Biotransformační aspekty nových karbocyklických analogů nukleosidů. / Biotransformation aspects on novel carbocyclic nucleoside analogs.

Rozumová, Nela

January 2012

Carbocyclic nucleoside analogs with norbornane moiety that have been synthesized at IOCB AS CR, represent new potential chemotherapeutic agents with significant activity against Coxsackieviruses. The main objective of this work was to study the metabolism and mechanism of action of the original analog carbocyclic nucleoside MS 254, which is characterized by its antiviral and cytostatic effects. The attention was partially paid also to the two structurally related substances (MS 255, MS 320). In this work, we determined cytotoxicity of these compounds in cell culture and the effect of MS 254 on the amount of total and oxidized glutathione, activity of glutathione-S-transferase (GST), glutathione reductase (GR) and the effect on cellular oxidative stress. The kinetics of the conjugation of MS 254 by human GST was also studied. It was found that of the three substances tested MS 255 was the most cytotoxic and MS 254 was the least cytotoxic compound. It was further found that MS 254 does not cause significant oxidative stress and that it increases the activity of GST and GR in a dose-dependent manner. Michaelis-Menten constant of the conjugation of MS 254 with the glutathione (main metabolic pathway) was determined in the milimolar range, indicating a relatively low affinity of MS 254 for GST.

Endogenous Small RNAs in the <em>Drosophila</em> Soma: A Dissertation

Ghildiyal, Megha

11 March 2010

Since the discovery in 1993 of the first small silencing RNA, a dizzying number of small RNAs have been identified, including microRNAs (miRNAs), small interfering RNAs (siRNAs) and Piwi-interacting RNAs (piRNAs). These classes differ in their biogenesis, modes of target regulation and in the biological pathways they regulate. Historically, siRNAs were believed to arise only from exogenous double-stranded RNA triggers in organisms lacking RNA-dependent RNA polymerases. However, the discovery of endogenous siRNAs in flies expanded the biological significance of siRNAs beyond viral defense. By high throughput sequencing we identified Drosophila endosiRNAs as 21 nt small RNAs, bearing a 2´-O-methyl group at their 3´ ends, and depleted in dicer-2 mutants. Methylation of small RNAs at the 3´ end in the soma, is a consequence of assembly into a mature Argonaute2-RNA induced silencing complex. In addition to endo-siRNAs, we observed certain miRNAs or their miRNA* partners loading into Argonaute2. We discovered, that irrespective of its biogenesis, a miRNA duplex can load into either Argonaute (Ago1 or Ago2), contingent on its structural and sequence features, followed by assignment of one of the strands in the duplex as the functional or guide strand. Usually the miRNA strand is selected as the guide in complex with Ago1 and miRNA* strand with Ago2. In our efforts towards finding 3´ modified small RNAs in the fly soma, we also discovered 24-28nt small RNAs in certain fly genotypes, particularly ago2 and dcr-2mutants. 24-28nt small RNAs share many features with piRNAs present in the germline, and a significant fraction of the 24-28nt small RNAs originate from similar transposon clusters as somatic endo-siRNAs. Therefore the same RNA can potentially act as a precursor for both endo-siRNA and piRNA-like small RNA biogenesis. We are analyzing the genomic regions that spawn somatic small RNAs in order to understand the triggers for their production. Ultimately, we want to attain insight into the underlying complexity that interconnects these small RNA pathways. Dysregulation of small RNAs leads to defects in germline development, organogenesis, cell growth and differentiation. This thesis research provides vital insight into the network of interactions that fine-tune the small RNA pathways. Understanding the flow of information between the small RNA pathways, a great deal of which has been revealed only in the recent years, will help us comprehend how the pathways compete and collaborate with each other, enabling each other’s optimum function.

