Global ETD Search

1	Mitochondrial gene expression in trypanosomatids PROCHÁZKOVÁ, Michaela January 2018 (has links) This thesis comprises of diverse projects all focused towards analysis of mitochondrial translation in unicellular parasites. As only two mitochondrially encoded genes are required during the life cycle stage when Trypanosoma brucei resides in the bloodstream of a mammalian host, this protist provides a simplified background in which to study mitochondrial translation termination phase. The leading project utilizes T. brucei to examine mitochondrial translation termination factor TbMrf1 by gene knockout. Subsequently, it is suggested that the peptidyl-tRNA hydrolase TbPth4 is able to abate the TbMrf1 knockout phenotype by its ability to rescue mitoribosomes that become stalled when TbMrf1 is absent. Additionally, modifying methyltransferase of TbMrf1, the TbMTQ1, was characterized. And finally, this work contributed to the development of the protein expression regulation method in Leishmania parasites, a protocol for measurement of proton pumping activity of FoF1 ATPase complex in native mitochondria, and optimization of purification protocol for hydrophobic recombinant proteins.
2	Characterization of putative methyltransferase MT420 in \kur{Trypanosoma brucei.} PROCHÁZKOVÁ, Michaela January 2010 (has links) Localization and characterization of putative mitochondrial methzltransferase acc. No.: Tb10.6k15.0440 in Trypanosoma brucei was performed. Employed molecular methods included immunofluorescence, sub-cellular fractionation and tandem affinity purification. Protein was overexpressed in an E. coli expression system, using an in-fusion expression vector pOPINM with maltose binding protei (MBP) tag.
3	From Structure to Function with Binding Free Energy Calculations for Codon Reading, Riboswitches and Lectins Sund, Johan January 2013 (has links) Molecular association is part of many important processes in living cells. Computational methods for calculating binding free energies allows for a quantitative examination of biomolecular structures and hypotheses drawn from biochemical experiments. Here, binding free energy calculations for tRNAs and release factors binding to mRNA codons on the ribosome, sugars binding to lectins and purine analogs binding to the purine riboswitch are presented. The relative affinities between cognate and non-cognate tRNAs for different states involved in codon reading on the ribosome were determined. The calculations show that tRNA discrimination varies between different conformations of the 30S subunit, where the existence of both low and high selectivity states provides an efficient common mechanism for initial selection and proofreading. The simulations reveal a desolvation mechanism for the 30S conformational switch with which the accuracy of peptide bond formation can be amplified. When an mRNA stop codon (UAA, UAG or UGA) is located in the ribosomal A-site release factors bind to the ribosome and the synthesized protein is released. RF1 is specific for UAA and UAG whereas RF2 is specific for UAA and UGA. The free energy calculations and an analysis of the performed simulations show the mechanisms for how RF1 and RF2 are able to read the stop codons with different specificities. Also mitochondrial release factors were investigated. Vertebrate mitochondria have four stop codons, UAA, UAG, AGA and AGG and two release factors mtRF1 and mtRF1a. The calculations show how the specificities of both mtRF1 and mtRF1a agree with RF1 and that none of them are likely to read the non-standard stop codons AGA and AGG. The linear interaction energy method has also been examined for the RSL and PA-IIL lectins and for the purine riboswitch. The standard parameterization of the method works well for RSL, but fails for PA-IIL and the purine riboswitch due to compositions of the active sites in these systems. The development of new parameterizations to overcome these problems leads to a better understanding of both the method and the binding mechanisms in these systems. binding free energy ribosome codon reading release factor mitochondrial translation purine riboswitch lectin molecular dynamics free energy perturbation
