Global ETD Search

131	Molecular mechanisms involved in the pathogenesis of beet soil-borne viruses / Mécanismes moléculaires à l'origine de la pathogenicité de phytovirus de betterave sucrière transmis par un vecteur tellurique Delbianco, Alice 11 April 2013 (has links) Le virus des nervures jaunes et nécrotiques de la betterave (Beet necrotic yellow vein virus, BNYVV) est l’agent infectieux responsable de la rhizomanie de la betterave sucrière, une maladie caractérisée par une prolifération anarchique du chevelu racinaire. Le Beet soil-borne mosaic virus (BSBMV) appartient également au genre Benyvirus mais n’est retrouvé qu’en Amérique du Nord. Ce virus, identifié pour la première fois au Texas, est morphologiquement et génétiquement semblable au BNYVV mais sérologiquement éloigné. Compte tenu des différences moléculaires existant, le BSBMV et BNYVV correspondent à deux espèces virales distinctes. Mon projet de thèse a consisté à étudier les interactions moléculaires entre le BNYVV et le BSBMV et rechercher les mécanismes impliqués dans la pathogénicité de ces deux virus. Des clones complets cDNA infectieux du BNYVV étaient disponibles, tout comme ceux de BSBMV. Compte tenu de l’aspect versatile de l’obtention de transcrits infectieux de ces différents clones, j’ai entrepris de produire des clones cDNA de chacun des ARN viraux sous contrôle d’un promoteur constitutive végétal pour initier l’infection par agroinfiltration. Les plantes hôtes Chenopodium quinoa et Nicotiana benthamiana ont été inoculées par des transcrits et agroinfiltrées pour initier l’infection virale et étudier l’interaction entre les ARN génomiques 1 et 2 des deux virus et étudier les propriétés de constructions chimères. En parallèle à ce travail, j’ai réalisé la caractérisation du suppresseur de RNA silencing du BSBMV en le comparant à celui du BNYVV. / The genus Benyvirus includes the most important and widespread sugar beet viruses transmitted through the soil by the plasmodiophorid Polymyxa betae. In particular Beet necrotic yellow vein virus (BNYVV), the leading infectious agent that affects sugar beet, causes an abnormal rootlet proliferation known as rhizomania. Beet soil-borne mosaic virus (BSBMV) is widely distributed in the United States and, up to date has not been reported in others countries. My PhD project aims to investigate molecular interactions between BNYVV and BSBMV and the mechanisms involved in the pathogenesis of these viruses.BNYVV full-length infectious cDNA clones were available as well as full-length cDNA clones of BSBMV RNA-1, -2, -3 and -4. Handling of these cDNA clones in order to produce in vitro infectious transcripts need sensitive and expensive steps, so Ideveloped agroclones of BNYVV and BSBMV RNAs, as well as viral replicons allowing the expression of different proteins.Chenopodium quinoa and Nicotiana benthamiana plants have been infected with in vitro transcripts and agroclones to investigate the interaction between BNYVV and BSBMV RNA-1 and -2 and the behavior of artificial viral chimeras. Simultaneously I characterized BSBMV p14 and demonstrated that it is a suppressor of posttranscriptional gene silencing sharing common features with BNYVV p14. Benyvirus Rhizomanie RNA silencing Beet necrotic yellow vein virus Beet soil-borne mosaic virus Benyvirus Agroinfection Post-transcriptional gene silencing P14 Chimeras 579.2
