Global ETD Search

291	The p97 ATPase and the Drosophila Proteasome : Protein Unfolding and Regulation Björk Grimberg, Kristian January 2010 (has links) For all living systems, there is a requirement to recycle and regulate proteins. In eukaryotic organisms this is accomplished by the proteasome. The p97 ATPase is another highly conserved and essential complex present throughout the eukaryotic cell. In Paper I we utilized UFD fluorescent substrates to address the role of p97 and cofactors in soluble proteasome degradation. Results using RNAi and Drosophila p97 mutants propose p97 to function upstream of the proteasome on cytosolic proteasome targets as an important unfoldase together with its Ufd1/Npl4 cofactors. The results implicate p97 to be important for degradation of proteasome substrates lacking natural extended peptide regions. In Paper II we focused on identifying transcription factors essential for production of proteasomal subunits and associated proteins in Drosophila S2 cells. We utilized an RNA library targeting 993 known or candidate transcription factors and monitored RNAi depleted Drosophila S2 cells expressing the UFD reporter UbG76VGFP. We identified a range of potential candidates and focused on the bZIP transcription factor Cnc-C. RNAi and qrt-PCR experiments implicated Cnc-C to be involved in transcription of proteasomal subunits. In Paper III we applied our knowledge gained from Paper I about p97 dependent substrates and set up a high-throughput microscopy screening method to potentially find inhibitors specifically targeting the p97 proteasomal sub-pathway. Utilizing UFD substrates with and without C-terminal peptide tails we determined if compounds inhibited the core proteasomal machinery or the p97 pathway specifically. Through a primary and secondary round of screening we identified several new compounds inhibiting the ubiquitin-proteasome pathway though none from our initial screening had specificity for p97. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Manuscript. proteasome ubiquitin p97 unfolding regulation RNAi screen high-throughput screen cnc basic leucine zipper transcription factors proteasome inhibition Molecular biology Molekylärbiologi
292	Développement de nanoparticules lipidiques pour la délivrance de courtes séquences d'ARN interférents / Designing of lipid nanoparticles for active delivery of siRNA Bruniaux, Jonathan 01 December 2014 (has links) L'ARN interférence est un mécanisme d'inhibition post-transcriptionnel, capable de réguler l'expression des gènes. Ce mécanisme endogène, activé par l'intermédiaire de microARN, peut être détourné après transfection de cours fragments d'ARN synthétiques, notamment les siARN. Cette technique autorise ainsi le ciblage spécifique de l'ensemble des gènes composant le génome, dont l'extinction transitoire permet d'étudier à la fois leurs fonctions, mais aussi de découvrir de nouvelles cibles thérapeutiques ou de nouveaux biomarqueurs. Ce très fort potentiel pour la recherche in vitro se retrouve également in vivo, où l'ARN interférence peut être directement utilisé comme agent thérapeutique pour des situations pathologiques telles que les cancers, les infections ou les maladies systémiques. Cependant, la délivrance intra-cytoplasmique des ARN interférents exogènes est nécessaire pour déclencher ce mécanisme de régulation. À l'heure actuelle, en dépit de nombreuses méthodes de transfection développées dans la littérature, cette étape de délivrance reste une limite importante selon les applications envisagées.En ce sens, ces travaux de thèse ont permis de développer un nouveau vecteur à base de nanoparticules lipidiques cationiques, les cLNP, dédié à la transfection cellulaire de siARN. Cette formulation de cLNP a été adaptée, à l'aide d'un plan d'expérience, d'une formulation neutre de LNP permettant l'encapsulation de molécules lipophiles pour des applications en imagerie de fluorescence et/ou de délivrance de médicaments liposolubles. Les caractérisations physico-chimiques des particules cLNP ont démontré une très forte stabilité colloïdale, à la fois pour dans les tampons aqueux et dans les milieux de culture cellulaire complémentés par du sérum. En outre, ces nano-vecteurs se sont avérés extrêmement efficaces pour établir et conserver des liaisons