CRITICAL EVENTS IN HUMAN METAPNEUMOVIRUS INFECTION: FROM ENTRY TO EGRESS

Hackett, Brent A

01 January 2013

Human metapneumovirus (HMPV) is a respiratory pathogen in Paramyxovirus family that demonstrates extremely high morbidity in the population, with most individuals having been infected by the age of five. Despite the prevalence of this negative-sense RNA virus in the population for decades, it was only identified in 2001. As such, there is currently no specific treatment for HMPV and the potentially severe consequences of infection for elderly and immunocompromised individuals and particularly infants make development of antivirals targeting HMPV of high significance. HMPV constitutes a quarter of all respiratory hospitalizations among infants, placing it second only to RSV, in addition to becoming a greater concern in concentrated populations of seniors. For these susceptible populations, the consequences of infection have a much greater probability of leading to pneumonia, bronchiolitis and even death. These studies investigate events throughout the infectious cycle of HMPV. They describe specific amino acids that modulate the triggering of viral fusion activity in response to low pH. They also include a report on the dynamic and variable control exercised over gene transcription by viral promoters. Finally, the interplay between viral nonstructural proteins and their distinct roles in both replication and assembly are examined. Ultimately, this work seeks to elucidate the goings-on within an HMPV-infected cell at multiple points throughout the process.

Human metapneumovirus (HMPV)

RNA-dependent RNA polymerase (RdRp)

phosphoprotein

nucleocapsid

minireplicon

Biochemistry

Virology

Optical Tweezers studies of Nucleic Acids and their Interaction with Proteins

Kalafut, Bennett Samuel

January 2011

Mechanics and biological function of nucleic acids are intimately coupled. The DNA double helix must be opened to allow base pairing of RNA during transcription; RNA must bend and fold in its many cellular functions. Presented in this dissertation are two investigations of mechanical deformations of nucleic acids, conducted with optical tweezers.In the introduction, the mechanical properties of DNA and RNA and their relevance to their cellular functions are introduced, to give the reader context for the results presented in the Chapters 2 and 3. This is followed by an introduction to the theory of semiflexible polymer elasticity. The optical tweezers instruments used in conducting these investigations are then presented, along with calibration procedures and a short introduction to optical trapping physics.Chapter 2 presents an investigation of the effect of downstream DNA tension on initiation by T7 RNA polymerase. A hidden Markov model is fit to force-dependent lifetimes obtained from optical tweezers experiments, allowing us to identify which steps in initiation are force-dependent and estimate rates and transition state distances. We find that 1-2 pN of tension is sufficient to turn o gene expression by causing transcription bubble collapse and destabilizing the bound state. Our force-dependence scheme and estimated transition distances provide independent supportfor the \scrunching" model of initiation.The effects of cation binding and screening on single-stranded helix formation in poly(A) RNA are presented in Chapter 3. Magnesium and calcium bind to poly(A), stabilize the helix, and change its mechanical properties. A new model of helix-coil transitions is presented and used to estimate energetics and mechanical properties.Chapter 4 presents the first fully objective algorithm for use in analyzing the noisy staircaselike data that is often produced by single-molecule fluorescence experiments. A test based on the SIC (BIC) statistic is used in conjunction with a progressive step-placement scheme to locate changepoints (steps) in noisy data. Its performance is compared to other step detection algorithms in use by biophysicists by repeating tests performed in a recent review.Experimental protocols and computer codes used in these investigations are presentedin detail in the appendices.

optical tweezers

RNA elasticity

RNA polymerase

single molecule

Physics

changepoint

helix-coil transition

Role of R-loops in pause-dependent transcriptional termination of RNA polymerase II

Skourti-Stathaki, Konstantina

January 2012

Transcription termination of RNA polymerase II (Pol II) in mammals requires a functional poly(A) signal and either downstream pause sites or co-transcriptional cleavage (CoTC) sequences together with 3’transcript degradation by the nuclear 5’-3’ exonuclease Xrn2. However the molecular mechanism of pause-dependent transcriptional termination is not yet fully understood. This thesis investigates the molecular role of R-loop structures in pause-dependent transcriptional termination of mammalian genes. The results described in Chapters 3 and 4 indicate that nascent transcripts form RNA/DNA hybrid structures (R-loops) behind elongating Pol II and are especially prevalent over G-rich pause sites positioned downstream of gene poly(A) signals. Senataxin, a helicase protein and the human homologue of the yeast Sen1, acts to resolve these R-loop structures and by so doing allows access of Xrn2 at 3’ cleavage poly(A) sites. This ultimately leads to efficient Pol II termination. In effect R-loops formed over G-rich pause sites, followed by their resolution by senataxin, are required for efficient pause-dependent transcriptional termination. In addition to this, the 3’ end processing factor, Pcf11 is also involved in this process. Experiments presented in the final part of this study reveal a link between R-loops and RNAi-dependent H3K9me2 formation over G-rich termination regions. Overall my results suggest that R-loop structures and the H3K9me2 repressive mark over pause regions are important features of Pol II pause-dependent transcriptional termination of mammalian genes.

