Global ETD Search

11	Regulation of gene expression by small non-coding RNA and CRISPR-dCas9 Hoque, Mohammed Enamul 22 November 2022 (has links) No description available. Biochemistry Chemistry Cellular Biology Biophysics
12	Towards the Development of Synergistic Inhibitors that Exploit the Replication Strategy of HIV-1 Pattenden, Leonard Keith January 2005 (has links) HIV-1 has evolved with a great deal of functional complexity contained within a very small genome by encoding small, but critical viral proteins within larger viral genes and dividing the replication cycle into early and late phases to differentially produce all proteins leading to efficient replication and virion release. Early replication is restricted by the host spliceosome that processes HIV-1 vRNA transcripts so only the small intragenomic proteins are produced, one of which is Rev (Regulator of Virion Expression). Rev in turn governs the transition from early to late replication by interacting with a highly structured region of vRNA termed the Rev Response Element (RRE). The binding of Rev to the RRE is believed to cause a change in the vRNA tertiary structure and inhibition of splicing of the vRNA. Once, a Rev:RRE complex is formed, a nuclear export signal within Rev facilitates the export of partially spliced and unspliced vRNA to the cytoplasm. During late replication the partially spliced and unspliced vRNA is translated to polyproteins and is packaged into a budding virion where the viral aspartyl protease (HIV-1 PR) autocatalytically excises itself from the larger polyprotein and processes the remaining polyproteins to release all viral structural and functional proteins to form a mature and infectious virion. Since the vRNA salvaged by Rev is translated to the polyproteins containing HIV-1 PR, the inhibition of Rev function will reduce the amount of HIV-1 PR available and thereby reduce the amount of HIV-1 PR therapeutics required to elicit a clinical effect. Therfore a combination approach to HIV-1 treatment using suitably developed therapeutics that inhibit Rev and HIV-1 PR function represents an attractive synergistic approach to treating HIV-1 infection in vivo. The work of this thesis was divided into two parts, the first part was concerned with HIV-1 PR structural biology and addressing problems encountered with inhibitor design. A bicyclic peptide (based on inhibitors of analogous structure) was co-crystallised with active HIV-1 PR to develop an enzyme-product (E-P) complex and with a catalytically inactive mutant HIV-1 PR to provide an analogy to the enzyme-substrate (E-S) complex. Both structures of the E-P and E-S complexes were solved to 1.6Å resolution and were compared to a hydroxyethylamine isostere enzyme-inhibitor complex (E-I), highlighting the similarity of binding mode for all ligands. The inhibitor in the E-I complex was translated towards the S1 - S3 pockets of the substrate binding cleft relative to the substrate in the E-S complex due to the increased length of the hydroxylethylamine isostere compared to the peptide backbone, although the inhibitor "puckered" the isostere linkage and maintains a binding mode similar to the substrate with very little overall differences in the position of the ligands and surrounding protein. The similarity of the E-S, E-I and E-P complexes was attributed to the macrocyclic ligands ordering the surrounding protein environment, especially the protein -strand "flap" structures that form a roof over the ligands in the active site but were not found to close more tightly in any of the trapped catalytic states. The new structures allowed refinement of details of the mechanism of peptide hydrolysis. The mechanism relies on the optimal nucleophilic attack of a water molecule on the scissile amide bond with concerted acid-base catalysis of the active site aspartyl residues intitiated by D125. The alignment and intrinsic position of the N-terminus of the bicyclic substrate was interpreted as being critical to facilitate efficient electron transfer with the bicyclic substrate. An N-terminal cyclic inhibitor, similar to the N-terminal portion of the bicyclic substrate, was used to address a major problem in HIV-1 PR drug design termed "cooperativity," where the sequential optimisation of an inhibitor (or substrate) to