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1	Untersuchungen zu Struktur und Expression des Plastidengenoms höherer Pflanzen / Investigation of structure and expression of the plastid genome of higher plants Drechsel, Oliver January 2008 (has links) Auf dem Weg der genetischen Information stellt die Translation der RNA in eine Aminosäuresequenz den letzten Schritt dar. In Chloroplasten, den grünen Organellen der Pflanzenzellen, findet ein Großteil der Regulation der Genexpression auf Ebene der Initiation dieses Schrittes statt. Eine Vielzahl von Eigenschaften der RNA und von Faktoren, die an die RNA binden, entfalten einen Einfluss auf diesen Schritt. Bisher unvollständig aufgeklärt ist die Rolle einer konservierten Nukleotidsequenz in der untranslatierten Region der RNA -- der Shine-Dalgarno-Sequenz. Diese stellt in Bakterien, wie z.B. E. coli als Ribosomenbindestelle sicher, dass Ribosomen den Anfang der zu translatierenden Sequenz zuverlässig erkennen. Im Rahmen dieser Arbeit wurden diverse DNA-Konstrukte in Plastiden von Tabak eingebracht. Hierzu zählten Konstrukte, die sowohl eine erhöhte Anzahl von Ribosomenbindestellen enthielten als auch vermehrte Startpunkte der Translation. Zusätzlich wurden Konstrukte hergestellt, die die Situation von mehreren zu translatierenden Regionen in der RNA nachstellten. Es konnte festgestellt werden, dass plastidäre Ribosomen die strangaufwärts gelegenen Translationsstartpunkte bevorzugen -- im Gegensatz zu E. coli, wo alle Startpunkte gleichmäßig genutzt wurden. Hierdurch zeigten die prokaryotischen Ribosomen aus Chloroplasten, die sich aus bakteriellen Systemen ableiten, Eigenschaften von eukaryotischen Ribosomen. Ein zweites Teilprojekt dieser Arbeit beschäftigte sich mit der Inkompatibilität von Chloroplasten mit dem Kerngenom. In Kreuzungen von Arten der Gattung Pelargonium fielen Kombinationen auf, bei denen die Tochterpflanzen bleiche Blattbereiche bis hin zu vollständig weißen Pflanzen zeigten. Dieses Phänomen wird als Bastardbleichheit bezeichnet. In der Gattung Pelargonium werden Chloroplasten von beiden Elternteilen an die Tochterpflanzen vererbt. Da das Phänomen der Bastardbleichheit nur in einem der Plastiden vorkommt, nicht jedoch im anderen in der gleichen Pflanze, muss von einem Effekt ausgegangen werden, der von Plastiden ausgeht. Die Interaktionen zwischen Zellkern und Chloroplasten sind offensichtlich stark gestört. Zur detaillierten Untersuchung dieses Effekts wurde die Nukleotidsequenz von drei Chloroplastengenomen aufgeklärt. Es konnte eine Reihe von Sequenzunterschieden der Genome ermittelt werden. Aus diesen wurde eine Reihe von Unterschieden beobachtet, die einen solchen Effekt zur Folge haben können. Aus diesen Unterschieden wurde eine Reihe von potentiellen Kandidatengenen zusammengestellt, die in weiteren Arbeiten auf ihre Rolle in der Entstehung der Bastardbleichheit untersucht werden. / Chloroplasts are the green organelles of plants with a evolutionary prokaryotic background. During evolution chloroplasts established translation initiation as the major step in regulation of gene expression. A vast number of factors, e.g. sequence elements, secondary structures or RNA binding proteins, influences the regulation of translation initiation. A conserved sequence – Shine-Dalgarno sequence – can be identified both in prokaryotes as well as chloroplasts. In prokaryotes this sequence provides a faithful means for positioning of the ribosome to the start codon. Due to lower conservation of Shine-Dalgarno sequences the role of this sequence in translation initiation is not completely understood. We designed a series of constructs that contain different arrangements of these sequences in the 5’ UTR resulting in an increased number of potential ribosome binding sites or translation initiation sites. Additionally we constructed a series of 5’ UTRs that resembled polycistronic transcripts. The results showed a dramatic effect of the different constructs on the translation efficiency of the reporter protein. It could be shown that numerous translation initiation sites increase translation efficiency, whereas increased numbers of ribosome binding sites do not. Additionally it could be shown, that plastidic ribosomes preferentially initiate on 5’ translations initiation sites in contrast to prokaryotic ribosomes that recognize initiation sites equally. This illustrates that plastidic ribosomes in contrast to prokaryotic ribosomes show a scanning like mechanism. Hence plastidic ribosomes gained some eukaryotic properties during evolution. A second project was dealing with hybrid variegation. This phenomenon is based on plastid-nuclear genome incompatibility. Due to biparental plastid inheritance in Pelargonium hybrids may show chimeric phenotypes with bleached (incompatible) and green (compatible) sectors. This points to the plastome as cause for the hybrid variegation. To this end the nucleotide sequence of three plastid genomes was determined and an array of candidate genes causing the incompatibility could be compiled. Shine-Dalgarno-Sequenzen Translationsinitiation Plastid Bastardbleichheit Shine-Dalgarno sequences translation initiation plastid hybrid variegation Life sciences
