@phdthesis{Pils2005, author = {Pils, Birgit}, title = {Insights into the evolution of protein domains give rise to improvements of function prediction}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-16805}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {The growing number of uncharacterised sequences in public databases has turned the prediction of protein function into a challenging research field. Traditional annotation methods are often error-prone due to the small subset of proteins with experimentally verified function. Goal of this thesis was to analyse the function and evolution of protein domains in order to understand molecular processes in the cell. The focus was on signalling domains of little understood function, as well as on functional sites of protein domains in general. Glucosaminidases (GlcNAcases) represent key enzymes in signal transduction pathways. Together with glucosamine transferases, they serve as molecular switches, similar to kinases and phosphatases. Little was known about the molecular function and structure of the GlcNAcases. In this thesis, the GlcNAcases were identified as remote homologues of N-acetyltransferases. By comparing the homologous sequences, I was able to predict functional sites of the GlcNAcase family and to identify the GlcNAcases as the first family member of the acetyltransferase superfamily with a distinct catalytic mechanism, which is not involved in the transfer of acetyl groups. In a similar approach, the sensor domain of a plant hormone receptor was studied. I was able to predict putative ligand-binding sites by comparing evolutionary constraints in functionally diverged subfamilies. Most of the putative ligand-binding sites have been experimentally confirmed in the meantime. Due to the importance of enzymes involved in cellular signalling, it seems impossible to find substitutions of catalytic amino acids that turn them catalytically inactive. Nevertheless, by scanning catalytic positions of the protein tyrosine phosphatase families, I found many inactive domains among single domain and tandem domain phosphatases in metazoan proteomes. In addition, I found that inactive phosphatases are conserved throughout evolution, which led to the question about the function of these catalytically inactive phosphatase domains. An analysis of evolutionary site rates of amino acid substitutions revealed a cluster of conserved residues in the apparently redundant domain of tandem phosphatases. This putative regulatory center might be responsible for the experimentally verified dimerization of the active and inactive domain in order to control the catalytic activity of the active phosphatase domain. Moreover, I detected a subgroup of inactive phosphatases, which presumably functions in substrate recognition, based on different evolutionary site rates within the phosphatase family. The characterization of these new regulatory modules in the phosphatase family raised the question whether inactivation of enzymes is a more general evolutionary mechanism to enlarge signalling pathways and whether inactive domains are also found in other enzyme families. A large-scale analysis of substitutions at catalytic positions of enzymatic domains was performed in this work. I identified many domains with inactivating substitutions in various enzyme families. Signalling domains harbour a particular high occurrence of catalytically inactive domains indicating that these domains have evolved to modulate existing regulatory pathways. Furthermore, it was shown that inactivation of enzymes by single substitutions happened multiple times independently in evolution. The surprising variability of amino acids at catalytic positions was decisive for a subsequent analysis of the diversity of functional sites in general. Using functional residues extracted from structural complexes I could show that functional sites of protein domains do not only vary in their type of amino acid but also in their structural location within the domain. In the process of evolution, protein domains have arisen from duplication events and subsequently adapted to new binding partners and developed new functions, which is reflected in the high variability of functional sites. However, great differences exist between domain families. The analysis demonstrated that functional sites of nuclear domains are more conserved than functional sites of extracellular domains. Furthermore, the type of ligand influences the degree of conservation, for example ion binding sites are more conserved than peptide binding sites. The work presented in this thesis has led to the detection of functional sites in various protein domains involved in signalling pathways and it has resulted in insights into the molecular function of those domains. In addition, properties of functional sites of protein domains were revealed. This knowledge can be used in the future to improve the prediction of protein function and to identify functional sites of proteins.