Analyses of the Life Cycle of TLC1 and the Nuclear RNA Quality Control System in Saccharomyces cerevisiae

Wu, Haijia

23 April 2015

No description available.

570

TLC1

non-coding RNA

Telomerase

nuclear transport

Mex67

Xpo1

Biologie (PPN619462639)

Non-coding RNA in T cell activation and function

Lind, Liza

January 2013

For a long time research has focused on the protein-coding mRNA, but there is a complex world of non-coding RNAs regulating the human body that we yet know very little about. Non-coding RNAs (ncRNAs) are involved in modulation of different cell processes including proliferation, differentiation and apoptosis. In the current study the role of ncRNAs in T cell activation and function was investigated. T cells are important mediators of immune responses, for example upon viral infections. The T helper cells (TH or CD4+ cells) are involved in orchestrating immune processes like aiding the activation of macrophages and enhancement of B cell function. The TH1 cell subtype is generally pro-inflammatory and IFNγ-secreting. There are regulatory T (Treg) cells that are involved in downregulation of TH1 cells, to decrease or terminate the immune response. It has been shown that upon repeated stimulation TH1 cells can switch into a Treg-like IL10-secreting anti-inflammatory phenotype. In the IL10-secreting Treg-like cells the microRNA 150 (miR-150) was found upregulated compared to IFNγ-secreting TH1 cells. Thus, miR-150 was believed to be a candidate in key regulation of the switch between the two phenotypes. Predicted target genes of miR-150 were identified using mRNA arrays investigating down-regulated genes in the IL10-secreting Treg-like subpopulation. In this thesis predicted targets of miR-150 were investigated using luciferase assays. Unfortunately no targets were identified. Upon isolation of IFNγ-secreting TH1 cells and Treg-like IL10-secreting cells, it was found that the ncRNA 886 (nc886) was upregulated in these activated cells, compared to resting TH cells. This indicates that nc886 has an important role in T cell activation. Nc886 has been shown to inhibit PKR activation in other cell types. The effect of nc886 on protein kinase R (PKR) was therefore investigated. PKR shuts down translation upon activation in response to viral double-stranded RNA or cellular stress. We showed that in an activated T cell phenotype nc886 is affecting PKR upon activation by dsRNA from HIV or synthetic origin. The PKR activation pattern is reversed in a resting T cell phenotype.

ncRNA 886

non-coding RNA 886

microRNA 150

miRNA 150

PKR

T cell activation

luciferase assay

Non-protein-coding RNA : Transcription and regulation of ribosomal RNA

Böhm, Stefanie

January 2014

Cell growth and proliferation are processes in the cell that must be tightly regulated. Transcription of ribosomal RNA and ribosomal biogenesis are directly linked to cell growth and proliferation, since the ribosomal RNA encodes for the majority of transcription in a cell and ribosomal biogenesis influences directly the number of proteins that are synthesized. In the work presented in this thesis, we have investigated the ribosomal RNA genes, namely the ribosomal DNA genes and the 5S rRNA genes, and their transcriptional regulation. One protein complex that is involved in RNA polymerase I and III transcription is the chromatin remodelling complex B‑WICH (WSTF, SNF2h, NM1). RNA polymerase I transcribes the rDNA gene, while RNA polymerase III transcribes the 5S rRNA gene, among others. In Study I we determined the mechanism by which B‑WICH is involved in regulating RNA polymerase I transcription. B‑WICH is associated with the rDNA gene and was able to create a more open chromatin structure, thereby facilitating the binding of HATs and the subsequent histone acetylation. This resulted in a more active transcription of the ribosomal DNA gene. In Study II we wanted to specify the role of NM1 in RNA polymerase I transcription. We found that NM1 is not capable of remodelling chromatin in the same way as B‑WICH, but we demonstrated also that NM1 is needed for active RNA polymerase I transcription and is able to attract the HAT PCAF. In Study III we investigated the intergenic part of the ribosomal DNA gene. We detected non-coding RNAs transcribed from the intergenic region that are transcribed by different RNA polymerases and that are regulated differently in different stress situations. Furthermore, these ncRNAs are distributed at different locations in the cell, suggesting that they have different functions. In Study IV we showed the involvement of B‑WICH in RNA Pol III transcription and, as we previously had shown in Study I, that B‑WICH is able to create a more open chromatin structure, in this case by acting as a licensing factor for c-Myc and the Myc/Max/Mxd network. Taken together, we have revealed the mechanism by which the B‑WICH complex is able to regulate RNA Pol I and Pol III transcription and we have determined the role of NM1 in the B‑WICH complex. We conclude that B‑WICH is an important factor in the regulation of cell growth and proliferation. Furthermore, we found that the intergenic spacer of the rDNA gene is actively transcribed, producing ncRNAs. Different cellular locations suggest that the ncRNAs have different functions. / <p>At the time of the doctoral defence the following papers were unpublished and had a status as follows: Paper 2: Manuscript; Paper 3: Manuscript</p>

