Global ETD Search

191	Triagem de enzimas associadas à biotransformação de hidrocarbonetos a partir de metagenoma de sedimentos contaminados com petroléo e metais pesados / Screening of Enzymes Related to Biotransformation of Hydrocarbons from Metagenome of Contaminated Sediments with Oil and Heavy Metals Simões, Tiago Henrique Nogueira 08 July 2009 (has links) A metagenômica trouxe novas perspectivas ao estudo de comunidades microbianas no ambiente, permitindo explorar tanto a diversidade taxonômica de microrganismos ainda não-cultivados, como o acesso direto a genes e vias metabólicas. Neste trabalho, foram construídas bibliotecas metagenômicas a partir de amostras de sedimentos de mangue da Baía de Guanabara (RJ), impactadas com hidrocarbonetos de petróleo e metais pesados. Proteobacteria (33,3%), bactérias afiliadas a redutoras-de-sulfato (29,7%) e Firmicutes (20%) representaram os grupos principais nas amostras ambientais, baseado em análises filogenéticas de rDNA 16S, ao passo que isolamentos seletivos utilizando diesel e naftaleno permitiram a recuperação preferencial de delta-Proteobacteria e actinomicetos. Bibliotecas metagenômicas dos sedimentos enriquecidos com óleo diesel, com insertos entre 25 e 35 Kb clonados em fosmídeos, foram triadas para detecção de genes catabólicos de monoxigenases (alkB1) e expressão de epóxido-hidrolases, esterases, lipases e monoxigenases em ensaios de alto desempenho (HTS, high throughput screening). Clones reativos a alkB1 foram detectados, porém não foram funcionais nas condições de HTS testadas. Nas bibliotecas de fosmídeos triadas, vários clones apresentaram atividade enzimática, sendo que dois apresentaram atividade de lipase-esterase com alta seletividade, elevada taxa de conversão de substratos e excesso enantiomérico (ee >99%). Os resultados de HTS comprovaram a eficiência do uso da clonagem direta de DNA ambiental na expressão de vias metabólicas de interesse com potencial de aplicação biotecnológica. / Metagenomics brought a new perspective to the study of microbial communities in the environment, enabling access to the taxonomic diversity of uncultured microorganisms, as well as direct access to genes and metabolic pathways. In the current study, metagenomic libraries were constructed from mangrove sediment samples of the Guanabara Bay (RJ, Brazil), impacted with oil hydrocarbons and heavy metals. Proteobacteria (33.3%), sulfate-reducing affiliated bacteria (29.7%) and Firmicutes (20%) represented the main groups in the environmental samples based upon 16S rDNA phylogenetic analysis, whereas selective isolation using diesel and naphtalene yielded delta-Proteobacteria and actinomycetes. Metagenomic libraries of diesel-enriched sediment samples, with 25 to 35 Kb fosmid inserts, were screened for detecting monooxigenase genes (alkB1) and expression of epoxide hydrolases, esterases, lipases and monooxigenases in high throughput screening (HTS) assays. Clones reactive to the alkB1 probe were detected, but were not functional under the HTS conditions used. Several functional clones were detected in the clone library, and two showed lipase-esterase activity with high rates of substrate conversion and enantiomeric ratio (ee >99%). The results obtained on HTS showed the efficiency of the direct cloning of environmental DNA for the expression of metabolic pathways with potential biotechnological application. 16S Rdna 16S Rdna Bibliotecas metagenômicas Epoxide- hydrolase Epoxido-hidrolases Esterases High throughput screening Lipase Metagenomic libraries Monooxigenase Monoxigenases Triagem de alto desempenho
192	Endocannabinoid-Like Lipids in Plants Chilufya, Jedaidah Y., Devaiah, Shivakumar P., Sante, Richard R., Kilaru, Aruna 15 October 2015 (has links) Classically, endogenous fatty acid ethanolamides and their derivatives that bind to the cannabinoid receptors and trigger a signalling pathway are referred to as endocannabinoids. Although derivatives of arachidonic acid, including arachidonylethanolamine or anandamide, are the known endogenous ligands for cannabinoid receptors, other fatty acid ethanolamides or N-acylethanolamines (NAE) that vary in carbon chain length and saturation occur ubiquitously in eukaryotic organisms and play an important role in their physiology and development. The metabolic pathway for NAEs is highly conserved among eukaryotes and well characterised in mammalian systems. Although NAE pathway is only partly elucidated in plants, significant progress has been made in the past 20 years in understanding the implications of the metabolism of saturated and unsaturated endocannabinoid-like molecules in plant development and growth. The latest advancements in the field of plant endocannabinoid research are reviewed. Key Concepts Endocannabinoids are endogenous ligands