572.8

Structure of the RNA-dependent RNA polymerase from influenza C virus

Hengrung, Narin

January 2014

The influenza virus causes a disease that kills approximately 500,000 people worldwide each year. Influenza is a negative-sense RNA virus that encodes its own RNA-dependent RNA polymerase. This protein (FluPol) carries out both genome replication and viral transcription. Therefore, like the L-proteins of non-segmented negative-sense RNA (nsRNA) viruses, FluPol also contains mRNA capping and polyadenylation functionality. In FluPol, capping is achieved by snatching cap structures from cellular mRNAs, so requiring cap-binding and endonuclease activities. This makes FluPol a substantial machine. It is a heterotrimeric complex, composed of PB1, PB2 and PA/P3 subunits, with a total molecular weight of 255 kDa. PB1 houses the polymerase active site, whereas PB2 and PA contain, respectively, cap-binding and endonuclease domains. Currently, we only have high resolution structural information for isolated fragments of FluPol. This severely hampers our understanding of influenza replication and consequently inhibits the development of therapies against the virus. In this DPhil project, I have determined a preliminary structure for the heterotrimeric FluPol of influenza C/Johannesburg/1/66, solved by x-ray crystallography to 3.6 Å. Overall, FluPol has an elongated structure with a conspicuous deep groove. PB1 displays the canonical right-hand-like polymerase fold. It sits at the centre of the particle, sandwiched between the two domains of P3, and with PB2 stacked against one side of this dimer. In the structure, the polymerase and endonuclease catalytic sites are both ~40 Å away from the cap-binding pocket. This pocket also faces a tunnel leading to the polymerase core. This suggests a mechanism for how capped cellular mRNAs are cleaved and then fed into the polymerase active site to prime transcription. The structure also hints at a unique trajectory for template RNA, in which the RNA exits at an angle ~180° from which it came in. This provides an explanation for how the polymerases of influenza, and other nsRNA viruses, can copy templates that are packaged into ribonucleoprotein complexes. My work reveals the first molecular structure of any polymerase from an nsRNA virus. It uncovers the arrangement of functional domains within FluPol, illuminating the mechanisms of this and related viral polymerases. This work will help focus future experiments into FluPol biology, and should hopefully spur the development of novel antiviral drugs.

616

Regulation of human RNA polymerase II CTD modifications

Kuznetsova, Olga

January 2015

Transcription of human protein-coding genes and most small nuclear RNA genes is mediated by RNA Polymerase II (Pol II). During a cycle of transcription, Pol II recruits a variety of factors that facilitate transcription elongation, RNA processing and termination, through its long, unstructured C-terminal domain (CTD). The CTD in humans comprises 52 tandem heptapeptide repeats with the consensus sequence Y₁S₂P₃T₄S₅P₆S₇. Each amino acid of the heptapeptide can be chemically modified, which influences the recruitment of other protein factors to the transcription machinery. Not all enzymes that modify the CTD have been discovered. Recent studies have identified a novel CTD phosphatase: RPAP2 in humans and its yeast homologue Rtr1, which dephosphorylate phospho-Ser5 of the heptapeptide repeats. RPAP2 has been shown to stimulate 3' end cleavage of nascent snRNAs through recruitment of the Integrator complex, and unpublished work suggests the involvement of RPAP2 in regulating vertebrate developmental programs. However, the exact mechanisms that regulate the function of human RPAP2, and thus impact on CTD modification, are not well-understood. This thesis presents a novel mechanism whereby RPAP2 recruits protein phosphatase 1 (PP1) to snRNA genes, where PP1 is postulated to activate P-TEFb to phosphorylate Ser2 of the CTD. At the same time, P-TEFb may have a role in activating the phosphatase activity of RPAP2. Furthermore, RPAP2 itself is shown to be recruited to a number of gene promoters by the RPRD1A protein, which also stimulates its phosphatase activity. RPAP2 was shown to have another role in regulating transcription termination: by recruiting the Integrator complex, which is shown here to mediate termination of snRNA genes, and by a so far unknown mechanism on a long protein-coding gene. An attempt was made to purify and crystallise the human RPAP2 to obtain a crystal structure, however the crystallisation trials were not successful. Finally, a correlation was found in human embryonic stem cells and induced pluripotent stem cells between low levels of RPAP2 and high levels of CTD Ser5P, suggesting a potential involvement of RPAP2 in regulating transcription at a key developmental stage. The results presented here contribute to the understanding of human transcriptional mechanisms and the numerous interactions within the transcription machinery. In particular, the mechanism of terminating the transcription of snRNA genes is identified. An interesting possibility is the regulation of development and stem cell differentiation by RPAP2; however the exact pathways by which this occurs are yet to be discovered.