2	Shine-Dalgarno Anti-Shine-Dalgarno Sequence Interactions and Their Functional Role in Translational Efficiency of Bacteria and Archaea Abolbaghaei, Akram January 2016 (has links) Translation is a crucial factor in determining the rate of protein biosynthesis; for this reason, bacterial species typically evolve features to improve translation efficiency. Biosynthesis is a finely tuned cellular process aimed at providing the cell with an appropriate amount of proteins and RNAs to fulfill all of its metabolic functions. A key bacterial feature for faster recognition of the start codon on mRNA is the binding between the anti-Shine-Dalgarno (aSD) sequence on prokaryotic ribosomes at the 3’ end of the small subunit (SSU) 16S rRNA and Shine-Dalgarno (SD) sequence, a purine-rich sequence located upstream of the start codon in the mRNA. This binding helps to facilitate positioning of initiation codon at the ribosomal P site. This pairing, as well as factors such as the location of aSD binding relative to the start codon and the sequence of the aSD motif can heavily influence translation efficiency. The objective of this thesis is to understand the SD-aSD interactions and how changes in aSD sequences can affect SD sequences in addition to the underlying impact these changes have on the translational efficiency of prokaryotes. In chapter two, we hypothesized that differences in the prevalence of SD motifs between B. subtilis and E. coli arise as a result of changes in the free 3' end of 16S rRNA which may have led B. subtilis and E. coli to evolve differently. E. coli is expected to be more amenable to the acquisition of SD motifs that do not perfectly correspond with its free 3’ 16S rRNA end than B. subtilis. Further, we proposed that the evolutionary divergence of these upstream sequences may be exacerbated in B. subtilis by the absence of a functional S1 protein. Based on the differences between E. coli and B. subtilis, we were able to identify SD motifs that can only perfectly base pair in one of the two species and are expected to work well in one species, but not the other. Furthermore, we determine the frequency and proportion of these specific SD motifs that are expected to be preferentially present in one of the two species. Our motif detection is in keeping with the expectation that the predicted five categories of SD that are associated with B. subtilis and are expected to be less efficient in E. coli exhibit greater usage in the former than latter. Similarly, the predicted category of SD motifs associated with the E. coli 16S rRNA 3’ end is used more frequently in E. coli.Across prokaryote genomes, translation initiation efficiency varies due to codon usage differences whereas among genes, translation initiation varies because different genes vary in SD strength and location. In chapter 3 we hypothesized that there is differential translation initiation between 16 archaeal and 26 bacterial genomes. Translation initiation was found to be more efficient in Gram-positive than in Gram-negative bacteria and also more efficient in Euryarchaeota than in Crenarchaeota. We assessed the efficiency of translation initiation by measuring: i) the SD sequence’s strength and position and ii) the stability of the secondary structure flanking the start codon, which both affect accessibility of the start codon Shine-Dalgarno Anti-Shine-Dalgarno Sequence translational efficiency Bacteria and Archaea 16S rRNA Translation initiaion
3	Regulatory Features of the 5' Untranslated Leader Region of <i>aroL</i> in <i>Escherichia coli</i> K12 and the sRNA, <i>ryhB</i>, in <i>Shewanella oneidensis</i> MR-1 Devine, Racheal A. 03 January 2018 (has links) No description available. Microbiology Molecular Biology translation initiation non-canonical translation initiation Shine-Dalgarno non-Shine-Dalgarno led mRNA
4	Factors Affecting Translational Efficiency of Bacteriophages Prabhakaran, Ramanandan January 2015 (has links) Mass production of translationally optimized bacteriophages (hereafter referred to as phages) is the need of the hour in the application of phages to therapy. Understanding translational efficiency of phages is the major preliminary step for mass producing efficient phages. The objective of this thesis is to understand factors affecting translational efficiency of phages. In chapter two, we hypothesized that weak translation initiation efficiency is responsible for weak codon concordance of Escherichia coli lambdoid phages with that of their hosts. We measured the strength of translation initiation using two indices namely minimum folding energy (MFE) and proportion of Shine-Dalgarno sequence (PSD). Empirical results substantiate our hypothesis suggesting lack of strong selection for improving codon