DNA Gyrase And Topo NM From Mycobacteria : Insights into Mechanism And Drug Action

Kumar, Rupesh

January 2014

Maintenance of a topological homeostasis by introduction and removal of the supercoils to relieve excessive strain on the DNA is a hallmark of topoisomerase function in the cell. The requirement of the topoisomerases during DNA transaction processes marks a ubiquitous presence of the enzymes in all the life forms. Different reactions carried out by the enzymes include relaxation of positive and negative supercoils required majorly during DNA replication and transcription, decatenation at the end of DNA replication to separate the daughter chromosomes and removal of lethal knots generated in the circular chromosome. In eubacteria, the enzymes introduce negative supercoils to facilitate easier strand separation for DNA transaction processes. However, in thermophiles, a different enzyme maintains the genome in a positively supercoiled form to protect from denaturation by excessive heat. These varied functions are carried out by different topoisomerases. Therefore, each organism maintains a minimum required set of the enzymes and the absence of a certain enzyme may be compensated for by topoisomerases with dual functions. For example, Mycobacterium tuberculosis and many other slow growing mycobacteria do not possess topoisomerase IV or its homologs. In these organisms, the DNA gyrase is suggested to carry out both negative supercoiling and decatenation reactions. Therefore, the mycobacterial DNA gyrase must be able to manage between both the functions in vivo. In contrast, Mycobacterium smegmatis and few other mycobacteria contain an additional type II topoisomerase which does not resemble any known type II enzyme but could catalyze relaxation and decatenation reactions. Importantly, the enzyme displays a unique ability to introduce limited positive supercoils and may have certain functions inside the cell which remains to be studied. Owing to the indispensability for bacterial survival topoisomerases present themselves as important drug targets. A large number of inhibitors have been found to inhibit the enzyme and thereby killing the bacterial. Among these, quinolones are successfully being used as broad spectrum antibacterial drugs. Although the commonly used quinolones inhibit many bacterial pathogens, a reduced susceptibility is exhibited by some of the pathogens e.g. Mycobacterium tuberculosis. To circumvent the lower efficacy of existing drugs, new and modified quinolones have been developed which are highly effective against mycobacteria. The difference in the susceptibility may be conferred by a difference in the chemical property of the drug and the interacting residues present in the enzyme. In the present thesis efforts have been made to understand the mechanism of the type II topoisomerases from mycobacteria and drug action on these enzymes. The thesis is divided into four chapters. In Chapter I of the thesis an introduction is provided on the topoisomerases, their classification and different reactions catalyzed by these enzymes. As the work in present thesis has been carried out with type II topoisomerases, introduction of type II enzymes, their structure and mechanisms is elaborated. DNA gyrase, its mechanism of reaction and in vitro and in vivo functions are explained in great detail. DNA gyrase and topoisomerase IV are targeted by a range of different inhibitors. These different classes of inhibitors and their mechanism of action are described. Finally, the mechanism of mycobacterial DNA gyrase with structural information and the current understanding of quinolone action on the enzyme are explained. The chapter ends with the objective of the study in the present thesis. In chapter II, the studies are aimed at understanding the molecular basis for decatenation carried out by mycobacterial DNA gyrase. Previous work from the laboratory showed that the enzyme can carry out decatenation more efficiently than its homolog from E. coli. It was shown that the mycobacterial enzyme binds two DNA molecules in trans in a length dependent manner. The ability to bind the second DNA is conferred upon the holoenzyme by ATPase subunit (GyrB) subunit which alone can bind DNA. Similar studies using topo IV from E. coli, the strongest known decatenase showed binding of two DNA molecules and the second DNA binding by ATPase (ParE) subunit. However, GyrB subunit from E. coli DNA gyrase, a weaker decatenase, does not bind second DNA molecule efficiently. The results provide a general mechanism for decatenation by type II enzymes in which efficient binding of second DNA is important. In Chapter III, studies have been carried out using topo NM, an atypical type II topoisomerase from Mycobacterium smegmatis. The enzyme has been characterized previously in the laboratory. In addition to efficient decatenation and relaxation, the enzyme exhibits a unique ability to introduce positive supercoils into the DNA. As demonstrated for the mycobacterial DNA gyrase and topo IV in the Chapter II, the ATPase subunit (Topo N) of topo NM, binds second DNA efficiently. The binding of both gate and transport segments increases with the length of the DNA. Binding of two DNA molecules by the holoenzyme appears to be a cumulative effect of DNA binding to individual subunits. In the absence of any inhibitor, the enzyme accumulates cleaved DNA products with shorter DNA but not with larger DNA. The cleavage of the shorter DNA is supported only in the presence of Mg2+ and Mn2+. Another important property of the enzyme is to introduce positive supercoils which appears to be due to its efficient utilization of ATP and a high rate of reaction. Chapter IV deals with the interaction of mycobacterial gyrase with fluoroquinolones (FQs). Although DNA gyrase is the sole target of the FQs in M. tuberculosis, the lower susceptibility to commonly used FQs have led to the studies to find out more effective quinolones. Previous studies from the laboratory showed a lower susceptibility of the mycobacterial gyrase to ciprofloxacin, but moxifloxacin could inhibit the enzyme efficiently. The better inhibition by moxifloxacin appears to be due to efficient trapping of the enzyme-DNA covalent complex. Both ciprofloxacin and moxifloxacin bind the DNA gyrase from mycobacteria, E. coli and E. coli topo IV, independent of DNA. The extent of binding also correlates with the inhibition potential of the drug against a given enzyme. A general model of quinolone enzyme interaction is provided wherein the quinolones are shown to interact with GyrA subunit or holoenzyme or the enzyme- DNA complex which would finally result in the trapping of the covalent complex.