Drosophila

Drosophila Proteins

RNA

Untranslated

RNA

Small Interfering

MicroRNAs

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Studies on the Regulation of Cytoplasmic Polyadenylation Element-Binding Protein: A Dissertation

Lin, Chien-Ling

11 January 2012

Post-transcriptional regulation of gene expression sits at the core of proteomic complexity; trans-acting factors that regulate RNA localization and translation capacity are thus indispensible. In this thesis, I present studies of the cytoplasmic polyadenylation element binding protein (CPEB), a sequence specific RNA-binding protein important for cell cycle progression and neural synaptic plasticity. I focus on CPEB because the activity of RNA-binding proteins affects the destiny of their mRNA substrates. As presented in Chapter II, CPEB, though mostly cytoplasmic at steady state, shuttles between the nucleus and the cytoplasm. Surprisingly, the RNA recognition motifs are essential for the nuclear localization. CPEB associates with the polyadenylation machinery in both compartments, suggesting it is involved in both nuclear mRNA processing and cytoplasmic translational regulation. Moreover, the nuclear translocalization is critical to relay a tight translation repression on CPE-containing mRNAs. Chapter III focuses on the regulation of CPEB dimerization. CPEB dimerizes through the RNA-binding domains to inhibit its own RNA binding ability in a cell cycle-dependent manner. By dimerizing, CPEB has enhanced binding to protein destruction factors so that robust active degradation occurs in the later cell cycle. The degradation of CPEB is required for translation activation of a subset of mRNAs and cell cycle progression. In addition, dimerization protects cells from being overloaded with excess CPEB. In sum, the localization and dimerization status of CPEB is dynamic and highly regulated; they in turn regulate the activity of CPEB, which results in responsive translation control. These studies provide a strong foundation to decipher CPEB-mediated gene expression.

RNA-Binding Proteins

Poly(A)-Binding Proteins

Polyadenylation

Amino Acids, Peptides, and Proteins

Genetic Phenomena

Role of Host Cellular Membrane Raft Domains in the Assembly and Release of Newcastle Disease Virus: A Dissertation

Laliberte, Jason P.

01 April 2008

Newcastle disease virus (NDV) belongs to the Paramyxoviridae, a family of enveloped RNA viruses that includes many important human and animal pathogens. Although many aspects of the paramyxovirus life cycle are known in detail, our understanding of the mechanisms regulating paramyxovirus assembly and release are poorly understood. For many enveloped RNA viruses, it has recently become apparent that both viral and host cellular determinants coordinate the proper and efficient assembly of infectious progeny virions. Utilizing NDV as a model system to explore viral and cellular determinants of paramyxovirus assembly, we have shown that host cell membrane lipid raft domains serve as platforms of NDV assembly and release. This conclusion was supported by several key experimental results, including the exclusive incorporation of host cell membrane raftassociated molecules into virions, the association of structural components of the NDV particle with membrane lipid raft domains in infected cells and the strong correlation between the kinetics of viral protein dissociation from membrane lipid raft domains and incorporation into virions. Moreover, perturbation of infected cell membrane raft domains during virus assembly resulted in the disordered assembly of abnormal virions with reduced infectivity. These results further established membrane raft domains as sites of virus assembly and showed the integrity of these domains to be critical for the proper assembly of infectious virions. Although specific viral protein-protein interactions are thought to occur during paramyxovirus assembly, our understanding of how these interactions are coordinated is incomplete. While exploring the mechanisms underlying the disordered assembly of non-infectious virions in membrane raft-perturbed cells, we determined that the integrity of membrane raft domains was critical in the formation and virion incorporation of a complex consisting of the NDV attachment (HN) and fusion (F) proteins. The reduced virus-to-cell membrane fusion capacity of particles released from membrane raft-perturbed cells was attributed to an absence of the HN – F glycoprotein-containing complex within the virion envelope. This result also correlated with a reduction of these glycoprotein complexes in membrane lipid raft fractions of membrane raft-perturbed cells. Specifically, it was determined that the formation of newly synthesized HN and F polypeptides into the glycoprotein complex destined for virion incorporation was dependent on membrane lipid raft integrity. Finally, a novel virion complex between the ribonucleoprotein (RNP) structure and the HN attachment protein was identified and characterized. Unlike the glycoprotein complex, the detection of the RNP – HN protein-containing complex was not affected by membrane raft perturbation during virus assembly in the cell. The biological importance of this novel complex for the proper assembly of an infectious progeny virion is currently under investigation. The results presented in this thesis outline the role of host cell membrane lipid raft domains in the assembly and release processes of a model paramyxovirus. Furthermore, the present work extends our understanding of how these particular host cell domains mechanistically facilitate the ordered assembly and release of an enveloped RNA virus.