électrostatiques avec des siARN, permettant ainsi d'obtenir rapidement des complexes démontrant une stabilité élevée dans le temps. Les efficacités d'inhibition fonctionnelle de ces nanoparticules ont été testées avec succès sur 3 lignées cellulaires différentes (PC3, HeLa et U2OS). L'ensemble des résultats obtenus confirme le fort potentiel de ce nouveau nano-vecteur, en termes d'inhibition fonctionnelle et d'absence de cytotoxicité, et le positionne parmi les meilleurs agents de transfection commerciaux testés. Ces caractéristiques sont complétées par des capacités de multi-modalité, dont la possibilité d'encapsuler dans le cœur des particules des drogues ou des fluorophores lipophiles. Enfin, des tests préliminaires réalisés sur des cellules considérées comme difficile à transfecter (cellules primaires, cellules non-adhérentes, neurones), ou sur des structures cellulaires tridimensionnelles plus complexes, ouvrent de nouvelles perspectives extrêmement prometteuses. / L'auteur n'a pas fourni de résumé en anglais Nanovecteur lipidique SiARN ARNi Transfection in-vitro Innocuité Criblage haut-débit Lipid nanocarrier SiRNA RNAi In vitro transfection Safety High-througput screening 570
293	Studium poruch cytochrom c oxidasy a ATP synthasy na biochemické a molekulární úrovni / Biochemical and molecular studies of cytochrome c oxidase and ATP synthase deficiencies Fornůsková, Daniela January 2011 (has links) Mgr. Daniela Fornuskova PhD thesis Biochemical and molecular studies of cytochrome c oxidase and ATP synthase deficiencies ABSTRACT The mammalian organism fully depends on the oxidative phosphorylation system (OXPHOS) as the major energy (ATP) producer of the cell. Disturbances of OXPHOS may be caused by mutations in either mitochondrial DNA (mtDNA) or nuclear DNA (nDNA). One part of the thesis is focused on the role of early and late assembled nuclear-encoded structural subunits of cytochrome c oxidase (CcO) as well as Oxa1l, the human homologue of the yeast mitochondrial Oxa1 translocase, in the biogenesis and function of the human CcO complex using stable RNA interference of COX4, COX5A, COX6A1 and OXA1L, as well as expression of epitope-tagged Cox6a, Cox7a and Cox7b, in HEK (human embryonic kidney)- 293 cells. Our results indicate that, whereas nuclear- encoded CcO subunits Cox4 and Cox5a are required for the assembly of the functional CcO complex, the Cox6a subunit is required for the overall stability of the holoenzyme. In OXA1L knockdown HEK-293 cells, intriguingly, CcO activity and holoenzyme content were unaffected, although the inactivation of OXA1 in yeast was shown to cause complete absence of CcO activity. In addition, we compared OXPHOS protein deficiency patterns in mitochondria from skeletal...
294	In vivo study of the suppression of cell-autonomous and systemic RNA silencing by the Peanut clump virus protein P15 / Caractérisation in vivo de la suppression du RNA silencing intracellulaire et systémique par la protéine P15 du Peanut clump virus Incarbone, Marco 05 December 2016 (has links) Chez les plantes, le RNA silencing (RNAi) est le principal mécanisme de défense antivirale. Il est opéré par de petites molécules d’ARN (siRNA), de 21-22nt de long, générées à partir de l’ARN viral par DCL4 et DCL2, respectivement. Ces siRNA confèrent la séquence-spécificité des réactions de défense intracellulaire et peuvent se déplacer à longue distance pour immuniser les cellules saines. En conséquence, les virus ont développé des protéines (VSRs) capables de supprimer ces deux aspects du RNAi. Au cours de cette thèse, j’ai pu démontrer in vivo que la protéine P15 du Peanut clump virus (PCV) est capable de séquestrer les siRNA de 21 et 22nt et qu’elle bloque le mouvement de ces derniers plus efficacement que ceux de 21nt. Pour compenser cette faiblesse, au cours de l’infection par le PCV, P15 est transportée à l’intérieur des peroxisomes en association avec les siRNA qu’elle séquestre. Le confinement des siRNA mobiles de 21nt à l’intérieur de ces organelles conduit à une inhibition du RNAi systémique et stimule fortement la propagation du PCV à travers la plante. Ces travaux définissent une nouvelle stratégie de pathogénèse virale au cours de laquelle une organelle est utilisé pour neutraliser des molécules de défense produites