DNA Gyrase

Mycobacteria

DNA Topoisomerases

Drug Action

DNA Binding

Mycobacterial DNA Gyrase

Mycobacterial Topoisomerases

DNA Decatenation

Topo NM

Quinolone

Fluoroquinolones

Ciprofloxacin

Biochemistry

Utilização de informações termodinâmicas e estruturais na predição de sítios de ligação de receptores nucleares ao DNA: uma abordagem computacional / Using thermodynamic and structural information for predicting binding sites of nuclear receptors to DNA: a computational approach

Ana Claudia Mancusi Valeije

04 February 2015

Os projetos genoma têm fornecido uma grande quantidade de informação sobre a arquitetura gênica e sobre a configuração física de suas respectivas regiões flanqueadoras (RF). Estas RF contêm informações com o potencial de auxiliar na elucidação de vários processos biológicos, como os mecanismos de expressão gênica e de sua regulação. Estes mecanismos são de extrema importância para a compreensão do correto funcionamento dos organismos e das patologias que os afetam. Uma parte significativa dos mecanismos de controle de expressão gênica atuam na fase transcricional. Na base destes mecanismos está o recrutamento de proteínas que se ligam às regiões promotoras da transcrição, as quais são segmentos específicos de DNA que podem estar localizados tanto próximos à região de início da transcrição (TSS) quanto a centenas ou até a milhares de pares de bases dela. Essas proteínas compõem a maquinaria transcricional e podem ativar ou inibir o processo de transcrição. Experimentalmente, os segmentos regulatórios podem ser identificadas utilizando métodos complexos de biologia molecular, tais como SELEX, ChiP-ChiP, ChIP-Seq, dentre outros. Uma estratégia alternativa aos métodos experimentais é a utilização de metodologias computacionais. Análises computacionais tendem a ser mais rápidas, baratas e flexíveis do que protocolos experimentais, além de poderem ser utilizadas em larga escala. Atualmente, os métodos computacionais disponíveis necessitam de informações experimentais para a definição de padrões globais de preferências de sequências de DNA para a ligação de fatores de transcrição (TFBS, em inglês transcription factor binding sites). Entretanto, esses métodos apresentam uma elevada taxa de falso positivos e, por vezes, apresentam também taxas significativas de falso negativos, além de serem limitados ao estudo de fatores de transcrição de espécies bem conhecidas, o que diminui a área de aplicação dos mesmos. Diante deste cenário, o uso de métodos computacionais que não necessitem da informação referente aos sítios de ligação, bem como os que utilizem parâmetros mais robustos de detecção dos resultados, em detrimento dos escores de pontuação provindos de alinhamentos, podem acrescentar uma sensível melhoria ao processos de predição de regiões regulatórias. Neste projeto, foi desenvolvido um novo modelo computacional (TFBSAnalyzer) para análise e identificação de TFBS em elementos regulatórios, que utiliza técnicas de modelagem molecular para a construção de complexos entre um fator de transcrição ancorado a estruturas de DNA com sequências variáveis de bases e, através de cálculos termodinâmicos de entalpia de ligação, determina uma função de pontuação baseada na energia de ligação e realiza a predição de sítios de ligação ao DNA para o fator de transcrição em análise. Esta abordagem foi testada com três fatores de transcrição como sistemas-modelo, pertencentes à família dos receptores nucleares, a saber: o receptor de estrógeno ER-alfa (Estrogen Receptor Alpha), o receptor de ácido retinoico RAR-beta (Retinoid Acid Receptor Beta) e o receptor X retinóico RXR (Retinoid X Receptor). Os modelos previstos computacionalmente foram comparados aos dados experimentais disponíveis para estes receptores nucleares, os quais apresentaram as seguintes taxas de FP/FN: 10%/0 para RAR-beta e RXR, 21%/6% para ER-alfa. Também simulamos um experimento de ChIP-seq do ER-alfa no genoma humano, cujos genes selecionados foram submetidos a uma análise de enriquecimento de fatores de transcrição curados experimentalmente, que fazem sua regulação, revelando que o receptor de estrógeno está realmente envolvido no processo. Para mostrar a aplicabilidade geral de nosso método, nós modelamos a distribuição de energia de ligação para o receptor NHR-28 isoforma a de Caenorhabditis elegans com DNA . Obtivemos distribuições de energia semelhantes