individual pockets of the substrate binding cleft, can negatively impact on adjacent and downfield subsites and thereby alter the binding mode of the "optimised" inhibitor. The technique referred to here as "templating" uses the N-terminal cycle to lock the binding mode into a known conformation, probing the S1' and S2' pockets. The structure activity relationship suggested that by viewing the S1' - S3' pockets as a single trough, bulky aromatic groups attached to an N-alkyl sulfonamide could be directed along the line of the trough without adverse interactions with the tops of the S1' and S3' pockets, providing very potent inhibitors. It was also found that specificity and potency of an inhibitor can be maintained with smaller functionalities that carry their bulk low and close to the inhibitor backbone in the S2' pocket, making the P2 functionalities more substrate-like. The second part of the thesis was concerned with establishing suitable surface plasmon resonance assays for testing potential inhibitors of Rev function. Recombinant Rev and its minimal RNA aptamer target (stem loop II of the RRE termed RBE3), were expressed, purified, and used to develop BIAcore-based assays and test potential inhibitors of their interaction. The system was applied to screening of aminoglycoside antibiotics and other small molecules in a competitive assay, and also to quantitative assay of Neomycin and moderate sized analytes: Rev and three peptidic analogues of the high-affinity binding site of Rev - the native peptide, succinylated form of the peptide and a form incorporating a novel helix-inducing cap. The peptide and protein assay was undertaken to test the proposition that helix induction of the high-affinity binding site of Rev can increase affinity for the biologically important RNA target and thereby form the basis of a new class of inhibitors. The screen of small molecule antagonists found that Neomycin was the best inhibitor of the Rev:RBE3 interaction and that efficacy of other aminoglycosides was due to the neamine-base structure presenting charge to bind to the RNA and blocking interaction with Rev. The quantitative assay was optimised to reduce non-specific interactions of Rev protein to allow reliable studies of the analytes with RBE3 by the sytematic testing of buffers and modifiers. It was found that mutliple analytes bound to the RBE3 aptamer and a comparison of the KD values found that the native and capped peptides had similar affinity for RBE3 RNA (native slightly greater at 21 ± 7nM cf capped 41 ± 10nM) that was greater than the Rev protein (101 ± 19nM), however the succinylated peptide exhibited stronger binding with a KD ≤8nM and Neomycin had the lowest affinity (KD 13 ± 3M). The similarity of the native and capped peptides may be due to the high concentration of salt in the assay buffers and was necessary for the stability of the Rev protein, but is sufficient to influence secondary structure of the peptides. Therefore, it could not be stated that the helix-inducing cap increased the affinity of the native peptide for the biologically important therapeutic target. The work conducted in this thesis firmly establishes foundations for the continued development of inhibitors against both Rev and HIV-1 PR that play key roles in the HIV-1 replication strategy. It is envisaged this work could lead to a novel synergistic therapeutic approach to treating HIV-1 infection. Aspartyl Protease HIV-1 Protease Substrate Complex Product Complex X-ray Crystallography Cyclic Peptide -strand Mimetic Catalysis Cooperativity HIV-1 Rev RRE RBE3 RNA BIAcore Surface Plasmon Resonance in vitro transcription Aminoglycoside Helix-inducing Cap Neomycin Streptavidin Neutravidin Helix Mimetic