}, subject = {Dom{\"a}ne }, language = {en} } @phdthesis{Bertram2005, author = {Bertram, Helge}, title = {Bioinformatische Identifikation von Dom{\"a}nenunterschieden bei Parasit und Wirt am Beispiel der Malaria}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-17188}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {Diese Arbeit untersucht zellul{\"a}re Netzwerke mit dem Ziel, die so gewonnenen Einsichten medizinisch beziehungsweise biotechnologisch zu nutzen. Hierzu m{\"u}ssen zun{\"a}chst Proteindom{\"a}nen und wichtige regulatorische RNA Elemente erkannt werden. Dies geschieht f{\"u}r regulatorische Elemente in Nukleins{\"a}uren am Beispiel von Iron Responsive Elements (IREs) in Staphylococcus aureus, wobei sich solche Elemente in viel versprechender N{\"a}he zu exprimierten Sequenzen finden lassen (T. Dandekar, F. Du, H. Bertram (2001) Nonlinear Analysis 47(1): 225-34). Noch bedeutsamer als Ziele zur Medikamentenentwicklung gegen Parasiten sind Dom{\"a}nenunterschiede in Struktur und Sequenz bei Proteinen (T. Dandekar, F. Du, H. Bertram (2001) Nonlinear Analysis 47(1): 225-34). Ihre Identifikation wird am Beispiel eines potentiellen Transportproteins in Plasmodium falciparum exemplarisch dargestellt. Anschließend wird das Zusammenwirken von regulatorischen Elementen und Dom{\"a}nen in Netzwerken betrachtet (einschließlich experimenteller Daten). Dies kann einerseits zu allgemeineren Schlussfolgerungen {\"u}ber das Netzwerkverhalten f{\"u}hren, andererseits f{\"u}r konkrete Anwendungen genutzt werden. Als Beispiel w{\"a}hlten wir hier Redoxnetzwerke und die Bek{\"a}mpfung von Plasmodien als Verursacher der Malaria. Da das gesamte Redoxnetzwerk einer lebenden Zelle mit Methoden der pH Wert Messung nur unzureichend zu erfassen ist, werden als alternative Messmethode f{\"u}r dieses Netzwerk Mikrokristalle der Glutathionreduktase als Indikatorsystem nach digitaler Verst{\"a}rkung experimentell genutzt (H. Bertram, M. A. Keese, C. Boulin, R. H. Schirmer, R. Pepperkok, T. Dandekar (2002) Chemical Nanotechnology Talks III - Nano for Life Sciences). Um komplexe Redoxnetzwerke auch bioinformatisch zu modulieren, werden Verfahren der metabolischen Fluxanalyse vorgestellt und verbessert, um insbesondere ihrer Verzahnung besser gerecht zu werden und solche Netzwerke mit m{\"o}glichst wenig elementaren Flussmoden zutreffend beschreiben zu k{\"o}nnen. Die Reduktion der Anzahl von Elementarmoden bei sehr großen metabolischen Netzwerken einer Zelle gelingt hier mit Hilfe unterschiedlicher Methoden und f{\"u}hrt zu einer vereinfachten Darstellungsm{\"o}glichkeit komplexer Stoffwechselwege von Metaboliten. Dabei dient bei jeder dieser Methoden die biochemisch sinnvolle Definition von externen Metaboliten als Grundlage (T. Dandekar, F. Moldenhauer, S. Bulik, H. Bertram, S. Schuster (2003) Biosystems 70(3): 255-70). Allgemeiner werden Verfahren der Proteindom{\"a}nenklassifikation sowie neue Strategien gegen mikrobielle Erreger betrachtet. In Bezug auf automatisierte Einteilung von Proteinen in Dom{\"a}nen wird ein neues System von Taylor (2002b) mit bekannten Systemen verglichen, die in unterschiedlichem Umfang menschlichen Eingriffs bed{\"u}rfen (H. Bertram, T. Dandekar (2002) Chemtracts 15: 735-9). Außerdem wurde neben einer Arbeit {\"u}ber die verschiedenen Methoden aus den Daten eines Genoms Informationen {\"u}ber das metabolische Netzwerk der Zelle zu erlangen (H. Bertram, T. Dandekar (2004) it 46(1): 5-11) auch eine {\"U}bersicht {\"u}ber die Schwerpunkte der Bioinformatik in W{\"u}rzburg zusammengestellt (H. Bertram, S. Balthasar, T. Dandekar (2003) Bioforum 1-2: 26-7). Schließlich wird beschrieben, wie die Pathogenomik und Virulenz von Bakterien der bioinformatischen Analyse zug{\"a}nglich gemacht werden k{\"o}nnen (H. Bertram, S. Balthasar, T. Dandekar (2003) Bioforum Eur. 3: 157-9). Im letzten Teil wird die metabolische Fluxanalyse zur Identifikation neuer Strategien zur Bek{\"a}mpfung von Plasmodien dargestellt: Beim Vergleich der Stoffwechselwege mit Glutathion und Thioredoxin in Plasmodium falciparum, Anopheles und Mensch geht es darum, gezielte St{\"o}rungen im Stoffwechsel des Malariaerregers auszul{\"o}sen und dabei den Wirt zu schonen. Es ergeben sich einige interessante Ansatzpunkte, deren medizinische Nutzung experimentell angestrebt werden kann.