ribosomal RNA

non-coding RNA

ribosomal genes

rDNA gene

B-WICH

chromatin remodelling

histone modification

Investigation of two early events in amyotrophic lateral sclerosis mRNA oxidation and up-regulation of a novel protective factor MSUR1 /

Chang, Yueming,

January 2007

Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 171-189).

Role of DksA and Hfq in Shigella flexneri virulence

Sharma, Ashima Krishankumar,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.

Biotagging, a genetically encoded toolkit in the zebrafish, reveals novel non-coding RNA players during neural crest and myocardium development

Chong, Vanessa

January 2017

Complex multicellular organisms are composed of at least 200 cell types, which contain the same DNA "black box" of genetic information. It is the precise regime according to which they express their genes, exquisitely controlled by gene regulatory circuits, that defines their cellular identity, morphology and function. We have developed an in vivo biotinylation method that uses genetically encoded components in zebrafish, termed biotagging, for genome-wide regulatory analysis of defined embryonic cell populations. By labelling selected proteins in specific cell types, biotagging eliminates background inherent to analyses of complex embryonic environments via highly stringent biochemical procedures and targeting of specific interactions without the need for cell sorting. We utilised biotagging to characterise the in vivo translational landscape on polysomes as well as the transcriptional regulatory landscape in nuclei of migratory neural crest cells, which intermix with environing tissues during their migration. Our migratory neural crest translatome presented both known and novel players of the neural crest gene regulatory network. An in depth look into the active nuclear transcriptome uncovered a complex world of non-coding regulatory RNAs that potentially specify migratory neural crest identity and present evidence of active bidirectional transcription on regions of open chromatin that include putative cis-regulatory elements. Analysis of our transcribed cis-regulatory modules functionally links these elements to known genes that are key to migratory neural crest function and its derivatives. We also identified a novel cohort of circular RNAs enriched at regions of tandem duplicated genes. Last but not least, we recovered developmentally regulated long non-coding RNAs and transcribed transposable elements. To functionally dissect the biological roles of these factors, we have built two Ac/Ds-mediated in vivo toolkits for efficient screening of putative enhancers and for CRISPR/Cas9-based transcriptional modulation. Overall, our methods and findings present a comprehensive view of the active coding and non-coding landscapes of migratory neural crest on a genome-wide scale that refine the current regulatory architecture underlying neural crest identity.

Identification and characterisation of long non-coding RNAs expressed downstream of EGF-induced signalling programme

