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The effect of selected endogenous and exogenous factors on bacterial growth
Šiková, Michaela ; Krásný, Libor (advisor) ; Valášek, Leoš (referee) ; Vopálenský, Václav (referee)
The growth of bacteria by binary division is a key characteristic of these organisms. This growth depends on two types of factors: endogenous and exogenous. Endogenous factors make up the molecular apparatus of cells. Among important endogenous factors belong also those involved in gene expression and its regulation. Exogenous factors are external conditions such as nutrient availability, temperature, pH, various stresses or the presence of antibacterial agents. The main aim of my Thesis was to study the effects of selected endogenous and exogenous factors on bacterial growth. As endogenous factors I studied RNase J1 in Bacillus subtilis and a small RNA called Ms1 in Mycobacterium smegmatis, which are involved in regulation of gene expression at the transcriptional level. I showed that RNase J1 can, besides its role in RNA degradation, play a role in genome integrity by removing stalled RNA polymerase (RNAP) complexes from DNA. I further showed that Ms1 binds to the RNAP core and affects the level of RNAP in the cell. The results revealed new mechanistic aspects of the transcription apparatus and show how individual components or their combinations affect bacterial growth. As exogenous factors I studied the recently discovered antibacterial compounds, called lipophosphonoxins, their interaction...
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The effect of the environment on bacterial DNA topology and gene expression.
Mikesková, Klára ; Krásný, Libor (advisor) ; Večerek, Branislav (referee)
Biological processes in the cell are affected by DNA topology, i. e. by DNA structure and shape. An important topological parameter is the level of supercoiling - additional twisting of DNA is relieved by positive (twisting in the same direction as the helix turns) or negative (twisting in the opposite direction) supercoils. In this Thesis I review the role of supercoiling in gene expression regulation. I describe how supercoiling is involved in homeostatic mechanisms that control the transcriptional output from some genes. Environmental changes such as shifts in temperature, oxidative stress, extreme pH and antibiotics and other inhibitors affect the level of DNA supercoiling. DNA supercoiling then affects the expression of enzymes, which influence DNA topology, as well as some other genes/proteins. In summary, this Thesis describes how changes in the environment influence bacterial DNA topology and gene expression with a brief mention of this type of regulation in eukaryotes.
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Interaction of nucleic acids with RNA polymerase
Janoušková, Martina ; Krásný, Libor (advisor) ; Vopálenský, Václav (referee) ; Knejzlík, Zdeněk (referee)
Regulation of gene expression by RNA polymerase (RNAP) is an essential ability of living organisms, required for their adaption to a changing environment and ultimately enabling their survival. Interaction of RNAP with ribonucleic acids (DNA or RNA) is crucial for transcription and its regulation. This Doctoral Thesis contains two projects addressing interactions of RNAP with nucleic acids: (i) Transcription of modified DNA templates and (ii) Ms1, a small RNA (sRNA) from M. smegmatis. (i) We investigated the influence of modifications in the major groove of DNA on bacterial transcription in vitro. We found out that transcription of modified DNA templates is influenced on the transcription initiation level and that the promoter sequence is important for the effect of the modifications. Furthermore, we successfully performed transcription switch ON and OFF in vitro by bioorthogonal reactions. This regulation of transcription by artificial DNA modifications has a future in biotechnologies and/or medical therapy. (ii) Regulators of transcription are also small non-coding RNAs. These molecules have an important role in gene expression regulation among prokaryotes and eukaryotes. Ms1 is an sRNA found in mycobacteria. It makes a complex with the RNAP core and it is abundant in stationary phase (in amounts...