par l’hôte. / In plants, RNA interference (RNAi) is the main antiviral defense mechanism. It is initiated through the processing of viral RNA into 21-22nt long siRNA by DCL4 and DCL2, respectively. These siRNA can mediate sequence-specific local defense reactions (cell-autonomous RNAi) or move to distant tissues to prime defenses in naive cells (systemic RNAi). Consequently, viruses have evolved proteins (VSRs) to suppress both aspects of RNAi. In this in vivo study, I show that P15, the VSR of Peanut clump virus (PCV), binds and sequesters both 21nt and 22nt siRNA. Importantly, it stops the movement of 22nt siRNA more efficiently than 21nt siRNA. During infection, P15 is shuttled into peroxisomes, and is able to « piggyback » siRNA into these organelles. By confining mobile DCL4-dependent antiviral 21nt siRNA within peroxisomes, P15 is able to shut down systemic RNAi and strongly promote PCV movement. This work describes a novel pathogenic strategy in which an organelle is used to neutralize host defensive molecules. Virus SiRNA RNA silencing systémique Suppresseur de RNA silencing Peroxisome Virus SiRNA Non-cell autonomous RNAi Suppressor of RNA silencing Peroxisome Piggyback 572.8 581
295	Vývoj chemických regulátorů drah mikroRNA a RNAi / Vývoj chemických regulátorů drah mikroRNA a RNAi Bruštíková, Kateřina January 2015 (has links) MicroRNAs are noncoding RNAs inducing sequence-specific posttranscriptional inhibition of gene expression and represent the major class of small endogenous RNAs in mammalian cells. Over 2,500 of human microRNAs potentially regulating more than 60% of human protein-coding genes have been identified. MicroRNAs participate in the majority of cellular processes, and their expression changes in various diseases, including cancer. Currently, there is no efficient small chemical compound available for the modulation of microRNA pathway activity. At the same time, small chemical compounds represent excellent tools for research of processes involving RNA silencing pathways, for biotechnological applications, and would have a considerable therapeutic potential. The presented work represents a part of a broader project, whose ultimate goal is: (i) to find a set of small molecules allowing for stimulation or inhibition of RNA silencing and (ii) to identify crosstalks between RNA silencing and other cellular pathways. This thesis summarizes results from the first two phases of the project, the development of high-throughput screening assays and the high- throughput screening (HTS) of available libraries of small compounds. To monitor the microRNA pathway activity, we developed and optimized one biochemical...
296	Delineating the Role of OsMADS1 in Auxin Distribution, Floret Identity and Floret Meristem Determinacy Lhaineikim, Grace January 2016 (has links) (PDF) Rice have highly derived florets borne on a short branch called ‘spikelet’ comprised of a pair of rudimentary glumes and sterile lemma (empty glumes) that subtends a single fertile floret. The floral organs consist of a pair of lodicules, six stamens and a central carpel that are enclosed by a pair of bract-like organs, called lemma and palea. A progressive reprogramming of meristem identity during the floral development of flowers, on branches on the inflorescence, is correlated with changes in transcriptional status of regulatory genes that execute cascades of distinct developmental events. On the other hand phytohormones such as auxin and cytokinin that are critical in predetermining the sites of new organ primordia emergence and in maintaining the size or populations of meristems. Molecular genetic analyses of mutants have expanded the repository of genes regulating floral organ specification and identity, yet the finer mechanistic details on process downstream to these regulatory genes and co-ordination with phytohormone signalling pathways needs further investigation. One aim of the study presented in this thesis is to develop a tool that would display of spatial description of dynamic auxin or cytokinin accumulation in developing rice inflorescence and floral meristems and to evaluate auxin distribution defects of OsMADS1-RNAi florets using this tool. Additionally, we aim to understand the regulatory effects on OsMADS1 on candidate floral organ and