àquelas encontradas para os NRs modelos, portanto seria possível aplicar o método para buscar possíveis TFBSs para este receptor no genoma de C. elegans. Os dados gerados e as metodologias desenvolvidas neste projeto devem acrescentar uma sensível melhoria aos processos de predição de regiões regulatórias e consequentemente auxiliar no entendimento dos mecanismos envolvidos no processo de expressão gênica e de sua regulação. / The genome projects have provided a lot of information about the genetic architecture, as well as on the physical configuration of their flanking regions (FR). These FR have the potential to aid in the elucidation of many biological processes, such as the mechanisms involved in gene expression and its regulation. These mechanisms are extremely important for undeerstanfind the correct functioning of organisms as well as the pathologies that affect them. A significant part of the control mechanisms of gene expression act during transcription. On the basis of this mechanisms is the recruitment of proteins that bind to promoter regions of transcription, which are specific segments of DNA that can be located either near the transcription start site or at hundreds or even thousands of base pairs away. These proteins form the transcription machinery, which can activate or inhibit the transcription process. The regulatory segments can be identified experimentally using complex methods of molecular biology, such as SELEX, ChIP-chip, ChIP-seq, among others. An alternative strategy to these experimental methods is the use of computational methodologies for predicting regulatory regions. Computational analysis tend to be faster, cheaper and more flexible than the experimental protocols, and can be used on a larger scale. Currently, the available computational methods require information previously obtained from experiments in order to define global standards of preference of DNA-Binding sequences for transcription factors (TFBS - Transcription Factor Binding Sites). However, these methods have a high rate of false positives and sometimes also have significant rates of false negatives, besides being limited to the study of transcription factors of well-known species, which decreases their application area. In this scenario, the use of computational methods that do not require previous information concerning the binding sites and use more robust parameters of results detection, instead of alignment scores, may add significant improvement to the processes of predicting regulatory regions. In this project, we developed a new computational model TFBSAnalyzer) for analysis and identification of regulatory elements using molecular modeling techniques for the construction of complexes between a transcription factor bound to specific DNA structures with variable sequences of bases and, by means of thermodynamic calculations of bond enthalpy, provides a scoring function based on the binding energy and predicts the DNA binding sites for the transcription factor in analysis. This approach was tested initially with three transcription factors as models, belonging to the nuclear receptor family, namely estrogen receptor ER-alpha (Estrogen Receptor Alpha), the retinoic acid receptor RAR-beta (Retinoid Acid Receptor Beta) and the retinoic X receptor RXR (Retinoid X Receptor). The computationally predicted models were compared to experimental data available for these nuclear receptors, and presented the following rates of FP/FN: 10%/0 for RAR-beta and RXR, 21%/6% for ER-alpha. We also simulated an experiment of ChIP-seq with ER-alpha with the human genome, where the selected genes were subjected to a transcription factor enrichment analysis, with curated information, revealing that the estrogen receptor is indeed involved in their regulation. To show that our method has a general applicability, we modeled the binding energy distribution for the NHR-28 receptor, isoform a, from Caenorhabditis elegans. The energy distributions obtained were similar to the ones obtained for the model NR, so it would be possible to use the method and search for possible TFBS in the C. elegans genome. The data generated and the methodologies developed in this project should add a significant improvement to the prediction processes of regulatory regions and, consequently, help to understand the mechanisms involved in the gene expression process and its regulation.