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Factors interacting with bacterial RNA polymerase and their effect on the regulation of transcription initiation
Ramaniuk, Volha
(ENGLISH) The bacterial cell needs to regulate its gene expression in response to changing environmental conditions. RNA polymerase (RNAP) is the pivotal enzyme of this process and its activity is controlled by a number of auxiliary factors. Here I focus on RNAP-associating factors involved in regulation of transcription in G+ bacteria: factors, initiating nucleoside triphosphates (iNTPs), HelD, δ and small RNA Ms1. The main emphasis is on σ factors from Bacillus subtilis. σ factors allow RNAP to specifically recognize promoter DNA. In my first project I set up in vitro transcription systems with purified alternative σ factors, σB , σD , σH , σI from B. subtilis. Using these systems, I studied the effect of initiating NTP concentration ([iNTP]) on transcription initiation. I showed that promoters of alternative factors are often regulated by [iNTP]. In the next project I comprehensively characterized one of the least explored alternative factors from B. subtilis, I . I identified ~130 genes affected by I , though only 16 of them were directly affected. Moreover, I discovered that I is involved in iron metabolism. Finally, I showed that I binding requires not only the conserved -35 and -10 hexamers, but also extended -35 and -10 elements located in the spacer region. In collaboration with...
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Factors interacting with bacterial RNA polymerase and their effect on the regulation of transcription initiation
Ramaniuk, Volha ; Krásný, Libor (advisor) ; Lichá, Irena (referee) ; Valášek, Leoš (referee)
(ENGLISH) The bacterial cell needs to regulate its gene expression in response to changing environmental conditions. RNA polymerase (RNAP) is the pivotal enzyme of this process and its activity is controlled by a number of auxiliary factors. Here I focus on RNAP-associating factors involved in regulation of transcription in G+ bacteria: factors, initiating nucleoside triphosphates (iNTPs), HelD, δ and small RNA Ms1. The main emphasis is on σ factors from Bacillus subtilis. σ factors allow RNAP to specifically recognize promoter DNA. In my first project I set up in vitro transcription systems with purified alternative σ factors, σB , σD , σH , σI from B. subtilis. Using these systems, I studied the effect of initiating NTP concentration ([iNTP]) on transcription initiation. I showed that promoters of alternative factors are often regulated by [iNTP]. In the next project I comprehensively characterized one of the least explored alternative factors from B. subtilis, I . I identified ~130 genes affected by I , though only 16 of them were directly affected. Moreover, I discovered that I is involved in iron metabolism. Finally, I showed that I binding requires not only the conserved -35 and -10 hexamers, but also extended -35 and -10 elements located in the spacer region. In collaboration with...
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Bacterial RNA polymerase and molecules affecting its function
Jirát Matějčková, Jitka ; Krásný, Libor (advisor) ; Vopálenský, Václav (referee) ; Staněk, David (referee)
RNA polymerase (RNAP) transcribes DNA into RNA and is the only transcriptional enzyme in bacteria. This key enzyme responds to external and internal signals from the cell, resolves the intensity of transcription of individual genes and thus regulates gene expression. RNAP is not only affected by its own subunits, but also protein factors, small molecules or small RNAs (sRNAs). The aim of this Thesis was to contribute to the understanding of the regulation of the RNAP and to add missing fragments to this broad topic. The first part of this Thesis is focused on the influence of selected proteins (δ, YdeB, GreA) on the sensitivity of RNAP to the concentration of the initiating nucleoside triphosphate ([iNTP]) during transcription initiation in Bacillus subtilis. We showed that δ affects the sensitivity of RNAP to [iNTP] at [iNTP]-sensitive promoters, but not at [iNTP]-insensitive promoters neither in vitro nor in vivo. The δ subunit is essential for cell survival during competition with other strains, because it enables the cell to react immediately to changing conditions. Further we showed that YdeB protein does not bind to RNAP in B. subtilis, and has not shown any effect on transcription in vitro. We found that both, GreA and YdeB proteins (unlike δ subunit) were unable to affect RNAP by [iNTP] at...
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Effect of promoter sequence on utilization of NAD+ as a substrate for transcription initiation by RNA polymerase
Pinkas, Daniel ; Krásný, Libor (advisor) ; Fišer, Radovan (referee)
For a long time, 5' cap has been thought to be privilege only for eukaryotic organisms in form of 7-methylguanosine cap at the end of mRNA. This was changed only a few years ago. By using methods liquid chromatography and mass spectrometry a new molecule associated with RNA of Escherichia coli has been found. This molecule turned out to be nicotinamide adenine dinucleotide (NAD+ ) attached to 5' end of some small regulatory RNAs (sRNA). Later it has been shown, that RNA polymerase can attach NAD+ at 5' of RNA ab initio, meaning that RNA polymerase can utilize NAD+ as a substrate for transcription initiation. To some extent substrate for transcription initiation is chosen based on promoter sequence. Crucial requirement is presence of adenine at +1 position of DNA coding strand. This thesis focuses on promoter sequence requirements for transcription initiation with NAD+ . As a template for transcription four promoters with different modifications and their chimeras are used: RNA1, Pveg, lac UV5 and rrnB P1. Also, I tried to compare RNA polymerase from E. coli and B. subtilis in terms of transcription initiation substrate usage. Lastly, I describe here isolation of NudC, enzyme that cleaves NAD+ to nicotinamide mononucleotide (NMN) and adenosine monophosphate (AMP). NudC will be used for upcoming...