of cannabinoid receptors in mammalian systems. Endocannabinoids belong to a class of small bioactive lipid molecules that are derivatives of fatty acids including their ethanolamides, referred to as N-acylethanolamines. N-Acylethanolamines are ubiquitous and their metabolic pathway is highly conserved among eukaryotes. In higher plants, only 12–18C N-acylethanolamines have been identified and their metabolic pathway is partly elucidated. The endocannabinoid-like lipids play an important role in seed germination, seedling development, flowering and cellular organisation. In plants, N-acylethanolamines also participate in mediating responses to biotic and abiotic stress. anandamide cannabinoid receptor endocannabinoid fatty acid amide hydrolase fatty acid ethanolamide lipoxygenase N-acylethanolamine N-acylphosphatidylethanolamine oxylipins plant lipid signalling Biological Sciences Biology
193	Investigation of genes and proteins involved in xylan biosynthesis Winzell, Anders January 2010 (has links) Wood formation or xylogenesis is a fundamental process for so diverse issues as industry, shelter and a sustainable environment. Wood is comprised of secondary xylem, rigid large cells with thick cell walls that are lignified. The basis for the sturdy cells is an advanced composite made up of cellulose fibers cross-linked by hemicelluloses and finally embedded in lignin. This fiber-composite is the secondary cell walls of woody plants. Cell division and differentiation is regulated by switching on and off genes. Proteins encoded by these genes execute the major functions in the cells. They steer the entire machinery operating the structure and function of the cells, maintaining growth and synthesising essential products such as the cell wall carbohydrates. Here we describe the investigation of genes and proteins involved in xylan formation as well as the development of a model system that will aid the functional analysis of wood formation. Xylan is the main hemicellulose or cross linking glycan in dicot wood and thereby one of the most abundant carbohydrates on earth. We demonstrate that hybrid aspen cell suspension cultures can be used as a model system for secondary cell wall formation. We have also examined glycosyltransferases from CAZy family 43 that play a part in secondary cell wall formation. We have focused on one of these, Pt×tGT43A, a likely ortholog of Arabidopsis IRX9, which plays a crucial role in xylan formation. The protein was transiently expressed in Nicotiana benthamiana and its function and localization is described. Also, we investigate a glycoside hydrolase, Pt×tXyn10A, involved in wood formation. Its role is not clear but it most likely modifies xylan as it gets incorporated into the secondary cell wall after secretion from the Golgi. This influences the interaction between cellulose, xylan and lignin in the finished wood cell. We have also cloned a transcription factor, Pt×tMYB021, a likely ortholog of Arabidopsis MYB46 and we show that it activates GT43A, GT43B and Xyn10A. By analysis of the promoter sequences we identify a CA-rich motif putatively important for xylem-specific genes. By mastering proteins involved in xylogenesis we will acquire the tools to improve and develop the wood product market. Xylan is an immense unexploited source of renewable carbohydrate. New products envisioned include e.g. faster growing trees, changed fiber characteristics, optimised utilization of wood carbohydrates for biofuels and biomaterials as well as invention of intelligent materials by biomimetic engineering. / Vedbildning, eller xylogenes, är en grundläggande mekanism för så skilda områden som industri, boende och en hållbar miljö. Ved består av sekundärt xylem som är starka, stora celler med tjocka cellväggar som är lignifierade. Grunden för de starka cellerna är en avancerad komposit bestående av cellulosafibrer tvärbundna av hemicellulosa och slutligen ingjutet i lignin. Denna fiberkomposit är den sekundära cellväggen i vedartade växter. Celldelning och differentiering regleras genom att sätta igång och stänga av gener. Proteiner som kodas av dessa gener utför de viktigaste funktionerna i cellerna. De styr hela maskineriet som upprätthåller cellernas struktur och funktion, underhåller tillväxt samt tillverkar nödvändiga produkter såsom cellväggskolhydraterna. Här beskriver vi utforskningen av gener och proteiner som är inblandade i xylanbildning liksom utvecklandet av ett modellsystem som kommer vara en hjälp i den funktionella analysen av vedbildning. Xylan är den vanligaste hemicellulosan, eller korsbindande glykanen, i lövträd och därför en av de vanligaste kolhydraterna på jorden. Vi demonstrerar att hybridaspcellkulturer i suspension kan användas som ett modellsystem för sekundär cellväggsbildning. Vi har också