}, subject = {Plasmodium falciparum}, language = {de} } @phdthesis{Thakar2006, author = {Thakar, Juilee}, title = {Computational models for the study of responses to infections}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-17266}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2006}, abstract = {In diesem Jahrhundert haben neue experimentelle Techniken und Computer-Verfahren enorme Mengen an Information erzeugt, die bereits viele biologische R{\"a}tsel enth{\"u}llt haben. Doch die Komplexit{\"a}t biologischer Systeme wirft immer weitere neue Fragen auf. Um ein System zu verstehen, bestand der Hauptansatz bis jetzt darin, es in Komponenten zu zerlegen, die untersucht werden k{\"o}nnen. Ein neues Paradigma verkn{\"u}pft die einzelnen Informationsteile, um sie auf globaler Ebene verstehen zu k{\"o}nnen. In der vorgelegten Doktorarbeit habe ich deshalb versucht, infekti{\"o}se Krankheiten mit globalen Methoden („Systembiologie") bioinformatisch zu untersuchen. Im ersten Teil wird der Apoptose-Signalweg analysiert. Apoptose (Programmierter Zelltod) wird bei verschiedenen Infektionen, zum Beispiel bei Viruserkrankungen, als Abwehrmaßnahme eingesetzt. Die Interaktionen zwischen Proteinen, die ‚death' Dom{\"a}nen beinhalten, wurden untersucht, um folgende Fragen zu kl{\"a}ren: i) wie wird die Spezifit{\"a}t der Interaktionen erzielt? -sie wird durch Adapter erreicht, ii) wie werden Proliferation/ {\"U}berlebenssignale w{\"a}hrend der Aktivierung der Apoptose eingeleitet? - wir fanden Hinweise f{\"u}r eine entscheidende Rolle des RIP Proteins (Rezeptor-Interagierende Serine/Threonine-Proteinkinase 1). Das Modell erlaubte uns, die Interaktions-Oberfl{\"a}chen von RIP vorherzusagen. Der Signalweg wurde anschließend auf globaler Ebene mit Simulationen f{\"u}r verschiedene Zeitpunkte analysiert, um die Evolution der Aktivatoren und Inhibitoren des Signalwegs und seine Struktur besser zu verstehen. Weiterhin wird die Signalverarbeitung f{\"u}r Apoptosis-Signalwege in der Maus detailliert modelliert, um den Konzentrationsverlauf der Effektor-Kaspasen vorherzusagen. Weitere experimentelle Messungen von Kaspase-3 und die {\"U}berlebenskurven von Zellen best{\"a}tigen das Modell. Der zweite Teil der Resultate konzentriert sich auf das Phagosom, eine Organelle, die eine entscheidende Rolle bei der Eliminierung von Krankheitserregern spielt. Dies wird am Beispiel von M. tuberculosis veranschaulicht. Die Fragestellung wird wiederum in zwei Aspekten behandelt: i) Um die Prozesse, die durch M. tuberculosis inhibiert werden zu verstehen, haben wir uns auf das Phospholipid-Netzwerk konzentriert, das bei der Unterdr{\"u}ckung oder Aktivierung der Aktin-Polymerisation eine große Rolle spielt. Wir haben f{\"u}r diese Netzwerkanalyse eine Simulation f{\"u}r verschiedene Zeitpunkte {\"a}hnlich wie in Teil eins angewandt. ii) Es wird vermutet, dass Aktin-Polymere bei der Fusion des Phagosoms mit dem Lysosom eine Rolle spielen. Um diese Hypothese zu untersuchen, wurde ein in silico Modell von uns entwickelt. Wir fanden heraus, dass in der Anwesenheit von Aktin-Polymeren die Suchzeit f{\"u}r das Lysosom um das F{\"u}nffache reduziert wurde. Weiterhin wurden die Effekte der L{\"a}nge der Aktin-Polymere, die Gr{\"o}ße der Lysosomen sowie der Phagosomen und etliche andere Modellparameter analysiert. Nach der Untersuchung eines Signalwegs und einer Organelle f{\"u}hrte der n{\"a}chste Schritt zur Untersuchung eines komplexen biologischen Systems der Infektabwehr. Dies wurde am Beispiel der Wirt-Pathogen Interaktion bei Bordetella pertussis und Bordetella bronchiseptica dargestellt. Die geringe Menge verf{\"u}gbarer quantitativer Daten war der ausschlaggebende Faktor bei unserer Modellwahl. F{\"u}r die dynamische Simulation wurde ein selbst entwickeltes Bool'sches Modell verwendet. Die Ergebnisse sagen wichtige Faktoren bei der Pathologie von