Global ETD Search

91	Studies on Translation Initiation and Termination in Escherichia coli Ibrahim Isak, Georgina January 2012 (has links) Translation initiation factor 1 (IF1) has been shown to be an RNA chaperone. In order to find functional interactions that IF1 may have with rRNA, we have isolated second-site suppressors of a cold-sensitive IF1 mutant. Joining of the ribosomal subunit seems to be affected in the IF1 mutant strain and the suppressive effect is a consequence of decreasing the available pool of mature 50S subunits. The results serve as additional evidence that IF1 is an RNA chaperone and that final maturation of the ribosome takes place during translation initiation. In this study we have also investigated the effect of a cold-sensitive mutant IF1 or kasugamycin addition on gene expression using a 2D gel electrophoresis technique. The effect is much more dramatic when cells are treated with kasugamycin compared to mutant IF1. The ybgF gene is uniquely sensitive to the IF1 mutation as well as the addition of kasugamycin. This effect on the native gene could be connected with some property of the TIR sequence of ybgF and supports the notion that kasugamycin addition and the IF1 cold-sensitive mutation have a similar TIR-specific effect on mRNA translation. Finally we have isolated a suppressor of a temperature-sensitive mutation in ribosomal release factor 1 (RF1) to shed more light on the translation termination process. The suppressor mutation is linked to an IS10 insertion into the cysB gene and results in a Cys- phenotype. Our results suggest that suppression of the thermosensitive growth is a consequence of the mnm5s2U hypomodification of certain tRNA species. The ability of mnm5s2U hypomodified tRNA to induce frameshifting may be responsible for the suppression mechanism and it supports the hypothesis that modified nucleosides in the anticodon of tRNA act in part to prevent frameshifting by the ribosome. / At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript. Escherichia coli translation ribosome IF1 RF1 kasugamycin tRNA
92	Rate and Accuracy of Bacterial Protein Synthesis Johansson, Magnus January 2012 (has links) High levels of accuracy in transcription, aminoacylation of tRNA, and mRNA translation are essential for all life forms. However, high accuracy also necessarily means large energy dissipation and slow kinetics. Therefore, in vivo there is a fine tuned balance between rate and accuracy of key chemical reactions. We have shown that in our optimized in vitro bacterial protein synthesis system we have in vivo compatible rate and accuracy of ribosomal protein elongation. Our measurements of the temperature and the pH dependence of peptide bond formation with native substrates also suggest that the chemical step of peptidyl transfer, rather than tRNA accommodation, limits the rate of peptide bond formation. This work has made it possible to study ribosomal peptidyl transfer with native substrates. Furthermore, we have developed a general theoretical model for the rate-accuracy trade-off in enzymatic reactions. When considering this trade-off for protein synthesis in the context of the living bacterial cell, where cognate aa-tRNAs compete for ribosome binding with an excess of non-cognate aa-tRNAs, the model predicts an accuracy optimum where the inhibitory effect of non-cognate substrate binding and the efficiency loss due to high discard rate of cognate aa-tRNAs are minimized. However, these results also show that commonly used biochemical systems for protein synthesis studies operate at exceptionally suboptimal conditions. This makes it difficult, if not impossible, to relate the biochemical data to protein synthesis in the living cell. To validate our theoretical model we developed a method, based on variation of the concentration of Mg2+ ions in the buffer, to study the rate-accuracy trade-off of bacterial protein synthesis in vitro. We found a linear trade-off between rate and accuracy of tRNA selection on the ribosome, from which we could estimate the maximal accuracy. Exploiting this method for a complete set of single-mismatch readings by one tRNA species, we found simple patterns of genetic code reading, where the accuracy was highest for the second and lowest for the third codon position. The results bridge the gap between in vivo and in vitro protein synthesis and allow calibration of our test tube conditions to those of the living cell. protein synthesis ribosome peptidyl transfer rate-accuracy trade-off kinetics