undersökt glykosyltransferaser från CAZy-familj 43 som tycks spela en viktig roll i bildandet av sekundär cellvägg. Vi har fokuserat på en av dessa, Pt×tGT43A, en trolig ortolog till Arabidopsis IRX9 som spelar en viktig roll i xylanbildning. Proteinet har uttryckts övergående i Nicotiana benthamiana och dess funktion och lokalisering beskrivs. Dessutom undersöker vi ett glykosidhydrolas, Pt×tXyn10A, involverad i vedbildning. Dess roll är oklar men högst sannolikt modifierar det xylan medan det inkorporeras i sekundära cellväggen efter sekretion från Golgi. Detta influerar interaktionen mellan cellulosa, hemicellulosa och lignin i den slutliga vedcellen. Vi har också klonat en transkriptionsfaktor, Pt×tMYB021, en trolig ortolog till Arabidopsis MYB46 och vi visar att den aktiverar GT43A, GT43B och Xyn10A. Genom analys av promotorsekvenserna har vi identifierat ett CA-rikt motiv förmodat viktigt för xylemspecifika gener.Genom att bemästra proteinerna som är ansvariga för vedbildning får vi verktyg att utveckla skogsproduktsmarknaden. Xylan är en ofantligt stor outnyttjad källa till förnyelsebara kolhydrater. En vision är nya produkter som till exempel snabbväxande träd, ändrade fiberegenskaper, optimerat användande av vedkolhydrater för biobränsle och biomaterial såväl som utvecklandet av intelligenta material genom biomimetisk ingenjörskonst. / QC20100730 Populus xylan biosynthesis hemicellulose glycosyltransferase GT43 IRX glycoside hydrolase GH10 Xyn10A CAZy transcription factor MYB wood formation secondary cell wall Arabidopsis Molecular biology Molekylärbiologi
194	On the engineering of proteins: methods and applications for carbohydrate-active enzymes Gullfot, Fredrika January 2010 (has links) This thesis presents the application of different protein engineering methods on enzymes and non-catalytic proteins that act upon xyloglucans. Xyloglucans are polysaccharides found as storage polymers in seeds and tubers, and as cross-linking glucans in the cell wall of plants. Their structure is complex with intricate branching patterns, which contribute to the physical properties of the polysaccharide including its binding to and interaction with other glucans such as cellulose. One important group of xyloglucan-active enzymes is encoded by the GH16 XTH gene family in plants, including xyloglucan endo-transglycosylases (XET) and xyloglucan endo-hydrolases (XEH). The molecular determinants behind the different catalytic routes of these homologous enzymes are still not fully understood. By combining structural data and molecular dynamics (MD) simulations, interesting facts were revealed about enzyme-substrate interaction. Furthermore, a pilot study was performed using structure-guided recombination to generate a restricted library of XET/XEH chimeras. Glycosynthases are hydrolytically inactive mutant glycoside hydrolases (GH) that catalyse the formation of glycosidic linkages between glycosyl fluoride donors and glycoside acceptors. Different enzymes with xyloglucan hydrolase activity were engineered into glycosynthases, and characterised as tools for the synthesis of well-defined homogenous xyloglucan oligo- and polysaccharides with regular substitution patterns. Carbohydrate-binding modules (CBM) are non-catalytic protein domains that bind to polysaccharidic substrates. An important technical application involves their use as molecular probes to detect and localise specific carbohydrates in vivo. The three-dimensional structure of an evolved xyloglucan binding module (XGBM) was solved by X-ray diffraction. Affinity-guided directed evolution of this first generation XGBM resulted in highly specific probes that were used to localise non-fucosylated xyloglucans in plant tissue sections. / QC 20100902 enzyme engineering rational design directed evolution DNA shuffling glycosynthase xyloglucan xyloglucan endo-transglycosylase retaining glycoside hydrolase xyloglucanase carbohydrate binding module polysaccharide synthesis Bioengineering Bioteknik
195	Structural, Kinetic and Mutational Analysis of Two Bacterial Carboxylesterases Liu, Ping 04 August 2007 (has links) The crystal structures of two thermostable carboxylesterase Est30 and Est55 from Geobacillus stearothermophilus were determined to help understand their functions and applications in industry or medicine. The crystal structure of Est30 was determined at 1.63 Å resolution by the multiple anomalous dispersion method. The two-domain Est30 structure showed a large domain with a modified alpha/beta hydrolase core including a seven, rather than an eight-stranded beta sheet, and a smaller cap domain comprising three alpha helices. A 100 Da tetrahedral ligand, propyl acetate, was observed to be covalently bound to the side chain of Ser94 in the catalytic triad. This ligand complex represents