Cholesterol

HN Protein

Membrane Microdomains

Newcastle disease virus

Viral Fusion Proteins

Virus Assembly

Amino Acids, Peptides, and Proteins

Lipids

Polycyclic Compounds

Viruses

RNA Recognition by the Caenorhabditis elegans Embryonic Determinants MEX-5 and MEX-3: A Dissertation

Pagano, John M., Jr.

01 June 2010

Post-transcriptional regulation of gene expression is a mechanism that governs developmental and cellular events in metazoans. In early embryogenesis, transcriptionally quiescent cells depend upon maternally supplied factors such as RNA binding proteins and RNA that control key decisions. Morphogen gradients form and in turn pattern the early embryo generating different cell types and spatial order. In the nematode Caenorhabditis elegans, the early embryo relies upon several RNA binding proteins that control mRNA stability, translation efficiency, and/or mRNA localization of cell fate determinants essential for proper development. MEX-5 and MEX-3 are two conserved RNA-binding proteins required to pattern the anterior/posterior axis and early embryo. Mutation of either gene results in a maternal effect lethal phenotype with proliferating posterior muscle into the anterior blastomeres (Muscle EXcess). Several cell-fate determinants are aberrantly expressed in mex-5 and mex-3 embryos. Both proteins are thought to interact with cis-regulatory elements present in 3’-UTRs of target RNAs controlling their metabolism. However, previous studies failed to demonstrate that these proteins regulate maternal transcripts directly. This dissertation presents a thorough assessment of the RNA binding properties of MEX-5 and MEX-3. Quantitative biochemical approaches were used to determine the RNA binding specificity of both proteins. MEX-5 has a relaxed specificity, binding with high affinity to linear RNA containing a tract of six or more uridines within an eight-nucleotide window. This is very different from its mammalian homologs Tristetraprolin (TTP) and ERF-2. I was able to identify two amino acids present within the MEX-5 RNA binding domain that are required for the differential RNA recognition observed between MEX-5 and TTP. MEX-3 on the other hand is a specific RNA binding protein, recognizing a bipartite element with flexible spacing between two four-nucleotide half-sites. I demonstrate that this element is required for MEX-3 dependent regulation in vivo. Previous studies only identify a small number of candidate regulatory targets of MEX-5 and MEX-3. The defined sequence specificity of both proteins is used to predict new putative targets that may be regulated by either protein. Collectively, this study examines the RNA binding properties of MEX-5 and MEX-3 to clarify their role as post-transcriptional regulators in nematode development.

Caenorhabditis elegans Proteins

RNA-Binding Proteins

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Embryonic Structures

Genetic Phenomena

Drosophila piRNA Function in Genome Maintenance, Telomere Protection and Genome Evolution: A Dissertation

Khurana, Jaspreet S.