13	Structural elucidation of mRNA(Sirt1)-microRNA 34a complex Farshchian, Mona January 2015 (has links) The aim of this thesis is to understand RNA-RNA interactions steering cellular functions, as in the case of this thesis the structure of mRNA(Sirt1) in complex with microRNA-34a (miR-34a). MiR-34a regulates the cancer protein p53 via Sirt1 modulation. This work will be the basis for future drug design and the understanding of misguided regulation in cancer. The miR-34a binds to the mRNA(Sirt1) 3’ untranslated region (3’-UTR) and will either inhibit the translation of the protein Sirtuin 1 by capturing its mRNA or by degrading it. p53, a key activator of miR-34a, prevents cancer development by inducing programmed cell death (apoptosis) on cells with DNA damage. In contrast, the protein Sirtuin 1 (Sirt1) has been shown to help cells with DNA damage to survive by down regulating the activity of protein p53 and will therefore increase the risk of cancer development. Studying the interaction between the mRNA(Sirt1) and miR-34a can present valuable information on the structure of the complex as well as the mode miR-34a uses to inhibit translation of mRNA(Sirt1) leading to down regulation of protein Sirtuin 1 and therefore prevent cancer development. For the elucidation of this question different biochemical and biophysical methods were applied, such as in vitro transcription, gel electrophoresis, RNA purification with gel, crush & soak and Cicular Dichroism (CD) melting studies. For this thesis work, the target sequence in mRNA(Sirt1) was optimized and purified so melting studies could be carried out. For future structural characterization using Nuclear Magnetic Resonance (NMR) studies with the miR-34a also produced in the lab. The mRNA(Sirt1) target sequence was produced and purified with the final yield of 0.02%. The results show that the sequence is highly ATP dependent and suggest the ratio between the nucleotides ATP/CTP to be 1:2. Low yield of purified mRNA(Sirt1) was received and still contained some impurities, which imply that another method than crush & soak should be used when purifying. The results, indicate that High-Preformance Liquid Chromatography (HPLC) might be a better solution for the pufication process. The melting profiles done on mRNA(Sirt1) show that the secondary structures decrease with an increase in temperature. Accroding to the results, the mRNA(Sirt1) sequence is folded in room temperature, though not very stable. The wavelength which provided the best resolution was at 268 nm and the melting point of mRNA(Sirt1) was determined to 44 °C. This thesis also contains an educational part, where an educational material was provided and testing was conducted for the subject Chemistry 2 for students age 18 and the material was evaluated with qualitative methods together with pedagogical methods. The study showed that the student can develope the different abilities stated in the curriculum with the material created. The results also showed that the students preferably choose cultural arguments when dicussing socio scientific question, rather than economical, democratic or utility arguments. / Syftet med studien är att förstå RNA-RNAinteraktioner som styr cellulära funktioner, i detta fall mRNA(Sirt1) i komplex med microRNA-34a (miR-34a). MiR-34a reglerar cancerproteinet p53 via modulation av Sirt1. Detta arbete kommer lägga grund för framtida läkemedelsdesign vid reglering av cancer. MiR-34a binder till den 3’ otranslerade regionen i mRNA(Sirt1) och hämmar antingen translationen av protein Sirtuin 1 (Sirt1) genom att fånga dess mRNA eller genom att försämra det. p53 förhindrar utvecklingen av cancer genom att framkalla programmerad cell död (apoptosis) av celler med skadat DNA. Det har visats att proteinet Sirtuin 1 hjälper celler med skadat DNA att överleva, genom att sänka aktiviteten av p53. På så vis ökar risken för utveckling av cancer. Genom att studera interaktionen mellan mRNA(Sirt1) och miR-34a kan värdefull information kring komplexets struktur fås. Samt hur miR-34a hämmar translationen av mRNA(Sirt1), vilket leder till minskad aktivitet av protein Sirt1. För att klarlägga denna fråga har olika biokemiska och biofysiska metoder använts, såsom in vitro transkription, gelelektrofores, RNA rening med gel och Circular Dichroism (CD). För detta arbete har målsekvensen i mRNA(Sirt1) optimerats och renats så CD smältstudier med kunde genomföras. Resultatet visar att mRNA(Sirt1) sekvensen renats med ett utbyte på 0.02 %. Sekvensen är beroende av ATP och förhållandet mellan ATP/CTP nukleotider bör vara 1:2. Resutatet visar på ett lågt utbyte som visar på att High-Performance Liquid Chromatography (HPLC) kan vara en bättre metod än Crush & soak för reningen av mRNA(Sirt1). Ur de smältprofiler som gjorts visade det sig att de sekundära strukturerna av mRNA(Sirt1) minskade med ökande temperatur. I enlighet