the first tetrahedral intermediate in the reaction mechanism. Therefore, this Est30 crystal structure will help understand the mode of action of all enzymes in the serine hydrolase superfamily. Est55 is a bacterial homologue of the mammalian carboxylesterases involved in hydrolysis and detoxification of numerous peptides and drugs and in prodrug activation. Est55 crystals were grown at pH 6.2 and pH 6.8 and the structures were determined at resolutions of 2.0 and 1.58 Å respectively. Est55 folds into three domains, a catalytic domain, an α/β domain and a regulatory domain. This structure is in an inactive form; the side chain of His409, one of the catalytic triad residues, is pointing away from the active site. Moreover, the adjacent Cys408 is triply oxidized and lies in the oxyanion hole, which would block the entry of substrate to its binding site. This structure suggested a self-inactivation mechanism, however, Cys408 is not essential for enzyme activity. Mutation of Cys408 showed that hydrophobic side chains at this position were favorable, while polar serine was unfavorable for enzyme activity. Both Est30 and Est55 were shown to hydrolyze the prodrug CPT-11 into the active form SN-38. Therefore, Est30 and Est55 are potential candidates for use with irinotecan in cancer therapy. The catalytic efficiency (kcat/Km) of Est30 is about 10-fold lower than that of Est55. The effects of the Cys408 substitutions on Est55 activity differed for the two substrates, p-NP butyrate and CPT-11. Mutant C408V may provide a more stable form of Est55. thermostable carboxylesterase crystal structure cancer gene therapy prodrug activation CPT-11 reaction mechanism alpha/beta hydrolase tetrahedral intermediate multiple anomalous dispersion Geobacillus stearothermophilus Biology, general
196	Role of the Endocannabinoid System in Extinction of Learned Behaviours Motivated by Opioid-Induced Reward and Aversion in Rats Manwell, Laurie 26 August 2013 (has links) Recent evidence suggesting that the endogenous cannabinoid (ECB) system can be selectively manipulated to facilitate or impair the extinction of learned behaviours — specifically regarding drug-induced aversive memories — has important consequences for research on opiate withdrawal and abstinence. Data presented here support and expand previous findings that the ECB system has an important function in the extinction of aversively motivated behaviors and is mediated by i) an increase in available endogenous CB1 receptor agonists, primarily anandamide, and ii) the exogenous CB1 receptor agonist Δ9-THC, in a manner that is dependent upon both the dose and route of administration. Experiments demonstrated that the fatty acid amide hydrolase (FAAH) inhibitor, URB597, which blocks deactivation of endogenous CB1 ligands, such as anandamide, significantly facilitated extinction of naloxone-precipitated morphine withdrawal-induced conditioned cue aversion, whereas the CB1 receptor antagonist/inverse agonist SR141716 significantly impaired extinction. Several experiments demonstrated that neither the CB1 antagonist AM251 nor the FAAH inhibitor URB597 had any effect on extinction learning for morphine-induced conditioned cue preference. A method was developed for analysing cannabinoid levels in blood by liquid chromatography/mass spectrometry (LC/MS) to compare bioavailable levels of Δ9-THC and its primary psychoactive metabolite. Experiments were designed to meet three primary objectives: 1) to provide further support for the role of the ECB system in the extinction of aversively-motivated behaviours, 2) to compare bioavailable levels of Δ9-THC and its primary psychoactive metabolite, 11-OH-Δ9-THC, after pulmonary and parenteral administration, and 3) to demonstrate that the route of administration of Δ9-THC can have a significant impact on whether or not it facilitates or impairs extinction learning. Results showed that inhaled Δ9-THC dose- and time-dependently facilitated rates of extinction learning of the conditioned aversion whereas injected Δ9-THC significantly impaired extinction. These data suggest that the route of administration of Δ9-THC has important consequences for its resulting pharmacokinetic and behavioural effects, specifically, that pulmonary exposure facilitates, whereas parenteral exposure impairs, rates of extinction learning for conditioned cue aversion. Thus, pulmonary administration of Δ9-THC may prove more beneficial for pharmacological potentiation of extinction learning for aversive memories, such as those supporting drug-craving/seeking in opiate withdrawal-syndrome. / NSERC and OGS