572.8

Charakterizace Ms1, nově identifikované malé RNA z Mycobacterium smegmatis / Characterization of Ms1, a newly identified small RNA from Mycobacterium smegmatis

Pospíšil, Jiří

January 2014

Introduction: In recent years, there has been growing interest in regulation of gene expression by small non-coding RNA (sRNA). The first sRNA discovered in 1960s was 6S RNA from E. coli (length ~184 nt). It took ~ 30 years to obtain meaningful insights into its function. 6S RNA binds during stationary phase to RNA polymerase (RNAP) containing sigma factor 70 (primary sigma factor), thereby preventing transcription from σ70 - dependent promoters. In our laboratory we discovered a small RNA (length ~300 nt) in stationary phase of growht in Mycobacterium smegmatis. This sRNA was named Ms 1. The function of Ms 1 is uknown and preliminary experiments indicated that Ms 1may bind to RNAP that lacks σ factor (σA ). Goals: The aim of this Diploma project is to contribute to the characterization of Ms 1. Approaches: First, by molecular cloning, affinity chromatography and in vitro transcription I prepared the tools for subsequent experiments in vitro: RNAP, σA , Ms 1 and its mutated variants. Next, these tools were used for binding experiments on native gels and for transcription experiments. Results: RNAP, σA , Ms 1 and its variants were prepared. In vitro binding assays showed that wt Ms 1 but not a mutated variant of Ms 1 binds to RNAP. Using this assays were identified areas of Ms 1 that are important...

Role promotoru při regulaci RNA sestřihu / Role of promoter in the regulation of alternative splicing

Kozáková, Eva

January 2014

It was shown that 95 % of human multi-exon genes are alternatively spliced and the regulation of alternative splicing is extremely complex. Most pre-mRNA splicing events occur co- transcriptionally and there is increasing body of evidence, that chromatin modifications play an important role in the regulation of alternative splicing. Here we showed that inhibition of histone deacetylases (HDACs) modulates alternative splicing of ~700 genes via induction of histone H4 acetylation and increase of Pol II elongation rate along alternative region. We identified HDAC1 the catalytic activity of which is responsible for changes in alternative splicing. Then, we analyzed whether acetylhistone binding protein Brd2 regulates alternative splicing and showed that Brd2 occupies promoter regions of targeted genes and controls alternative splicing of ~300 genes. Later we showed that knockdown of histone acetyltransferase p300 promotes inclusion of the alternative fibronectin (FN1) EDB exon. p300 associates with CRE sites in the promoter via the CREB transcription factor. We created mini-gene reporters driven by an artificial promoter containing CRE sites. Both deletion and mutation of the CRE site affected EDB alternative splicing in the same manner as the p300 knockdown. Next we showed that p300 controls histone...

Charakterizace transkripčního aparátu lineárních plasmidů kvasinky Kluyveromyces lactis / Characterization of transcription apparatus encoded by the linear plasmids of the yeast Kluyveromyces lactis

Sýkora, Michal

January 2013

Transcription is an essential step in the expression of genetic information. This process depends on protein complex of multisubunit RNA polymerases that are exceptionally conserved among all cellular organisms. These enzymes together with eukaryotic RNA-dependent RNA polymerases involved in gene silencing form a monophyletic protein family whose members contain two double-ψ β-barrel structural motifs in their active center. This family also includes a group of mainly in silico predicted non-canonical DNA-dependent RNA polymerases which differ from multisubunit RNA polymerases in reduced composition. Putative non-canonical RNA polymerase consisting of two subunits is also encoded by cytoplasmic linear plasmids of the yeast Kluyveromyces lactis and highly likely transcribes genes of these plasmids. Characterization of a unique transcription machinery of Kluyveromyces lactis plasmids with major emphasis on non-canonical RNA polymerase has become the aim of this work. Bioinformatic analysis in silico was used to examine the evidence leading to an assumption of existence of specific RNA polymerase. Subsequent genetic and biochemical methods were used for: 1) production of putative RNA polymerase subunits in several expression systems; 2) testing interaction between several components of transcription...