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Regulatory network controlled by sigma factors of RNA polymerase in Corynebacterium glutamicum
Kučera, Tomáš ; Pátek, Miroslav (advisor) ; Roučová, Kristina (referee)
An important feature of bacteria is an ability to adapt to changing environment by regulating gene expression. Level of gene expression and its right timing depends mainly on activation or repression of the gene by transcriptional regulators and recognition of the respective promoter by the sigma factor which is a subunit of RNA polymerase. Transcription regulators with sigma factors and other control elements, form a complex regulatory network. The regulatory network in Corynebacterium glutamicum is one of the best studied networks among gram-positive bacteria owing to genome sequencing and application of a number of techniques at the genome level. There has been a lot of success in understanding the roles of individual regulators and interactions between regulators in response to changes in environment. This work summarizes currently known knowledge of mutual relationships between sigma factors, the influence of sigma factors on transcriptional regulators and their cooperative effect on the initiation of transcription. In the thesis, a regulatory network of sigma factors in C. glutamicum and a regulatory cascade in response to the stress situation is schematically created. Key words: sigma factor (FS), Corynebacterium glutamicum, transription regulator (TR), transcription, regulation
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Development of high-throughput screening assay for the identification of inhibitors targeting influenza A polymerase
Karlukova, Elena ; Konvalinka, Jan (advisor) ; Obšil, Tomáš (referee)
Influenza virus A circulates in birds and mammals and causes severe infectious disease that affects from 3 to 5 million people each year. There are two classes of anti-influenza drugs currently available: neuraminidase and M2 channel inhibitors. However, increasing resistance against these two types of inhibitors along with the potential emergence of new viral strains and unpredictability of pandemic outbreaks emphasize an unmet need for new types of inhibitors. RNA-dependent influenza polymerase serves as a novel promising target for the development of anti-influenza medications. The aim of this master thesis is to develop in vitro high-throughput assays for screening of compounds targeting influenza RNA polymerase, particularly, its cap binding and endonuclease domains. For cap-binding domain the screening is based on DIANA (DNA-linked Inhibitor ANtibody Assay) method that was recently developed in our laboratory; for endonuclease domain, the method is based on AlphaScreen technology. For the purposes of the methods development, recombinant cap binding domain of PB2 subunit and N-terminal endonuclease domain of PA subunit of influenza polymerase were expressed with appropriate fusion tags and purified using affinity and gel permeation chromatography. The probes for the screening assays were...
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Computational modeling of complexes consisting of the Zika virus RNA-dependent RNA polymerase and NTP analogs
Ronovský, Michal ; Barvík, Ivan (advisor) ; Pospíšil, Miroslav (referee)
The recently published crystallographic structure of the Zika virus RNA-dependent RNA polymerase (RdRp) allows to produce molecular dyna- mics (MD) simulations of this enzyme that can help in the rational design of its inhibitors - potential chemotherapeutics. In the theoretical part of the thesis are first described basic principles of MD simulations and the method of calculation of binding free energy. This is followed by a brief introduction into the structure of nucleic acids, proteins, RNA polymerases and into mechanisms of expression of genetic information. In the practical part are presented the alchemical trans- formations of ADP to its analogues, which were recently synthesized at ÚOCHB AV ČR. Transformations are performed first in the water envelope and then in the active site of HCV RdRp. Additionally, the conformation of the Zika virus RdRp is modified to match the hepatitis C virus polymerase conformation that can accommodate nucleic acids. Finally, MD simulations of the ADP analogues in the active site of the Zika virus polymerase are produced.
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