Global ETD Search

81	piRNA Biogenesis and Transposon Silencing in Drosophila: A Dissertation Zhang, Zhao 06 November 2013 (has links) piRNAs guide PIWI proteins to silence transposons in animal germ cells. In Drosophila, the heterochromatic piRNA clusters transcribe piRNA precursors to be transported into nuage, a perinuclear structure for piRNA production and transposon silencing. At nuage, reciprocal cycles of piRNA-directed RNA cleavage—catalyzed by the PIWI proteins Aubergine (Aub) and Argonaute3 (Ago3) in Drosophila—destroy the sense transposon mRNA and expand the population of antisense piRNAs in response to transposon expression, a process called the Ping-Pong cycle. Heterotypic Ping-Pong between Aub and Ago3 ensures that antisense piRNAs predominate. My thesis research mainly focuses on two fundamental questions about the piRNA production: How does the germ cell differentiate piRNA precursor from mRNAs for piRNA biogenesis? And what is the mechanism to impose Aub Ping-Pong with Ago3? For the first question, we show that the HP1 homolog protein Rhino marks the piRNA cluster regions in the genome for piRNA biogenesis. Rhino seems to anchor a nuclear complex that suppresses cluster transcript splicing, which may differentiate piRNA precursors from mature mRNAs. Moreover, LacI::Rhino fusion protein binding suppresses splicing of a reporter transgene and is sufficient to trigger de novo piRNA production from a trans combination of sense and antisense transgenes. For the second question, we show that Qin, a new piRNA pathway factor contains both E3 ligase and Tudor domains, colocalizes with Aub and Ago3 in nuage, enforces heterotypic Ping- Pong between Aub and Ago3. Loss of qinleads to less Ago3 binding to Aub, futile Aub:Aub homotypic Ping-Pong prevails, antisense piRNAs decrease, many families of mobile genetic elements are reactivated, DNA damage accumulates in the germ cells and flies are sterile. Small Interfering RNA RNA Interference DNA Transposable Elements Drosophila Proteins Dissertations, UMMS RNA, Small Interfering Molecular Genetics
82	När oro för jobbförlust påverkar upplevd work-life conflict : En kvantitativ studie om hur oro för jobbförlust kan leda till svårigheter att släppa arbetets krav, vilket i sin tur kan öka upplevd work-life conflict. Eriksson, Josefin, Orén, Ellinor January 2023 (has links) Syftet med uppsatsen var att undersöka om det finns ett samband mellan oro för jobbförlust och upplevd work-life conflict. Uppsatsens teoretiska utgångspunkt grundar sig i forskning om rollkonflikt och anställningsotrygghet. Work-life conflict (WLC) definieras som en rollkonflikt där arbetslivet och privatlivet konkurrerar om en individs begränsade resurser. Oro för jobbförlust syftar i huvudsak till en subjektiv oro över att bli av med sin anställning, snarare än faktiskt otrygga anställningsvillkor. Uppsatsens datamaterial kommer från en tvärsnittsundersökning från den svenska studien inom det internationella forskningsprojektet ISSP från 2015 vilken undersöker åsikter om jobbet och arbetslivet via enkäter. Det obundna slumpmässiga urvalet har begränsats i uppsatsen och består av totalt 596 respondenter som alla vid tillfälle för besvarad enkät förvärvsarbetar. För att undersöka sambandet och testa hypotesen används linjär regressionsmodell som analysmetod. Resultaten visade på ett positivt samband mellan oro för jobbförlust och work-life conflict vilket förstärker tidigare forskningsresultat på området. I den multivariata regressionsanalysen inkluderas kontroll för demografiska, samt arbetslivsrelaterade variabler och sambandet blir något starkare. Sammanfattningsvis går det positiva sambandet mellan oro för jobbförlust och work-life conflict att generalisera till hela populationen, det vill säga Sveriges arbetande befolkning då resultatet i den multivariata regressionsanalysen är av statistisk signifikans. Dessa resultat bidrar med en ny kontext på forskningsfrågan i och med det bredare urvalet och intressanta samhällsläget. Oro för jobbförlust anställningsotrygghet work-life conflict work-family conflict work interfering with life life interfering with work Sociology Sociologi