Bordetellen hervor, besonders die Bedeutung der Th1 assoziierten Antworten und dagegen nicht der Th2 assoziierten Antworten f{\"u}r die Eliminierung des Pathogens. Einige der quantitativen Vorhersagen wurden durch Experimente wie die Untersuchung des Verlaufs einer Infektion in verschiedenen Mutanten und Wildtyp-M{\"a}usen {\"u}berpr{\"u}ft. Die begrenzte Verf{\"u}gbarkeit kinetischer Daten war der kritische Faktor bei der Auswahl der computer-gest{\"u}tzten Modelle. Der Erfolg unserer Modelle konnte durch den Vergleich mit experimentellen Beobachtungen belegt werden. Die vergleichenden Modelle in Kapitel 6 und 9 k{\"o}nnen zur Untersuchung neuer Wirt-Pathogen Interaktionen verwendet werden. Beispielsweise f{\"u}hrt in Kapitel 6 die Analyse von Inhibitoren und inhibitorischer Signalwege aus drei Organismen zur Identifikation wichtiger regulatorischer Zentren in komplexen Organismen und in Kapitel 9 erm{\"o}glicht die Identifikation von drei Phasen in B. bronchiseptica und der Inhibition von IFN-\&\#947; durch den Faktor TTSS die Untersuchung {\"a}hnlicher Phasen und die Inhibition von IFN-\&\#947; in B. pertussis. Eine weitere wichtige Bedeutung bekommen diese Modelle durch die m{\"o}gliche Identifikation neuer, essentieller Komponenten in Wirt-Pathogen Interaktionen. In silico Modelle der Effekte von Deletionen zeigen solche Komponenten auf, die anschließend durch experimentelle Mutationen weiter untersucht werden k{\"o}nnen.}, subject = {Bordetella pertussis}, language = {en} } @misc{Selig2007, type = {Master Thesis}, author = {Selig, Christian}, title = {The ITS2 Database - Application and Extension}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-23895}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2007}, abstract = {Der internal transcribed spacer 2 (ITS2) des ribosomalen Genrepeats ist ein zunehmend wichtiger phylogenetischer Marker, dessen RNA-Sekund{\"a}rstruktur innerhalb vieler eukaryontischer Organismen konserviert ist. Die ITS2-Datenbank hat zum Ziel, eine umfangreiche Ressource f{\"u}r ITS2-Sequenzen und -Sekund{\"a}rstrukturen auf Basis direkter thermodynamischer als auch homologiemodellierter RNA-Faltung zu sein. Ergebnisse: (a) Eine komplette Neufassung der urspr{\"u}nglichen die ITS2-Datenbank generierenden Skripte, angewandt auf einen aktuellen NCBI-Datensatz, deckte mehr als 65.000 ITS2-Strukturen auf. Dies verdoppelt den Inhalt der urspr{\"u}nglichen Datenbank und verdreifacht ihn, wenn partielle Strukturen mit einbezogen werden. (b) Die Endbenutzer-Schnittstelle wurde neu geschrieben, erweitert und ist jetzt in der Lage, benutzerdefinierte Homologiemodellierungen durchzuf{\"u}hren. (c) Andere m{\"o}glichen RNA-Strukturaufkl{\"a}rungsmethoden (suboptimales und formenbasiertes Falten) sind hilfreich, k{\"o}nnen aber Homologiemodellierung nicht ersetzen. (d) Ein Anwendungsfall der ITS2-Datenbank in Zusammenhang mit anderen am Lehrstuhl entwickelten Werkzeugen gab Einblick in die Verwendung von ITS2 f{\"u}r molekulare Phylogenie.}, subject = {Phylogenie}, language = {en} } @phdthesis{Blenk2007, author = {Blenk, Steffen}, title = {Bioinformatical analysis of B-cell lymphomas}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-27421}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2007}, abstract = {Background: The frequency of the most observed cancer, Non Hodgkin Lymphoma (NHL), is further rising. Diffuse large B-cell lymphoma (DLBCL) is the most common of the NHLs. There are two subgroups of DLBCL with different gene expression patterns: ABC ("Activated B-like DLBCL") and GCB ("Germinal Center B-like DLBCL"). Without therapy the patients often die within a few months, the ABC type exhibits the more aggressive behaviour. A further B-cell lymphoma is the Mantle cell lymphoma (MCL). It is rare and shows very poor prognosis. There is no cure yet. Methods: In this project these B-cell lymphomas were examined with methods from bioinformatics, to find new characteristics or undiscovered events on the molecular level. This would improve understanding and therapy of lymphomas. For this purpose we used survival, gene expression and comparative genomic hybridization (CGH) data. In some clinical studies, you get large data sets, from which one can reveal yet unknown trends. Results (MCL): The published proliferation signature correlates directly with survival. Exploratory analyses of gene expression and CGH data