Global ETD Search

111	Etude fonctionnelle du dégradosome d'Escherichia coli et régulation de la RNase E par phosphorylation Toesca, Isabelle 17 March 2005 (has links) (PDF) Le dégradosome d'E. coli est un complexe protéique impliqué dans la dégradation des ARNm constitué de quatre protéines majeures : RNase E, PNPase, RhlB et l'Enolase. Dans le but de mieux comprendre l'action du dégradosome, des études de l'interaction de RhlB et des autres hélicases DEAD-box de la cellule avec la RNase E ont été menées. Deux sites distincts d'interaction ont été mis en évidence dont l'un spécifique de RhlB. Ceci suggère l'existence de dégradosome alternatif différents selon les conditions de croissance. Des travaux menés sur l'Enolase afin de déterminer son rôle au sein du complexe semblent écarter un rôle structural du complexe ou global de la dégradation des ARNm. L'hypothèse d'un effet plus spécifique est privilégiée. Enfin, des travaux sur la régulation de la RNase E par phosphorylation ont conduit à plusieurs modèles de mécanismes son inhibition par ce processus. Une relation étroite entre le domaine NTH et CTH de la RNase E a ainsi été mise en évidence. De plus, il semble qu'une kinase endogène de E. coli puisse phosphoryler le CTH de la RNase E, uniquement en absence du NTH. dégradation des ARNm dégradosome RNAse E RhlB DEAD box hélicases Enolase Régulation Kinase phosphorylation
112	Metal ion cooperativity in <i>Escherichia coli</i> RNase P RNA Brännvall, Mathias January 2002 (has links) <p>RNase P is an essential ribonuclease responsible for removal of the 5’ leader of tRNA precursors. Bacterial RNase P consists of an RNA subunit and a small basic protein. The catalytic activity is associated with the RNA subunit, i.e. bacterial RNase P RNA is a ribozyme. The protein subunit is, however, essential for activity in vivo. RNase P RNA, as well as the holoenzyme, requires the presence of divalent metal ions for activity. The aim of this thesis was to increase our understanding of the catalytic mechanism of RNase P RNA mediated cleavage. The importance of the nucleotides close to the cleavage site and the roles of divalent metal ions in RNase P RNA-catalyzed reaction were investigated. Escherichia coli RNase P RNA (M1 RNA) was used as a model system.</p><p>It was shown that different metal ions have differential effects on cleavage site recognition. Cleavage activity was rescued by mixing metal ions that do not promote cleavage activity by themselves. This suggests that efficient and correct cleavage is the result of metal ion cooperativity in the RNase P RNA-mediated cleavage reaction. The results suggested that one of the metal ions involved in this cooperativity is positioned in the vicinity of a well-known interaction between RNase P RNA and its substrate. Based on my studies on how different metal ions bind to RNA and influence its activity we raise the interesting possibility that the activity of biocatalysts that depend on RNA for activity are up- or downregulated depending on the intracellular concentrations of the bulk biological metal ions Mg<sup>2+</sup> and Ca<sup>2+</sup>.</p><p>The nucleotides upstream of the cleavage site in the substrate were found to influence the cleavage efficiency. This was not exclusively due to intermolecular base pairing within the substrate but also dependent on the identities of the nucleotides at position –2 and –1. The strength of the base pair at position –1/+73 was demonstrated to affect cleavage efficiency. These observations are in keeping with previous suggestion that the nucleotides close to the cleavage site are important for RNase P cleavage. We conclude that the residue at -1 is a positive determinant for cleavage by RNase P. Hence, my studies extend our understanding of the RNase P cleavage site recognition process.</p> Cell and molecular biology RNase P divalent metal ions substrate interaction Cell- och molekylärbiologi Cell and molecular biology Cell- och molekylärbiologi