meristem fate determining genes during two temporal phases of flower development to decipher other regulatory cascades controlled by OsMADS1. Spatial distribution profile of phytohormones in young and developing meristems of rice Cytokinin promotes meristem activity (Su et al., 2011) while auxin accumulation, directed by auxin efflux transport PIN proteins predicts sites of new organ initiation (Reinhardt et al., 2003; van Mourik et al., 2012). Previous studies in the lab deciphered that OsMADS1 exerts positive regulatory effects on genes in auxin pathways and repressive effects on cytokinin signaling and biosynthetic genes (Khanday et al., 2013). Thus, the need for a reliable system to understand auxin and cytokinin activity in live inflorescence and floral meristems of rice motivated us to raise promoter: reporter tools to map the spatial and temporal phytohormone distribution. Confocal live imaging conditions in primary roots of IR4DR-GFP and DR5-CyPet lines was performed and responsiveness of the DR5 elements to auxin was authenticated. Auxin maxima were distinctly seen in the epidermal and sub-epidermal cells of inflorescence branch primordia anlagen and apices of newly emerged branch primordia. As floral organs were being initiated, on the floret meristem, we discerned the sequential appearance of auxin accumulation at sites of organ primordia while apices of early floral meristems (FM) showed low auxin content. We clearly detect canalization of auxin streams marking regions of vascular inception. Using this live imaging system we probed auxin patterns and levels in malformed and indeterminate OsMADS1-RNAi florets and we observed a significant reduction in the levels of auxin. Two oppositely positioned peaks of auxin were noted in the persistent FM of OsMADS1-RNAi florets, a pattern similar to auxin dynamics at sites of rudimentary glume primordia on the wild-type (WT) spikelet meristem. These studies were followed up with immunohistochemistry (IHC) on fixed tissues for “PIN” transport proteins that suggest PIN convergence towards organ initiation sites, regions where auxin accumulation was clearly visualized by the IR4DR5-GFP and DR5-CyPet reporters. IHC experiments that detected GFP, in fixed tissues of TCSn-mGFP ER (WT) and TCSn-mGFP ER;OsMADS1-RNAi (OsMADS1-RNAi) inflorescence and florets showed an ectopic increase in the domain of cells with cytokinin response in OsMADS1-RNAi florets, compared to that of WT. Intriguingly, cytokinin responsive cells persisted in the central FM of OsMADS1-RNAi florets that might partially account for some of the FM indeterminacy defects seen in these florets. A correlative observation of these different imaging data hint at some exclusive patterns of the IR4DR5/DR5 and TCSn reporters that in turn lead us to speculate that a cross talk between auxin and cytokinin distribution may contribute to the precise phyllotaxy of lateral organs in rice inflorescence. Studies on novel targets of OsMADS1 in floral organ identity and meristem determinacy Loss of OsMADS1 function results in rice florets with miss specified floral organs and an indeterminate carpel produces new abnormal florets. Despite having several mutants in OsMADS1, mechanisms of how OsMADS1 regulates meristem maintenance and termination is not well understood. Global expression profile in OsMADS1-RNAi vs. WT tissues encompassing a wide range of developing florets (0.2 to 2cm panicles), gave an overview of OsMADS1 functions in many aspects of floret development. Here, a gene-targeted knockout of OsMADS1 named - osmads1ko (generated in a collaborative study) was characterized and found to display extreme defects in floral organs and an indeterminate FM. Strikingly, in addition to loss of determinacy, FM reverts to a prior developmental fate of inflorescence on whose new rachis are leaf-like malformed florets. We suggest these phenotypes reflect the null phenotype of OsMADS1 and its role in meristem fate maintenance. We tested gene expression levels for some proven targets of OsMADS1 (Khanday et al., 2013) and utilized panicles in two developmental phases- young early FMs (panicles of 0.2 to 0.5 cm) and older florets with organ differentiation (panicles of 0.5 to 1cm). We observed temporally different effects on the regulation of OsMADS34 