adaptation in these phages is due to their weak translation initiation. In chapter three, we measured codon usage concordance between GC-rich and GC-poor Aeromonas phages with their GC-rich host Aeromonas salmonicida. We found low codon usage concordance in the GC-poor Aeromonas phages. We were interested in testing for the role of tRNAs in the GC-poor phages. We observed that the GC-poor phages carry tRNAs for codons that are overused by the phages and underused by the host. These findings suggest that the GC-poor Aeromonas phages carry their own tRNAs for compensating for the compositional difference between their genomes and that of their host. Previously several studies have reported observed avoidance of stable secondary structures in start site of mRNA in a wide range of species. We probed the genomes of 422 phage species and measured their secondary structure stability using MFE. We observed strong patterns of secondary structure avoidance (less negative MFE values) in the translation initiation region (TIR) and translation termination region (TTR) of all analyzed phages. These findings imply selection is operating at these translationally important sites to control stable secondary structures in order to maintain efficient translation. Phages Translation initiation Translation elongation Translation termination Codon usage Shine Dalgarno Phage encoded tRNAs Secondary structure
5	Studying the Paradox of the Anti-Shine Dalgarno Sequence in the Bacteroidetes McNutt, Zakkary Alan 10 August 2022 (has links) No description available. Biochemistry Genetics Microbiology Molecular Biology Ribosome Translation Bacteroidetes Flavobacterium Shine-Dalgarno
6	Computational Analysis of the Interplay Between RNA Structure and Function Shatoff, Elan Arielle January 2021 (has links) No description available. Physics RNA dsRBP SNP SNV secondary structure Shine-Dalgarno SD ASD S21 HuR TRBP structure prediction
7	Roles of <i>Escherichia coli</i> 5’-terminal AUG triplets in translation initiation and regulation Beck, Heather Joann 18 July 2016 (has links) No description available. Microbiology translation initiation leaderless mRNA ribosomal recognition non-canonical mRNA non-Shine-Dalgarno
8	Studies on translation initiation and gene expression in <i>Escherichia coli</i> Gonzalez de Valdivia, Ernesto I. January 2006 (has links) <p>In prokaryotes, several mRNA sequences surrounding the initiation codon have been found to influence the translation process; these include the downstream region and its codon context, the Shine-Dalgarno sequence and the S1 ribosomal protein-binding site. In this thesis, the purpose has been to study the role of the downstream region and Shine-Dalgarno-like sequences on early translation elongation and gene expression in <i>Escherichia coli</i>.</p><p>The downstream region (DR) after the initiation codon (around five to seven codons), has an important role in the initiation of translation. We find that most of the codons which give very low gene expression at +2 (considering AUG as +1), reach 5 to 10 fold higher expression when those codons are positioned posteriori to +2, with the exception of the NGG codons. The NGG codons abort the translation process if located within the first five codons of the DR, due to peptidyl-tRNA drop-off. However, when the NGG codons are situated further down from the DR, the protein expression was increased at the same level of expression as in the presence of any other codon.</p><p>The Shine-Dalgarno (SD) is an important region of initiation in translation of bacteria. In spite of this, it has been found that Gram-negative bacteria could translate mRNAs with weak or non-functional SD, while the DR carries out a main role in the efficiency of translation. In addition, positions of SD and SD-like sequences are very important to direct initiation of translation in the choice between two possible initiation codons. A strong SD between two initiation sites will favor the second initiation site if it consists of a canonical start codon followed by a good DR.</p><p>The results suggest that the mRNA sequences surrounding the initiation codon: the downstream region and the Shine-Dalgarno and SD-like sequences, are very important contributors to the translation level and gene expression in <i>Escherichia coli</i>.</p> Downstream region NGG codons abortive translation drop-off Shine-Dalgarno sequence gene expression and Escherichia coli NATURAL SCIENCES NATURVETENSKAP