113	Aspects of Antisense and Antigene Chemistry of Oligonucleotides Tethered to Intercalators Ossipov, Dimitri January 2002 (has links) <p>Synthetic and physicochemical studies on appropriately functionalized ODN-conjugates have been performed to evaluate their abilities to act as antisense agents against RNA or as intramolecular DNA cross-linking agents. Intercalating aromatic systems [phenazine (Pnz), dipyridophenazine (DPPZ)] and metallointercalators such as Ru<sup>2+</sup>(phen)<sub>2</sub>(DPPZ) and Ru<sup>2+</sup>(tpy)(DPPZ)<b>L</b> [where <b>L</b> = chemically or photochemically labile ligand, phen = phenanthroline, tpy = terpyridine], which are covalently tethered to the oligo-deoxynucleotides (ODNs), have been chosen for this purpose. The ODN-conjugates were typically prepared by automated solid phase synthesis using phosphoramidite building blocks, or on solid supports, both functionalized with the chromophore groups. The photosensitive metal complex, Ru<sup>2+</sup>(tpy)(DPPZ)(CH<sub>3</sub>CN), has been incorporated by post-synthetic coupling to the amino-linker modified ODNs <i>via</i> an amide bond. The intercalating ability of the tethered chromophores gave enhanced stability of the duplexes and triplexes formed with ODN-conjugates and their complementary targets: DNA, RNA, or double-stranded DNA. The conjugation of DPPZ chromophore to ODN (at 3', 5' or at the middle) led us to incorporate Ru<sup>2+</sup>(phen)<sub>2</sub>(DPPZ) through the DPPZ ligand, for the first time. The corresponding (Ru<sup>2+</sup>-ODN)•DNA duplexes showed dramatic stabilization (ΔT<sub>m</sub> = 19.4 – 22.0ºC). The CD and DNase I footprinting experiments suggest that the stabilization is owing to metallointercalation by threading of the Ru<sup>2+</sup>(phen)<sub>2</sub> moiety through the ODN•DNA duplex core, thus "stapling" the two helical strands from the minor to major groove. On the other hand, Ru<sup>2+</sup>(tpy)(DPPZ)(CH<sub>3</sub>CN)-ODN conjugates represent a new class of oligonucleotides containing the photoactivatible Ru<sup>2+</sup> complexes, which can successfully crosslink to the complementary strand. The mechanism of cross-linking upon photoirradiation of [Ru<sup>2+</sup>(tpy)(DPPZ)(CH<sub>3</sub>CN)-ODN]•DNA involves <i>in situ</i> conversion to the reactive [Ru<sup>2+</sup>(tpy)(DPPZ)(H<sub>2</sub>O)-ODN]•DNA which are subsequently cross-linked through the G residue of the complementary DNA strand. All starting materials and products have been purified by HPLC and/or by PAGE and subsequently characterized by MALDI-TOF as well as ESI mass spectroscopy. Terminal conjugation of the planar Pnz and DPPZ groups through the flexible linkers were also shown to improve thermal stability of the ODN•RNA hybrid duplexes without alteration of the initial AB-type global helical structure as revealed from CD experiments. As a result, RNase H mediated cleavage of the RNA strand in the intercalator-tethered ODN•RNA duplexes was more efficient compared to the natural counterpart. The RNase H cleavage pattern was also found to be dependent on the chemical nature of the chromophore. It appeared that introduction of a tether at the 3'-end of the ODN can be most easily tolerated by the enzyme regardless of the nature of the appending chromophore. The tethered DPPZ group has also been shown to chelate Cu<sup>2+</sup> and Fe<sup>3+</sup>, like phenanthroline group, followed by the formation of redox-active metal complex which cleaves the complementary DNA strand in a sequence-specific manner. This shows that the choice of appropriate ligand is useful to (i) attain improved intercalation giving Tm enhancement, and (ii) sequence-specifically inactivate target RNA or DNA molecules using multiple modes of chemistry (RNase H mediated cleavage, free-radical, oxidative pathways or photocross-linkage).</p> Bioorganic chemistry oligonucleotides intercalators ruthenium complexes RNase H cleavage photocross-linkage Bioorganisk kemi Bioorganic chemistry Bioorganisk kemi
