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Mechanisms and Inhibition of EF-G-dependent Translocation and Recycling of the Bacterial RibosomeBorg, Anneli January 2015 (has links)
The GTPase elongation factor G (EF-G) is an important player in the complex process of protein synthesis by bacterial ribosomes. Although extensively studied much remains to be learned about this fascinating protein. In the elongation phase, after incorporation of each amino acid into the growing peptide chain, EF-G translocates the ribosome along the mRNA template. In the recycling phase, when the synthesis of a protein has been completed, EF-G, together with ribosome recycling factor (RRF), splits the ribosome into its subunits. We developed the first in vitro assay for measuring the average time of a complete translocation step at any position along the mRNA. Inside the open reading frame, at saturating EF-G concentration and low magnesium ion concentration, translocation rates were fast and compatible with elongation rates observed in vivo. We also determined the complete kinetic mechanism for EF-G- and RRF-dependent splitting of the post-termination ribosome. We showed that splitting occurs only when RRF binds before EF-G and that the rate and GTP consumption of the reaction varies greatly with the factor concentrations. The antibiotic fusidic acid (FA) inhibits bacterial protein synthesis by binding to EF-G when the factor is ribosome bound, during translocation and ribosome recycling. We developed experimental methods and a theoretical framework for analyzing the effect of tight-binding inhibitors like FA on protein synthesis. We found that FA targets three different states during each elongation cycle and that it binds to EF-G on the post-termination ribosome both in the presence and absence of RRF. The stalling time of an FA-inhibited ribosome is about hundred-fold longer than the time of an uninhibited elongation cycle and therefore each binding event has a large impact on the protein synthesis rate and may induce queuing of ribosomes on the mRNA. Although ribosomes in the elongation and the recycling phases are targeted with similar efficiency, we showed that the main effect of FA in vivo is on elongation. Our results may serve as a basis for modelling of EF-G function and FA inhibition inside the living cell and for structure determination of mechanistically important intermediate states in translocation and ribosome recycling.
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Biochemical Studies Of Abce1Sims, Lynn 01 January 2012 (has links)
The growth and survival of all cells require functional ribosomes that are capable of protein synthesis. The disruption of the steps required for the function of ribosomes represents a potential future target for pharmacological anti-cancer therapy. ABCE1 is an essential Fe-S protein involved in ribosomal function and is vital for protein synthesis and cell survival. Thus, ABCE1 is potentially a great therapeutic target for cancer treatment. Previously, cell biological, genetic, and structural studies uncovered the general importance of ABCE1, although the exact function of the Fe-S clusters was previously unclear, only a simple structural role was suggested. Additionally, due to the essential nature of ABCE1, its function in ribosome biogenesis, ribosome recycling, and the presence of Fe-S within ABCE1, the protein has been hypothesized to be a target for oxidative degradation by ROS and critically impact cellular function. In an effort to better understand the function of ABCE1 and its associated Fe-S cofactors, the goal of this research was to achieve a better biochemical understanding of the Fe-S clusters of ABCE1. The kinetics of the ATPase activity for the Pyrococcus abyssi ABCE1 (PabABCE1) was studied using both apo- (without reconstituted Fe-S clusters) and holo- (with full complement of Fe-S clusters reconstituted post-purification) forms, and is shown to be jointly regulated by the status of Fe-S clusters and Mg2+. Typically, ATPases require Mg2+, as is true for PabABCE1, but Mg2+ also acts as a unusual negative allosteric effector that modulates ATP affinity of PabABCE1. Comparative kinetic analysis of Mg2+ inhibition shows differences in the degree of allosteric regulation between the apo- and holo-PabABCE1 where the apparent Km for ATP of apo- iv PabABCE1 increases >30 fold from ~30 µM to over 1 mM when in the presence of physiologically relevant concentrations of Mg2+. This effect would significantly convert the ATPase activity of PabABCE1 from being independent of cellular energy charge () to being dependent on with cellular [Mg2+]. The effect of ROS on the Fe-S clusters within ABCE1 from Saccharomyces cerevisiae was studied by in vivo 55Fe labeling. A dose and time dependent depletion of ABCE1 bound 55Fe after exposure to H2O2 was discovered, suggesting the progressive degradation of Fe-S clusters under oxidative stress conditions. Furthermore, our experiments show growth recovery, upon removal of the H2O2, reaching a growth rate close to that of untreated cells after ~8 hrs. Additionally, a corresponding increase (~88% recovery) in the ABCE1 bound 55Fe (Fe-S) was demonstrated. Observations presented in this work demonstrate that the majority of growth inhibition, induced by oxidative stress, can be explained by a comparable decrease in ABCE1 bound 55Fe and likely loss of ABCE1 activity that is necessary for normal ribosomal activity. The regulatory roles of the Fe-S clusters with ABCE1 provide the cell a way to modulate the activity of ABCE1 and effectively regulate translation based on both cellular energy charge and the redox state of the cell. Intricate overlapping effects by both [Mg2+] and the status of Fe-S clusters regulate ABCE1’s ATPase activity and suggest a regulatory mechanism, where under oxidative stress conditions, the translational activity of ABCE1 can be inhibited by oxidative degradation of the Fe-S clusters. These findings uncover the regulatory function of the Fe-S clusters with v ABCE1, providing important clues needed for the development of pharmacological agents toward ABCE1 targeted anti-cancer therapy.
