Global ETD Search

91	Genomic analysis of ribosomal DNA and its application to the investigation of disease pathogenesis Zentner, Gabriel Etienne January 2011 (has links) No description available. Genetics rDNA ribosomal DNA rRNA ribosomal RNA CHD7 CHARGE syndrome ChIP-seq UBF upstream binding factor CTCF histone modifications haploinsufficiency TCOF1 treacle
92	Architecture and core of the small ribosomal subunit Gulen, Burak 27 May 2016 (has links) The ribosome is one of the most universal molecular machinery, synthesizing proteins in all living systems. The small ribosomal subunit plays a crucial role in decoding the messenger RNA during translation. We propose and validate a new architectural model of the ribosomal small subunit, with broad implications for function, biogenesis and evolution. We define an rRNA domain: compact and modular, stabilized by self-consistent molecular interactions, with ability to fold autonomously when it is isolated from surrounding RNA or protein. Each rRNA helix must be allocated uniquely to a single domain. These criteria identify a core domain of small subunit rRNA (domain A), which acts as a hub, linking to all other domains by A-form helical spokes. Experimental characterization of isolated domain A, and mutations and truncations of it, by methods including selective 2’OH acylation analyzed by primer extension and circular dichroism spectroscopy are consistent with autonomous folding, and therefore classification as a domain. We show that the domain concept is applicable and useful for understanding the small ribosomal subunit. Our results support the utility of the concept of the domain as applied to at least some RNAs, the interdependence of the elements of domain A, and its ability to fold autonomously. Moreover, domain A, which exhibits elements of tRNA mimicry, is the essential core of the small ribosomal subunit. Understanding the structure and dynamics of domain A will provide valuable insight into the translational machinery. Ribosome Small subunit Central pseudoknot SSU Translation tRNA mimicry Ribosomal evolution SHAPE S5 S12
93	PHYLOGĖNIE MOLĖCULAIRE DES MELANOPLINAE (INSECTA: ORTHOPTERA: CAELIFERA: ACRIDIDAE) Chintauan-Marquier, I. 15 December 2010 (has links) (PDF) La phylogénie moléculaire reconstruit des relations de parenté entre unités évolutives, en se basant sur des changements structurels au niveau moléculaire (ADN, protéines). Elle constitue donc un outil précieux pour déchiffrer l'évolution spatio-temporelle de la biodiversité. Le présent travail examine l'histoire évolutive d'un groupe de criquets (Insecta: Orthoptera: Caelifera), par le biais de méthodes phylogénétiques (parcimonie, maximum de vraisemblance et bayésienne) et de datation, appliquées à l'étude de séquences d'ADN nucléaire et mitochondrial combinées. Dans un premier temps, nous étudions la sous-famille Melanoplinae (Orthoptera: Acrididae) et l'une de ses tribus, Podismini, pour éclaircir leur histoire évolutive, la resituer dans un contexte paléobiogéographique, et la mettre en relation avec la taxonomie existante. Dans un deuxième temps, les méthodes de reconstruction phylogénétiques et de datation sont appliquées à l'étude de la dynamique de l'évolution concertée au sein de l'espèce Podisma pedestris, en analysant le polymorphisme intra- et interindividuels de l'ADN ribosomal, i.e. gènes et pseudogènes d'ITS1. Acrididae Melanoplinae ADN ribosomal pseudogène phylogénie moléculaire datation biogéographie taxonomie
94	Identification and Characterization of Novel Proteins and Pathways for mRNA Degradation and Quality Control in Saccharomyces Cerevisiae Doma, Meenakshi Kshirsagar January 2006 (has links) In eukaryotes, mRNA decay pathways are important for cellular response to various physiological conditions and also function in co-translational quality control systems that target translationally aberrant mRNAs for degradation. My work on identification and characterization of novel components and pathways of mRNA degradation and quality control in Saccharomyces cerevisiae is summarized below.I have identified Edc3p as a novel protein important for mRNA decay. Deletion of Edc3p leads to a defect in mRNA decay in strains deficient in decapping enzymes and, in combination with a block to the 3' to 5' decay pathway, causes exaggerated growth defects and synthetic lethality. An Edc3p-GFP fusion protein localizes in processing bodies, which are specialized cytoplasmic foci containing decapping proteins. Together, these observations indicate that Edc3p directly interacts with the decapping complex to stimulate the mRNA decapping rate.Quality control during mRNA translation is critical for regulation of gene expression. My work shows that yeast mRNAs with defects in translation elongation, due to strong translational pauses, are recognized and targeted for degradation via an endonucleolytic cleavage in a novel process referred to as No-Go Decay (NGD). The cellular mRNA decay machinery degrades the 5' and 3' cleavage products produced by NGD. NGD is translation-dependent, occurs in a range of mRNAs and can be induced by a variety of elongation pauses. These results indicate NGD may occur at some rate in response to any stalled ribosome.I also show that two highly conserved proteins, Dom34p and Hbs1p, homologous to the eukaryotic release factors eRF1 and eRF3 respectively, are required for NGD. Further characterization of the No-Go decay pathway indicates that Dom34p function during NGD is conserved across species. Identification of RPS30, a small ribosomal protein as a trans-acting factor during NGD suggests that the ribosome may have a novel role during NGD. Other experiments indicate that the No-Go decay pathway may cross talk with the unfolded protein response pathway. The identification of No-Go decay as a novel quality control pathway during translation elongation supports the existence of a global cellular mechanism for maintenance of translational quality control. mRNA decay Translation elongation Ribosomal stall Quality control mRNA surveillance
