Retroviral vector-based RNA interference against Marek's disease virus and avian leukosis virus

Chen, Mo.

January 2008

Thesis (Ph. D.)--Michigan State University. Microbiology and Molecular Genetics, 2008. / Title from PDF t.p. (Proquest, viewed on Aug. 20, 2009) Includes bibliographical references. Also issued in print.

Synthetic RNA interference against influenza A virus

Lee, Hung-chiu.

January 2005

Thesis (M. Phil.)--University of Hong Kong, 2006. / Title proper from title frame. Also available in printed format.

Endogenous and antiviral RNA silencing pathways in Arabidopsis /

Chapman, Elisabeth J.

January 1900

Thesis (Ph. D.)--Oregon State University, 2007. / Printout. Includes bibliographical references (leaves 112-128). Also available on the World Wide Web.

Exploring natural and engineered resistance to potyviruses

Pyott, Douglas Euan

January 2017

Viruses are ubiquitous in natural growth environments and cause severe losses to crop yields, globally. Approximately 30% of plant viruses described to date are grouped within the family Potyviridae, making it one of the largest plant virus families. Furthermore, certain potyvirus species can cause devastating diseases in several agriculturally and economically important crops. Hence, gaining insight into potyvirus resistance and recovery mechanisms in plants is an important research focus. This thesis firstly explores how environmental cues can modulate the activity of a central form of viral defence, namely RNA silencing. Specifically, high temperatures and low light intensities were found to increase the efficacy of viral RNA silencing in Arabidopsis, resulting in recovery from infection by Turnip Mosaic Virus. The biological context and potential for agricultural exploitation of these phenomena are discussed. Secondly, this thesis explores the ability to engineer resistance alleles using the latest genome editing techniques. Specifically, resistance to Turnip Mosaic Virus was successfully engineered in Arabidopsis by CRISPR/Cas9-induced deletion of a known susceptibility factor eIF(iso)4E. Biotechnological methods to implement this proof of concept research in crop species were also investigated.

Použití rostlinných virů pro navození cílených epigenetických změn u Solanum tuberosum a Nicotiana benthamiana / Introducing targeted epigenetic changes in Solanum tuberosum and Nicotiana benthamiana by plant viruses

Dušek, Jakub

January 2016

In this thesis we have focused on the induction of targeted epigenetic changes using modified Potato Virus X vector (PVX, Potato virus X). The gene coding sequence phytoene desaturase (PDS) was isloated from Solanum tuberosum and Nicotiana benthamiana plants using PCR. Primers were specifically designed as universal for both plant species and their Tm temperatures was in the range of 5 °C. The primers also added flanking restriction sites XhoI and ClaI to simplify cloning of PDS PCR products into full length PVX viral vector in AS orientation. The PVX viral vector pGR106 was later introduced into the plants using Agrobacterium tumefaciens. Infection led to the degradation of the target transcript and to efficient gene silencing (PTGS posttranscriptional gene silencing). The process has been manifested by complete or partial fading of a green plant tissue phenotype.. Some of the plants were aslso inoculated in in vitro conditions, for which a novel technique has been implemented.

Charaterization of RNA silencing and avirulence in two related smut fungi

Laurie, John Drummond

05 1900

The basidiomycete cereal pathogens Ustilago hordei and U. maydis are closely related and possess genomes with a high degree of homology and synteny. I report on the disparity of the RNAi phenomenon between U. hordei and U. maydis. Using an RNAi expression vector I targeted both a GUS transgene and an endogenous mating-type gene and confirmed the presence of double-stranded (ds)RNA in transgenic cells of both species. However, down-regulation of the GUS gene and production of siRNAs were seen only in U. hordei. The biological effect was a reduction in GUS protein and activity, and reduced mating only in U. hordei. In support of this experimental evidence, homologs to Dicer and Argonaute were found in the U. hordei genome but not in the published U. maydis genome. Interestingly, preliminary U. hordei sequences reveal conservation and synteny in U. maydis in the regions spanning these loci, with the only noticeable difference being the lack of Dicer and Argonaute genes in U. maydis. U. maydis also appears to differ from U. hordei with respect to genes presumed to be involved in transcriptional gene silencing and also has far fewer transposons in its genome. Efforts to clone the avirulent gene UhAvr1 led to a locus containing a large number of small proteins predicted to be secreted. This locus appears to be heterochromatic and is orthologous to the largest cluster of secreted proteins in U. maydis. Other laboratories have reported that deletion of this cluster in U. maydis results in a dramatic reduction in virulence. Genetic evidence for an avirulence gene at this locus in U. hordei suggests that the locus may also be important for U. hordei. Differences between these two smut fungi at this locus and at others identified in this study point to key differences in gene regulation and genome evolution. / Science, Faculty of / Botany, Department of / Graduate

Ustilago

RNA silencing

Avirulence

UhAvr1

Characterization

Data for proteomic analysis of murine cardiomyocytic HL1 cells treated with siRNA against tissue factor

Brioschi, M., Lento, S., Barcella, S., Nasim, Md. Talat, Tremoli, E., Banfi, C.