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Structural Studies on Mycobacterium Tuberculosis Peptidyl-tRNA Hydrolase and Ribosome Recycling Factor, Two Proteins Involved in TranslationSelvaraj, M January 2013 (has links) (PDF)
Protein synthesis is a process by which organisms manufacture their proteins that perform various cellular activities either alone or in combination with other similar or different molecules. In eubacteria, protein synthesis proceeds at a rate of around 15 amino acids per second. The ribosomes, charged tRNAs and mRNAs can be considered as the core components of protein synthesis system which, in addition, involves a panel of non-ribosomal proteins that regulate the speed, specificity and accuracy of the process. Peptidyl-tRNA hydrolase (Pth) and ribosome recycling factor (RRF) are two such non-ribosomal proteins involved in protein synthesis. These two proteins are essential for eubacterial survival and the work reported in this thesis involves structural characterization of these two proteins from the bacterial pathogen, Mycobacterium tuberculosis.
The protein structures were solved using established techniques of protein crystallography. Hanging drop vapour diffusion method and crystallization under oil using microbatch plates were the methods employed for protein crystallization. X-ray intensity data were collected on a MAR Research imaging plate mounted on a Rigaku RU200 X-ray generator in all the cases. The data were processed using DENZO and MOSFLM. The structures were solved by molecular replacement method using the program PHASER. Structure refinements were carried out using programs CNS and REFMAC. Model building was carried out using COOT. PROCHECK, ALIGN, CHIMERA, and PYMOL were used for structure validation and analysis of the refined structures.
Peptidyl-tRNA hydrolase cleaves the ester bond between tRNA and the attached peptide in peptidyl-tRNA that has dropped off from ribosome before reaching the stop codon, in order to avoid the toxicity resulting from peptidyl-tRNA accumulation and to free the tRNA to make it available for further rounds in protein synthesis. To begin with, the structure of the enzyme from M. tuberculosis (MtPth) was determined in three crystal forms. This structure and the structure of the same enzyme from Escherichia coli (EcPth) in its crystal differ substantially on account of the binding of the C-terminus of the E.coli enzyme to the peptide binding site of a neighboring molecule in the crystal. A detailed examination of this difference led to an elucidation of the plasticity of the binding site of the enzyme. The peptide-binding site of the enzyme is a cleft between the body of the molecule and a polypeptide stretch involving a loop and a helix. This stretch is in open conformation when the enzyme is in the free state as in the crystals of MtPth. Furthermore, there is no physical continuity between the tRNA and the peptide-binding sites. The molecule in the EcPth crystal mimics the peptide-bound conformation of the enzyme. The peptide stretch involving a loop and a helix, referred to earlier, now closes on the bound peptide. Concurrently, a gate connecting the tRNA and the peptide-binding site opens primarily through the concerted movement of the two residues. Thus, the crystal structure of MtPth when compared with that of EcPth, leads to a model of structural changes associated with enzyme action on the basis of the plasticity of the molecule.
A discrepancy between the X-ray results and NMR results, which subsequently became available, led to X-ray studies on new crystal forms of the enzyme. The results of these studies and those of the enzyme from different sources that became available, confirmed the connection deduced previously between the closure of the lid at the peptide-binding site and the opening of the gate that separates the peptide-binding site and tRNA binding site. The plasticity of the molecule indicated by X-ray structures is in general agreement with that deduced from the available solution NMR results. The correlation between the lid and the gate movement is not, however, observed in the NMR structure of MtPth.