93	The Protein Traffic on the Ribosome : The Mechanism and Regulation of Protein Synthesis in Prokaryotes / Протеин трафик на рибосоме : The Mechanism and Regulation of Protein Synthesis in Prokaryotes Zavialov, Andrey January 2004 (has links) The aim of this work was to understand the molecular mechanism of translation and the mechanism of translation termination, in particular. Cleavage of peptidyl-tRNA and peptide release terminates translation of mRNA on the ribosome. In prokaryotes, three release factors (RFs) are involved in this process. RF1 and RF2 recognise the three stop codons on mRNA and induce hydrolysis of the ester bond in peptidyl-tRNA. RF3 accelerates the rate of RF1 and RF2 recycling between ribosome in a GTP-dependent manner. We have clarified the mechanism of action of peptide release factor RF3. In the cell, free RF3 is in the GDP conformation. When RF3∙GDP binds to ribosome in complex with RF1 or RF2, these ribosome complexes act as guanine exchange factors for RF3 by inducing rapid dissociation of GDP. If, and only if, the peptide has been removed from tRNA, GDP is quickly replaced by GTP. Binding of GTP to RF3 induces a conformation of the factor with high affinity for the ribosome, which forces RF1 or RF2 to rapidly dissociate. Subsequent hydrolysis of GTP on RF3 induces a factor conformation with low affinity for the ribosome and rapid release of RF3∙GDP. It was further shown how the position of peptidyl-tRNA on the ribosome and the presence or absence of its peptide regulates the binding and GTPase activity of translation factors IF2, EF-G and EF-Tu. The result explains how idling GTPase hydrolysis and negative interference between different translation factors are minimized in living cells. The present biochemical observations, in conjunction with cryo-EM results, lead to new proposals for the role of hybrid sites in translocation of tRNAs, recycling of RF1 and RF2 by RF3 and recycling of post-termination ribosomes back to a new round of initiation. Biochemistry yellow ribosome translation Gagarin nobel prize Biokemi Biochemistry Biokemi
94	The importance of maturation factors in 30S ribosomal subunit assembly Nord, Stefan January 2010 (has links) The assembly of the ribosome is a complex process that needs to be highly efficient to support maximum growth. Although the individual subunits of the ribosome can be reconstituted in vitro, such a reaction is inefficient in comparison to the assembly rate in vivo. What differentiates the in vivo from the in vitro assembly is primarily the presence of ribosome assembly proteins. These are proteins that assist in the assembly of the ribosomal subunits but are not part of the mature ribosome. In bacteria, the ribosome assembly proteins include rRNA processing enzymes and rRNA/ribosomal protein (r-protein) modifying enzymes. One set of ribosome assembly proteins, the ribosome maturation factors, have been difficult to classify due to their differences in structure and their apparent lack of similarities with regard to function. As part of this thesis, the previously uncharacterized RimP (ribosome maturation) protein formerly known as P15A or YhbC, was studied. Deletion of the rimP gene affected the growth rate more severely at 44°C than at 37°C and 30°C. Polysome profile analysis revealed a decrease in the amount of translating ribosomes and a corresponding increase in the amount of free 50S and 30S ribosomal subunits. The disproportionate large increase in 50S relative to 30S subunits indicated a 30S assembly defect. RimP was shown to localize to the 30S ribosomal subunit, and an accumulation of 17S rRNA, a precursor to 16S rRNA, supports a role for RimP in 30S subunit maturation. The results from in vitro reconstitution experiments have given valuable insights in the assembly of the 30S subunit. By using a recently developed method, the role of ribosome maturation factors Era, RimM and RimP during in vitro reconstitutions of the 30S subunit was investigated. Era was found to increase the incorporation rate for most of the late binding r-proteins, while RimM and RimP had more specific effects. RimM increased the incorporation rate for r-proteins S19 and S9 and inhibited the incorporation of S13 and S12, whereas RimP increased the incorporation rate primarily for S12 and S5. A comparison of the ribosome maturation factors RimP and RbfA (ribosome binding factor A) revealed structural similarities between the N-terminal domain of RimP