coli strains deficient for the rRNA processing enzymes RNase III, RNase E, RNase G or RNase PH showed significantly reduced subunit amounts after antibiotic treatment. A substantial increase in a 16S RNA precursor molecule was observed as well. Ribosomal RNA turnover was stimulated, and an enhancement of 16S and 23S rRNA fragmentation was detected in E. coli cells deficient for these enzymes. This work indicates that bacterial RNases may be novel antimicrobial targets.
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Development of a FRET-based assay to determine binding affinities of RsmG to 30S 5'-domain RNA-protein complexesHawkins, Caitlin Marie 29 May 2019 (has links)
No description available.
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Interactions entre l'ARN 23S et les protéines uL24 et uL4 dans l'assemblage de la grande sous-unité du ribosome : mesures de force par piège optique / Interactions between 23S RNA and proteins uL24 and uL4 during the assembly of the large ribosomal subunit : force measurements by optical tweezersGeffroy, Laurent 04 December 2017 (has links)
Le ribosome est un organite essentiel de la cellule qui assure la synthèse des protéines. C'est une structure très conservée, composée d'ARN et de protéines ribosomiques organisés en deux sous-unités. Les expériences de reconstitution in vitro du ribosome d'E. coli ont montré que l'assemblage est un processus coordonné impliquant de nombreuses interactions entre les différents constituants. En particulier, les premières étapes de l'assemblage de la grande sous-unité dépendent fortement de la fixation coopérative de cinq protéines ribosomiques à l'ARN 23S, mais les mécanismes moléculaires sous-jacents sont mal connus.Cette étude à l'échelle de la molécule unique vise à préciser ces mécanismes et porte sur un fragment constitué des hélices H18, H19 et H20 du domaine I de l'ARN ribosomique 23S contenant les sites de fixation des protéines uL24 et uL4. Ce fragment d'ARN a été préparé dans une configuration qui permet la mesure de force via un double piège optique. Les courbes de force obtenues ont permis de dresser une cartographie de la stabilité des structures du fragment d'ARN.Ces cartes ont été comparées en absence et en présence des protéines ribosomiques uL24 et/ou uL4, démontrant ainsi que le fragment d'ARN est stabilisé par la fixation des protéines uL24 et/ou uL4. Leur fixation est coopérative et la présence conjointe des deux protéines sur-stabilise les structures du fragment d'ARN.Ces résultats sont discutés dans la perspective de préciser le rôle du fragment d'ARN et des protéines ribosomiques uL24 et uL4 dans l'assemblage de la grande sous-unité du ribosome. / Ribosomes are essential organelles of the cell responsible for the synthesis of proteins. Their well conserved structure made of RNA and proteins is organized into two subunits. In vitro reconstitution of E. coli ribosomes showed that their assembly is a coordinated process which involves many interactions between the components. More specifically, the early stages of the large subunit assembly depend strongly on the cooperative binding of five ribosomal proteins to the 23S RNA. The underlying molecular mechanisms however remain poorly understood.The aim of this study is to shine new light on these mechanisms at the single molecule level. It focuses on a 23S ribosomal RNA fragment composed of the helices H18, H19 and H20 in domain I which encompasses the binding sites of the ribosomal proteins uL24 and uL4. This RNA fragment has been prepared in a dumbbell configuration and force versus displacement measurements have been performed using a dual optical trap. From these measurements, a map summarizing the mechanical stability of the RNA fragment has been determined.The maps obtained in absence and in presence of the ribosomal proteins uL24 and/or uL4 have been compared consequently demonstrating mechanical stabilization of the RNA fragment induced by the binding of uL24 and/or uL4. Moreover, their binding is cooperative and when both are present, the mechanical stabilization of the RNA fragment is enhanced.These results are discussed to specify the role of the RNA fragment and proteins uL24 and uL4 in the large ribosomal subunit assembly.
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Protein factors involved in the biogenesis of the mitochondrial ribosomeD'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.
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Characterization of a 30S Ribsomal Subunit Intermediate Found in <em>Escherichia coli<em> Cells Growing with Neomycin and Paromomycin.Foster, Cerrone Renee 14 August 2007 (has links) (PDF)
The bacterial ribosome is a target for inhibition by numerous antibiotics. Neomycin and paromomycin are aminoglycoside antibiotics that specifically stimulate the misreading of mRNA by binding to the decoding site of 16S rRNA in the 30S ribosomal subunit. Recent work has shown that both antibiotics also inhibit 30S subunit assembly in Escherichia coli and Staphylococcus aureus cells. This work describes the characteristics of an assembly intermediate produced in E.coli cells grown with neomycin or paromomycin. Antibiotic treatment stimulated the accumulation of a 30S assembly precursor with a sedimentation coefficient of 21S. The particle was able to bind radio labeled antibiotics both in vivo and in vitro. Hybridization experiments showed that the 21S precursor particle contained 16S and 17S rRNA. Ten 30S ribosomal proteins were found in the precursor after inhibition by each drug in vivo. In addition, cell free reconstitution assays generated a 21S particle during incubation with either aminoglycoside. Precursor formation was inhibited with increasing drug concentration. This work examines features of a novel antibiotic target for aminoglycoside and will provide information that is needed for the design of more effective antimicrobial agents.