Charakterizace proteinu HelD z Bacillus subtilis / Characterization of the HelD protein from Bacillus subtilis

Sudzinová, Petra

January 2013

BACKGROUND: Bacterial RNA polymerase (RNAP) is an extensively studied enzyme required for gene expression. In our Laboratory we found a new protein named HelD. HelD copurifies with B. subtilis RNAP. HelD is a ~90 kDa protein from the UvrD/Rep helicase family, which contains protein with the 3'-5' DNA unwinding activity. The molecular role(s) HelD in cell are still unknown and its potential role in transcription has not been studied so far. OBJECTIVE: The main aim of this Diploma project was to describe HelD. APPROACHES: The characterization was carried out on three levels: (i) bioinformatics analysis in silico was used to identify HelD homologs in other bacteria; (ii) growth tests in vivo were used to determine the phenotype(s) of the HelD-null mutant strain compared to wt; and (iii) biochemical experiments in vitro were utilized to describe the effects of HelD on transcription, and to test whether HelD has DNA binding and DNA unwinding activities. RESULTS: The in silico analysis revealed that HelD is present in Firmicutes, an industrially and medicinally important group of G+ bacteria. The phenotypic experiments showed that HelD is required for rapid adaptations to nutritional changes in the environment. The biochemical experiments showed that HelD stimulates transcription despite the fact that it...

Organisation de la chromatine et signalisation par les oestrogènes / Impact of the chromatine organization in transcriptional regulation mediated by estrogen receptor

Quintin, Justine

06 March 2013

En réponse à son environnement composé de signaux endogènes et exogènes, une cellule doit pouvoir adapter son transcriptome, et cela à travers une modulation fine de l'expression de ses gènes. Les mécanismes permettant une telle adaptation reposent sur de multiples paramètres, entre autre l'organisation du génome, que ce soit au niveau de sa séquence primaire ou de son organisation au sein de la chromatine qui est un support pour l'intégration de nombreuses informations (structurelles et épigénétiques). De plus, l'organisation tridimensionnelle du noyau cellulaire apporte des contraintes physiques et fonctionnelles qui contribuent également à ces régulations. Afin de comprendre comment toutes ces informations peuvent être intégrées lorsqu'un signal régule la transcription d'un ensemble de gènes colinéaires («cluster» de gènes), nos études se sont focalisées sur la description et dissection des mécanismes impliqués dans la régulation coordonnées de gènes œstrogéno-dépendant par le récepteur aux œstrogènes (ER) et ses facteurs pionniers (FOXA1, FOXA2 et GATAs) dans des cellules cancéreuses d'origine mammaire. Dans ce cadre, nous nous sommes plus particulièrement intéressés au cluster TFF, situé sur le bras long du chromosome 21, incluant le gène modèle TFF1, en utilisant des techniques d'analyse à grande échelle (ChIP-chip, ChIP-seq, 4C et analyses transcriptomiques). / A given cell has to be able to adapt its fate and homeostasis in response to endogenous and exogenous signals. This adaptation occurs through finely tuned regulations of genes' expressions leading to the variation of their transcriptomes. Multiple parameters have to be integrated in order to provide such mechanisms of regulation. First, the primary sequence of the genome and its organization into chromatin are major regulatory components that harbor genetic, structural and epigenetic information. Second, the three-dimensional organization of the genome into the nucleus brings both physical and functional constraints that also contribute towards these regulatory processes. Here, we engaged a work aiming to understand and dissect how these several levels of information are integrated during the transcriptional regulation of colinear genes (cluster of genes) by the same signal. We took as a model the coordinated regulation of the estrogen-sensitive TFF cluster driven by the estrogen receptor (ER) and its pioneering factors (FOXA1, FOXA2 and GATAs) in mammary cancer cells. This cluster is located within the long arm of the chromosome 21, and contains the gene model termed TFF1. We used large-scale methods (ChIP-chip, ChIP-seq, 4C and microarray transcriptomic analyses) to decipher these dynamic mechanisms.

Adn

Transcription

ARN polymerase II

Régulation

Oestrogènes

Chromatine

DNA

Estrogen

RNA polymerase II

Chromatin

Genetic transcription