that together with histology of young osmads1ko inflorescences suggest that the mutant is impeded for spikelet to floral meristem transition. In addition, OsMADS1 had a positive regulatory effect on genes implicated for lemma and palea organ identity such as OsIDS1, OsDH1, OsYABBY1, OsMADS15, OsMADS32, OsDP1 and OsSPL16 in both young and old panicles while OsIG1 was negatively regulated in both phases of development. MADS-box genes important for carpel and ovule development - OsMADS13 and OsMADS58 were had significantly reduced expression in florets undergoing organ differentiation. OsMADS1 positively regulated several other non MADS-box developmental genes - OsSPT, OsHEC2 and OsULT1, whose Arabidopsis homologs control carpel development and FM determinacy. These genes are de-regulated in later stages of osmads1ko floret development and are unaffected in younger panicles. Finally, OsMADS1 continually activated meristem maintenance genes - OsBAM2-like and OsMADS6 while the activation of OSH1 in early floral meristems was later altered to a repressive effect in developing florets. Perhaps such dynamic temporal effects on meristem genes are instrumental in the timely termination of the floral meristem after floral organ differentiation. More importantly, we show that regulation of many of these genes is directly affected by OsMADS1, through our studies on expression levels before and after chemical induction of OsMADS1-GR protein in amiRNAOsMADS1 florets. Further, some key downstream targets were re-affirmed by studying expression status in transgenic lines, with the OsMADS1-EAR repressive protein variant. These results provide new insights into the developmentally phased roles of OsMADS1 on floral meristem regulators and determinants of organ identity to form a determinate rice floret. Gene networks regulated by OsMADS1 during early flower development To identify global targets in early floret meristems, we determined the differential RNA transcriptome in osmads1ko tissues as compared to wild-type tissues. These data revealed regulators of inflorescence architecture, floral organ identity including MADS-box floral homeotic factors, factors for meristem maintenance, auxin response, transport and biosynthesis as some of the important functional classes amongst the 2725 differentially expressed genes (DEGs). Integrating DEGs with OsMADS1 ChIP-seq data (prior studies from our lab) we deciphered direct vs. indirect and positive vs. negatively regulated targets of OsMADS1. These datasets reveal an enrichment for functional categories such as metabolic processes, signaling, RNA transcription and processing, hormone metabolism and protein modification. Using Bio-Tapestry plot as a tool we present a visualization of a floral stage-specific regulatory network for genes with likely functional roles in meristem specification and in organ development. Further, to examine if indirect targets regulated by OsMADS1 could be mediated through transcription factors (that are themselves direct targets), we constructed a small network with the transcription factors OSH1, OSH15 and OsYABBY1 as key nodal genes and we predicted their downstream effects. Taken together, these analyses provide examples of the complex networks that OsMADS1 controls during the process of rice floret development. In summary, we surmise that defect in phytohormone distribution in OsMADS1 knockdown florets results in irregular patterns of lateral organ primordia emergence. In addition, the derangements in the developmentally stage specific expression of floral meristems identity and organ identity genes culminates in miss-specified and irregularly patterned abnormal organs in Osmads1 florets. Thus, our study highlights the versatility of OsMADS1 in regulating components of hormone signaling and response, and its effects on various floral development regulators results in the formation of a single determinate floret on the spikelet. References: Khanday I, Yadav S.R, and Vijayraghavan U. (2013). Plant Physiol 161, 1970–1983. van Mourik S , Kaufmann K, van Dijk AD, Angenent G.C, Merks R.M.H, Molenaar J. (2012). PLOS One 1, e28762 Reinhardt D, Pesce E, Stieger P, Mandel T, Baltensperger K, Bennett M, Traas J, Friml J and Kuhlemeier C. (2003). Nature 426, 255-260 Su Y, Liu Y and Zhang X. (2011) Mol Plant 4, 616–625 Rice Meristem Horet Meristem Determinacy OsMADS1 Spikelet Meristems of Rice OsMADS1-RNAi Florets Meristem Determinacy Phytochromosomes Distribution Floral Meristem Development Cell Biology