132	Rôle du gène de floraison VvFT dans la mise en place de la floraison chez la vigne : mise en évidence des mécanismes d'extinction génique chez la vigne et de leurs réponses face aux stress abiotiques / Rôle VvFT flowering gene in the establishment of flowering in grapes : demonstration of gene silencing mechanisms in grapevine and their response ta abiotic stress Romon, Marjorie 19 September 2013 (has links) Chez la vigne, les gibbérellines activent le débourrement des bourgeons latents et stimulent la formation de vrilles mais contrairement à Arabidopsis, celles-ci semblent inhiber la formation d'inflorescences. Par ailleurs, comme la floraison de la vigne n'est pas sensible à la photopériode,on peut se demander si l'orthologue du gène FT (VvFT) a tout de même un rôle intégrateur au niveau des feuilles et s'il active l'expression de l'orthologue du gène LFY (VFL). Dans la première partie de ma thèse, nous avons conduit une analyse moléculaire avec un matériel original : un porte-greffe 41 B transformé avec une construction contenant le gène VvFT sous contrôle du promoteur 35S et une plante dérivée du Pinot Meunier, portant une mutation dans le gène GA-INSENSITIVE (GAl). Notre étude montre que les gibbérellines ou/et le gène VvFT activent les gènes de floraison comme VFL. mais avec des réponses très différentes entre la vrille, les bourgeons latents et les inflorescences.Dans la seconde partie de ma thèse, nous nous sommes intéressés au silencing. Nous avons produit des plantes transgéniques de la lignée PN40024 contenant soit le gène codant la GFP, soit une construction tige-boucle GF-FG, soit les deux. Les cals embryogènes transgéniques GFP et GFP+GF-FG sont fluorescents. Par contre, nous avons observé une disparition totale de la fluorescence chez ces PN40024 GFP+GF-FG, dès l'apparition des premières feuilles et chez la plante entière. L'étude moléculaire a mis en évidence des petits ARNs de 21 nt et 24nt produits à partir de la construction tige-boucle GF-FG. Des petits ARNs secondaires de 21 nt produit à partir de la séquence de la GFP ont été également été détectés. / In grapevine, gibberellins activate latent bud and stimulate the formation of tendrils but in contrast to Arabidopsis, they appear to inhibit the formation of inflorescences. Moreover, as the flowering of the grapevine is not sensitive ta photoperiod, one might wonder whether the ortholog of the FTgene (VvFT) still has an integrative raie in leaves and it activates the expression of the ortholog ofLFY gene (VFL). ln the first part of my thesis, we conducted a molecular analysis with original material: a rootstock 41 B transformed with a construct containing the VvFT gene under the control of the 35S promoter and a derivative of the plant Pinot Meunier, carrying a mutation in the GA-INSENSITIVE gene (GAl). Our study shows that gibberellins and 1 or the gene VvFT activate genes in flowering as a VFL, but with very different responses between the tendril, latent buds and inflorescences.ln the second part of my thesis, we are interested in silencing. We produced transgenic plants of the PN40024 which line containing either the gene encoding GFP, a stem-loop structure GF-FG, orbath. The embryogenic callus transgenic GFP and GFP + GF-FG fluoresce. We observed acomplete disappearance of fluorescence in PN40024 GFP + GF-FG, from the first leaves appear and in the whole plant Molecular analysis revealed small RNAs of 21 nt and 24nt produced from the stem-loop structure GF-FG. Small secondary 21 nt RNAs produced from the sequence of the GFP were also detected. Vigne Floraison VFL/Leafy FT Silencing / PTGS GFP RDR6 Gibbéréllines Grapevine Flowering gene VFL/Leafy FT Silencing / PTGS GFP RDR6 Gibberellins 572.8
133	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...