114	Metal ion cooperativity in Escherichia coli RNase P RNA Brännvall, Mathias January 2002 (has links) RNase P is an essential ribonuclease responsible for removal of the 5’ leader of tRNA precursors. Bacterial RNase P consists of an RNA subunit and a small basic protein. The catalytic activity is associated with the RNA subunit, i.e. bacterial RNase P RNA is a ribozyme. The protein subunit is, however, essential for activity in vivo. RNase P RNA, as well as the holoenzyme, requires the presence of divalent metal ions for activity. The aim of this thesis was to increase our understanding of the catalytic mechanism of RNase P RNA mediated cleavage. The importance of the nucleotides close to the cleavage site and the roles of divalent metal ions in RNase P RNA-catalyzed reaction were investigated. Escherichia coli RNase P RNA (M1 RNA) was used as a model system. It was shown that different metal ions have differential effects on cleavage site recognition. Cleavage activity was rescued by mixing metal ions that do not promote cleavage activity by themselves. This suggests that efficient and correct cleavage is the result of metal ion cooperativity in the RNase P RNA-mediated cleavage reaction. The results suggested that one of the metal ions involved in this cooperativity is positioned in the vicinity of a well-known interaction between RNase P RNA and its substrate. Based on my studies on how different metal ions bind to RNA and influence its activity we raise the interesting possibility that the activity of biocatalysts that depend on RNA for activity are up- or downregulated depending on the intracellular concentrations of the bulk biological metal ions Mg2+ and Ca2+. The nucleotides upstream of the cleavage site in the substrate were found to influence the cleavage efficiency. This was not exclusively due to intermolecular base pairing within the substrate but also dependent on the identities of the nucleotides at position –2 and –1. The strength of the base pair at position –1/+73 was demonstrated to affect cleavage efficiency. These observations are in keeping with previous suggestion that the nucleotides close to the cleavage site are important for RNase P cleavage. We conclude that the residue at -1 is a positive determinant for cleavage by RNase P. Hence, my studies extend our understanding of the RNase P cleavage site recognition process. Cell and molecular biology RNase P divalent metal ions substrate interaction Cell- och molekylärbiologi Cell and molecular biology Cell- och molekylärbiologi
115	Aspects of Antisense and Antigene Chemistry of Oligonucleotides Tethered to Intercalators Ossipov, Dimitri January 2002 (has links) Synthetic and physicochemical studies on appropriately functionalized ODN-conjugates have been performed to evaluate their abilities to act as antisense agents against RNA or as intramolecular DNA cross-linking agents. Intercalating aromatic systems [phenazine (Pnz), dipyridophenazine (DPPZ)] and metallointercalators such as Ru2+(phen)2(DPPZ) and Ru2+(tpy)(DPPZ)<b>L</b> [where <b>L</b> = chemically or photochemically labile ligand, phen = phenanthroline, tpy = terpyridine], which are covalently tethered to the oligo-deoxynucleotides (ODNs), have been chosen for this purpose. The ODN-conjugates were typically prepared by automated solid phase synthesis using phosphoramidite building blocks, or on solid supports, both functionalized with the chromophore groups. The photosensitive metal complex, Ru2+(tpy)(DPPZ)(CH3CN), has been incorporated by post-synthetic coupling to the amino-linker modified ODNs via an amide bond. The intercalating ability of the tethered chromophores gave enhanced stability of the duplexes and triplexes formed with ODN-conjugates and their complementary targets: DNA, RNA, or double-stranded DNA. The conjugation of DPPZ chromophore to ODN (at 3', 5' or at the middle) led us to incorporate Ru2+(phen)2(DPPZ) through the DPPZ ligand, for the first time. The corresponding (Ru2+-ODN)•DNA duplexes showed dramatic stabilization (ΔTm = 19.4 – 22.0ºC). The CD and DNase I footprinting experiments suggest that the stabilization is owing to metallointercalation by threading of the Ru2+(phen)2 moiety through the ODN•DNA duplex core, thus "stapling" the two helical strands from the minor to major groove. On the other hand, Ru2+(tpy)(DPPZ)(CH3CN)-ODN conjugates represent a new class of oligonucleotides containing the photoactivatible Ru2+ complexes, which can successfully crosslink to the complementary strand. The mechanism of cross-linking upon photoirradiation of [Ru2+(tpy)(DPPZ)(CH3CN)-ODN]•DNA involves in situ conversion to the reactive [Ru2+(tpy)(DPPZ)(H2O)-ODN]•DNA which are subsequently cross-linked through the G residue of the complementary DNA strand. All starting materials and products have been purified by HPLC and/or by PAGE and subsequently characterized by MALDI-TOF as well as ESI mass spectroscopy. Terminal conjugation of the planar Pnz and DPPZ groups through the flexible linkers were also shown to improve thermal stability of the ODN•RNA hybrid duplexes without alteration of the initial AB-type global helical structure as revealed from CD experiments. As a result, RNase H mediated cleavage of the RNA strand in the intercalator-tethered ODN•RNA duplexes was more efficient compared to the natural counterpart. The RNase H cleavage pattern was also found to be dependent on the chemical nature of the chromophore. It appeared that introduction of a tether at the 3'-end of the ODN can be most easily tolerated by the enzyme regardless of the nature of the appending chromophore. The tethered DPPZ group has also been shown to chelate Cu2+ and Fe3+, like phenanthroline group, followed by the formation of redox-active metal complex which cleaves the complementary DNA strand in a sequence-specific manner. This shows that the choice of appropriate ligand is useful to (i) attain improved intercalation giving Tm enhancement, and (ii) sequence-specifically inactivate target RNA or DNA molecules using multiple modes of chemistry (RNase H mediated cleavage, free-radical, oxidative pathways or photocross-linkage). Bioorganic chemistry oligonucleotides intercalators ruthenium complexes RNase H cleavage photocross-linkage Bioorganisk kemi Bioorganic chemistry Bioorganisk kemi
116	Genetics and Growth Regulation in Salmonella enterica Bergman, Jessica M. January 2014 (has links) Most free-living bacteria will encounter different environments and it is therefore critical to be able to rapidly adjust to new growth conditions in order to be competitively successful. Responding to changes requires efficient gene regulation in terms of transcription, RNA stability, translation and post-translational modifications. Studies of an extremely slow-growing mutant of Salmonella enterica, with a Glu125Arg mutant version of EF-Tu, revealed it to be trapped in a stringent response. The perceived starvation was demonstrated to be the result of increased mRNA cleavage of aminoacyl-tRNA synthetase genes leading to lower prolyl-tRNA levels. The mutant EF-Tu caused an uncoupling of transcription and translation, leading to increased turnover of mRNA, which trapped the mutant in a futile stringent response. To examine the essentiality of RNase E, we selected and mapped three classes of extragenic suppressors of a ts RNase E phenotype. The ts RNase E mutants were defective in the degradation of mRNA and in the processing of tRNA and rRNA. Only the degradation of mRNA was suppressed by the compensatory mutations. We therefore suggest that degradation of at least a subset of cellular mRNAs is an essential function of RNase E. Bioinformatically, we discovered that the mRNA of tufB, one of the two genes encoding EF-Tu, could form a stable structure masking the ribosomal binding site. This, together with previous studies that suggested that the level of EF-Tu protein could affect the expression of tufB, led us to propose three models for how this could occur. The stability of the tufB RNA structure could be affected by the elongation rate of tufB-translating ribosomes, possibly influenced by the presence of rare codons early in the in tufB mRNA. Using proteomic and genetic assays we concluded that two previously isolated RNAP mutants, each with a growth advantage when present as subpopulations on aging wild-type colonies, were dependent on the utilization of acetate for this phenotype. Increased growth of a subpopulation of wild-type cells on a colony unable to re-assimilate acetate demonstrated that in aging colonies, acetate is available in levels sufficient to sustain the growth of at least a small subpopulation of bacteria. tufA tufB EF-Tu ppGpp Stringent response RNase E RNA turnover Post-transcriptional regulation rpoB rpoS Growth in stationary phase