Dedos de zinco

Fatores de transcrição

Interação proteína-DNA

Receptores nucleares

Sítios de ligação ao DNA

TFBS

DNA binding sites

Nuclear receptors

Protein-DNA interactions

TFBS

Transcription factors

Zinc fingers

Peptídeos bioativos do plasma de Acanthoscurria rondoniae. / Bioactives Peptides from Plasma of Acanthoscurria rondoniae.

Katie Cristina Takeuti Riciluca

08 June 2016

Peptídeos antimicrobianos (AMP) são importantes componentes do sistema imune de todos os organismos vivos. No plasma de Acanthoscurria rondoniae isolamos 15 AMP com similaridade com a hemocianina. As sete subunidades da hemocianina foram sequenciadas e sua estrutura tridimensional determinada. A rondonina, processada a partir de uma enzima do plasma em condições ácidas apresentou melhor atividade em pH ácido, sinergismo com gomesina, não citotóxico, não interagiu com membranas artificiais lipídicas, protegeu as células da infecção por vírus humanos de RNA e seu mecanismo de ação em leveduras está associado com material genético. Nossos resultados nos ajudam a entender porque aracnídeos sobreviveram por um longo tempo na escala evolutiva. E como as doenças infecciosas estão entre as principais causas de morte da população humana torna-se vital investir na busca de substâncias naturais ou sintéticas que exibam atividades antimicrobianas específicas e, acima de tudo, que as exerçam através de mecanismos de ação alternativos daqueles dos antibióticos disponíveis. / Antimicrobial peptides (AMP) are important components of the immune system of all living organisms. In the plasma of Acanthoscurria rondoniae we isolated 15 AMP with similarity to hemocyanin. The seven subunits hemocyanin were sequenced and determined its three-dimensional structure. The rondonin, processed from a plasma enzyme under acidic conditions showed best activity at acid pH, synergism with gomesin, non-cytotoxic, does not interacted with lipid artificial membrane, protected the cells from infection by human virus RNA and its mechanism of action in yeast is associated with genetic material. Our results help us understand why arachnids have survived for a long time on the evolutionary scale. And how infectious diseases are among the leading causes of death in human population becomes vital to invest in the search for natural or synthetic substances that exhibit specific antimicrobial activities and, above all, that engage through alternative mechanisms of action of these antibiotics available.