134	Molecular Mechanism of RNA-Mediated Gene Silencing in Human Cells: A Dissertation Chu, Chia-Ying 09 October 2008 (has links) Small non-coding RNAs regulate gene expression at posttranscriptional level in eukaryotic cells. Two classes of such small (~21-25 nt) RNAs that have been extensively studied in gene silencing are short interfering RNAs (siRNAs) and microRNAs (miRNAs). RNA interference (RNAi) is process whereby double-stranded RNA induces the sequence-specific degradation of homologous mRNA. The RNAi machinery can also be programmed in human cells by introducing 21-nt siRNA duplexes that are assembled into RNA-induced silencing complexes (RISC). In this dissertation, systematic analysis of siRNAs with deletions at the passenger and/or guide strand reveals that a short RNAi trigger, 16-nt siRNA, induces potent RNAi in human cells. The 16-nt siRNA more effectively knocked down mRNA and protein levels than 19-nt siRNA when targeting the endogenous CDK9 gene. In vitro kinetic analysis of human RISC indicates that 16-nt siRNA has a higher RISC-loading capacity than 19-nt siRNA. These results suggest that 16-nt duplexes can be designed as potent triggers for RNAi. RISC can be programmed by small interfering RNAs (siRISC) to cleave a perfectly complementary target mRNA, or endogenous microRNAs (miRISC) to inhibit translation by binding imperfectly matched sequences in the 3’-untranslated region (3’-UTR) of target mRNA. Both RISCs contain Argonaute2 (Ago2), which localizes to cytoplasmic mRNA processing P-bodies. This dissertation shows that RCK/p54, a DEAD box helicase, interacts with Ago2, in affinity-purified active siRISC or miRISC, facilitates formation of P-bodies. Depletion of RCK/p54 disrupted P-bodies and dispersed Ago2 throughout the cytoplasm, but did not significantly affect siRNA-mediated RNAi. Depleting RCK/p54 releases general and miRNA-induced translational repression. These findings imply that miRISC-mediated translation repression requires RCK/p54, also suggest that location of miRISC to P-bodies is not required for miRNA function, but is the consequence of translation repression. To elucidate the function of RCK/p54 in miRNA-mediated gene silencing, analysis of a series of YFP-tagged RCK/p54 mutants reveals the motif required for P-body localization, interaction with Ago2, and/or facilitating the miRNA-mediated translation repression. Additionally, rabbit reticulocyte lysate system was used to recapitulate the miRISC function in a cell-free system and confirmed the requirement of RCK/p54 for miRNA function in vitro. Analysis of Ago2 distribution in the polysome profiling in RCK/p54-depleted cells, compared to that in normal cells, revealed that RCK/p54 facilitates miRISC by trapping it at translation initiation complex. These data suggest that interaction of RCK/p54 with Ago2 is involved in the repression of translation initiation of miRNA function. gene silencing short interfering RNAs siRNAs RNA interference RNAi mRNA RNA-induced silencing complexes RISC Genetics and Genomics
135	Contrôle de la différenciation sexuelle de la levure Schizosaccharomyces pombe par un ARN non-codant et la protéine de liaison à l’ARN Mmi1 / Control of sexual differentiation in the yeast Schizosaccharomyces pombe by a non-coding RNA and the RNA binding protein Mmi1 Dangin, Mathieu 27 November 2017 (has links) Au cours des cinq dernières années l’existence d’un contrôle de la transcription par les ARN non-codants longs (lncRNAs) a été décrite dans une large variété d’eucaryotes. Cependant, les mécanismes par lesquels les lncRNAs régulent la transcription restent en grande partie méconnus. Les premiers travaux effectués dans le cadre de cette thèse ont participé à la caractérisation du mécanisme mis en jeu par un lncRNA, nommé nam1, dans le contrôle de l’entrée en différenciation sexuelle chez la levure Schizosaccharomyces pombe. Il a ainsi été montré qu’au cours de sa synthèse le lncRNA nam1 est ciblé par la protéine de liaison à l’ARN Mmi1 et une machinerie de surveillance des ARN qui comprend l’exosome, un complexe de dégradation des ARN conservé au cours de l’évolution. La fixation de Mmi1 au lncRNA nam1 contrôle la terminaison de la transcription de nam1 et empêche ainsi la transcription de se poursuivre et d’interférer alors avec la