197	Molecular and thermodynamic determinants of carbohydrate recognition by carbohydrate-binding modules and a bacterial pullulanase Lammerts van Bueren, Alicia 09 September 2008 (has links) Protein-carbohydrate interactions are pivotal to many biological processes, from plant cell wall degradation to host-pathogen interactions. Many of these processes require the deployment of carbohydrate-active enzymes in order to achieve their intended effects. One such class of enzymes, glycoside hydrolases, break down carbohydrate substrates by hydrolyzing the glycosidic bond within polysaccharides or between carbohydrates and non-carbohydrate moieties. The catalytic efficiency of glycoside hydrolases is often enhanced by carbohydrate-binding modules (CBMs) which are part of the modular structure of these enzymes. Understanding the carbohydrate binding function of these modules is often key to studying the catalytic properties of the enzyme. This thesis investigates the molecular determinants of carbohydrate recognition by CBMs that share similar amino acid sequences and overall three-dimensional structures and thus fall within the same CBM family. Specifically this research focused on two families; plant cell wall binding family 6 CBMs and the alpha-glucan binding family 41 CBMs. Through X-ray crystallography, isothermal titration calorimetry and other biochemical experiments, the structural and biophysical properties of CBMs were analyzed. Studying members of CBM family 6 allowed us to establish the overall picture of how similar CBMs interact with a diverse range of polysaccharide ligands. This was found to be due to changes in the topology of the binding site brought about by changes in amino acid side chains in very distinct regions of the binding pocket such that it adopted a three-dimensional shape that is complementary to the shape of the carbohydrate ligand. Members of CBM family 41 were shown to have nearly identical modes of starch recognition as found in starch-binding CBMs from other families. However family 41 CBMs are distinct as they are found mainly in pullulanases (starch debranching enzymes) and have developed binding pockets which are able to accommodate alpha-1,6-linkages, unlike other starch-binding CBM families. These are the first studies comparing multiple CBMs from within a given CBM family at the molecular level whose results allow us to examine the distinct modes of carbohydrate recognition within a CBM family. Analysis of the family 41 CBMs revealed that these CBMs are mainly found in pullulanases from pathogenic bacteria. Members from Streptococcal species were shown to specifically interact with glycogen stores within mouse lung tissue, leading us to investigate the role of alpha-glucan degradation by the pullulanase SpuA in the pathogenesis of Streptococcus pneumoniae. SpuA targets the alpha-1,6-branches in glycogen granules, forming alpha-1,4-glucan products of varying lengths. The overall three-dimensional structure of SpuA in complex with maltotetraose was determined by X-ray crystallography and showed that its active site architecture is optimal for interacting with branched substrates. Additionally, the N-terminal CBM41 module participates in binding substrate within the active site, a novel feature for CBMs. This is the first study of alpha-glucan degradation by a streptococcal virulence factor and aids in explaining why it is crucial for full virulence of the organism. X-Ray crystallography Protein-carbohydrate interaction carbohydrate-binding module Streptococcus pneumoniae glycoside hydrolase
198	Structural and functional studies on secreted glycoside hydrolases produced by clostridium perfringens Ficko-Blean, Elizabeth 21 April 2009 (has links) Clostridium perfringens is a gram positive spore forming anaerobe and a causative agent of gas gangrene, necrotic enteritis (pig-bel) and food poisoning in humans and other animals. This organism secretes a battery of exotoxins during the course of infection as well as a variety of virulence factors which may help to potentiate the activities of the toxins. Among these virulence factors is the μ-toxin, a family 84 glycoside hydrolase which acts to degrade hyaluronan, a component of human connective tissue. C. perfringens has 53 open reading frames encoding glycoside hydrolases. About half of these glycoside hydrolases are predicted to be secreted. Among these are CpGH84C, a paralogue of the μ-toxin, and CpGH89. CpGH89 shares sequence similarity to the human α-N-acetylglucosaminidase, NAGLU, in which mutations can cause a devastating genetic disease called mucopolysaccharidosis IIIB. One striking feature of the secreted glycoside hydrolase enzymes of C. perfringens is their modularity, with modules predicted to be dedicated to catalysis, carbohydrate-binding, protein-protein interactions and cell wall attachment. The extent of the modularity is remarkable, with some enzymes containing up to eight ancillary modules. In order to help understand the role of