Nowicki-Osuch, Karol Piotr

January 2016

It has recently become apparent that cells encode a large number of novel non-protein-coding genes called long non-coding RNAs (lncRNAs). Whilst the biological function of many lncRNAs remains unknown, recent evidence has suggested that lncRNAs may be important regulators of cellular growth, differentiation and may play a significant role in cancer. Epidermal growth factor (EGF) – an activator of the ERK1/2 signalling cascade – is an important spatio-temporal regulator of transcription and, ultimately, of cellular growth and movement. EGF stimulation triggers a wave-like expression of immediate-early genes (IE genes), followed by delayed-early genes (DE genes) and secondary-response genes (SR genes). Over the years, considerable effort has been made to unravel the regulatory loops downstream of EGF signalling. This study investigated whether lncRNAs are sensitive to EGF signalling and whether they play a role in the transcriptional programme associated with EGF signalling. In order to identify lncRNAs regulated by EGF signalling, I sequenced nuclear RNA in the presence or absence of EGF stimulation. RNA-seq data showed that 173 lncRNAs are upregulated by EGF, of which 89 were intergenic lncRNAs (lincRNAs). The time-dependent expression profile of EGF-upregulated lincRNAs followed the well-established expression pattern of IE genes. Finally, investigation of the expression of lincRNAs in primary breast and lung cancer cells showed that EGF-upregulated lincRNAs were differentially expressed in cancer. The EGF-dependent induction profile and cancer enrichment were particularly strong for one of the transcripts – EGF-induced lncRNA 1 (EIN1) – and I selected it for further studies. Firstly, using bioinformatics and biochemical approaches, I confirmed the non-coding status of the EIN1 transcript. Secondly, I confirmed that EIN1 transcription is ERK1/2-dependent and is independent of protein synthesis. Investigation of EIN1 expression in normal tissues showed its high enrichment in the human cardiovascular system. At the cellular level, the EIN1 transcript was predominantly found in the nucleus. Functionally, the depletion of endogenous EIN1 transcripts (using the newly developed CRISPRi approach) led to changes in the EGF-dependent transcription programme. EIN1 downregulation resulted in the addition of normally EGF-independent genes into the EGF-dependent expression programme. Collectively, these results show that EGF (via the ERK1/2 pathway) can regulate transcription of lincRNAs. The EIN1 example suggests that lincRNAs may play a crucial role in the modulation of the EGF-dependent expression programme by limiting of the scope of the programme.

572.8

A Computational Tool for the Prediction of Small Non-coding RNAs in Genome Sequences

Yu, Ning

01 December 2009

The purpose of researching bacterial gene expression is to control and prevent the diseases which are caused by bacteria. Recently researchers discovered small non-coding RNAs (ncRNA / sRNA) perform a variety of critical regulatory functions in bacteria. The genome-wide searching for sRNAs, especially the computational method, has become an effective way to predict the small non-coding RNAs because sRNAs have the consistent sequence characteristics. This article proposes a hybrid computational approach, HybridRNA, for the prediction of small non-coding RNAs, which integrates three critical techniques, including secondary structural algorithm, thermo-dynamic stability analysis and sequence conservation prediction. Relying on these computational techniques, our approach was used to search for sRNAs in Streptococcus pyogenes which is one of the most important bacteria for human health. This search led five strongest candidates of sRNA to be predicted as the key components of known regulatory pathways in S. pyogens.

Computational methods

genome sequences

prediction

sequence conservation

small non-coding RNA

sRNA

Epigenetic regulation of chronological and replicative longevity in Saccharomyces cerevisiae