and the single domain of RbfA. RbfA is a 15 kDa protein that was found to high copy-suppress a dominant C23U 16S rRNA mutation giving rise to cold-sensitivity in E. coli. A number of chromosomal suppressor mutations that increased the growth rate of an rbfA null mutant were isolated. The five strongest suppressor mutations were localized to the rpsE gene, for r-protein S5 and resulted in amino acid substitutions in three positions: G87A, G87S, G91A, A127V and A127T. These alterations improved translation and the processing of 16S rRNA in the rbfA null mutant. Moreover, they also suppressed the slow growth of the C23U rRNA mutant at 30, 37 and 44°C. / Monteringen av ribosomen är en komplex process som måste vara effektiv för cellen skall kunna växa så fort som möjligt. Det är visat sedan tidigare att ribosomens två subenheter kan monteras ihop in vitro och sedan vara del av en ribosom som gungerar vid proteinsyntes, dock är den typen av rekonstrueringsreaktioner mycket ineffektiva i jämförelse med vad som krävs in vivo. Skillnaden mellan dessa två tillstånd är primärt in vivo-reaktionens närvaro av hjälpproteiner. Hjälpproteinerna assisterar monteringen av ribosomens subenheter men är själva inte en del av den färdiga ribosomen. Inom denna klass av proteiner återfinns proteiner som t.ex. processerar ribosomalt RNA och proteiner som modifierar ribosomalt RNA och ribosomala protein. En klass av hjälpproteiner, mognadsfaktorerna, har varit svåra att klassificera på grund av strukturella olikheter och en brist på funktionella likheter. En del i detta avhandlingsarbete var karaktäriseringen av den tidigare okända mognadsfaktorn RimP, tidigare kallad YhbC eller P15A. En deletion av rimP hade störst påverkan på tillväxthastigheten vid 44°C, men effekter kunde även ses vid 30°C och 37°C. En analys av den ribosomala statusen visade på en minskning av ribosomer aktiva i translation och en motsvarande ökning av fria 50S- och 30S-subenheter. Den oproportionerligt höga ökningen av fria 50S-subenheter, i relation till 30S-subenheter, indikerade att något var fel i monteringen av 30S-subenheten. RimP-proteinet återfanns lokaliserat till fria 30S-subenheter, och en ökning av omoget 16S ribosomalt RNA i en stam som saknar RimP stödjer dess roll i monteringen av 30S-subenheten. Rekonstrueringsexperiment In vitro har gett många värdefulla ledtrådar till hur 30S-subenheten monteras ihop. Genom att använda en nyligen utvecklad metod kunde vi undersöka hur mognadsfaktorerna Era, RimM och RimP påverkade monteringen av ribosomens 30S subenhet in vitro. Era ökade inkorporeringshastigheten av många av de ribosomala proteiner som inkorporeras sent i monteringen av 30S, medans RimM och RimP uppvisade mer specifika effekter. RimM ökade inkorporeringshastigheten för de ribosomala proteinerna S19 och S9, men dessutom inhiberade RimM inkorporeringen av de ribosomala proteinerna S13 och S12. RimP uppvisade den tydligaste effekten av de undersökta proteinerna genom att kraftigt öka 8 inkorporeringshastigheten för det ribosomala proteinet S12, och ökade även inkorporeringshastigheten för det ribosomala proteinet S5. En jämförelse av de två mognadsfaktorerna RbfA och RimP visade på strukturella likheter mellan RimP:s N-terminala domän och den enda domänen hos RbfA. RbfA är ett 15 kDa protein som upptäcktes som en hög-kopiesupressor av en dominant C23U-mutation i 16S ribosomalt RNA som leder till köld-känslighet hos E. coli. Ett antal kromosomala supressormutationer som ökade tillväxthastigheten för en mutant som saknar RbfA isolerades och de fem starkaste av dessa lokaliserades till rpsE genen som kodar för det ribosomala proteinet S5. Mutationerna gav upphov till aminosyra utbyten i tre positioner i S5: G87A, G87S, G91A, A127T och A127V. Förändringarna i S5 förbättrade translationen och processningen av 16S ribosomalt RNA i mutantensom saknar RbfA. Dessutom förbättrade mutationerna tillväxthastigheten hos C23U-mutanten vid 30, 37 och 44°C. Ribosome 30S rRNA RimP RbfA C23U rpsE Molecular biology Molekylärbiologi