297	Dynamique de l’émergence in vitro des mutants d’échappement du virus de la peste des petits ruminants (PPRV) face à l’activité ARN interférente ciblant le gène de la nucléoprotéine : implications pour les stratégies thérapeutiques / Dynamics of the in vitro emergence of escape mutants of the peste des petits ruminants virus (PPRV) to interfering RNAs targeting the nucleoprotein gene : implications for therapeutics Holz Correia, Carine Lidiane 04 November 2011 (has links) Les membres du genre Morbillivirus, famille Paramyxoviridae sont responsables de graves maladies chez l'homme et les animaux, comme la rougeole, la peste bovine (RP) et la peste des petits ruminants (PPR). Malgré l'existence de vaccins efficaces contre ces maladies, des traitements spécifiques sont souhaitables. L'inhibition de la réplication de ces virus peut-être acquise par interférence ARN (ARNi), un mécanisme d'inhibition post-transcriptionnel déclenché par des séquences courtes d'ARN double-brin (siARN). Le CIRAD a précédemment identifié 3 siARNs ciblant des régions conservées du gène de la nucléoprotéine virale capables d'inhiber au moins 80% de la réplication in vitro des virus de la rougeole, de la RP et de la PPR. Cependant, un problème majeur dans la stratégie d'ARNi est le risque d'apparition de virus résistants. Dans cette étude, nous avons évalué le risque d'apparition de mutants d'échappement du virus de la PPR sous pression de sélection de 3 siARNs appliqués seul ou en association après plusieurs transfections successives in vitro. Excepté pour la combinaison des 3 siARNs, le virus a échappé à l'ARNi après 3 à 20 passages consécutifs, avec des mutations simples ou multiples (synonymes ou pas) ou une délétion de 6 nucléotides dans la zone cible des siARN. Ces résultats mettent en évidence une plasticité génomique inattendue des morbillivirus surtout illustrée par cette délétion non-délétère d'une partie significative d'un gène viral essentiel, qui devrait être considérée comme un obstacle à l'utilisation de l'ARNi comme thérapie antivirale. Cependant, l'utilisation combinée de 3 siARNs peut être proposée pour diminuer le risque d'échappement aux siARNs. / Viruses in the genus Morbillivirus, within the family Paramyxoviridae are responsible for severe humans and animal diseases, including measles, rinderpest (RP) and peste des petits ruminants (PPR). In spite of the existence of efficient vaccines against these diseases, specific treatments to be applied when the infection is already present are desirable. Inhibition of morbillivirus replication can be achieved by RNA interference (RNAi), a mechanism of post-transcriptional gene silencing triggered by small double-stranded RNA (siRNA). The CIRAD previously identified three siRNAs that target conserved regions of the essential gene encoding the viral nucleoprotein and are able to prevent in vitro at least 80% of the replication of measles, RP and PPR viruses . However, a major problem in RNAi is the important risk of emergence of escape mutants. In this study, we investigated the ability of PPR virus to escape the inhibition conferred by single or multiple siRNAs after several consecutive transfections in vitro. Except with the combination of the three different siRNAs, the virus systematically escaped RNAi after 3 to 20 consecutive passages. The mutations were characterized by either single or multiple punctual nucleotide mutations (synonymous or not) or a deletion of a stretch of 6 nucleotides into the siRNA target. These results demonstrate that the genomic plasticity of morbilliviruses, illustrated maily by this significant and no-deleterious deletion in an essential viral gene, should be considered as an obstacle to the use of RNAi in antiviral therapy. However, the combined use of three siRNAs can be proposed to prevent treatment failure with siRNAs. Morbillivirus Interférence ARN (ARNi) SiARN Virus d’échappement Thérapie antiviral Morbillivirus Peste des petits ruminants virus (PPRV) RNA interference (RNAi) SiRNA Escape virus Antiviral therapy