117	The regulatory effect of CsrA on cstA, glgCAP and flhDC in an RNase P ts mutant Escherichia coli Hilow, Zeinalabedin January 2017 (has links) CsrA is a global post-transcriptional regulatory protein that has a great impact on many physiological pathways in a cell. It regulates central carbon metabolism, motility and biofilm formation as well as virulence, pathogenesis, quorum sensing and the oxidative stress response. However, CsrA is in turn also regulated by CsrB and CsrC sRNAs, among other factors. In this study, we explore its regulatory effect on three different genes/operons, cstA, glgCAP and flhDC. We performed beta-galactosidase assays on wild type (wt) and RNase P temperature sensitive (ts) cells to determine the dependence on RNaseP for the CsrA, CsrB and CsrC regulatory cascade on these three genes. Our results showed a clear decrease in cstA and glgCAP activity during CsrA activation, suggesting a regulatory cascade in which inhibition of RNase P leads to an inactivation of CsrB and CsrC. This in turn leads to an activation of CsrA and an inhibition of cstA and glgCAP. The effect on flhDC, however, was not as clear and needs further investigation. CsrA CsrB CsrC CsrD GlgCAP FlhDC CstA E. Coli Glolbal regulator RNase P C5 ts wt Cell Biology Cellbiologi
118	La régulation de l’expression génique peut passer par un mécanisme de terminaison prémature de la transcription dépendant de la RNase III chez Saccharomyces cerevisiae / Gene expression can be regulated with a premature termination mechanism targeting ongoing transcription dependent on the RNase III in Saccharomyces cerevisiae Malenfant, Francis January 2017 (has links) L’expression des gènes est un ensemble hautement régulé de mécanismes ayant pour objectifs de synthétiser les protéines fonctionnelles dont la cellule a besoin à partir des codes inscrits dans l’ADN. Pour contrôler la quantité de signal utilisé et pour que ce message puisse physiquement traverser la cellule, celle-ci utilise la transcription des ARN messagers comme intermédiaire. Pour assurer la qualité de ce signal et pour contrôler son niveau d’expression, plusieurs mécanismes de dégradation des ARNm se coordonnent dans les organismes en fonction de leurs spécificités propres. La littérature a depuis longtemps démontré les liens entre les machineries de synthèse des ARNm et celles de leur dégradation en identifiant comment ceux-ci travaillent ensemble pour assurer une bonne régulation génique. Un de ces mécanismes induit une terminaison dans la région non-codante en 3’ de certains gènes à partir d’un clivage par la ribonucléase III. Dans ce mémoire, nous voulons démontrer qu’un mécanisme similaire dépendant de la ribonucléase III peut induire une terminaison prémature de la transcription à l’intérieur même de séquences codantes. Ce mécanisme semble être indépendant du promoteur et du terminateur des gènes, préférant réguler sa sélectivité à partir de la structure liée au clivage de l’ARNm. Plusieurs séquences et structures sous forme de tige-boucles d’ARNm peuvent être reconnues par la ribonucléase III. Cependant, il existe des différences fonctionnelles entre les différentes tige-boucles et toutes n’induisent pas un mécanisme de terminaison prématurée. Comme ce type de mécanisme doit être inductible et/ou permissible afin de ne pas empêcher complètement l’expression des gènes cibles, nous pouvons potentiellement faire affaire à un nouveau modèle de régulation génique. / Abstract : Gene expression is a highly regulated coordination of processes with the objective of producing functional proteins from the DNA code of the cell. To control the amount of proteins produced, cells use messenger RNAs as an intermediate to permit genomic information to move across the cell. To assure the quality of this signal and to control the level of gene expression, many RNA degradation mechanisms coordinate together according to their own specificities. Scientific literature has demonstrated long ago the existing interactions between RNA synthesis and RNA degradation pathways and how they closely work together to achieve viable gene expression regulation. One of those mechanisms induces transcription termination in the 3’ untranscribed region of coding genes initiated with a RNA cleavage