95	Characterization of the four genes encoding cytoplasmic ribosomal protein S15a in Arabidopsis thaliana Hulm, Jacqueline Louise 31 March 2008 Eukaryotic cytosolic ribosomes are composed of two distinct subunits consisting of four individual ribosomal RNAs and, in Arabidopsis thaliana, 81 ribosomal proteins. Functional subunit assembly is dependent on the production of each ribosomal component. Arabidopsis thaliana r-protein genes exist in multi-gene families ranging in size from two to seven transcriptionally active members. The cytosolic RPS15a gene family consists of four members (RPS15aA, -C, -D and -F) that, at the amino acid level, share 87-100% identity. Using semi-quantitative RT-PCR I have shown that RPS15aC is not expressed and that transcript abundance differs both spatially and temporally among the remaining RPS15a genes in non-treated Arabidopsis tissues and in seedlings following a variety of abiotic stresses. A comprehensive analysis of the RPS15a 5' regulatory regions (RRs) using a series of deletion constructs was used to determine the minimal region required for gene expression and identify putative cis-regulatory elements. Transcription start site mapping using 5' RACE indicated multiple sites of initiation for RPS15aA and -F and only a single site for RPS15aD while all three genes contain a leader intron upstream of the start codon. Analysis of reporter gene activity in transgenic Arabidopsis containing a series of 5' RR deletion::GUS fusions showed that, similar to previous RT-PCR results, there was a trend for mitotically active tissues to stain for GUS activity. Putative cis-elements including the TELO box, PCNA Site II motif and pollen specific elements were identified. However, there was not always a clear correlation between the presence of a putative element and RPS15a transcript abundance or GUS activity. Although variation in transcriptional activity of each RPS15a gene has been observed, subcellular localization of both RPS15aA and -D in the nucleolus has been confirmed in planta by confocal microscopy. The results of this thesis research suggest while all three active RPS15a genes are transcriptionally regulated, additional post-transcriptional and/or translational regulation may be responsible for final RPS15a levels while differential isoform incorporation into ribosomal subunits may be the final point of r-protein regulation. gene expression transcriptional regulation Arabidopsis S15a ribosomal protein ribosome
96	Binding characteristics and localization of <i>Arabidopsis thaliana</i> ribosomal protein S15a isoforms Wakely, Heather 13 November 2008 Ribosomes which conduct protein synthesis in all living organisms are comprised of two subunits. The large 60S ribosomal subunit catalyzes peptidyl transferase reactions and includes the polypeptide exit tunnel, while the small (40S) ribosomal subunit recruits incoming messenger RNAs (mRNAs) and performs proofreading. The plant 80S cytoplasmic ribosome is composed of 4 ribosomal RNAs (rRNAs: 25-28S, 5.8S and 5S in the large subunit and 18S in the small subunit) and 81 ribosomal proteins (r-proteins: 48 in the large subunit, 33 in the small subunit). RPS15a, a putative small subunit primary binder, is encoded by a six member gene family (RPS15aA-F), where RPS15aB and RPS15aE are evolutionarily distinct and thought to be incorporated into mitochondrial ribosomes. In vitro synthesized cytoplasmic 18S rRNA, 18S rRNA loop fragments, and RPS15a mRNA molecules were combined in electrophoretic shift assays (EMSAs) to determine the RNA binding characteristics of RPS15aA/-D/-E/-F. RPS15aA/F, -D and -E bind to cytoplasmic 18S rRNA in the absence of cellular components. However, RPS15aE r-protein tested that binds mitochondrial 18S rRNA. In addition, RPS15aA/F only binds one of three 18S rRNA loop fragments of helix 23 whereas RPS15aD/-E bind all three 18S rRNA helix 23 loop fragments. Additionally, RPS15aD and RPS15aE did not bind their respective mRNA transcripts, likely indicating that this form of negative feedback is not a post-transcriptional control mechanism for this r-protein gene family. Furthermore, the addition of RPS15a transcripts to the EMSAs did not affect the binding of RPS15aA/F, -D and -E to 18S rRNA helix 23 loop 4-6, indicating that rRNA binding is specific. Supershift EMSAs further confirmed the specificity of RPS15aA/F and RPS15aE binding to loop fragment (4-6) of 18S rRNA. Taken together, these data support a role for RPS15a in early ribosome small subunit assembly. RNA binding ribosomal RNA ribosome ribosomal proteins plant molecular biology