9	Studies on translation initiation and gene expression in Escherichia coli Gonzalez de Valdivia, Ernesto I. January 2006 (has links) In prokaryotes, several mRNA sequences surrounding the initiation codon have been found to influence the translation process; these include the downstream region and its codon context, the Shine-Dalgarno sequence and the S1 ribosomal protein-binding site. In this thesis, the purpose has been to study the role of the downstream region and Shine-Dalgarno-like sequences on early translation elongation and gene expression in Escherichia coli. The downstream region (DR) after the initiation codon (around five to seven codons), has an important role in the initiation of translation. We find that most of the codons which give very low gene expression at +2 (considering AUG as +1), reach 5 to 10 fold higher expression when those codons are positioned posteriori to +2, with the exception of the NGG codons. The NGG codons abort the translation process if located within the first five codons of the DR, due to peptidyl-tRNA drop-off. However, when the NGG codons are situated further down from the DR, the protein expression was increased at the same level of expression as in the presence of any other codon. The Shine-Dalgarno (SD) is an important region of initiation in translation of bacteria. In spite of this, it has been found that Gram-negative bacteria could translate mRNAs with weak or non-functional SD, while the DR carries out a main role in the efficiency of translation. In addition, positions of SD and SD-like sequences are very important to direct initiation of translation in the choice between two possible initiation codons. A strong SD between two initiation sites will favor the second initiation site if it consists of a canonical start codon followed by a good DR. The results suggest that the mRNA sequences surrounding the initiation codon: the downstream region and the Shine-Dalgarno and SD-like sequences, are very important contributors to the translation level and gene expression in Escherichia coli. Downstream region NGG codons abortive translation drop-off Shine-Dalgarno sequence gene expression and Escherichia coli NATURAL SCIENCES NATURVETENSKAP
10	Computational insights into intergenic regions and overlapping genes among prokaryote genomes Pallejà Caro, Albert 25 February 2009 (has links) Computational Insights into Intergenic Regions and Overlapping Genes among Prokaryote GenomesTot i la gran varietat d'estils de vida de les espècies bacterianes, tots ells presenten trets arquitectònics comuns. En aquesta tesi s'estudia les regions intergèniques i els solapaments entre gens en els genomes procariotes.Hem vist que per predir els orígens de replicació, a part de l'anàlisi de la composició de nucleòtids del DNA, es requereix experiments computacionals complementaris per aconseguir millors prediccions. Els solapaments entre gens acostumen a ser curts, respecten el codi genètic i es veuen influenciats per la pressió selectiva en contra de grans solapaments. En canvi, com més llarg és un solapament entre dos gens, més risc hi ha que una mutació pugui afectar a dues proteïnes de la cèl·lula al mateix temps. Hem detectat que els solapaments més llargs de 60 parells de bases són deguts a errors en la seqüenciació o en l'anotació dels gens. En quant a les regions intergèniques, hem vist que la presència d'una seqüència reguladora entre gens, com és la Shine-Dalgarno (responsable de iniciar eficientment la traducció de RNA missatger a proteïna) pot influir en la mida d'aquestes regions i afectar l'ús de codons d'aturada. Finalment, hem construït una aplicació web ( http://genomes.urv.cat/pwneigh/ ) que permet estudiar fàcilment la conservació els solapaments en les espècies i les regions intergèniques en els genomes procariotes. / Computational Insights into Intergenic Regions and Overlapping Genes among Prokaryote GenomesAlthough prokaryote organisms live in a huge variety of habitats, they have architectural features in common. In this thesis we analyze the intergenic regions and the overlaps between genes among the prokaryote genomes.Although the DNA compositional analysis brings us near to the origin of replication, alternative analyses are required in order to achieve better predictions. The overlaps between prokaryote genes tend to be short and they arise according to the structure of the genetic code. Furthermore, there is a selective pressure against the long ones. As longer is an overlap there is more risk of a deleterious mutation that can affect two proteins of the cell. We detected that the overlaps longer than 60 bps are due to sequencing or annotation errors. Regarding the intergenic regions we found that the presence of a regulatory signal such as the Shine-Dalgarno sequence (responsible of an efficient translation of the mRNA to protein) can influence the length of this regions and the stop codon usage of the previous genes. Finally, we developed the PairWise Neighbours database ( http://genomes.urv.cat/pwneigh/ ) which permits the study of the overlaps and its conservation across the species, as well as the SD presence within the intergenic regions.Albert Pallejà CaroDepartament de Bioquímica i BiotecnologiaUniversitat Rovira i VirgiliCampus Sesceladesc/Marcel·lí Domingo, s/n43007 Tarragona - Catalunya errors d'anotació sequència shine-Dalgarno regions intergèniques origen de replicació gens solapats Bacteriana Genómica 57 573 577 6

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