The discrepancy between the X-ray and NMR structures of MtPth in relation to the functionally important plasticity of the molecule, referred to earlier, also led to molecular dynamics simulations. The X-ray and the NMR studies along with the simulations indicated an inverse correlation between crowding and molecular volume. A detailed comparison of proteins for which X-ray and the NMR structures are available appears to confirm this correlation. In consonance with the reported results of the investigation in cellular components and aqueous solutions, the comparison indicates that the crowding results in compaction of the molecule as well as change in its shape, which could specifically involve regions of the molecule important for function. Crowding could thus influence the action of proteins through modulation of the functionally important plasticity of the molecule.
After termination of protein synthesis at the stop codon, the ribosome remains as a post-termination complex (PoTC), consisting of the 30S and the 50S subunits, mRNA and a deacylated tRNA. This complex has to be disassembled so that the ribosome is available for the next round of translation initiation. Ribosome recycling factor (RRF) binds to ribosome and in concert with elongation factor G (EF.G), performs the recycling of ribosome that results in disassembly of PoTC. The structure of this L-shaped protein with two domains connected by a hinge, from Mycobacterium tuberculosis (MtRRF) was solved previously in our laboratory. The relative movement of domains lies at the heart of RRF function. Three salt bridges were hypothesized to reduce the flexibility of MtRRF when compared to the protein from E.coli (EcRRF), which has only one such salt bridge. Out of these three bridges, two are between domain 1 and domain 2, whereas the third is between the hinge region and the C-terminus of the molecule. These salt bridges were disrupted with appropriate mutations and the structure and activity of the mutants and their ability to complement EcRRF were explored. An inactive C-terminal deletion mutant of MtRRF was also studied. Major, but different, structural changes were observed in the C-terminal deletion mutant and the mutant involving the hinge region. Unlike the wild type protein and the other mutants, the hinge mutant complements EcRRF. This appears to result from the increased mobility of the domains in the mutant, as evidenced by the results of librational analysis.
In addition to the work on PTH and RRF, the author was involved during the period of studentship in carrying out X-ray studies of crystalline complexes involving amino acids and carboxylic acids, which is described in the Appendix of the thesis. The complexes studied are that of tartaric acid with arginine and lysine.
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Mechanism Of Ribosome Recycling In Eubacteria, And The Impact Of rRNA Methylations On Ribosome Recycling And Fidelity Of Initiation In Esherichia coliAnuradha, S 02 1900 (has links)
The studies reported in this thesis address, firstly, aspects of ribosome recycling in eubacteria, and secondly, a preliminary characterization of an EFG-like locus from Mycobacterium smegmatis. A hitherto unsuspected role of the ribosome recycling factor in governing the fidelity of initiation has been discovered during the course of this work. A summary of the relevant literature is presented in chapter 1. Section I of the ‘General Introduction’ provides a brief review of the current understanding of protein biosynthesis, with a special emphasis on ribosome recycling and the fidelity of translation initiation. Section II provides a brief introduction to mycobacterial translation, and known deviations from the E. coli prototype are highlighted. This is followed by three chapters containing experimental work, as summarized below.
(i) Role of elongation factor G in governing specificity of ribosome recycling
In eubacteria and the eukaryotic organelles, the post-termination ribosome complexes are recycled by the combined action of ribosome recycling factor (RRF) and elongation factor G (EFG). Earlier studies both from our laboratory and other laboratories have revealed the existence of specific interactions between RRF and EFG that are crucial for ribosome recycling, using ribosomes from E. coli and factors from both E. coli and heterologous sources such as Mycobacterium tuberculosis, Thermus thermophilus etc. In this study, to further understand the mechanism of ribosome recycling, we employed polysomes from both E. coli and M. smegmatis and monitored ribosome recycling in in vitro assays using RRF and EFG from both these sources; in addition, in vivo assays were performed in E. coli using either temperature-sensitive strains or strains carrying a deletion in frr (encoding RRF) or fusA (encoding EFG) genes. It was found that, in E. coli, RRF from Mycobacterium tuberculosis and M. smegmatis function with MtuEFG or MsmEFG but not with EcoEFG. In vitro assays revealed that the mycobacterial EFGs facilitate recycling of both the mycobacterial and E. coli polysomes not only with mycobacterial RRFs but also with EcoRRF. In contrast, although EcoEFG binds to mycobacterial polysomes, carries out GTP hydrolysis and is reported to sustain translocation on mycobacterial ribosomes, its activity in recycling mycobacterial polysomes was undetectable with EcoRRF, as well as with the mycobacterial RRFs. Such an observation allowed us to infer that EFG establishes specific interactions with the ribosome that are crucial for ribosome recycling but not for translocation, suggesting that translocation and ribosome recycling are distinct functions of EFG. In addition, a number of EFG chimeras generated by swapping corresponding domains between Msm- and Eco-EFGs were analyzed for their ability to sustain translocation and/or ribosome recycling in E. coli and M. smegmatis, using a combination of in vivo (for E. coli) and in vitro (for both E. coli and M. smegmatis) approaches. Our observations reveal that a dual set of specific interactions of EFG with RRF and ribosome is essential for ribosome recycling. While the RRF-EFG specific interactions are predominantly localized to the domains IV and V of EFG, the EFG-ribosome specific interactions that are crucial for ribosome recycling are not localized to a specific region of EFG but are found throughout the molecule. Our novel observations also emphasize the importance of using ribosomes from heterologous sources to understand the mechanism of this crucial process.