med resultaten visar det att mRNA(Sirt1) är veckat i rumstemperatur men är inte stabil. Den bästa upplösningen erhölls vid 268 nm och mRNA(Sirt1) har en smältpunkt runt 44 °C. Detta arbete innehåller även ett utbildningskapitel, där ett utbildningsmaterial har skapats och testats på 18-åriga kemi 2 studenter i åldern 18 år. Materialet har utvärderats med hjälp av kvalitativa metoder tillsammans med pedagogiska metoder. Studien visade att de flesta förmågorna för kemi 2 kan utvecklas med hjälp av denna typ samhällsfrågor i det naturvetenskapliga klassrummet (SNI-fall) förutom förmågan att planera och genomföra experiment. Det argument som eleverna helst väljer att använda då de diskuterar det skapade SNI-fallet är Kulturargument och det minst använda är Demikratiargument. mRNA(Sirt1) miR-34a in vitro transcription gel electrophoresis CD spectroscopy NMR cancer regulation via p53 HPLC mRNA(Sirt1) miR-34a in vitro transkription gel elektroforesis CD spektroskopi NMR cancer regulering via p53 HPLC Chemical Sciences Kemi
14	Drug Discovery Targeting Bacterial and Viral non-coding RNA: pH Modulation of RNAStability and RNA-RNA Interactions Hossain, Md Ismail 23 May 2022 (has links) No description available. Biochemistry Biology Genetics Non-coding RNA T-box Riboswitch Stem-Loop II Motif RNA thermometer ompA shuT shuA Drug Discovery SARS-CoV-2 tRNA-mRNA interaction In vitro transcription Fluorescence Anisotropy EMSA Thermal denaturation pH RNA stability and conformation RNA structure probing Thermal hysteresis 16S rRNA Nucleic acid research
15	Untersuchungen von inter- und intramolekularen Interaktionen des globalen Regulators AbrB und dessen Antirepressors AbbA Neubauer, Svetlana 16 January 2014 (has links) Aus den frühen Bindungsstudien des globalen Regulators AbrB mit der ausgedehnten phyC-Promotorregion von Bacillus amyloliquefaciens FZB45 konnte ein mehrstufiger kooperativer Bindungsprozess abgeleitet werden. Dabei verlangt die AbrB-vermittelte Repression von phyC nach Integrität zweier großer Bindungsstellen, ABS1 und ABS2, die 162 bp voneinander entfernt liegen. In der vorliegenden Arbeit wurden die ersten Echtzeitkinetiken zur DNA-AbrB-Interaktion mittels der Oberflächenplasmonresonanz (SPR) gemessen und analysiert. AbrB zeigte hohe Affinitäten zu den 40 bp langen Oligonukleotiden, die den beiden Bindungsstellen entstammen. Dabei verursachten alle Oligonukleotide der ABS2 und nur eine kurze Region innerhalb der ABS1 bei der Bindung von AbrB Konformationsänderungen im Protein und in der DNA (CD - Zirkulardichroismusspektroskopie) und wiesen eine Kooperativität von 2 / In previous binding studies it could be demonstrated that a global regulator AbrB and the extensive phyC promoter region of Bacillus amyloliquefaciens FZB45 interact in a complex manner. AbrB binding is a multistep cooperative process. The integrity of both binding sites, ABS1 and ABS2, which are separated by 162 bp, is crucial for the AbrB-mediated repression of phyC. This work presents the first real-time binding kinetics of the AbrB-DNA interaction using surface plasmon resonance (SPR). AbrB exhibited high affinities to all analyzed 40-bp oligonucleotides that were derived from the ABSs of phyC. All parts of the ABS2, but only a small region within ABS1, were bound cooperatively to AbrB with a stoichiometry of 2 DNA to 1 AbrB tetramer and with 2 Mutagenese AbrB AbbA phyC-Promotor Protein-DNA-Interaktion Bacillus amyloliquefaciens FZB45 Oberflächenplasmonresonanz (SPR) Echtzeitbindungskinetiken positive Kooperativität negative Kooperativität Hill-Koeffizient Gleichgewichtskonstante der Dissoziation Zirkulardichroismus (CD) chemische Interferenzfootprints Röntgenkleinwinkelstreuung (SAXS) Alaninsubstitution Gelretardationsassays (EMSA) in vitro Transkription mutagenesis AbrB AbbA phyC-promoter protein-DNA interaction Bacillus amyloliquefaciens FZB45 surface plasmon resonance (SPR) real-time binding kinetics positive cooperativity negative cooperativity Hill-coefficient equilibrium dissociation constant circular dichroism (CD) chemical interference footprints small angle X-ray scattering (SAXS) alanine substitution gel retardation assays (EMSA) in vitro transcription 570 Biowissenschaften, Biologie 32 Biologie WG 4050 ddc:570

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