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Characterization of Ribosomes and Ribosome Assembly Complexes by Mass SpectrometryDator, Romel P. January 2013 (has links)
No description available.
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THE CRYO-EM STRUCTURE OF THE ∆RIMM IMMATURE 30S RIBOSOMAL SUBUNIT: A SNAPSHOT OF THE PROTEIN FACTORY UNDER CONSTRUCTIONKent, Meredith C. 04 1900 (has links)
<p>The ribosome is part of the indispensable machinery of every living cell. This large macromolecule, which decodes messenger RNA to produce proteins, is the subject of intense study as the mediator of an essential process. The prokaryotic ribosome is a major target for antimicrobial therapy, as its structure differs significantly from the eukaryotic ribosome. At present, the in vivo process of translation on the mature bacterial, or 70S, ribosome is well studied and increasingly understood, while the process of assembling the small (30S) and large (50S) subunits of this complex ribonucleoprotein enzyme has mostly been studied in vitro. Consequently, the significance of in vivo events such as ribosomal RNA (rRNA) maturation and factor-mediated maturation is incompletely understood. By studying the nature and structure of an in vivo assembled immature 30S subunit, this thesis aims to gain a better understanding of the key events in 30S subunit biogenesis. Deletion of the assembly cofactor Ribosome Maturation Factor M (RimM) results in slow growth, inefficient rRNA processing, and accumulation of nonfunctional, immature 30S subunits. This work presents the first cryo-EM model of the immature 30S purified from a RimM knockout strain of <em>E. coli</em>. The structure reveals distortion of the decoding centre and a disrupted 50S-binding interface, attesting to the importance of rRNA processing in 30S maturation. Additionally, the model suggests consequences for ribosomal protein incorporation and rRNA domain position relative to the mature 30S.</p> / Master of Science (MSc)
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ELUCIDATING THE ROLE OF THE YJEQ AND RBGA GTPASES IN THE ASSEMBLY OF THE BACTERIAL RIBOSOMEJomaa, Ahmad January 2013 (has links)
<p>Ribosome assembly is a complex process, facilitated by more than 20 protein factors in bacteria. GTPases and ATPases represent the energy driving force of these factors. In my research as a PhD student, I studied the function of two GTPases, YjeQ and RbgA, involved in the assembly of the small and the large ribosomal subunits, respectively.</p> <p>We isolated and characterized <em>in-vivo</em> assembled immature small (30S) and large (50S) subunits using a perturbation in the genes coding for these proteins. We observed that both subunits contained an incomplete ribosomal protein content, mainly lacking late-binding r-proteins. Additionally, we observed distortions in the functional core of the immature ribosomal subunit, particularly in the mRNA decoding center of the 30S subunit, the peptidyltransferase center of the 50S subunit, and tRNA binding sites.</p> <p>Additionally, we have determined that the YjeQ protein interacts with the 30S subunit through its N-terminal OB-fold domain, and C-terminal Zn-finger motif. The binding site of YjeQ on the 30S subunit prevents the interaction with tRNAs, translation factors, and the 50S subunit.</p> <p>Finally, we uncovered a novel functional interplay between RbgA and the ribosomal protein L16 during late stages of ribosomal assembly. We proposed that recruitment of L16 to the assembling 50S subunit would induce a conformational rearrangement that would ultimately promote the GTP-dependent release of RbgA.</p> <p>The function of the assembly factors associated with the process of <em>in-vivo</em> ribosome assembly is not known, and thus a framework on how ribosomes are built is still elusive. I believe the research presented in this thesis provides novel insights into the role of YjeQ and RbgA in the assembly of ribosomes</p> / Doctor of Philosophy (PhD)
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The Role of the YjeQ GTPase in Bacterial Ribosome Biogenesis: Function of the C-terminal Zinc-finger DomainJeganathan, Ajitha 14 May 2015 (has links)
<p>Our understanding of the mechanism of ribosome assembly in bacteria is still in its infancy. Work from our laboratory and others have recently established that some protein assembly factors assist the assembly process at its late stages, mediating the correct folding of the functional core of the 30S and 50S subunits. The GTPase YjeQ is an assembly factor that displaces the upper domain of h44 of the mature 30S subunit upon binding, inducing a distortion in the decoding center. We hypothesized that the displacement of h44 is caused by the zinc-finger domain of YjeQ and mediates the release of RbfA, another assembly factor involved in 30S subunit maturation. To understand how the zinc-finger domain of YjeQ implements the functional interplay with RbfA, we constructed several deletion mutants of the domain. We found that the zinc-finger domain of YjeQ was required to bind the 30S subunit, but not the C-terminal extension (CTE) of the domain. The CTE was necessary for stimulation of GTPase activity upon binding to the 30S subunit and removal of bound RbfA from the 30S subunit. The data presented here suggests that the zinc-finger domain is essential for YjeQ to bind the 30S subunit and to implement the functional interplay with RbfA. Ongoing structural studies of the complex formed by the YjeQ CTE variant and the 30S subunit will provide a three dimensional view of the conformational changes that occur to implement the functional interplay between YjeQ and RbfA at the late stages of 30S subunit assembly.</p> / Master of Science (MSc)
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