of MCL samples (n=71) revealed a valid grouping according to the median of the proliferation signature values. The second axis of correspondence analysis distinguishes between good and bad prognosis. Statistical testing (moderate t-test, Wilcoxon rank-sum test) showed differences in the cell cycle and delivered a network of kinases, which are responsible for the difference between good and bad prognosis. A set of seven genes (CENPE, CDC20, HPRT1, CDC2, BIRC5, ASPM, IGF2BP3) predicted, similarly well, survival patterns as proliferation signature with 20 genes. Furthermore, some bands could be associated with prognosis in the explorative analysis (chromosome 9: 9p24, 9p23, 9p22, 9p21, 9q33 and 9q34). Results (DLBCL): New normalization of gene expression data of DLBCL patients revealed better separation of risk groups by the 2002 published signature based predictor. We could achieve, similarly well, a separation with six genes. Exploratory analysis of gene expression data could confirm the subgroups ABC and GCB. We recognized a clear difference in early and late cell cycle stages of cell cycle genes, which can separate ABC and GCB. Classical lymphoma and best separating genes form a network, which can classify and explain the ABC and GCB groups. Together with gene sets which identify ABC and GCB we get a network, which can classify and explain the ABC and GCB groups (ASB13, BCL2, BCL6, BCL7A, CCND2, COL3A1, CTGF, FN1, FOXP1, IGHM, IRF4, LMO2, LRMP, MAPK10, MME, MYBL1, NEIL1 and SH3BP5; Altogether these findings are useful for diagnosis, prognosis and therapy (cytostatic drugs).}, subject = {Bioinformatik}, language = {en} } @phdthesis{Schwarz2008, author = {Schwarz, Roland}, title = {Modellierung von Metabolismus, Transkriptom und Zellentwicklung bei Arabidopsis, Listerien und anderen Organismen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-27622}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {Im gleichen Maße wie informatisches Wissen mehr und mehr in den wissenschaftlichen Alltag aller Lebenswissenschaften Einzug gehalten hat, hat sich der Schwerpunkt bioinformatischer Forschung in st{\"a}rker mathematisch und informatisch-orientierte Themengebiete verschoben. Bioinformatik heute ist mehr als die computergest{\"u}tzte Verarbeitung großer Mengen an biologischen Daten, sondern hat einen entscheidenden Fokus auf der Modellierung komplexer biologischer Systeme. Zur Anwendung kommen hierbei insbesondere Theorien aus dem Bereich der Stochastik und Statistik, des maschinellen Lernens und der theoretischen Informatik. In der vorliegenden Dissertation beschreibe ich in Fallstudien die systematische Modellierung biologischer Systeme aus einem informatisch - mathematischen Standpunkt unter Anwendung von Verfahren aus den genannten Teilbereichen und auf unterschiedlichen Ebenen biologischer Abstraktion. Ausgehend von der Sequenzinformation {\"u}ber Transkriptom, Metabolom und deren regulatorischer Interaktion hin zur Modellierung von Populationseffekten werden hierbei aktuelle biologische Fragestellungen mit mathematisch - informatischen Modellen und einer Vielzahl experimenteller Daten kombiniert. Ein besonderer Augenmerk liegt dabei auf dem Vorgang der Modellierung und des Modellbegriffs als solchem im Rahmen moderner bioinformatischer Forschung. Im Detail umfassen die Projekte (mehrere Publikationen) die Entwicklung eines neuen Ansatzes zur Einbettung und Visualisierung von Multiplen Sequenz- und Sequenz-Strukturalignments, illustriert am Beispiel eines Hemagglutininalignments unterschiedlicher H5N1 Varianten, sowie die Modellierung des Transkriptoms von A. thaliana, bei welchem mit Hilfe einer kernelisierten nicht-parametrischen Metaanalyse neue, an der Infektionsabwehr beteiligten, Gene ausfindig gemacht werden konnten. Desweiteren ist uns mit Hilfe unserer Software YANAsquare eine detaillierte Untersuchung des Metabolismus von L. monocytogenes unter Aktivierung des Transkriptionsfaktors prfA gelungen, dessen Vorhersagen durch experimentelle 13C Isotopologstudien belegt werden konnten. In einem Anschlußprojekt war der Zusammenhang zwischen Regulation des Metabolismus durch Regulation der Genexpression und der Fluxverteilung des metabolischen Steady- State-Netzwerks das Ziel. Die Modellierung eines komplexen organismischen Ph{\"a}notyps, der Zellgr{\"o}ßenentwicklung der Diatomee Pseudo-nitzschia delicatissima, schließt die Untersuchungen ab.