transcription du gène situé en aval (codant pour une MAP kinase essentielle à l’entrée en différenciation). Les travaux suivant montrent l’implication dans ce mécanisme de la protéine Cti1, un des co-facteurs connus de l’exosome. Fait marquant, ces travaux rapportent aussi l’existence d’un mode de production inédit pour un lncRNA. En effet, ils révèlent que la transcription non-interrompue d’un gène codant conduirait à la production d’un ARN bi-cistronique. La maturation co-transcriptionnelle de cet ARN bi-cistronique produirait, d’un côté, un ARN messager et, de l’autre, le lncRNA nam1. Enfin, ils ont permit la caractérisation initiale d’un nouveau composant de la machinerie de surveillance des ARN recrutée sur nam1 par Mmi1. Ainsi, dans leur ensemble, ces travaux contribuent à une meilleure connaissance des mécanismes pouvant être mis en jeu par un lncRNA et agissant en cis pour réguler l’expression génique et, à travers elle, des processus cellulaires majeurs, tel que la différenciation cellulaire. De plus, ils décrivent un nouveau mécanisme de biogénèse d’un lncRNA. / Over the last five years, the control of transcription mediated by long non-coding RNAs (lncRNAs) has been reported to take place in a wide variety of eukaryotes. However, the mechanisms by which lncRNAs regulate transcription remain relatively poorly described. The first work conducted in the context of this PhD thesis has contributed to the characterization of the mechanism used by a lncRNA, named nam1, to control entry into sexual differentiation of the fission yeast Schizosaccharomyces pombe. It was shown that, while the lncRNA nam1 is being produced, it is targeted by the RNA binding protein Mmi1 and a RNA surveillance machinery that includes the exosome, a conserved complex throughout evolution. The binding of Mmi1 to nam1 lncRNA controls the termination of transcription of nam1, which prevents this non-coding transcription from interfering with the transcription of the downstream gene, coding for a MAP kinase essential to entry into differentiation. The following work shows the importance of the protein Cti1, one of the known co-factor of the exosome, in the nam1-dependent control of sexual differentiation. Remarkably, it also strongly suggests the existence of a new way of producing a lncRNA. Indeed, it reveals that read-through transcription of a protein-coding gene leads to the production of a bi-cistronic RNA, which is co-transcriptionally matured to produce on one side a messenger RNA and on the other side the lncRNA nam1. Finally, this work initiated the characterization of a new component of the RNA surveillance machinery targeting nam1. Collectively, this work brings several insights into the mechanisms used by cis-acting lncRNAs to regulate gene expression and, thereby, major cellular processes such as cell differentiation. Moreover, it also provides insights into the biogenesis of lncRNAs by reporting a new mode of production of lncRNAs. ARN non-Codant Différenciation Sexuelle Silencing Transcriptionnel des Gènes Complexe Exosome Surveillance des ARN Schizossacharomyces pombe Non-Coding RNA Sexual Differentiation Transcriptional Gene Silencing Exosome Complex RNA Surveillance Schizossacharomyces pombe 570
136	Dissection génétique de la résistance végétale contre les virus / Genetic dissection of plant-virus interactions Ma, Xiaofang January 2015 (has links) Résumé : Pour se propager dans les cellules de son hôte et évader les réponses immunitaires, les virus végétaux ont développé plusieurs stratégies de défense. Ici, nous avons investigué les structures génétiques du Apple stem pitting virus (ASPV). Nous avons aussi étudié la diversité moléculaire des isolats d’ASPV provenant des poires en regardant les séquences des gènes CP et TGB afin de mieux comprendre les mécanismes évolutionnaires utilisés par ASPV. Nos études ont démontré que les mutations, incluant les insertions et les délétions, la sélection purificatrice et la recombinaison furent des facteurs importants dans l’évolution du l’ASPV en Chine et possiblement mondialement. Comme tous les virus végétaux, l’ASPV se défend contre le RNA silencing de l’hôte grâce à un suppresseur de RNA silencing (VSR) et nous avons montré que le VSR de l’ASPV est la protéine de capside (CP) du virus. Nous avons aussi