from a ribonuclease III. In this master thesis, we show that a similar RNase III dependent mechanism can induce premature transcription termination inside the coding sequence. This mechanism seems promotor and terminator independent and depends mostly on the sequence coding for a stem-loop structure in the mRNA. Different sequences can induce a stem-loop structure recognizable by RNase III. However, there are some functional differences between stem-loop structures and not all of them can induce premature transcription termination. Since this mechanism must not happen every time and somehow must be inducible to permit gene expression when needed, this could possibly lead to a new gene regulation model. Terminaison de la transcription Terminaison prémature RNase III Saccharomyces cerevisiae Poly-A indépendant Modèle torpille Premature termination Torpedo model Transcription termination Poly-A independent
119	Analýza a mapování vazebných míst regulátorů genové exprese u streptomycet. / Analysis and mapping of binding sites of gene expression regulators in the genus of Streptomyces. Šmídová, Klára January 2020 (has links) Streptomyces are medically important soil-living bacteria that undergo morphological changes from spores to aerial hyphae and are important producers of bioactive compounds including antibiotics. Their gene expression is tightly regulated at the early level of transcription and translation. In the transcriptional control, sigma factors play a central role; the model organism Streptomyces coelicolor possesses astonishing 65 sigma factors. The expression of sigma factors themselves is controlled on the post-transcriptional level through the action of sRNAs that modify their mRNA level. However, only several sigma factors in Streptomyces have known regulons and also their sRNAs-mediated regulation has not been studied so far. According to previously measured gene expression data, we selected several highly expressed sigma factors. Using mutant strains with HA-tagged sigma factors, regulons of two important sigma factors, SigQ and HrdB, were analyzed by ChIP-seq procedure. Other sigma factors were further studied to see if they possess asRNAs, using 5' and 3' RACE method and northern blotting. Our data confirm the essentiality of HrdB sigma factor during the vegetative phase of growth. The other sigma factor, SigQ, has been revealed to be an important regulator of nitrogen metabolism and osmotic...
120	Purification and Characterization of Novel Nucleases from a Thermophilic Fungus Landry, Kyle S 01 January 2012 (has links) (PDF) A thermophilic fungus was isolated from composted horse manure. The organism was as a Chaetomium sp. by sequencing the highly conserved ITS region of the fungus and comparing to known regions in a genomic database and was referred to as TM-417. TM-417 was found to have an optimal growth temperature of 45 oC and an optimal pH of 7.0. An extracellular DNase and RNase was found to be produced by the isolate and were purified 145.58-fold and 127.6-fold respectively using a combination of size exclusion chromatography and a novel affinity membrane purification system. The extent of purification was determined electrophoretically using 4-15% gradient polyacrylamide gels. Both DNase and RNase were dependent on metal co-factors for activity. The metal ion Mg2+ was the preferred ion for the DNase, whereas for the RNase, Zn2+ and Mn2+ yielded an increase in enzyme activity over that with Mg2+. The purified DNase demonstrated maximum activity at pH 6.0 with no activity at pH 2.0 or 10.0. The RNase exhibited two peaks of maximum activity, on at pH 3.0 and the other at pH 7.0 with no activity at pH 2.0 or 10.0. The optimal temperature for the purified DNase was 65oC. The optimal temperature for the RNase was 70oC. The molecular of the DNase and RNase were determined to be 56 kDa and 69kDa respectively using a Sephadex G-75 column. A standard curve was generated using several standard proteins of known molecular weight. Thermophilic fungi DNase RNase Affinity purification Agriculture Biochemistry Biotechnology Food Biotechnology Food Microbiology Other Plant Sciences

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