26 October 2010

Upon fertilization, the early embryo sustains most of the cellular processes using the maternally deposited reserves in the egg itself until the zygotic gene expression takes charge. Among the plethora of essential components provided by the mother are small non-coding RNAs called PIWI-interacting RNAs (piRNAs), which provide immunity to the zygote against transposon challenge. In this thesis, I have presented three different functions of piRNAs in Drosophila melanogaster- in maintenance of genomic integrity, telomere protection and their role as an adaptive immune system against genomic parasites. In Chapter 2, I have described the phenotypic effects of the loss of piRNA function in early embryos. The mutations affecting the piRNA pathway are known to cause embryonic lethality. To describe this lethality in detail, I have shown that all the characterized piRNA mutants show compromised zygotic genomic integrity during early embryogenesis. In addition, two piRNA pathway components, Aubergine (Aub) and Armitage (Armi) are also required for telomere resolution during early embryogenesis. Aub and Armi recruit telomeric protection complex proteins, HOAP and HP1, to the telomeric ends and thus avoid activation of the Non-homologous end joining (NHEJ) DNA repair pathway at the telomeres. There are about 120 transposon families in Drosophila melanogaster and piRNA pathway mutations cause activation of many of the resident transposons in the genome. In Chapter 3, I have described the effects of infection by a single transposon, P-element, in naïve strains by introduction through the zygote. Activation of the P-element leads to desilencing of unrelated transposons, causing accumulation of germline DNA damage which is linked to severely reduced fertility in the hybrid females. However, there is partial restoration of fertility as the hybrid progeny age, which correlates with P-element piRNA production and thus P-element silencing. Additionally, a number of transposons mobilize into piRNA generating heterochromatic clusters in the genome, and these insertions are stably inherited in the progeny. Collectively our data shows that piRNA production can be triggered in the adults in an absence of maternal contribution and that piRNAs serve as an adaptive immune system which helps resolve an internal genetic conflict between the host and the parasite. In an effort to understand the phenotypic effects of piRNA dysfunction in Drosophila, we have uncovered new exciting roles for piRNAs in development and presented evidence how transposons can act as architects in restructuring the host genome.

RNA

Small Interfering

Drosophila melanogaster

Genome

Insect

Telomere

DNA Transposable Elements

Animal Experimentation and Research

Genetic Phenomena

Genetics and Genomics

Hemic and Immune Systems

Cellular and Molecular Mechanisms Driving Glial Engulfment of Degenerating Axons: A Dissertation

Doherty, Johnna E.

14 November 2011

The nervous system is made up of two major cell types, neurons and glia. The major distinguishing feature between neuronal cells and glial cells is that neurons are capable of transmitting action potentials while glial cells are electrically incompetent. For over a century glial cells were neglected and it was thought they existed merely to provide trophic and structural support to neurons. However, in the past few decades it has become increasingly clear that glial cell functions underlie almost all aspects of nervous system development, maintenance, and health. During development, glia act as permissive substrates for axons, provide guidance cues, regulate axon bundling, facilitate synapse formation, refine synaptic connections, and promote neuronal survival. In the mature nervous system glial cells regulate adult neurogenesis through phagocytosis, act as the primary immune cell, and contribute to complex processes such as learning and memory. In recent years, glial cells have also become a primary focus in the study of neurodegenerative diseases. Mounting evidence shows that glial cells exert both beneficial as well as detrimental effects in the pathology of several nervous system disorders, and modulation of glial activity is emerging as a viable therapeutic strategy for many diseases. Although glial cells are critical to the proper development and functioning of the nervous system, there is still relatively little known about the molecular mechanisms used by glial cells, how they exert their effects on neurons, and how glia and neurons communicate. Despite the relative simplicity and small size of the Drosophila nervous system, glial cell organization and function in flies shows a remarkable complexity similar to vertebrate glial cells. In this study I use Drosophila as a model organism to study cellular and molecular mechanisms of glial clearance of axonal debris after acute axotomy. In chapter two of this thesis, I characterize three distinct subtypes of glial cells in the adult brain; cell body glia which ensheath neuronal cell bodies in the cortex region of the brain, astrocyte like glial cells which bear striking morphological similarity to mammalian astrocytes and share common molecular components, and ensheathing glial cells which I show act as the primary phagocytic cell type in the neuropil region of the brain. In addition, I identify dCed-6, the ortholog of mammalian GULP, as a necessary component of the glial phagocytic machinery. In chapter three of this thesis, I perform a candidate based, in vivo, RNAi screen to identify novel genes involved in the glial engulfment of degenerating axon material. The Gal4/UAS system was used to drive UAS-RNAi for approximately 300 candidate genes with the glial specific repo-Gal4 driver. Two assays were used as a readout in this screen, clearance of axon material five days after injury, and Draper upregulation one day after maxillary palp or antennal injury. Overall, I identified 20 genes which, when knocked down specifically in glial cells, result in axon clearance defects after injury. Finally, in chapter four I identify Stat92E as a novel glial gene required for glial phagocytic function. I show that Stat92E regulates both basal and injury induced Draper expression. Injury-induced Draper expression is transcriptionally regulated through a Stat92E dependent non-canonical signaling mechanism whereby signaling through the Draper receptor activates Stat92E which in turn transcriptionally activates draper through a binding site located in the first intron of Draper. Draper represents only the second receptor known to positively regulate Stat92E transcriptional activity under normal physiological conditions.