83	Identification of Molecular Determinants that Shift Co- and Post-Translational N-Glycosylation Kinetics in Type I Transmembrane Peptides: A Dissertation Malaby, Heidi L. H. 07 April 2014 (has links) Asparagine (N)-linked glycosylation occurs on 90% of membrane and secretory proteins and drives folding and trafficking along the secretory pathway. The N-glycan can be attached to an N-X-T/S-Y (X,Y ≠ P) consensus site by one of two oligosaccharyltransferase (OST) STT3 enzymatic isoforms either during protein translation (co-translational) or after protein translation has completed (post-translational). While co-translational N-glycosylation is both rapid and efficient, post-translational N-glycosylation occurs on a much slower time scale and, due to competition with protein degradation and forward trafficking, could be detrimental to the success of a peptide heavily reliant on post-translational N-glycosylation. In evidence, mutations in K+ channel subunits that shift N-glycosylation kinetics have been directly linked to cardiac arrhythmias. My thesis work focuses on identifying primary sequence factors that affect the rate of N-glycosylation. To identify the molecular determinants that dictate whether a consensus site acquires its initial N-glycan during or after protein synthesis, I used short (~ 100-170 aa) type I transmembrane peptides from the KCNE family (E1-E5) of K+ channel regulatory subunits. The lifetime of these small membrane proteins in the ER translocon is short, which places a significant time constraint on the co-translational N-glycosylation machinery and increases the resolution between co- and post-translational events. Using rapid metabolic pulse-chase experiments described in Chapter II, I identified several molecular determinants among native consensus sites in the KCNE family that favor co-translational N-glycosylation: threonine containing-consensus sites (NXT), multiple N-terminal consensus sites, and long C-termini. The kinetics could also be shifted towards post-translational N-glycosylation by converting to a serine containing-consensus site (NXS), reducing the number of consensus sites in the peptide, and shortening the C-termini. In Chapter III, I utilized an E2 scaffold peptide to examine the N-glycosylation kinetics of the middle X residue in an NXS consensus site. I found that large hydrophobic and negatively charged residues hinder co-translational N-glycosylation, while polar, small hydrophobic, and positively charged residues had the highest N-glycosylation efficiencies. Poorly N-glycosylated NXS consensus sites with large hydrophobic and negatively charged X residues had a significantly improved co-translational N-glycosylation efficiency upon conversion to NXT sites. Also in Chapter III, I adapted a siRNA knockdown strategy to definitively identify the OST STT3 isoforms that perform co- and post-translational N-glycosylation for type I transmembrane substrates. I found that the STT3A isoform predominantly performs co-translational N-glycosylation while the STT3B isoform predominantly performs post-translational N-glycosylation, in agreement with the roles of these enzymatic subunits on topologically different substrates. Taken together, these findings further the ability to predict the success of a consensus site by primary sequence alone and will be helpful for the identification and characterization of N-glycosylation deficiency diseases. Asparagine Consensus Sequence Glycosylation Kinetics Membrane Proteins Voltage-Gated Potassium Channels RNA Small Interfering Dissertations, UMMS Potassium Channels, Voltage-Gated RNA, Small Interfering Biochemistry Molecular Biology Organic Chemistry
84	Single-Molecule Imaging Reveals that Argonaute Re-Shapes the Properties of its Nucleic Acid Guides: A Dissertation Salomon, William E. 07 December 2015 (has links) Small RNA silencing pathways regulate development, viral defense, and genomic integrity in all kingdoms of life. An Argonaute (Ago) protein, guided by a tightly bound, small RNA or DNA, lies at the core of these pathways. Argonaute uses its small RNA or DNA to find its target sequences, which it either cleaves or stably binds, acting as a binding scaffold for other proteins. We used Co-localization Single-Molecule Spectroscopy (CoSMoS) to analyze target binding and cleavage by Ago and its guide. We find that both eukaryotic and prokaryotic Argonaute proteins re-shape the fundamental properties of RNA:RNA, RNA:DNA, and DNA:DNA hybridization: a small RNA or DNA bound to Argonaute as a guide no longer follows the well-established rules by which oligonucleotides find, bind, and dissociate from complementary nucleic acid sequences. Counter to the rules of nucleic acid hybridization alone, we find that mouse AGO2 and its guide bind to microRNA targets 17,000 times tighter than the guide without Argonaute. Moreover, AGO2 can distinguish between microRNA-like targets that make seven base pairs with the guide and the products of cleavage, which bind via nine base pairs: AGO2 leaves the cleavage products faster, even though they pair more extensively. This thesis presents a detailed kinetic interrogation of microRNA and RNA interference pathways. We discovered sub-domains within the previously defined functional domains created by Argonaute and its bound DNA or RNA guide. These sub-domains have features that no longer conform to the well-established properties of unbound oligonucleotides. It is by re-writing the rules for nucleic acid hybridization that Argonautes allow oligonucleotides to serve as specificity determinants with thermodynamic and kinetic properties more typical of RNA-binding proteins than that of RNA or DNA. Taken altogether, these studies further our understanding about the biology of small RNA silencing pathways and may serve to guide future work related to all RNA-guided endonucleases. Small Interfering RNA Argonaute Proteins RNA Interference Drosophila Proteins Nucleic Acid Hybridization MicroRNAs Molecular Imaging Dissertations, UMMS RNA, Small Interfering Amino Acids, Peptides, and Proteins Biochemistry Molecular Biology