95	Structural and Biochemical Studies of Antibiotic Resistance and Ribosomal Frameshifting Chen, Yang January 2013 (has links) Protein synthesis, translation, performed by the ribosome, is a fundamental process of life and one of the main targets of antibacterial drugs. This thesis provides structural and biochemical understanding of three aspects of bacterial translation. Elongation factor G (EF-G) is the target for the antibiotic fusidic acid (FA). FA binds to EF-G only on the ribosome after GTP hydrolysis and prevents EF-G dissociation from the ribosome. Point mutations in EF-G can lead to FA resistance but are often accompanied by a fitness cost in terms of slower growth of the bacteria. Secondary mutations can compensate for this fitness cost while resistance is maintained. Here we present the crystal structure of the clinical FA drug target, Staphylococcus aureus EF-G, together with the mapping and analysis of all known FA-resistance mutations in EF-G. We also present crystal structures of the FA-resistant mutant F88L, the FA-hypersensitive mutant M16I and the FA-resistant but fitness-compensated double mutant F88L/M16I. Analysis of mutant structures together with biochemical data allowed us to propose that fitness loss and compensation are caused by effects on the conformational dynamics of EF-G on the ribosome. Aminoglycosides are another group of antibiotics that target the decoding region of the 30S ribosomal subunit. Resistance to aminoglycosides can be acquired by inactivation of the drugs via enzymatic modification. Here, we present the first crystal structure an aminoglycoside 3’’ adenyltransferase, AadA from Salmonella enterica. AadA displays two domains and unlike related structures most likely functions as a monomer. Frameshifts are deviations the standard three-base reading frame of translation. -1 frameshifting can be caused by normal tRNASer3 at GCA alanine codons and tRNAThr3 at CCA/CCG proline codons. This process has been proposed to involve doublet decoding using non-standard codon-anticodon interactions. In our study, we showed by equilibrium binding that these tRNAs bind with low micromolar Kd to the frameshift codons. Our results support the doublet-decoding model and show that non-standard anticodon loop structures need to be adopted for the frameshifts to happen. These findings provide new insights in antibiotic resistance and reading-frame maintenance and will contribute to a better understanding of the translation elongation process. protein synthesis elongation elongation factor G fusidic acid antibiotic resistance aminoglycoside adenyltransferase ribosomal frameshifting
96	Ribosomal protein mutants and their effects on plant growth and development 2012 October 1900 (has links) Ribosomes, large enzymatic complexes containing an RNA catalytic core, drive protein synthesis in all living organisms. 80S cytoplasmic eukaryotic ribosomes are comprised of four rRNAs and approximately 80 ribosomal proteins (r-proteins). R-proteins are encoded by gene families with large families (average of twelve members) predominating in mammals and smaller families (two to seven members) in plants. Increased ribosome heterogeneity is possible in plant ribosomes due to multiple transcriptionally active members in each family, whereas, in mammalian r-protein gene families, only one member is typically active. Multiple functional paralogs provide for greater plasticity in response to environmental/developmental cues, as well as, increasing the possibility of individual paralogs procuring or retaining extraribosomal functions. This research investigated the effects of r-protein mutations on plant growth and development. Through RNA interference (RNAi) mediated knockdown (KD) of type I (cytoplasmic: RPS15aA/D and F) and type II (non-cytosolic: RPS15aB and E) RPS15a family members I was able to confirm the delineation between the two types. Subcellular localization of the type I isoforms was nuclear/nucleolar while localization of type II isoforms was non-mitochondrial and probably cytosolic. Illumina sequencing of two r-protein mutant transcriptomes, pfl1 (rps18a) and pfl2 (rps13a), identified a novel set of up and down regulated genes, previously unknown or linked to r-protein mutants. The 20 genes identified were classified into four groups (1) plant defense, (2) transposable elements, (3) nitrogen metabolism and (4) genes with unknown function. Illumina miRNOME analysis revealed no changes in the miRNA profile of pfl1 and pfl2 plants. These data do not support the previously proposed theory that a disruption in ribosome biogenesis (by decreased r-protein synthesis) disrupts miRNA-mediated degradation of a range of auxin response genes. Finally, a novel double r-protein mutant, rps18a:HF/RPL18B, presented a late flowering/thickened bolt phenotype not seen in a rps13a:HF/RPL18B mutant, suggesting that RPS18A has an extraribosomal role in plant growth and development in Arabidopsis.