(ii) Impact of rRNA methylations on ribosome recycling and fidelity of initiation in Escherichia coli
Ribosomal RNA (rRNA) contains a number of modified nucleosides in functionally important regions including the intersubunit bridge regions; however, very little is known about the role of these rRNA modifications in ribosome function. As the activity of ribosome recycling factor (RRF) in separating the large and the small subunits of the ribosome involves disruption of the intersubunit bridges, we investigated the impact of rRNA methylations on ribosome recycling. The isolation of a folD122 mutant strain of E. coli with a deficiency in rRNA methylations, as well as the availability of E. coli strains deficient for various individual methyltransferases that modify specific rRNA residues, provided us with a genetic tool to assay the role of rRNA methylations in ribosome recycling. We observed that deficiency of rRNA methylations, especially at positions 1518 and 1519 of 16S rRNA near the interface with the 50S subunit and in the vicinity of the IF3 binding site, adversely affects the efficiency of RRF-mediated ribosome recycling. In addition, a compromise in the RRF activity was found to afford increased initiation with a mutant tRNAfMet wherein the three consecutive G-C base pairs (29GGG31:39CCC41), a highly conserved feature of the initiator tRNAs, were mutated to those found in the elongator tRNAMet (29UCA31:39ψGA41). This observation has allowed us to uncover a new role of RRF as a factor that contributes to fidelity of initiator tRNA selection on the ribosome. In addition, it was also found that IF3 and rRNA methylations, both of which are known to affect fidelity of initiation, exert their effects through distinct mechanisms, despite the proximity of a cluster of methylated rRNA residues to the IF3 binding site on the 30S subunit.
(iii) Characterization of the role of EFG2, an EFG-like locus in Mycobacterium smegmatis
Several bacteria, including various species of mycobacteria (with the exception of Mycobacterium leprae) contain a second EFG-like locus, denoted as fusA2, which shows considerable homology to fusA (encoding EFG). A comparison of the sequences of EFG and EFG2 from various bacteria reveals that EFG2 contains a GTPase domain and domains with significant homology to EFG domains IV and V, suggesting that it may function as an elongation factor. With the single exception of a recent study on Thermus thermophilus EFG2, this class of EFG-like protein factors has not been studied so far. Hence, it was of interest to characterize EFG2. In the current study, EFG2 from M. smegmatis was characterized both by in vitro biochemical assays as well as by in vivo experiments targeted to investigate the biological significance of EFG2 in mycobacteria. It was found that, unlike EFG, MsmEFG2 could not sustain either translocation or ribosome recycling in E. coli. Despite the fact that the purified MsmEFG2 could bind guanine nucleotides, it lacked the ribosome-dependent GTPase activity characteristic of EFG and other translation GTPases, suggesting that it was unlikely to function as an elongation factor. However, EFG2 was found to be expressed in stationary phase cultures of M. smegmatis. To understand the biological significance of EFG2, fusA2 was disrupted in M. smegmatis. The viability of the M. smegmatis mc2155 fusA2::kan derivative indicates that MsmfusA2 is a non-essential gene. While disruption of the fusA2 gene (encoding EFG2) in M. smegmatis does not appear to affect its growth and survival in log phase or stationary phase or under hypoxic conditions, preliminary experiments indicate that disruption of fusA2 confers a fitness disadvantage to M. smegmatis when competed against M. smegmatis mc2155 (with wild type fusA2 locus).