4	Corticotropin Releasing Factor up-Regulates the Expression and Function of Norepinephrine Transporter in SK-N-Be (2) m17 Cells Huang, Jingjing, Tufan, Turan, Deng, Maoxian, Wright, Gary, Zhu, Meng Yang 01 October 2015 (has links) Corticotropin releasing factor (CRF) has been implicated to act as a neurotransmitter or modulator in central nervous activation during stress. In this study, we examined the regulatory effect of CRF on the expression and function of the norepinephrine transporter (NET) in vitro. SK-N-BE (2) M17 cells were exposed to different concentrations of CRF for different periods. Results showed that exposure of cells to CRF significantly increased mRNA and protein levels of NET in a concentration- and time-dependent manner. The CRF-induced increase in NET expression was mimicked by agonists of either CRF receptor 1 or 2. Furthermore, similar CRF treatments induced a parallel increase in the uptake of [3H] norepinephrine. Both increased expression and function of NET caused by CRF were abolished by simultaneous administration of CRF receptor antagonists, indicating a mediation by CRF receptors. However, there was no additive effect for the combination of both receptor antagonists. Chromatin immunoprecipitation assays confirm an increased acetylation of histone H3 on the NET promoter following treatment with CRF. Taken together, this study demonstrates that CRF up-regulates the expression and function of NET in vitro. This regulation is mediated through CRF receptors and an epigenetic mechanism related to histone acetylation may be involved. This CRF-induced regulation on NET expression and function may play a role in development of stress-related depression and anxiety. This study demonstrated that corticotropin release factor (CRF) up-regulated the expression and function of norepinephrine transporter (NET) in a concentration- and time-dependent manner, through activation of CRF receptors and possible histone acetylation in NET promoter. The results indicate that their interaction may play an important role in stress-related physiological and pathological status. This study demonstrated that corticotropin release factor (CRF) up-regulated the expression and function of norepinephrine transporter (NET) in a concentration- and time-dependent manner, through activation of CRF receptors and possible histone acetylation in NET promoter. The results indicate that their interaction may play an important role in stress-related physiological and pathological status. corticotropin release factor gene regulation noradrenergic neurons norepinephrine transporter SK-N-BE(2)M17 cells Biomedical Sciences
5	Versatile Implementations of an Improved Cell-Free System for Protein Biosynthesis : Functional and structural studies of ribosomal protein L11 and class II release factor RF3. Novel biotechnological approach for continuous protein biosynthesis / Mångsidig Användning av ett Förbättrat Cell-Fritt System för Proteinbiosyntes : Funktionella och strukturella studier av ribosomalt protein L11 och klass II release faktor RF3. Ny bioteknologisk metod för kontinuerlig proteinbiosyntes Bouakaz, Lamine January 2006 (has links) <p>Advances in genetics, proteomics and chromatography techniques have enabled the successfully generation of a cell-free bacterial translation system composed of highly pure and active components. This system provided an ideal platform for better elucidating the mechanism of each individual step of the prokaryotic protein biosynthesis and the function of the translation factors involved in the process. </p><p>In doing so, we have discovered that the N-terminal domain or complete deletions of the ribosomal protein L11 reduced the termination efficiency of RF1 on cognate stop codons by four to six folds. The L11 deletions also conferred a two folds decrease in the missense error suggesting the increased nonsense termination accuracy of RF2 by two folds, which would clarified previous in vivo observations. </p><p>The versatility of the cell-free system has provided the additional possibility to study the effects of class II release factor RF3 mutations in mediating fast dissociation of class I release factors RF1 and RF2 from the post-termination ribosome complexes. The results show a series of mutations within RF3 conferring considerable reduction of the class I release factors recycling rate. These observations together with sequence alignment studies suggest the possible location on RF3 of the class I release factors interaction site. </p><p>In addition, the utilization of the cell-free system has made it possible to develop a new biotechnological approach for continuous production of polypeptides, based on gel filtration chromatography. The pilot trials have so far resulted in a six fold production increase of the MFTI test peptide compared to the conventional batch method.</p> Molecular biology Protein synthesis translation termination ribosome release factor cell-free system missense error gel filtration affinity chromatography Molekylärbiologi Molecular biology Molekylärbiologi