85	Functions of Argonaute Proteins in Self Versus Non-Self Recognition in the C. elegans Germline: A Dissertation Seth, Meetu 18 August 2016 (has links) Organisms employ sophisticated mechanisms to silence foreign nucleic acid, such as viruses and transposons. Evidence exists for pathways that sense copy number, unpaired DNA, or aberrant RNA (e.g., dsRNA), but the mechanisms that distinguish “self” from “non-self” are not well understood. Our studies on transgene silencing in C. elegans have uncovered an RNA surveillance system in which the PIWI protein, PRG-1, uses a vast repertoire of piRNAs to recognize foreign transcripts and to initiate epigenetic silencing. Partial base pairing by piRNAs is sufficient to guide PRG-1 targeting. PRG-1 in turn recruits RdRP to synthesize perfectly matching antisense siRNAs (22G-RNAs) that are loaded onto worm-specific Argonaute (WAGO) proteins. WAGOs collaborate with chromatin factors to maintain epigenetic silencing (RNAe). Since mismatches are allowed during piRNA targeting, piRNAs could—in theory— target any transcript expressed in the germline, but germline genes are not subject to silencing by RNAe. Moreover, some foreign sequences are expressed and appear to be adopted as “self.” How are “self” transcripts distinguished from foreign transcripts? We have found that another Argonaute, CSR-1, and its siRNAs—also synthesized by RdRP—protect endogenous genes from silencing by RNAe. We refer to this pathway as RNA-mediated gene activation (RNAa). Reducing CSR-1 or PRG-1 or increasing piRNA targeting can shift the balance towards expression or silencing, indicating that PRG-1 and CSR-1 compete for control over their targets. Thus worms have evolved a remarkable nucleic acids immunity mechanism in which opposing Argonaute pathways generate and maintain epigenetic memories of self and non-self nucleotide sequences. RNA Interference Small Interfering RNA Argonaute Proteins Caenorhabditis elegans Proteins Dissertations, UMMS RNA, Small Interfering Biochemistry Developmental Biology Genetics and Genomics Molecular Biology
86	TECHNIQUE FOR DETERMINING THE POWER FLUX DENSITY OF INTERFERING SIGNALS AT TELEMETRY RECEIVING STATIONS Law, Eugene 10 1900 (has links) ITC/USA 2005 Conference Proceedings / The Forty-First Annual International Telemetering Conference and Technical Exhibition / October 24-27, 2005 / Riviera Hotel & Convention Center, Las Vegas, Nevada / This paper will present techniques for accurately measuring the power flux density (PFD) of interfering signals at telemetry receiving stations. The solar power flux density is measured daily by radio astronomers and will be used as a calibration signal. The electromagnetic spectrum is being used more intensely as time marches on so being familiar with interference measurement techniques is becoming more important because more interfering signals are present. Telemetry power flux density interfering signal levels interference solar flux density
87	Gene organization of the lobster (Homarus americanus) Gonad inhibitinghormone, and its functional analysis in relation to vitellogenesis byRNA interference So, King-yip, Ken., 蘇景業. January 2008 (has links) published_or_final_version / Biological Sciences / Master / Master of Philosophy Peptide hormones. Small interfering RNA. Gene silencing. Lobsters - Reproduction. Lobsters - Genetics.
88	Glucose-regulated protein 78 as a novel target of BRCA1 for inhibitingstress-induced apoptosis Kwan, Wai-yin., 關偉然. January 2009 (has links) published_or_final_version / Biological Sciences / Master / Master of Philosophy Tumor suppressor proteins. Heat shock proteins. Small interfering RNA. Gene expression. Apoptosis.
89	Dysregulation of microRNAs in tongue squamous cell carcinoma Liu, Xiaobing, 劉小兵 January 2008 (has links) published_or_final_version / Surgery / Doctoral / Doctor of Philosophy Small interfering RNA. Tongue - Cancer - Genetic aspects.
90	Studies on antiviral effects of siRNAs against H5N1 influenza A virus infection Sui, Hongyan., 隋洪艷. January 2008 (has links) published_or_final_version / Microbiology / Doctoral / Doctor of Philosophy Small interfering RNA. Avian influenza A virus. Virus diseases - Genetic aspects. Antiviral agents.

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