Atividade antiviral

cryo-EM

Fragmentos de hemocianina

Ligação com DNA

Rondonina

Transcriptoma

Antiviral activity

cryo-EM

DNA-binding

Hemocyanins fragments

Rondonin

Transcriptome

Strukturelle Einblicke in die Funktionalität des Terminase-Proteins pUL89, eine Untereinheit des Nanomotors des humanen Cytomegalievirus (HCMV).

Theiß, Janine

23 November 2020

Der DNA-Verpackungsmechanismus des humanen Cytomegalievirus (HCMV) ist charakteristisch für große DNA-Viren wie Herpesviren und ds-Bakteriophagen. Er beruht auf der Spaltung der konkatemeren DNA durch einen viralen, hetero-oligomeren Proteinkomplex, der Terminase. In der vorliegenden Arbeit konnten die funktionellen Domänen der Terminase-Untereinheit pUL89 in vitro identifiziert und charakterisiert werden. Neben einer Nuklease-Aktivität besitzt pUL89 auch die Fähigkeit dsDNA sequenz-unabhängig zu binden. Durch Nuklease-Untersuchungen konnte gezeigt werden, dass pUL89 sowohl dsDNA, als auch lineare DNA spaltet. PUL89 weist dabei eine größere Spezifität zu dsDNA auf. Des Weiteren konnte nachgewiesen werden, dass die Aminosäure D463 eine zentrale Funktion innerhalb der Nuklease-Aktivität besitzt. Durch kolorimetrische DNA-Bindungsuntersuchungen konnte die Aminosäure R544 als essenziell für die dsDNA-Bindungsfähigkeit von pUL89 identifiziert werden. Basierend auf den in vitro Ergebnissen wurden rekombinanten TB40/E-Virusmutanten mit Mutationen im ORF UL89 durch die En Passant Mutagenese generiert. Mit Hilfe dieser Viren sollte der Einfluss der Mutationen auf die Replikation des Virus charakterisiert werden. Es war möglich nachzuweisen, dass die Aminosäuren E534 und R544 eine essenzielle Aufgabe innerhalb von HCMV erfüllen, da die Mutation einer dieser Aminosäure zu nicht wachstums-fähigen BAC-Mutanten führte. Zur Charakterisierung dieser Konstrukte wurden die Zelllinien HELF Fi301-UL89 und HELF Fi301-vProm-UL89 verwendet. Durch Untersuchungen hinsichtlich der Wachstumseigenschaften, Proteinexpression, DNA-Spaltung, DNA-Bindung sowie elektronenmikroskopischen Aufnahmen, konnte gezeigt werden, dass die wachstums-kompetenten BAC-Mutanten keinen signifikanten Unterschied zum Wildtyp-Virus TB40/E zeigten. Sodass nachgewiesen werden konnte, dass die basischen Aminosäuren H565 und H571 keine essenzielle Funktion in pUL89 erfüllen. / The human cytomegalovirus DNA packaging mechanism is characteristic for large DNA viruses like Herpes viruses and ds bacteriophages. This mechanism is based on the cleavage of concatemeric DNA by the viral heterooligomeric protein complex terminase. This dissertation includes the identification and characterization of functional domains of the HCMV terminase subunit pUL89. PUL89 contain a nuclease activity and the ability to bind dsDNA. This protein shows the property to cut as well dsDNA as linear DNA. The amino acid D463 shows a significant role in this cleavage event. Colorimetric DNA binding experiments show the central role of R544 in DNA binding by pUL89. Based of the in vitro results recombinant TB40/E viruses with mutations in the ORF UL89 were generated. These viruses allow a characterization of the impact of virus replication. It was possible to show that the amino acids E534 and R544 have a functional role in HCMV. The mutation of one of these amino acids was enough to generate a growth deficient mutant. The stable cell lines HELF Fi301-UL89 and HELF Fi301-vProm UL89 were used for the characterization of the growth deficient mutants. The growth competent mutants H656A and H571A show no significant differences in comparison with the wild type TB40/E virus. This was verified by growth kinetics, protein expression characterizations, pulse field gel electrophoresis, DNA binding assays and electron microscopy.