298	Knockdown of vitellogenin by RNAi increases survivorship but exhibits similar physiological responses to ovariectomy in grasshoppers Linquist, Alicia G. 01 January 2013 (has links) Reduced reproduction has been shown to increase lifespan in many animals, yet the mechanisms behind this trade-off are mostly unknown. A previous study has shown that in the lubber grasshopper, Romalea microptera, ovariectomized (OVX) individuals have a 30% increase in lifespan relative to controls (Sham). In a separate study, an increase in fat body mass and a halting of ovarian growth were seen upon reduction of vitellogenin transcript via RNAi (VgRNAi). These data suggest that VgRNAi increases lifespan through the trade-off between reproduction and longevity and animals with combined ovariectomy and VgRNAi, might show additive physiological responses. In this study, we used two injection control groups for the VgRNAi treatment, namely buffer injection or injection with RNAi against a 90kDa hexamerin storage protein (Hex90RNAi). We have combined these manipulations to test lifespans upon: OVX & VgRNAi, OVX & Hex90RNAi, OVX & Buffer, Sham & VgRNAi, Sham & Hex90RNAi, and Sham & Buffer. Ovariectomy and VgRNAi exhibited similar reductions in feeding (~40%) and extensions in lifespan (13-21%) but showed differences in vitellogenin protein levels. This study also observed the effects of reduced reproduction on hexamerin storage proteins. We observed that upon ovariectomy and VgRNAi, hexamerins were increased, emphasizing the importance of protein in insect life extension. When methods to reduce reproduction were combined (OVX VgRNAi), no additive physiological responses were observed, suggesting ovariectomy and VgRNAi each extend lifespan by overlapping or convergent pathways. Thesis University of North Florida UNF Dissertations Dissertations Academic -- UNF -- Biology Romalea microptera VgRNAi vitellogenin RNAi lifespan reduced reproduction Comparative and Evolutionary Physiology Physiology
299	Functional characterization and molecular identification of neuroprotective receptors for erythropoietin-like ligands Hahn, Nina 12 December 2021 (has links) No description available. 570 Neuroprotection Erythropoietin CRLF3 Cytokine receptor-like factor 3 Orphan cytokine receptor Neurodegenerativ diseases Tribolium castaneum Soaking RNAi Locusta migratoria Epo Nervous system Evolution Biologie (PPN619462639)
300	Biochemical Mechanism of Gene Expression Silencing by piRNA-directed PIWI-Clade Argonautes Arif, Amena 10 August 2021 (has links) Argonaute proteins are small DNA/RNA-guided endonucleases found in all domains of life. In animals, small RNAs of length 21–35 nucleotides direct the PIWI-clade of Argonautes to silence complementary target RNAs; these are called PIWI-interacting RNAs (piRNAs). During spermatogenesis in mice, piRNA-guided PIWI proteins, MIWI2, MILI, and MIWI, silence transposons, regulate expression of protein-coding genes and are necessary for fertility. A working endonuclease activity of MIWI and MILI is essential to complete spermatogenesis. Yet, both MIWI and MILI produce weak and slow target cleavage in vitro, thwarting biochemical examination of the silencing step. Here, we find that PIWI proteins require an auxiliary protein to efficiently cleave their targets, unlike any other known Argonaute. Gametocyte Specific Factor 1 (GTSF1) is a conserved zinc-finger protein essential for fertility and piRNA-directed silencing. We show GTSF1 accelerates the pre-steady-state rate of target cleavage by MIWI and MILI; this role of GTSF1 is also preserved in insects. A critical step in GTSF1 mechanism entails binding RNA. GTSF1 allowed detailed kinetic analyses of catalytic PIWIs: they require extensive 3′ complementarity between the guide and target to efficiently cleave them, but this base-pairing also limits turnover. Interestingly, within a species, different PIWI proteins have unique kinetic properties. In sum, our findings provide molecular mechanisms of GTSF1 function and target silencing by PIWIs as well as a useful method for future studies. piRNA PIWI Argonaute Zinc-Finger GTSF1 Spermatogenesis RNAi miRNAs siRNAs Asterix Evolution small RNA methylation non-coding RNAs small-silencing RNAs Biochemistry Molecular Biology

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