January 2015

Yes / This data article is related to the research article entitled Proteomics of Tissue Factor silencing in cardiomyocytic cells reveals a new role for this coagulation factor in splicing machinery control by Lento et al [1]. Tissue Factor (TF) is the key player in the coagulation cascade, but it has additional functions ranging from angiogenesis, tumor invasion and, in the heart, the maintenance of the integrity of cardiac cells. This article reports the nano-LC-MSE analysis of the cardiomyocytic HL-1 cell line proteome and describes the results obtained from a Gene Ontology analysis of those proteins affected by TF-gene silencing.

Proteomics

Tissue factor

Silencing

Tumour invasion

Investigating the roles of arabidopsis polycomb-group genes in regulating flowering time and during plant development by (I) challenging silencing and (II) developing approaches to dissect Pc-G action

Creasey, Kate M.

January 2009

Polycomb-group (Pc-G) proteins regulate homeotic gene silencing associated with the repressive covalent histone modification, trimethylation of histone H3 lysine 27 (H3K27me3). Pc-G mediated silencing is believed to remodel chromatin, rendering target genes inaccessible to transcription factors. Pc-G mediated silencing might result in irreversible changes in chromatin structure, however, there has been little analysis addressing whether Pc-G mediated silencing is reversible. In this work we focused on CURLY LEAF (CLF), the first Pc-G homologue discovered in Arabidopsis. CLF mediated repression of the floral homeotic gene AGAMOUS (AG) was challenged during early and late leaf development. AG was activated by the late leaf promoter, revealing that Pc-G mediated silencing can be overcome in old leaves in the presence of CLF. AG was also activated in young leaf primordia, yet did not persist in older leaves, revealing that transient activation of a Pc-G target is not epigenetically stable. To address the mechanism of Pc-G action within an endogenous environment, the histone dynamics at the APETALA1 (AP1) locus were characterized by Chromatin Immunoprecipitation. Unexpectedly, we found that the activation of AP1 in leaves did not require the removal of H3K27me3, questioning whether H3K27me3 is sufficient to silence. The roles of CLF in leaf and flower development are masked due to partial redundancy with SWINGER (SWN). clf- swn- mutants form a callus-like mass on sterile-tissue culture with no distinguishable plant organs. The role of CLF in regulating flowering time in natural populations of A. thaliana was investigated by complementing clf- mutants with CLF alleles from two accessions. We found that natural variation in CLF did not affect flowering time. To dissect the roles of CLF and SWN in late leaf and flower development, two approaches were developed for targeted expression. Firstly, CLF was introduced into the LhG4/ pOp transactivation system to provide CLF during early plant development. For mosaic analysis, CLF was introduced into the CRE lox recombination system in order to create clf- sectors surrounded by CLF+ SWN+ and CLF+ swn- cells.

581.35

Etude des voies de silencing transciptionnel indépendantes de la méthylation ADN chez Arabidopsis thaliana / Study of transcriptional gene silencing pathways independent of DNA methylation