DNA-Verpackung

Humanes Cytomegalievirus

Terminase-Komplex

DNA-Bindung

Nuklease

human cytomegalovirus

terminase

DNA packaging

DNA binding

nuclease

610 Medizin und Gesundheit

WF 4250

ddc:610

RAD21 Cooperates with Pluripotency Transcription Factors in the Maintenance of Embryonic Stem Cell Identity

Buchholz, Frank, Nitzsche, Anja, Paszkowski-Rogacz, Maciej, Matarese, Filomena, Janssen-Megens, Eva M., Hubner, Nina C., Schulz, Herbert, de Vries, Ingrid, Ding, Li, Huebner, Norbert, Mann, Matthias, Stunnenberg, Hendrik G.

18 January 2016

For self-renewal, embryonic stem cells (ESCs) require the expression of specific transcription factors accompanied by a particular chromosome organization to maintain a balance between pluripotency and the capacity for rapid differentiation. However, how transcriptional regulation is linked to chromosome organization in ESCs is not well understood. Here we show that the cohesin component RAD21 exhibits a functional role in maintaining ESC identity through association with the pluripotency transcriptional network. ChIP-seq analyses of RAD21 reveal an ESC specific cohesin binding pattern that is characterized by CTCF independent co-localization of cohesin with pluripotency related transcription factors Oct4, Nanog, Sox2, Esrrb and Klf4. Upon ESC differentiation, most of these binding sites disappear and instead new CTCF independent RAD21 binding sites emerge, which are enriched for binding sites of transcription factors implicated in early differentiation. Furthermore, knock-down of RAD21 causes expression changes that are similar to expression changes after Nanog depletion, demonstrating the functional relevance of the RAD21 - pluripotency transcriptional network association. Finally, we show that Nanog physically interacts with the cohesin or cohesin interacting proteins STAG1 and WAPL further substantiating this association. Based on these findings we propose that a dynamic placement of cohesin by pluripotency transcription factors contributes to a chromosome organization supporting the ESC expression program.

info:eu-repo/classification/ddc/570

ddc:570

The Structural Basis for the Phosphorylation-Induced Activation of Smad Proteins: a Dissertation

Chacko, Benoy M.

23 February 2004

The Smad proteins transduce the signal of transforming growth factor-β (TGF-β) and related factors from the cell surface to the nucleus. Following C-terminal phosphorylation by a corresponding receptor kinase, the R-Smad proteins form heteromeric complexes with Smad4. These complexes translocate into the nucleus, bind specific transcriptional activators and DNA, ultimately modulating gene expression. Though studied through a variety of means, the stoichiometry of the R-Smad/Smad4 complex is unclear. We investigated the stoichiometry of the phosphorylation-induced R-Smad/Smad4 complex by using acidic amino acid substitutions to simulate phosphorylation. Size exclusion chromatography, analytical ultracentrifugation, and isothermal titration calorimetry analysis revealed that the R-Smad/Smad4 complex is a heterotrimer consisting of two R-Smad subunits and one Smad4 subunit. In addition, a specific mechanism for phosphorylation-induced R-Smad/Smad4 complex formation was studied. Although it had been previously established that part of the mechanism through which phosphorylation induces Smad oligomerization is through relieving MH1-domain mediated autoinhibition of the MH2 (oligomerization) domain, it is also evident that phosphorylation serves to energetically drive Smad complex formation. Through mutational and size exclusion chromatography analysis, we established that phosphorylation induces oligomerization of the Smads by creating an electrostatic interaction between the phosphorylated C-terminal tail of one R-Smad subunit in a Smad trimer with a basic surface on an adjacent R-Smad or Smad4 subunit. The basic surface is defined largely by the L3 loop, a region that had previously been implicated in R-Smad interaction with the receptor kinase. Furthermore, the Smad MH2 domain shares a similar protein fold with the phosphoserine and phosphothreonine-binding FHA domains from proteins like Rad53 and Chk2. Taken together, these results suggest that the Smad MH2 domain may be a distinct phospho serine-binding domain, which utilizes a common basic surface to bind the receptor kinase and other Smads, and takes advantage of phosphorylation-induced allosteric changes dissociate from the receptor kinase and oligomerize with other Smads. Finally, the structural basis for the preferential formation of the R-Smad/Smad4 heterotrimeric complex over the R-Smad homotrimeric complex was explored through X-ray crystallography and isothermal titration calorimetry. Crystal structures of the Smad2/Smad4 and Smad3/Smad4 complexes revealed that specific residue differences in Smad4 compared to R-Smads resulted in highly favorable electrostatic interactions that explain the preference for the interaction with Smad4.