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Mechanism of Recycling of Ribosomes Stalled on mRNAs in Escherichia ColiSingh, Nongmaithem Sadananda January 2007 (has links) (PDF)
Studies reported in this thesis address the question of how pre-termination ribosomal complexes stalled during translation of mRNA are recycled. The process of recycling of the stalled ribosomes involves many translational factors. During the course of my studies, I have uncovered new roles of SsrA (tmRNA), IF3 and ribosome recycling factor (RRF) in recycling stalled ribosomes. These findings are summarized as follows:
(i) A physiological connection between tmRNA and peptidyl-tRNA hydrolase functions in
Escherichia coli
The bacterial ssrA gene codes for a dual function RNA, tmRNA, which possesses tRNA-like and mRNA-like regions. The tmRNA appends an oligopeptide tag to the polypeptide on the P-site tRNA by a trans-translation process that rescues ribosomes stalled on mRNAs and targets the aberrant protein for degradation. In cells, processing of the stalled ribosomes is also pioneered by drop-off of peptidyl-tRNAs. The ester bond linking the peptide to tRNA is hydrolyzed by peptidyl-tRNA hydrolase (Pth), an essential enzyme, which releases the tRNA and the aberrant peptide. As the trans-translation mechanism utilizes the peptidyl-transferase activity of the stalled ribosomes to free the tRNA (as opposed to peptidyl-tRNA drop-off), the need for Pth to recycle such tRNAs is bypassed. Thus, we hypothesized that tmRNA may rescue a defect in Pth. The findings of the experiments detailed in this thesis show that SsrA rescues a defect in Pth by reducing the peptidyl-tRNA load on Pth.
(ii) Evidence for a role of initiation factor 3 in recycling ribosomal complexes stalled on mRNAs in Escherichia coli.
Specific interactions between ribosome recycling factor (RRF) and EF-G mediate disassembly of post-termination ribosomal complexes for new rounds of initiation. The
interactions between RRF and EF-G are also important in peptidyl-tRNA release from pre-termination complexes. Unlike the post-termination complexes (harboring tRNA), the pre-termination complexes (harboring peptidyl-tRNA) are not recycled by RRF and EF-G in vitro, suggesting participation of additional factor(s) in the process. Using a combination of biochemical and genetic approaches, we show that, 1. Inclusion of IF3 with RRF and EF-G results in recycling of the pre-termination complexes; 2. IF3 overexpression in Escherichia coli LJ14 rescues its temperature sensitive phenotype for RRF; (3) Transduction of infC135 (encoding functionally compromised IF3) in E. coli LJ14 generates a ‘synthetic severe’ phenotype; (4) The infC135 and frr1 (a promoter down RRF gene) alleles synergistically rescue a temperature sensitive mutation in peptidyl-tRNA hydrolase in E. coli; and (5) IF3 facilitates ribosome recycling by Thermus thermophilus RRF and E. coli EFG in vivo and in vitro. These lines of evidence clearly demonstrate the physiological importance of IF3 in the overall mechanism of ribosome recycling in E. coli.
(iii) The role of RRF in dissociating of pre-termination ribosomal complexes stalled during elongation
Translating ribosomes often stall during the repetitive steps of elongation for various reasons. The stalled ribosomes are rescued by the process of trans-translation involving tmRNA (SsrA) or by a factor mediated dissociation of the stalled ribosome into its subunits leading to the drop-off of the peptidyl-tRNA. The mechanistic details of how the factor mediated dissociation is carried out, is not well studied. Studies described in the above section have highlighted the role of RRF in dissociating stalled pre-termination complexes. However, the in vivo studies in this area have been limited for lack of defined pre-termination complexes. Two in vivo systems based on translation of AGA minigene and the ung gene (EcoUngstopless) transcripts were designed. Evidence is presented to show that translation of both of these transcripts is toxic to E. coli because of the accumulation of the transcript specific stalled pre-termination complexes. Availability of these model systems has allowed us to address the role of RRF in dissociating stalled ribosomes. We show that RRF rescues stalled ribosomes on these constructs and its overexpression can rescue the toxicity. The physiological importance of this observation is highlighted by the rescue of AGA minigene inhibitory effect on λimmP22 hybrid phage growth upon RRF overexpression.
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Structural Studies On Mycobacterial ProteinsSaikrishnan, K 01 1900 (has links) (PDF)
No description available.
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