97	Characterization of the two genes encoding cytoplasmic ribosomal protein L23a in <i>Arabidopsis thaliana</i> McIntosh, Kerri Bryn 23 November 2005 <p>RPL23a is one of the ~80 ribosomal proteins (r-proteins) of the cytoplasmic ribosome in the model plant <i>Arabidopsis thaliana</i>. The objectives of this research were to establish Arabidopsis RPL23a as a functional r-protein, characterize expression patterns for the two genes (RPL23aA and B) encoding RPL23a using reverse transcription PCR (RT-PCR), and identify regulatory elements controlling the expression of RPL23aA and B. Complementation of a yeast l25 mutant with AtRPL23aA demonstrated that AtRPL23aA can fulfill all the essential functions of L25 in vivo. A survey of various Arabidopsis tissue types showed that, while RPL23aA and B expression patterns both showed increased transcript abundance in mitotically active tissues, RPL23aB transcript levels were generally lower than those of RPL23aA and responded differently to abiotic stresses. In order to determine cis regulatory elements controlling RPL23aA and B expression, the 5 regulatory region (RR) of each gene was characterized via plants carrying a series of 5 RR deletion fragments upstream of a reporter. Transcript start sites and 5 untranslated regions (UTRs) for both RPL23aA and B were also characterized using primer extension, and transcripts from 5 deletion transgenics were amplified using RT-PCR. No correlation was observed between putative cis-acting elements and the expression patterns from the RPL23aA and B deletion transgenics, although a 102 bp sequence in the RPL23aB 5 RR was found to contain pollen-specific elements. 5 leader introns were found in each RPL23a gene, and amplification of transgene transcripts from deletion series plants indicated the importance of post-transcriptional and translational regulation in RPL23aA and B expression. This thesis work is the first demonstration of a plant RPL23a protein as a functional member of the L23/L25 (L23p) conserved r-protein family, and is one of the few in-depth studies of the regulation of r-protein genes in plants. While the majority of previous research on plant r-protein gene expression has focused solely on transcript levels, I show herein that post-transcriptional mechanisms have a critical role in regulating these genes, and thus plant r-protein genes more strongly resemble their mammalian counterparts than those of yeast in terms of structure and regulation. regulatory region yeast complemetation ribosome ribosomal protein Arabidopsis gene expression
98	Shiga-like Toxin 1: Molecular Mechanism of Toxicity and Discovery of Inhibitors McCluskey, Andrew 18 January 2012 (has links) Ribosome-inactivating proteins (RIPs) such as Shiga-like toxin 1 (SLT-1) halt protein synthesis in eukaryotic cells by depurinating a single adenine base in the sarcin-ricin loop of 28S rRNA. The molecular details involved in the ER lumenal escape and subsequent site-specific depurination are lacking, despite a general understanding of the biochemical basis of SLT-1 toxicity. Using a combination of yeast-2-hybrid and HeLa lysate pull-down followed by LC-MS/MS we have discovered yeast and human proteins that interact with the catalytic A1 chain of SLT-1. Yeast-2-hybrid library screens followed by the expression of full-length protein candidates and pull-down experiments yielded Cue2 as the only yeast cellular component that binds to the SLT-1 A1 chain. Further truncational analysis revealed that the known protein domains (two Cue domains and a Smr domain) within the primary sequence of Cue 2 were not essential for the interaction. Cue2 is a yeast monoubiquitin binding protein of no known function that is structurally homologous to the human ubiquitin-associated domain which has been implicated in intracellular routing and ER-associated degradation. Pull-down experiments indicated that the mechanism by which the catalytic domain of RIPs cleaves its substrate involves initial docking interactions with the ribosomal stalk by virtue of a conserved acidic C-terminal peptide domain common to all three stalk proteins P0, P1, and P2. The A1 chain of SLT-1 transiently binds to this peptide with a modest binding constant and rapid on and off rates. Mutagenesis of charged residues within the A1 chain identified a cationic surface that interacts with the peptide motif. In addition, phage-display was used to rapidly probe the importance of each residue within this C-terminal ribosomal peptide. The analysis revealed a complementary acidic surface and an additional hydrophobic motif involved in the interaction. Moreover, deletion mutagenesis performed on the ribosomal protein P0 revealed that the A1 chain binds to an alternate site on P0 in proximity to the contact sites for P1/P2 heterodimers. These results demonstrate that the catalytic chain of RIPs such as SLT-1 dock on ribosomes using two classes of binding sites located within the ribosomal stalk which may aid in orienting their catalytic domain in close proximity to the depurination site. ribosome inactivating protein toxin ribosomal stalk proteomics 0307