Neuroglia

Neurons

Drosophila Proteins

Axons

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Nervous System

Neuroscience and Neurobiology

Molecular Mechanisms of piRNA Biogenesis and Function in Drosophila: A Dissertation

Li, Chengjian

05 April 2011

In the Drosophila germ line, PIWI-interacting RNAs (piRNAs) ensure genomic stability by silencing endogenous selfish genetic elements such as retrotransposons and repetitive sequences. We examined the genetic requirements for the biogenesis and function of piRNAs in both female and male germ line. We found that piRNAs function through the PIWI, rather than the AGO, family Argonaute proteins, and the production of piRNAs requires neither microRNA (miRNA) nor small interfering RNA (siRNA) pathway machinery. These findings allowed the discovery of the third conserved small RNA silencing pathway, which is distinct from both the miRNA and RNAi pathways in its mechanisms of biogenesis and function. We also found piRNAs in flies are modified. We determined that the chemical structure of the 3´-terminal modification is a 2´-O-methyl group, and also demonstrated that the same modification occurs on the 3´ termini of siRNAs in flies. Furthermore, we identified the RNA methyltransferase Drosophila Hen1, which catalyzes 2´-O-methylation on both siRNAs and piRNAs. Our data suggest that 2´-O-methylation by Hen1 is the final step of biogenesis of both the siRNA pathway and piRNA pathway. Studies from the Hannon Lab and the Siomi Lab suggest a ping-pong amplification loop for piRNA biogenesis and function in the Drosophila germline. In this model, an antisense piRNA, bound to Aubergine or Piwi, triggers production of a sense piRNA bound to the PIWI protein Argonaute3 (Ago3). In turn, the new piRNA is envisioned to produce a second antisense piRNA. We isolated the loss-of-function mutations in ago3, allowing a direct genetic test of this model. We found that Ago3 acts to amplify piRNA pools and to enforce on them an antisense bias, increasing the number of piRNAs that can act to silence transposons. Moreover, we also discovered a second Ago3-independent piRNA pathway in somatic ovarian follicle cells, suggesting a role for piRNAs beyond the germ line.

Drosophila

Drosophila Proteins

RNA

Small Interfering

Germ Cells

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Genetic Phenomena

The Role of miR-21 and miR-31 in Cellular Responses Mediated by TGF-β: A Dissertation