6	Versatile Implementations of an Improved Cell-Free System for Protein Biosynthesis : Functional and structural studies of ribosomal protein L11 and class II release factor RF3. Novel biotechnological approach for continuous protein biosynthesis / Mångsidig Användning av ett Förbättrat Cell-Fritt System för Proteinbiosyntes : Funktionella och strukturella studier av ribosomalt protein L11 och klass II release faktor RF3. Ny bioteknologisk metod för kontinuerlig proteinbiosyntes Bouakaz, Lamine January 2006 (has links) Advances in genetics, proteomics and chromatography techniques have enabled the successfully generation of a cell-free bacterial translation system composed of highly pure and active components. This system provided an ideal platform for better elucidating the mechanism of each individual step of the prokaryotic protein biosynthesis and the function of the translation factors involved in the process. In doing so, we have discovered that the N-terminal domain or complete deletions of the ribosomal protein L11 reduced the termination efficiency of RF1 on cognate stop codons by four to six folds. The L11 deletions also conferred a two folds decrease in the missense error suggesting the increased nonsense termination accuracy of RF2 by two folds, which would clarified previous in vivo observations. The versatility of the cell-free system has provided the additional possibility to study the effects of class II release factor RF3 mutations in mediating fast dissociation of class I release factors RF1 and RF2 from the post-termination ribosome complexes. The results show a series of mutations within RF3 conferring considerable reduction of the class I release factors recycling rate. These observations together with sequence alignment studies suggest the possible location on RF3 of the class I release factors interaction site. In addition, the utilization of the cell-free system has made it possible to develop a new biotechnological approach for continuous production of polypeptides, based on gel filtration chromatography. The pilot trials have so far resulted in a six fold production increase of the MFTI test peptide compared to the conventional batch method. Molecular biology Protein synthesis translation termination ribosome release factor cell-free system missense error gel filtration affinity chromatography Molekylärbiologi Molecular biology Molekylärbiologi
7	Computational Analysis of Molecular Recognition Involving the Ribosome and a Voltage Gated K+ Channel Andér, Martin January 2009 (has links) Over the last few decades, computer simulation techniques have been established as an essential tool for understanding biochemical processes. This thesis deals mainly with the application of free energy calculations to ribosomal complexes and a cardiac ion channel. The linear interaction energy (LIE) method is used to explore the energetic properties of the essential process of codon–anticodon recognition on the ribosome. The calculations show the structural and energetic consequences and effects of first, second, and third position mismatches in the ribosomal decoding center. Recognition of stop codons by ribosomal termination complexes is fundamentally different from sense codon recognition. Free energy perturbation simulations are used to study the detailed energetics of stop codon recognition by the bacterial ribosomal release factors RF1 and RF2. The calculations explain the vastly different responses to third codon position A to G substitutions by RF1 and RF2. Also, previously unknown highly specific water interactions are identified. The GGQ loop of ribosomal RFs is essential for its hydrolytic activity and contains a universally methylated glutamine residue. The structural effect of this methylation is investigated. The results strongly suggest that the methylation has no effect on the intrinsic conformation of the GGQ loop, and, thus, that its sole purpose is to enhance interactions in the ribosomal termination complex. A first microscopic, atomic level, analysis of blocker binding to the pharmaceutically interesting potassium ion channel Kv1.5 is presented. A previously unknown uniform binding mode is identified, and experimental binding data is accurately reproduced. Furthermore, problems associated with pharmacophore models based on minimized gas phase ligand conformations are highlighted. Generalized Born and Poisson–Boltzmann continuum models are incorporated into the LIE method to enable implicit treatment of solvent, in an effort to improve speed and convergence. The methods are evaluated and validated using a set of plasmepsin II inhibitors. computer simulations molecular dynamics ligand binding binding free energy linear interaction energy codon recognition translation termination release factor voltage gated potassium ion channel Kv1.5 Structural biology Strukturbiologi Biochemistry Biokemi