établi que la diversité moléculaire cause non seulement une variété de symptômes chez son hôte, Nicotiana occidentalis. Cependant elle cause aussi de la variabilité antigénique chez différents isolats, ce qui mène à des écarts de réactivité sérologique entre isolats. Les plantes ont développé plusieurs stratégies pour se défendre contre les virus. Ici, nous avons étudié comment la plante Arabidopsis se défend contre le Tobacco rattle virus (TRV) via le RNA silencing. Nous avons constaté que les phénomènes de susceptibilité, récupération et virus induced gene silencing (VIGS) sont des mécanismes séparables. Nous avons démontré que les protéines AGO2 et AGO4 sont nécessaires à la susceptibilité initiale au TRV, tandis qu’AGO1 est importante pour les VIGS, tandis que la récupération est médiée par d’autres acteurs qui n’ont pas encore été identifiés. Nos résultats suggèrent l’existence de complexes distincts ciblant différentes populations d’ARN viral et cellulaire. De plus, nous avons montré que la répression de la traduction est un mécanisme important durant la récupération de la plante suite à une infection virale, et que les complexes de décoiffage et de RNA processing jouent des rôles importants dans la dégradation des ARNs viraux. Finalement, nous avons montré que les plantes ayant une mutation dans le gène DCP2 présentent un niveaux de VIGS accrue, ainsi qu’une augmentation des niveaux d’ARN viral. Puisque DCP2 fait partie des complexes de décoiffage qui se trouvent dans des granules spécialisés nommés processing bodies (PBs), cela suggère que les PBs jouent un rôle important dans l’élimination les virus. / Abstract : To live in host cells or to escape from host immunity, plant viruses involved a series of defense strategies. Here we investigated Apple stem pitting virus (ASPV) population structures and molecular diversity of ASPV pear isolates based on its function important gene CP and TGB in China, so as to infer the evolution mechanisms of ASPV. Our study showed that mutations (including insertions or deletions), purifying selection, and recombination were important factors driving ASPV evolutions in China or maybe even in the world. And also ASPV defends against it hosts by encoding a VSR. We also showed that ASPV molecular diversity not only induced different biological properties on its herbaceous host N. occidentails but also resulted in antigenic variation of different ASPV CP isolates, which leaded to differences in serological reactivity among rCPs of different ASPV isolates. Plants have developed a series of mechanisms to defend themselves against viruses. Here we how Arabidopsis defend against. We show that virus susceptibility, recovery, and virus induced gene silencing (VIGS) appear to be separable phenomena, with AGO2 and AGO4 playing important roles in the initial susceptibility to TRV, AGO1 playing an important role in VIGS, and as yet unidentifid players mediating recovery. These results suggest the existence of distinct RNA-induced silencing complexes that target different RNA populations within the cell and over time. Furthermore, we showed that translational repression of viral RNA is likely to play an important role in virus recovery and that decapping function plays an important role in clearing viral RNA from the cell. We also showed that a decapping mutant (DCP2) displayed an increased VIGS and virus RNA accumulation, an important role for PBs in eliminating viral RNA. Apple stem pitting virus CP Pear VSR Argonaute VIGS RNA silencing Arabidopsis Tobacco rattle virus
137	A General Method to Determine the Optimal Profile of Porting Grooves in Positive Displacement Machines: the Case of External Gear Machines Gulati, Sidhant, Vacca, Andrea, Rigosi, Manuel 28 April 2016 (has links) (PDF) In all common hydrostatic pumps, compressibility affects the commutation phases of the displacing chambers, as they switch their connection from/to the inlet to/from the outlet port, leading to pressure peaks, localized cavitation, additional port flow fluctuations and volumetric efficiency reduction. In common pumps, these effects are reduced by proper grooves that realizes gradual port area variation in proximity of these transition regions. This paper presents a method to automatically find the optimal designs of these grooves, taking as reference the case of external gear pumps. The proposed procedure does not assume a specific geometric morphology for the grooves, and it determines the best feasible designs through a multi-objective optimization procedure. A commercial gear pump is used to experimentally demonstrate the potentials of the proposed method, for a particular case aimed at reducing delivery flow oscillations. External gear pumps design optimization relief or silencing grooves ddc:620 rvk:ZQ 5460