Bourguet, Pierre

07 December 2018

Le silencing transcriptionnel limite la transcription des gènes et des éléments transposables dont l’expression pourrait être délétère à la cellule. Il dépend d’une diversité de modifications de la chromatine comme la méthylation ADN ou les marques répressives des histones. De façon à mieux comprendre les mécanismes moléculaires à l’origine du silencing transcriptionnel, nous avons mené une approche de génétique directe à l’aide d’un transgène soumis au silencing dans la plante modèle Arabidopsis thaliana. Cette stratégie nous a permis d'isoler à la fois des mutants déficients pour le maintien du silencing transcriptionnel et des mutations qui empêchent la réactivation transcriptionnelle des éléments transposables en réponse à un stress thermique. Nous avons caractérisé les défauts provoqués par ces mutations en combinant des approches de biologie moléculaire, de cytologie et de génomique.Nous montrons ainsi que MED14, la sous-unité centrale du complexe Mediator, et UVH6, composant du complexe TFIIH, sont requis pour la transcription de l'hétérochromatine en stress thermique. MED14 stimule aussi la transcription de l'hétérochromatine en l'absence de stress, mais ne semble fonctionner qu'en présence de la méthylation ADN. En plus de cette fonction originale, nous identifions un nouveau rôle de MED14 dans le maintien de la méthylation ADN, possiblement via la voie de méthylation ADN dirigée par les petits ARN.Par ailleurs, nos résultats nous ont permis d’identifier le rôle des protéines MAIN et MAIL1, qui définissent une voie de silencing transcriptionnelle indépendante des voies connues jusqu'alors. De façon intéressante, MAIN et MAIL1 possèdent un domaine protéique partagé avec les éléments transposables, qui aurait successivement été capturé par les éléments transposables et leur hôte au cours de l’histoire évolutive des plantes à fleurs.Enfin, en isolant une nouvelle mutation du gène POL2A, nous confirmons le rôle de l’ADN polymérase epsilon dans le silencing transcriptionnel et caractérisons les propriétés chromatiniennes qui dépendent de POL2A. Nous montrons que les défauts de silencing des mutants pol2a corrèlent avec une désorganisation importante de l’hétérochromatine sans diminution drastique des marques qui y sont associées. Au contraire, nous détectons une hyperméthylation ADN prononcée dans le mutant, et explorons différentes hypothèses pour expliquer ce phénotype particulier. Nos données suggèrent que plusieurs mécanismes moléculaires sont à l’origine des défauts des mutants pol2a. Elles confirment le rôle prépondérant de la chromométhylase CMT3 dans la régulation de la méthylation ADN, et suggèrent qu’un stress réplicatif pourrait causer une hyperméthylation de l’ADN.Dans l’ensemble, ces travaux de thèse proposent des pistes de travail dont l’exploration pourrait permettre d’expliquer les effets des déficiences réplicatives dans le maintien du silencing transcriptionnel et de l’homéostasie de la méthylation ADN. Ils suggèrent en outre que MED14 a une fonction dédiée à la transcription de l’hétérochromatine qui pourrait stimuler le maintien de la méthylation ADN. / Transcriptional gene silencing hinders deleterious transcription of some genes and transposable elements. Silencing is maintained by numerous chromatin modifications such as DNA methylation and repressive histone marks. To better understand the molecular mechanisms of silencing, we conducted a forward genetic screen using a transgene reporter system targeted by transcriptional gene silencing in the model plant Arabidopsis thaliana. We isolated a first type of mutants with diminished maintenance of silencing and a second category that displayed deficient release of transgene silencing upon heat stress. We then combined molecular, cytological and genomic methods to characterize the defects associated with these mutations.First, we show that the Mediator subunit MED14 and the TFIIH complex subunit UVH6 are required for heat-stress-induced release of silencing. We further show that MED14, but not UVH6, promotes transcriptional activation of transposable elements in mutant contexts where silencing is defective. Importantly, MED14 is only required when DNA methylation is not affected, suggesting that MED14 has a specialized function to promote transcription of heterochromatin. Furthermore, we show that MED14 promote DNA methylation at targets regulated by RNA-directed DNA methylation.Characterizing mutants from the first category, we unveil the contribution of the MAIN and MAIL1 proteins into transcriptional gene silencing, and show that they likely act through a pathway independent of known silencing factors. Interestingly, MAIN and MAIL1 bear a protein domain that is shared with transposable elements, and that has been captured by transposable elements and genes throughout the evolutionary history of flower plants.Additionally, we confirm the involvement of the DNA polymerase epsilon in transcriptional gene silencing by isolating a new mutation of the POL2A gene among mutants of the first category. We characterize the effects of the pol2a mutation on several heterochromatin properties, and show that the pol2a mutant retains high levels of heterochromatin marks despite having highly disorganized heterochromatin. We actually detect a strong elevation of DNA methylation in the pol2a mutant and explore different hypothesis to explain this unusual phenotype. We show that increased expression of the CMT3 chromomethylase is a likely cause, but that additional molecular mechanisms are probably involved. Further exploration suggests that constitutive replicative stress occurring in pol2a mutants could be an additional cause of DNA hypermethylation.To summarize, this work provide putative causes for DNA hypermethylation and silencing defects in a situation of replicative deficiency. Further investigation will be required to identify the molecular components involved in the mechanism. Our data further suggest that MED14 has a function dedicated to heterochromatin transcription that could promote DNA methylation maintenance.

Silencing transcriptionnel

Méthylation ADN

ADN polymérase epsilon

Transcriptional gene silencing

DNA methylation

DNA polymerase epsilon

Small RNA pathways and the roles of tudor nucleases in gene silencing and DNA deletion in Tetrahymena thermopila /

Howard-Till, Rachel A.

January 2006

Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 90-99).