99	Shiga-like Toxin 1: Molecular Mechanism of Toxicity and Discovery of Inhibitors McCluskey, Andrew 18 January 2012 (has links) Ribosome-inactivating proteins (RIPs) such as Shiga-like toxin 1 (SLT-1) halt protein synthesis in eukaryotic cells by depurinating a single adenine base in the sarcin-ricin loop of 28S rRNA. The molecular details involved in the ER lumenal escape and subsequent site-specific depurination are lacking, despite a general understanding of the biochemical basis of SLT-1 toxicity. Using a combination of yeast-2-hybrid and HeLa lysate pull-down followed by LC-MS/MS we have discovered yeast and human proteins that interact with the catalytic A1 chain of SLT-1. Yeast-2-hybrid library screens followed by the expression of full-length protein candidates and pull-down experiments yielded Cue2 as the only yeast cellular component that binds to the SLT-1 A1 chain. Further truncational analysis revealed that the known protein domains (two Cue domains and a Smr domain) within the primary sequence of Cue 2 were not essential for the interaction. Cue2 is a yeast monoubiquitin binding protein of no known function that is structurally homologous to the human ubiquitin-associated domain which has been implicated in intracellular routing and ER-associated degradation. Pull-down experiments indicated that the mechanism by which the catalytic domain of RIPs cleaves its substrate involves initial docking interactions with the ribosomal stalk by virtue of a conserved acidic C-terminal peptide domain common to all three stalk proteins P0, P1, and P2. The A1 chain of SLT-1 transiently binds to this peptide with a modest binding constant and rapid on and off rates. Mutagenesis of charged residues within the A1 chain identified a cationic surface that interacts with the peptide motif. In addition, phage-display was used to rapidly probe the importance of each residue within this C-terminal ribosomal peptide. The analysis revealed a complementary acidic surface and an additional hydrophobic motif involved in the interaction. Moreover, deletion mutagenesis performed on the ribosomal protein P0 revealed that the A1 chain binds to an alternate site on P0 in proximity to the contact sites for P1/P2 heterodimers. These results demonstrate that the catalytic chain of RIPs such as SLT-1 dock on ribosomes using two classes of binding sites located within the ribosomal stalk which may aid in orienting their catalytic domain in close proximity to the depurination site. ribosome inactivating protein toxin ribosomal stalk proteomics 0307
100	Deconstructing the ribosome: specific interactions of a ribosomal RNA fragment with intact and fragmented L23 ribosomal protein Roy, Poorna 29 March 2013 (has links) The complexity of translation is a classical dilemma in the evolution of biological systems. Efficient translation requires coordination of complex, highly evolved RNAs and proteins; however, complex, highly evolved RNAs and proteins could not evolve without efficient translation system. At the heart of this complexity is the ribosome, itself a remarkably complex molecular machine. Our work illustrates the ribosome as deconstructed units of modification. Here we have deconstructed a segment of the ribosome to interacting RNA-protein units. L23 interacts in vivo with both Domain III (DIII) and Domain IIIcore (DIIIcore) independently of the fully assembled ribosome. This suggests that DIIIcore represents the functional rRNA unit in DIII-L23 interaction. Furthermore, L23peptide sustains binding function in vitro with both DIII and DIIIcore independently of any stabilizing effects from the globular domain of L23. The ability of L23peptide to form a 1:1 complex with both DIII and DIIIcore suggests that L23peptide is the functional rProtein unit in DIII-L23 interaction. We believe that our results will stimulate interest and discussions in the significance of 3D architecture and units of evolution in the ribosome. The ubiquity of the ribosome in cellular life prognosticates that our results impact and appeal to biologists, chemists, bioinformaticists, as well as the general scientific community. RNA Ribosome Yeast three-hybrid Evolution Nucleic acids Gene expression

Search results