DNA-Binding Proteins

Phosphorylation

Signal Transduction

Trans-Activators

Transforming Growth Factor beta

Amino Acids, Peptides, and Proteins

Cells

Enzymes and Coenzymes

Genetic Phenomena

Investigative Techniques

Synthesis of a new HYNIC-DAPI derivative for labelling with ⁹⁹ᵐTechnetium and its in vitro evaluation in an FRTL5 cell line

Ferl, Sandra, Wunderlich, Gerd, Smits, René, Hoepping, Alexander, Naumann, Anne, Kotzerke, Jörg

10 January 2020

4′,6-Diamidine-2-phenylindole (DAPI) is a common fluorochrome that is able to bind to deoxyribonucleic acid (DNA) with distinct, sequence-dependent enhancement of fluorescence. This work presents the synthesis of a new multifunctional compound that includes the fluorescent dye as a ⁹⁹ᵐTechnetium (⁹⁹ᵐTc) carrier. A new technique for the bioconjugation of DAPI with 6-hydrazinonicotinic acid (HYNIC) through an amide linkage was developed. The radiolabelling was performed with HYNIC as a chelator and N-IJ2-hydroxy-1,1-bisIJhydroxymethyl)ethyl)glycine (tricine) as a coligand. Furthermore, experimental evidence showed that ⁹⁹ᵐTc complexes with DAPI as DNA-binding moieties are detectable in living Fischer rat thyroid follicular cell line 5 (FRTL5) and their nuclei. The investigations indicated further that the new HYNIC-DAPI derivative is able to interact with double-stranded DNA. This establishes the possibility of locating ⁹⁹ᵐTc in close proximity to biological structures of living cells, of which especially the genetic information-carrying cell compartments are at the centre of interest. In this context, further investigations are related to the radiotoxic effects of DNA-bound ⁹⁹ᵐTc-HYNIC-DAPI derivatives and dosimetric calculations.

info:eu-repo/classification/ddc/540

ddc:540

Studium exprese jaderného receptoru nhr-97 v Caenorhabditis elegans / Study of expression of the nuclear receptor nhr-97 in Caenorhabditis elegans