97	Posttranscriptional Regulation of Embryonic Neurogenesis by the Exon Junction Complex Mao, Hanqian January 2016 (has links) <p>The six-layered neuron structure in the cerebral cortex is the foundation for human mental abilities. In the developing cerebral cortex, neural stem cells undergo proliferation and differentiate into intermediate progenitors and neurons, a process known as embryonic neurogenesis. Disrupted embryonic neurogenesis is the root cause of a wide range of neurodevelopmental disorders, including microcephaly and intellectual disabilities. Multiple layers of regulatory networks have been identified and extensively studied over the past decades to understand this complex but extremely crucial process of brain development. In recent years, post-transcriptional RNA regulation through RNA binding proteins has emerged as a critical regulatory nexus in embryonic neurogenesis. The exon junction complex (EJC) is a highly conserved RNA binding complex composed of four core proteins, Magoh, Rbm8a, Eif4a3, and Casc3. The EJC plays a major role in regulating RNA splicing, nuclear export, subcellular localization, translation, and nonsense mediated RNA decay. Human genetic studies have associated individual EJC components with various developmental disorders. We showed previously that haploinsufficiency of Magoh causes microcephaly and disrupted neural stem cell differentiation in mouse. However, it is unclear if other EJC core components are also required for embryonic neurogenesis. More importantly, the molecular mechanism through which the EJC regulates embryonic neurogenesis remains largely unknown. Here, we demonstrated with genetically modified mouse models that both Rbm8a and Eif4a3 are required for proper embryonic neurogenesis and the formation of a normal brain. Using transcriptome and proteomic analysis, we showed that the EJC posttranscriptionally regulates genes involved in the p53 pathway, splicing and translation regulation, as well as ribosomal biogenesis. This is the first in vivo evidence suggesting that the etiology of EJC associated neurodevelopmental diseases can be ribosomopathies. We also showed that, different from other EJC core components, depletion of Casc3 only led to mild neurogenesis defects in the mouse model. However, our data suggested that Casc3 is required for embryo viability, development progression, and is potentially a regulator of cardiac development. Together, data presented in this thesis suggests that the EJC is crucial for embryonic neurogenesis and that the EJC and its peripheral factors may regulate development in a tissue-specific manner.</p> / Dissertation Molecular biology Developmental biology Cellular biology Exon Junction Complex Posttranscriptional regulation ribosomal biogenesis RNA Splicing
98	Evaluation of PCR Approaches for Detection of Bartonella bacilliformis in Blood Samples Gomes, Cláudia, Martinez Puchol, Sandra, Pons, Maria J., Bazán, Jorge, Tinco, Carmen, Del Valle Mendoza, Juana Mercedes, Ruiz, Joaquim 09 March 2016 (has links) Background The lack of an effective diagnostic tool for Carrion’s disease leads to misdiagnosis, wrong treatments and perpetuation of asymptomatic carriers living in endemic areas. Conventional PCR approaches have been reported as a diagnostic technique. However, the detection limit of these techniques is not clear as well as if its usefulness in low bacteriemia cases. The aim of this study was to evaluate the detection limit of 3 PCR approaches. Methodology/Principal Findings We determined the detection limit of 3 different PCR approaches: Bartonella-specific 16S rRNA, fla and its genes. We also evaluated the viability of dry blood spots to be used as a sample transport system. Our results show that 16S rRNA PCR is the approach with a lowest detection limit, 5 CFU/μL, and thus, the best diagnostic PCR tool studied. Dry blood spots diminish the sensitivity of the assay. Methodology/Principal Findings We determined the detection limit of 3 different PCR approaches: Bartonella-specific 16S rRNA, fla and its genes. We also evaluated the viability of dry blood spots to be used as a sample transport system. Our results show that 16S rRNA PCR is the approach with a lowest detection limit, 5 CFU/μL, and thus, the best diagnostic PCR tool studied. Dry blood spots diminish the sensitivity of the assay. Conclusions/Significance From the tested PCRs, the 16S rRNA PCR-approach is the best to be used in the direct blood detection of acute cases of Carrion’s disease. However its use in samples from dry blood spots results in easier management of transport samples in rural areas, a slight decrease in the sensitivity was observed. The usefulness to detect by PCR the presence of low-bacteriemic or asymptomatic carriers is doubtful, showing the need to search for new more sensible techniques. Bastonella Polymerase chain reaction Carrion's disease Ribosomal RNA Blood Diagnostic medicine Gene amplification Filter paper