138	The development and characterisation of grapevine virus-based expression vectors Du Preez, Jacques 03 1900 (has links) Thesis (PhD (Genetics))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: Grapevine (Vitis vinifera L.) is a very important agricultural commodity that needs to be protected. To achieve this several in vivo tools are needed for the study of this crop and the pathogens that infect it. Recently the grapevine genome has been sequenced and the next important step will be gene annotation and function using these in vivo tools. In this study the use of Grapevine virus A (GVA), genus Vitivirus, family Flexiviridae, as transient expression and VIGS vector for heterologous protein expression and functional genomics in Nicotiana benthamiana and V. vinifera were evaluated. Full-length genomic sequences of three South African variants of the virus (GTR1-1, GTG11-1 and GTR1-2) were generated and used in a molecular sequence comparison study. Results confirmed the separation of GVA variants into three groups, with group III (mild variants) being the most distantly related. It showed the high molecular heterogeneity of the virus and that ORF 2 was the most diverse. The GVA variants GTG11-1, GTR1-2 and GTR1-1 were placed in molecular groups I, II and III respectively. A collaboration study investigating the molecular divergence of GVA variants linked to Shiraz disease (SD), described two interesting GVA variants of group II, namely GTR1-2 and P163-M5 (Goszczynski et al., 2008). The group II variants were found to be closely linked to the expression of SD. GTR1-2 was isolated from a susceptible grapevine plant that never showed SD symptoms (Goszczynski 2007). The P163-M5 variant that resulted in exceedingly severe symptoms in N. benthamiana and is that used as SD positive control by the grapevine industry, was found to contain a 119 nt insert within the native ORF2. Comparative analysis performed on the complete nt and aa sequences of group II GVA variants suggested that the components in the GVA genome that cause pathogenicity in V. vinifera are more complex (or different) to those that cause pathogenicity in N. benthamiana. The three South African variants (GTR1-1, GTG11-1 and GTR1-2) were assembled into fulllength cDNA clones under control of CaMV 35S promoters. After several strategies were attempted, including a population cloning strategy for GTR1-2, none of the clones generated were able to replicate in N. benthamiana plants. A single amino acid substitution at position 13 (Tyr/Y Cys/C) in ORF 5 of the GTR1-2 cDNA clone was shown to abolish or reduce replication of the virus to below a detectable level. Two infectious clones of Israeli variants of GVA (T7-GVA-GR5 and T7-GVA118, obtained from M. Mawassi) were brought under control of a CaMV 35S promoter (35S-GVA-GR5 and 35S-GVA118). Both clones were infectious, able to replicate, move systemically and induce typical GVA symptoms after agroinfiltration in N. benthamiana. These Israeli clones served as backbone for further experiments in characterisation of transient expression and VIGS vectors. The use of GVA as gene insertion vector (35S-GVA118) and gene exchange vector (35S-GVA-GR5- ORF2+sgMP) in N. benthamiana and V. vinifera was compared. The gene insertion vector, 35S-GVA118 was based on the full-length GVA genome. The gene exchange vector, 35SGVA- GR5- ORF2+sgMP, was constructed in this study by elimination of ORF 2 and insertion of a sgMP and unique restriction sites to facilitate transgene insertion. In N. benthamiana both vectors showed similar GUS expression levels and photobleaching symptoms upon virus-induced NbPDS silencing. In V. vinifera limited GUS expression levels and VIGS photobleaching symptoms were observed for the gene insertion vector, 35SGVA118. No GUS expression was observed