Boušová, Kristýna

January 2012

Nuclear hormone receptors (NHR) are important transcription factors that regulate development and metabolism in the large group of animals. Caenorhabditis elegans contains 284 nuclear receptors, which is unusually large amount compared to receptors of Drosophila melanogaster (18) and humans (48). 15 receptors of the C. elegans have homologous receptor structure with receptors of D. melanogaster and mammals. The remaining 269 NHR are specific to nematodes and belong to the group of supplementary nuclear receptors (SupNRs), the evolutionary precursor of the HNF4 - an important transcription factor in humans. In this work we describe the nuclear hormone receptor nhr-97 C. elegans, whose expression and function have not yet been studied. The gene is encoded in the genome of C. elegans and is among SupNRs. Nhr-97 consists of two isoforms A and B, whose expression in C. elegans tissues is different. Localization of gene expression in vivo was determined using lines expressing nhr-97:: GFP. For the A isoform expression of nhr-97::GFP was localized in neurons in the pharynx and the tail, in the intestine and hypodermis, in isoform B in the pharynx, in neurons around the corpus of pharynx, the head mesodermal cell and in anal sphincter. Nhr-97 expression during development of C. elegans was determined by...

Transkripční faktory CSL a jejich role v kvasince Schizosaccharomyces pombe / Transcription factors CSL and their role in the yeast Schizosaccharomyces pombe

Oravcová, Martina

January 2014

Proteins of the CSL family (CBF1/RBP-Jκ/Suppressor of Hairless/LAG-1) act as effectors of the Notch signalling pathway in metazoan organisms. They function as repressors or activators of gene transcription in the framework of this pathway and influence many developmental processes. Metazoan CSL proteins can regulate gene expression Notch-independently as well. Notch-independent functions of CSL proteins might be evolutionarily ancestral and in cells and organisms may be important equally as Notch-dependent functions. Presence of CSL proteins was identified in several fungal species, organisms lacking the Notch signalling pathway components and most of known metazoan interacting partners of CSL proteins. CSL paralogs of the fission yeast Schizosaccharomyces pombe, cbf11 and cbf12, are non-essential genes encoding proteins localized in the nucleus of the cell. They exert antagonistic effects on regulation of processes like coordination of nuclear and cellular division and cell cycle progression, ploidy maintenance, cell adhesion and other. In this study, we have proved that both CSL paralogs are able to sequence-specifically bind the CSL-response element DNA in vitro and Cbf11 in vivo as well. Both proteins could activate gene expression in vivo and perform the function of transcription factors....

The Role of PC4 in Oxidative Stress: A Dissertation

Yu, Lijian

29 June 2011

Oxidative stress is a cellular condition where cells are challenged by elevated levels of reactive oxygen species (ROS) that are produced endogenously or exogenously. ROS can damage vital cellular components, including lipid, protein, DNA and RNA. Oxidative damage to DNA often leads to cell death or mutagenesis, the underlying cause of various human disease states. Previously our laboratory discovered that human PC4 gene can prevent oxidative mutagenesis in the bacterium Escherichia coli and that the yeast homolog SUB1 has a conserved function in oxidation protection. In this thesis I examined the underlying mechanisms of PC4’s oxidation protection function. My initial efforts to examine the predicted role of SUB1 in transcription-coupled DNA repair essentially negated this hypothesis. Instead, results from our experiments suggest that PC4 and yeast SUB1 can directly protect genomic DNA from oxidative damage. While testing SUB1’s role in double strand DNA break (DSB) repair, I found the sub1Δ mutant resects DSB ends rapidly but still ligates chromosomal breaks effectively, suggesting that DSB resection is not inhibitory to nonhomologous end-joining, an important DSB repair pathway. Finally, in the course of studying transcription recovery after UV damage, I found UV induces a longer form of RPB2 mRNA and demonstrated that this is caused by alternative polyadenylation of the RPB2 mRNA and that alternative polyadenylation contributes to UV resistance. Based on results of preliminary experiments, I propose that UV activates an alternative RNA polymerase to transcribe RNA POL II mRNA, a novel mechanism to facilitate recovery from inhibition of transcription resulting from UV damage. The hypothetical polymerase switch may account for the UV-induced alternative polyadenylation of the RPB2 mRNA.

Oxidative Stress

DNA Damage

DNA-Binding Proteins

Subtilisins

Proprotein Convertases

Polyadenylation

Cells

Enzymes and Coenzymes

Genetic Phenomena