99	Uplatnění metod molekulární a buněčné biologie ve výzkumu prvoků Eimeria / Application of molecular and cellular biology methods in research of protozoa Eimeria Vrba, Vladimír January 2011 (has links) Eimeria is an apicomplexan parasite causing disease coccidiosis that is most prominent in poultry farming industry. This thesis is aimed to develop new molecular tools and resolve issues that would be a valuable contribution in the field from both research and industry perspective. Because immunity to Eimeria is strictly species- specific, it is important to know and recognize correctly all species that parasitize the host. Traditional diagnostic approaches rely on classical methods such as oocyst morphology determination under the microscope, measurement of prepatent period or in-vivo assessment of lesions caused by this parasite. However, diagnostics of individual species using these methods is very time-consuming and it is often unreliable, especially when mixture of multiple species whose parameters overlap is analyzed. Methods utilizing conventional PCR to distinguish species already exist, however, they lack advantages offered by quantitative real-time PCR (qPCR). The first aim of this thesis was to develop qPCR assays for detection and quantification of seven Eimeria species which infect chicken utilizing single-copy non-polymorphic targets in order to ensure maximal specifity and coverage of all strains of each species. Usefulness of this method was demonstrated by analysis of field...
100	Chromatin remodelling of ribosomal genes - be bewitched by B-WICH Vintermist, Anna January 2015 (has links) Transcription of the ribosomal genes accounts for the majority of transcription in the cell due to the constant high demand for ribosomes. The number of proteins synthesized correlates with an effective ribosomal biogenesis, which is regulated by cell growth and proliferation. In the work presented in this thesis, we have investigated the ribosomal RNA genes 45S and 5S rRNA, which are transcribed by RNA Pol I and RNA Pol III, respectively. The focus of this work is the chromatin remodelling complex B-WICH, which is composed of WSTF, the ATPase SNF2h and NM1. We have studied in particular its role in ribosomal gene transcription. We showed in Study I that B-WICH is required to set the stage at rRNA gene promoters by remodelling the chromatin into an open, transcriptionally active configuration. This results in the binding of histone acetyl transferases to the genes and subsequent histone acetylation, which is needed for ribosomal gene activation. Study II investigated the role of B-WICH in transcription mediated by RNA polymerase III. We showed that B-WICH is essential to create an accessible chromatin atmosphere at 5S rRNA genes, which is compatible with the results obtained in Study 1. In this case, however, B-WICH operates as a licensing factor for c-Myc and the Myc/Max/Mxd network. Study III confirmed the importance and the function of the B-WICH complex as an activator of ribosomal genes. We demonstrated that B-WICH is important for the remodelling of the rDNA chromatin into an active, competent state in response to extracellular stimuli, and that the association of the B-WICH complex to the rRNA gene promoter is regulated by proliferative and metabolic changes in cells. The work presented in this thesis has confirmed that the B-WICH complex is an important regulator and activator of Pol I and Pol III transcription. We conclude that B-WICH is essential for remodelling the rDNA chromatin into a transcriptionally active state, as required for efficient ribosomal gene transcription. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Manuscript.</p><p> </p> chromatin remodelling ribosomal genes rDNA transcription RNA polymerase I transcription RNA polymerase III transcription

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