8	Computational Studies of Protein Synthesis on the Ribosome and Ligand Binding to Riboswitches Lind, Christoffer January 2017 (has links) The ribosome is a macromolecular machine that produces proteins in all kingdoms of life. The proteins, in turn, control the biochemical processes within the cell. It is thus of extreme importance that the machine that makes the proteins works with high precision. By using three dimensional structures of the ribosome and homology modelling, we have applied molecular dynamics simulations and free-energy calculations to study the codon specificity of protein synthesis in initiation and termination on an atomistic level. In addition, we have examined the binding of small molecules to riboswitches, which can change the expression of an mRNA. The relative affinities on the ribosome between the eukaryotic initiator tRNA to the AUG start codon and six near-cognate codons were determined. The free-energy calculations show that the initiator tRNA has a strong preference for the start codon, but requires assistance from initiation factors 1 and 1A to uphold discrimination against near-cognate codons. When instead a stop codon (UAA, UGA or UAG) is positioned in the ribosomal A-site, a release factor binds and terminates protein synthesis by hydrolyzing the nascent peptide chain. However, vertebrate mitochondria have been thought to have four stop codons, namely AGA and AGG in addition to the standard UAA and UAG codons. Furthermore, two release factors have been identified, mtRF1 and mtRF1a. Free-energy calculations were used to determine if any of these two factors could bind to the two non-standard stop codons, and thereby terminate protein synthesis. Our calculations showed that the mtRF’s have similar stop codon specificity as bacterial RF1 and that it is highly unlikely that the mtRF’s are responsible for terminating at the AGA and AGG stop codons. The eukaryotic release factor 1, eRF1, on the other hand, can read all three stop codons singlehandedly. We show that eRF1 exerts a high discrimination against near-cognate codons, while having little preference for the different cognate stop codons. We also found an energetic mechanism for avoiding misreading of the UGG codon and could identify a conserved cluster of hydrophobic amino acids which prevents excessive solvent molecules to enter the codon binding site. The linear interaction energy method was used to examine binding of small molecules to the purine riboswitch and the FEP method was employed to explicitly calculate the LIE b-parameters. We show that the purine riboswitches have a remarkably high degree of electrostatic preorganization for their cognate ligands which is fundamental for discriminating against different purine analogs. Binding free energy Ribosome Codon reading Translation initiation Translation termination Mitochondrial translation Release factor Purine riboswitch Molecular Dynamics Free Energy Perturbation Biochemistry and Molecular Biology Biokemi och molekylärbiologi Bioinformatics (Computational Biology) Bioinformatik (beräkningsbiologi)
9	Orthogonality and Codon Preference of the Pyrrolysyl-tRNA Synthetase-tRNAPyl pair in Escherichia coli for the Genetic Code Expansion Odoi, Keturah 2012 May 1900 (has links) Systematic studies of basal nonsense suppression, orthogonality of tRNAPyl variants, and cross recognition between codons and tRNA anticodons are reported. E. coli displays detectable basal amber and opal suppression but shows a negligible ochre suppression. Although detectable, basal amber suppression is fully inhibited when a pyrrolysyl-tRNA synthetase (PylRS)-tRNAPyl_CUA pair is genetically encoded. trnaPyl_CUA is aminoacylated by an E. coli aminoacyl-tRNA synthetase at a low level, however, this misaminoacylation is fully inhibited when both PylRS and its substrate are present. Besides that it is fully orthogonal in E. coli and can be coupled with PylRS to genetically incorporate a NAA at an ochre codon, tRNAPyl_UUA is not able to recognize an UAG codon to induce amber suppression. This observation is in direct conflict with the wobble base pair hypothesis and enables using an evolved M. jannaschii tyrosyl-tRNA synthetase-tRNAPyl_UUA pair and the wild type or evolved PylRS-tRNAPyl_UUA pair to genetically incorporate two different NAAs at amber and ochre codons. tRNAPyl_UCA is charged by E. coli tryptophanyl-tRNA synthetase, thus not orthogonal in E. coli. Mutagenic studies of trnaPyl_UCA led to the discovery of its G73U form which shows a higher orthogonality. Mutating trnaPyl_CUA to trnaPyl_UCCU not only leads to the loss of the relative orthogonality of tRNAPyl in E. coli but also abolishes its aminoacylation by PylRS. Pyl, pyrrolysine PylRS, pyrrolysyl-tRNA synthetase NAA, noncanonical amino acid aaRS, aminoacyl-tRNA synthetase T4 PNK, T4 polynucleotide kinase AzF, para-azido-L-phenylalanine PCR, polymerase chain reaction RF, release factor TrpRS, tryptophanyl-tRNA synthetase ArgRS, arginyl-tRNA synthetase Trp, tryptophan Lys, lysine Glu, glutamate Gln, glutamine Phe, phenylalanine Arg, arginine.

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