for the gene exchange vector 35S-GVA-GR5- ORF2+sgMP in this host. As for silencing, one plant, agroinfiltrated with 35S-GVA-GR5- ORF2-VvPDS+sgMP, developed photobleaching symptoms in 3 systemic infected leaves after 4 months. This study showed that GVA can be used as gene insertion and gene exchange vector for expression and VIGS in N. benthamiana, but in grapevine its use is limited to expression and silencing of genes in the phloem tissue. It is also the first report that ORF 2 of GVA is not needed for long distance movement in grapevine. To investigate the possible role of the P163-M5 119 nt insertion and the GVA ORF 2 (of unknown function), in expression of symptoms in plants, ORF 2 of a 35S-GVA-GR5 cDNA clone was removed and subsequently substituted by the corresponding ORFs of four South African GVA variants. Upon agro-infiltration into N. benthamiana leaves, all chimaeric GVA constructs were able to move systemically through the plant. At this stage no correlation could be found between severity of symptoms, the presence of the P163-M5 insert and the specific GVA ORF 2 present in the chimaeras, indicating that other factors in the viral genome or the host plant probably play a crucial role. This study contributed to the pool of available in vivo tools for study and improvement of the valuable grapevine crop. It also opened several exciting research avenues to pursue in the near future. / AFRIKAANSE OPSOMMING: Wingerd (Vitis vinifera L.) is ‘n baie belangrike landboukundige gewas wat beskerm moet word. Om die rede word verskeie in vivo gereedskap vir die bestudering van die wingerdplant, en die patogene wat dit infekteer benodig. Die wingerd genoom se volgorde is bepaal en dus is die volgende logiese stap om die gene te annoteer en funksie daaraan toe te skryf. In hierdie studie is die gebruik van Grapevine virus A (GVA), genus Vitivirus, familie Flexiviridae, as tydelike uitdrukking- en virus-geinduseerde geenuitdowingsvektor vir heteroloë proteïen uitdrukking en funksionele genoomstudies in Nicotiana benthamiana en V. Vinifera getoets. Vollengte genoomvolgordes van drie Suid-Afrikaanse variante van die virus (GTR1-1, GTG11-1 en GTR1-2) is gegenereer en in ‘n molekulêre volgorde vergelyking studie gebruik. Resultate het die verdeling van GVA variante in drie groepe, waar groep III die verste verwant is, bevestig. Dit het ook gewys dat die virus ‘n baie hoë molekulêre heterogeniteit het en dat oopleesraam 2 (ORF 2) die mees divers is. ‘n Samewerking studie waar die molekulêre diversiteit van GVA variante, gekoppel aan Shiraz siekte (SD), ondersoek is, is twee interessante variante van groep II beskryf, naamlik GTR1-2 en P163-M5 (Goszczynski et al., 2008). Groep II variante is vooraf gevind om nou verwant te wees aan die ontwikkeling van SD in wingerd. Die GTR1-2 variant is uit ’n vatbare wingerd plant, wat nooit SD-simptome vertoon het nie, geïsoleer (Goszczynski et al., 2007). In die ORF 2 van die P163-M5 variant, wat simptome van die ergste graad in N. benthamiana geïnduseer het, en ook deur die industrie as betroubare SD-positiewe kontrole gebruik word, is ’n 119 nt invoeging gevind. Die vergelykende analise wat uitgevoer is, het daarop gedui dat die determinante van patogenisiteit in die GVA genoom moontlik meer kompleks kan wees in V. vinifera as in N. benthamiana. Die drie Suid-Afrikaanse variante (GTR1-1, GTG11-1 en GTR1-2) is in afsonderlike vollengte cDNA klone, onder beheer van CaMV 35S promotors, aanmekaargesit. Nadat verskeie kloneringstrategieë, insluitend ’n populasie kloneringstrategie vir die GTR1-2 kloon, gebruik is, het geen een van die cDNA klone die vermoë besit om in N. benthamiana te repliseer nie. ’n Enkele aminosuur substitusie in posisie 13 (Tyr/Y Cys/C) in ORF 5 van die GTR1-2 kloon, het die replisering van die virus tot laer as ’n opspoorbare vlak verlaag. Twee infektiewe klone van Israeliese GVA variante (T7-GVAGR5 en T7-GVA118, verkry van M. Mawassi) is onder beheer van ‘n CaMV 35S promotor geplaas (35S-GVA-GR5 and 35S-GVA118). Beide klone het na agro-infiltrasie in N. benthamiana plante gerepliseer, sistemies beweeg en tipiese GVA simptome geinduseer. Hierdie twee klone het as raamwerk gedien vir verdere eksperimente in karakterisering van tydelike uitdrukkings- en VIGS vektore. Die gebruik van GVA as