carbohydrate-active enzymes produced by bacterial pathogens, this thesis will focus on the structure and function of the modular extracellular glycoside hydrolase enzymes secreted by the disease causing bacterium, C. perfringens. These structure function studies examine two family 32 CBMs (carbohydrate-binding modules), one from the μ-toxin and the other from CpGH84C. As well we examine the complete structure of CpGH84C in order to help further our understanding of the structure of carbohydrate-active enzymes as a whole. Finally, the catalytic module of CpGH89 is characterized and its relationship to the human NAGLU enzyme is discussed. glycoside hydrolase GH84 carbohydrate binding module CBM32 Clostridium perfringens GH89 mucopolysaccharidosis IIIB Sanfilippo syndrome NAGLU modular enzymes
199	Identification des gènes impliqués lors de l'établissement de Lactobacillus casei dans l'intestin et caractérisation de l'opéron LSEI_0219-0221 / Identification of the genes involved in the establishment of Lactobacillus casei in the gut and characterization of the LSEI_0219_0221 Scornec, Hélène 04 November 2014 (has links) Chez les bactéries en contact direct avec leur milieu, la transcription des gènes et la synthèse des protéines sont régulées de manière efficace à chaque changement des paramètres environnementaux afin de permettre la survie cellulaire. Dans le cas des bactéries commensales de l’intestin, ces régulations doivent aussi permettre les interactions symbiotiques et la colonisation dont les mécanismes moléculaires, encore peu connus, sont probablement liés, entre autres, à la surface des bactéries (molécules exposées et sécrétées…). Lactobacillus casei, bactérie commensale, possède environ 330 gènes prédits comme intervenant dans la composition et la fonctionnalité de la surface cellulaire. Afin d’avoir une vue globale de la totalité des gènes qui interviennent dans l’établissement de L. casei dans l’intestin, une approche de génétique inverse a été réalisée. Pour cela, une banque de mutants aléatoires étiquetés de L. casei par « Signature-Tagged Mutagenesis » a été créée puis annotée et réorganisée grâce au séquençage des régions d’insertion du transposon. Les mutants ont été criblés quant à leur capacité à s’établir dans l’anse iléale ligaturée de lapin et quantifiés par qPCR. Parmi les 47 gènes identifiés comme étant impliqués dans l’établissement in vivo, trois gènes en opéron codant pour un système à deux composants et une « penicillin-binding protein » ont été caractérisés. Ces trois gènes sont impliqués dans la modulation de la surface cellulaire et plus particulièrement dans la régulation des hydrolases du peptidoglycane qui sont nécessaires à la protection de la bactérie dans l’environnement intestinal. / In bacteria which are in direct contact with their environment, genes transcription and proteins synthesis are efficiently regulated at each change of environmental parameters to allow cell survival. For intestinal commensal bacteria, these regulations must also allow symbiotic interactions and colonization whose molecular mechanisms, so far little known, are probably related, among others, to the bacteria surface (molecules exposed and secreted…). Lactobacillus casei, a commensal bacterium, has about 330 predicted genes involved in the composition and functionality of the cell surface. To have a global view of the whole genes involved in the establishment of L. casei in the gut, a reverse genetics approach was performed. For that, a library of L. casei random labeled-mutants by Signature-Tagged Mutagenesis was generated then annotated and reassembled thanks to the sequencing of transposon insertion sites. Mutants were screened for their ability to establish themselves in the rabbit ligated ileal loop and quantified by qPCR. Among the 47 genes identified as involved in the in vivo establishment, three genes in an operon encoding a two-component system and a penicillin-binding protein were characterized. These three genes are involved in the cell surface modulation and particularly in the regulation of peptidoglycan hydrolases which are required for the bacteria protection in the intestinal environment. Lactobacillus casei Signature-Tagged Mutagenesis Séquençage Système à deux composants Hydrolases du peptidoglycane Lactobacillus casei Signature-Tagged Mutagenesis Sequencing Two-component system Peptidoglycan hydrolase 572.8 579
200	Mechanism of Recycling of Ribosomes Stalled on mRNAs in Escherichia Coli Singh, 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. tRNA mRNA Ribosomes - Messenger RNA Ribosome Stalling SsrA RNA 10Sa RNA tmRNA Peptidyl-tRNA Hydrolase Initiation Factor 3 (IF3) Ribosomal Complexes Ribosome Recycling Factor Microbiology and Cell Biology

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