Cottonham, Charisa L

09 May 2011

The function of transforming growth factor β (TGF-β) in cancer is notoriously complex. Initially TGF-β limits tumorigenesis, but at later stages in tumor progression TGF-β promotes the malignant spread of tumor cells. Past studies to understand the pro-metastasis utility of TGF-β centered upon its ability to regulate protein-coding genes. Recently, a small class of non-coding RNAs known as microRNAs (miRNAs) emerged as novel posttranscriptional regulators of gene expression. The significance of miRNA function in cellular processes from embryonic development to the maintenance of homeostasis in adult tissues is becoming increasingly clear. Also apparent is the strong association between aberrant miRNA expression and human diseases, such as cancer. The contribution of miRNAs to TGF-β-mediated cellular responses remains an open question. Thus, I became interested if miRNAs offered an additional layer of regulation in TGF-β signaling through which this cytokine exerts its pro-metastasis function. To address this inquiry, in the first part of this dissertation I investigated whether miRNAs influenced the ability of TGF-β to induce cellular responses directly involved with carcinoma metastasis, such as epithelial-mesenchymal transition (EMT). Here, I identified two miRNAs, miR-21 and miR-31, that are upregulated during EMT in LIM 1863 organoids, a colon carcinoma model of EMT driven by TGF-β. We performed in vitro studies to characterize the function of miR-21 and miR-31 and found that these two miRNAs positively impact the induction of EMT, migration and invasion by TGF-β. Furthermore, we uncovered TIAM1 (T lymphoma and metastasis gene 1) as a novel target of both miR-21 and miR-31 and show that downregulation of TIAM1 is critical for the pro-migration and pro-invasion activities of miR-21 and miR-31. Together these findings reveal miR-21 and miR-31 as downstream effectors of TGF-β signaling by facilitating EMT, migration and invasion of colon carcinoma cells. How TGF-β regulates miR-21 and miR-31 became important questions and thus the focus of the second part of this thesis. Interestingly, I found that TGF-β and TNF-α synergize to increase miR-21 and miR-31 levels in LIM 1863 organoids and that the synthesis of new factors induced by TGF-β/TNF-α are required for this upregulation. Moreover, I report that regulation of miR-21 by TGF-β/TNF-α occurs at multiple levels of biogenesis. More specifically data provided here show that Smad4 binds to the promoter of miR-21 to upregulate its expression thereby specifying miR-21 as a typical TGF-β target gene. This mechanism is different from one recently observed in smooth muscle cells in which TGF-β did not stimulate miR-21 transcription, but interestingly, Smad4 enhanced the Drosha-mediated processing of the miR-21 precursor. These two mechanisms suggest that TGF-β regulation of miR-21 is contextual and highlight the complexity of TGF-β signaling. As a whole, my findings establish important roles for miR-21 and miR-31 in TGF-β-mediated cellular responses that facilitate the pro-metastasis utility of TGF-β in colon cancer. Also, I describe a novel mechanism by which TGF-β/TNF-α signaling elevates the level of miR-21 and miR-31. Future studies that identify additional targets of miR-21 and miR-31 may offer further insight into the molecular mechanisms underlying cellular regulation by TGF-β. This information will be vital for the design of therapeutic interventions for colon cancer patients.

MicroRNAs

Transforming Growth Factor beta

Gene Expression Regulation

Amino Acids, Peptides, and Proteins

Biological Factors

Cancer Biology

Cells

Genetic Phenomena

Neoplasms

Protein Ligand Interactions Probed by NMR: A Dissertation

Laine, Jennifer M.

25 July 2012

Molecular recognition, defined as the specific interactions between two or more molecules, is at the center of many biological processes including catalysis, signal transduction, gene regulation and allostery. Allosteric regulation is the modification of function caused by an intermolecular interaction. Allosteric proteins modify their activity in response to a biological signal that is often transmitted through the interaction with a small effector molecule. Therefore, determination of the origins of intermolecular interactions involved in molecular recognition and allostery are essential for understanding biological processes. Classically, molecular recognition and allosteric regulation have been associated to structural changes of the system. NMR spectroscopic methods have indicated that changes in protein dynamics may also contribute to molecular recognition and allostery. This thesis is an investigation of the contributions of both structure and dynamics in molecular binding phenomena. In chapter I, I describe molecular recognition, allostery and examples of allostery and cooperativity. Then I discuss the contribution of protein dynamics to function with a special focus on allosteric regulation. Lastly I introduce the hemoglobin homodimer, HbI of Scapharca inaequivalvis and the mRNA binding protein TIS11d. Chapter II is the primary focus of this thesis on the contribution of protein dynamics to allostery in the dimeric hemoglobin of scapharca inaequivalvis, HbI. Thereafter I concentrate on the mechanism of adenine recognition of the Tristetraprolin-like (TTP) protein TIS11d; this study is detailed in Chapter III. In Chapter IV I discuss broader impacts and future directions of my research. This thesis presents an example of the use of protein NMR spectroscopy to probe ligand binding. The studies presented in this thesis emphasize the importance of dynamics in understanding protein function. Measurements of protein motions will be an element of future studies to understand protein function in health and disease.

Ligands

Nuclear Magnetic Resonance

Biomolecular

Molecular Conformation

Protein Binding

Allosteric Regulation

Amino Acids, Peptides, and Proteins

Chemical Actions and Uses

Investigative Techniques

Molecular Biology