Ayling, Jonathan

January 2012

Ageing and senescence remain among the most intriguing questions in biology. Saccharomyces cerevisiae has become well established as a fertile model system for the investigation of ageing. Remarkable conservation has been found to exist between interventions extending lifespan in higher animals and yeast – genetic, chemical, and nutritional – suggesting a network of common regulatory pathways controlling large-scale shifts in gene expression involved in senescence. While it has been proposed that epigenetic regulation controls these shifts, evidence remains incomplete. To address this question, novel longevity mutants were isolated in S. cerevisiae using a purpose-designed high-precision screen based on ageing culture outgrowth. A novel long-lived mutant in uncharacterised gene YDR026C was discovered and found to participate in a pathway distinct from TOR signalling, but share epistasis with the histone deacetylase SIR2&Delta;, a well established regulator of replicative longevity and rDNA maintenance. Through equilibrium density centrifugal separation of culture subpopulations, SIR2&Delta; and Ydr026c&Delta; cultures were found to demonstrate reduced and improved maintenance of post-diauxic quiescence respectively, previously shown to underlie chronological survival in strains including snf1&Delta;. Development of a quantified TUNEL-based assay for genome fragmentation indicated early apoptotic-like behaviour in the SIR2&Delta; strain. Microdissection experiments and sectored-colony assays of strains containing an rDNA-embedded ADE2 reporter determined that Ydr026c&Delta; cells also exhibit extended replicative lifespan, and reduced recombination at the rDNA spacer region hotspot, abrogated in SIR2&Delta; strains. SIR2&Delta; is well established to repress RNA polymerase II-derived transcripts in the rDNA spacer region, including IGS1-R. Northern analysis determined Ydr026c also silences transcription in the spacer, possibly through preventing termination of the main rRNA transcript, interfering with IGS1-R expression. By transformation with a vector overexpressing IGS1-R, partial reconstitution of the SIR2&Delta; phenotype was observed, including rDNA hyperrecombination, shortened replicative longevity, and higher-order chromatin structure restoration. These data suggests a model whereby non-coding rDNA spacer transcripts epigenetically determine rDNA maintenance through recombination, leading to physiological phenotypes of replicative and chronological ageing.

572

Petits ARN non codants dérivant d’ARN de transfert et endoribonucléases impliquées dans leur biogenèse chez Arabidopsis thaliana / tRNA derived small non-coding RNA and endoribonuclease implicated in their biogenesis in Arabidopsis thaliana

Megel, Cyrille

29 June 2016

Parmi les petits ARN non codants, les fragments dérivant d’ARNt (tRF) ont été identifiés dans tous les embranchements de la vie. Cependant, très peu de donnée existe sur les tRF de plantes. Les populations de tRF issues de plusieurs banques de petits ARN (différents tissus, plantes soumises à des stress abiotiques, ou fractions immunoprécipitées avec la protéine ARGONAUTE1) ont été analysées. Les populations sont essentiellement constituées de tRF-5D ou des tRF-3T (clivage dans la boucle D ou T respectivement) et elles varient d’une banque à l’autre. Par une approche in silico suivie de tests de clivage in vitro, des RNases T2 d’A. thaliana (RNS) ont été identifiées comme étant capables de cliver les ARNt dans la région de l’anticodon, de la boucle D et de la boucle T. Lors de l’étude de l’expression des RNS, nous avons observé que deux d’entre elles sont fortement exprimées à un stade de maturation tardif des siliques. Ainsi, la population en tRF issue de stades de développement avancés des siliques a été analysée. Des expériences de carences en phosphate nous ont permis de démontrer l’implication d’une des RNS dans la genèse de tRF dans A. thaliana. Au final, nos données ouvrent de nouvelles perspectives quant à l’implication des RNS et des tRF comme des acteurs majeurs dans l’expression des gènes chez les plantes. / Among the small ncRNAs, tRNA-derived RNA fragments (tRFs) were identified in all domains of life. However, only few data report on plants tRFs. Short tRF were retrieved from A. thaliana small RNA libraries (various tissues, plants submitted to abiotic stress or argonaute immunoprecipitated fractions). Mainly tRF-5D or tRF-3T (cleavage in the D or T region respectively) were found, and fluctuations in the tRF population were observed.Using in vitro approaches, A. thaliana RNase T2 endoribonucleases (RNS) were shown to cleave tRNAs in the anticodon region but also in the D or T region. Through a whole study of RNS expression, we show that two RNS are also strongly expressed in the siliques at a late stage of development. Thus, we analyzed the tRF population of this particular developmental stage. Upon phosphate starvation, we demonstrate also the implication of one RNS in the production of tRFs in planta. Altogether, our data open new perspectives for RNS and tRFs as major actors of gene expression inplants.

Petits ARN non-codants

TRF

Endoribonucléase

RNS

ARNt

Small non-coding RNA

TRNA

TRF

Endoribonuclease

RNS

572.8

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