geen-insvoegingsvektor (35S-GVA118) en geen-vervangingsvektor (35S-GVA-GR5- ORF2+sgMP) is in N. benthamiana en V. vinifera vergelyk. Die geen-invoegingsvektor 35S-GVA118, was op die vollengte GVA genoom gebasseer. Die geen-vervangingsvektor 35S-GVA-GR5- ORF2+sgMP, was in hierdie studie gekonstrueer. Dit is gemaak eerstens deur eliminasie van ORF 2 in die 35S-GVA-GR5 kloon, en tweedens deur die invoeging van ’n subgenomiese promotor van die beweginsproteïen (sgMP) en unieke beperkings-ensiemsetels om klonering van transgene te fasiliteer. Beide vektore het in N. benthamiana vergelykbare GUS uitdrukkingsvlakke en fotobleikende simptome getoon na virus-geinduseerde NbPDS uitdowing. In V. Vinifera is beperkte GUS uitdrukkingsvlakke en VIGS fotobleikende simptome opgemerk met die geen-invoegingsvektor, 35S-GVA118. Geen GUS uitdrukking is in hierdie gasheerplant met die geen-vervangingsvektor opgemerk nie. Slegs een wingerdplant het fotobleikende simptome, na 4 maande in 3 sistemies geïnfekteerde blare gewys, na agroinfiltrasie van die 35S-GVA-GR5- ORF2-VvPDS+sgMP konstruk. Hierdie studie het bevestig dat GVA as geen-invoeging en geen-vervangingsvektor, vir heteroloë proteïenuitdrukking en VIGS, in N. benthamiana gebruik kan word, maar dit blyk of die gebruik daarvan in wingerd meer tot die floeëm weefsel beperk is. Hierdie studie wys vir die eerste keer dat ORF 2 nie nodig is vir langafstand beweging van die virus in wingerd nie. Om die moontlike rol van die P163-M5 119 nt invoeging en die GVA ORF 2 (met onbekende funksie), in die uitdrukking van simptome in plante te ondersoek, is ORF 2 van die 35SGVA- GR5 cDNA kloon verwyder en daaropvolgens vervang met die ooreenstemmende ORFs van vier Suid-Afrikaanse GVA variante. Na agro-infiltrasie in N. benthamiana blare, het al die chimeras die vermoë gehad om te repliseer, sistemies te beweeg en simptome te induseer. Geen korrelasie kon gevind word tussen die graad van simptome, die teenwoordigheid van die P163-M5 insersie en die spesifieke GVA ORF 2 teenwoordig in die chimeras nie, wat dus daarop dui dat ander faktore in die virusgenoom of die gasheerplant `n moontlike belangrike rol kan speel. Hierdie studie het bygedrae tot die beskikbare poel van in vivo gereedskap vir die bestudering en verbetering van die kosbare wingerdgewas. Dit het ook talle interessante navorsingsgeleenthede oopgemaak om in die nabye toekoms te betree. Grapevine virus A Virus-induced gene silencing Expression vectors
139	Virus induced gene silencing for the study of starch metabolism George, Gavin M. (Gavin Mager) 03 1900 (has links) Thesis (PhD (Plant Biotechnology))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: Virus Induced Gene Silencing (VIGS) was optimized to allow for the study of starch metabolism. The plastidial inorganic pyrophosphatase gene, for which a mutant has never been identified, was studied using VIGS and it was found to have a broad role in this subcellular compartment. The accumulation of inorganic pyrophosphate limited the production of starch, carotenoids, chlorophyll, and increased the plants susceptibility to drought stress. These effects highlight the importance of this enzyme in maintaining a low intraplastidial concentration of PPi providing an environment which facilitates these anabolic processes. Several genes involved in starch synthesis and degradation were also targeted with the aim of establishing a system of multiple gene silencing for the study of metabolic pathways. One, two and three genes were successfully silenced using this system which was validated based on previously published data. Interestingly, simultaneous silencing of the two isoforms of disproportionating enzyme led to a novel phenotype as a large reduction in starch instead of the expected increase was observed. / No Afrikaans abstract available Starch metabolism Plastidial pyrophosphate VIGS Dissertations -- Plant biotechnology Theses -- Plant biotechnology Plant biotechnology Gene silencing
140	Ras signalling pathway and MLL-rearranged leukaemias Ng, Ming-him., 吳明謙. January 2006 (has links) published_or_final_version / abstract / Pathology / Master / Master of Philosophy Ras oncogenes. Cellular signal transduction. Gene silencing. Acute leukemia - Genetic aspects.

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