}, subject = {Bioinformatik}, language = {de} } @phdthesis{Liang2009, author = {Liang, Chunguang}, title = {Tools for functional genomics applied to Staphylococci, Listeriae, Vaccinia virus and other organisms}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-48051}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2009}, abstract = {Genome sequence analysis A combination of genome analysis application has been established here during this project. This offers an efficient platform to interactively compare similar genome regions and reveal loci differences. The genes and operons can be rapidly analyzed and local collinear blocks (LCBs) categorized according to their function. The features of interests are parsed, recognized, and clustered into reports. Phylogenetic relationships can be readily examined such as the evolution of critical factors or a certain highly-conserved region. The resulting platform-independent software packages (GENOVA and inGeno), have been proven to be efficient and easy to handle in a number of projects. The capabilities of the software allowed the investigation of virulence factors, e.g., rsbU, strains' biological design, and in particular pathogenicity feature storage and management. We have successfully investigated the genomes of Staphylococcus aureus strains (COL, N315, 8325, RN1HG, Newman), Listeria spp. (welshimeri, innocua and monocytogenes), E.coli strains (O157:H7 and MG1655) and Vaccinia strains (WR, Copenhagen, Lister, LIVP, GLV-1h68 and parental strains). Metabolic network analysis Our YANAsquare package offers a workbench to rapidly establish the metabolic network of such as Staphylococcous aureus bacteria in genome-scale size as well as metabolic networks of interest such as the murine phagosome lipid signalling network. YANAsquare recruits reactions from online databases using an integrated KEGG browser. This reduces the efforts in building large metabolic networks. The involved calculation routines (METATOOL-derived wrapper or native Java implementation) readily obtain all possible flux modes (EM/EP) for metabolite fluxes within the network. Advanced layout algorithms visualize the topological structure of the network. In addition, the generated structure can be dynamically modified in the graphic interface. The generated network as well as the manipulated layout can be validated and stored (XML file: scheme of SBML level-2). This format can be further parsed and analyzed by other systems biology software, such as CellDesigner. Moreover, the integrated robustness-evaluation routine is able to examine the synthesis rates affected by each single mutation throughout the whole network. We have successfully applied the method to simulate single and multiple gene knockouts, and the affected fluxes are comprehensively revealed. Recently we applied the method to proteomic data and extra-cellular metabolite data of Staphylococci, the physiological changes regarding the flux distribution are studied. Calculations at different time points, including different conditions such as hypoxia or stress, show a good fit to experimental data. Moreover, using the proteomic data (enzyme amounts) calculated from 2D-Gel-EP experiments our study provides a way to compare the fluxome and the enzyme expression. Oncolytic vaccinia virus (VACV) We investigated the genetic differences between the de novo sequence of the recombinant oncolytic GLV-1h68 and other related VACVs, including function predictions for all found genome differences. Our phylogenetic analysis indicates that GLV-1h68 is closest to Lister strains but has lost several ORFs present in its parental LIVP strain, including genes encoding CrmE and a viral Golgi anti-apoptotic protein, v-GAAP. Functions of viral genes were either strain-specific, tissue-specific or host-specific comparing viral genes in the Lister, WR and COP strains. This helps to rationally design more optimized oncolytic virus strains to benefit cancer therapy in human patients. Identified differences from the comparison in open reading frames (ORFs) include genes for host-range selection, virulence and immune modulation proteins, e.g. ankyrin-like proteins, serine proteinase inhibitor SPI-2/CrmA, tumor necrosis factor (TNF) receptor homolog CrmC, semaphorin-like and interleukin-1 receptor homolog proteins. The contribution of foreign gene expression cassettes in the therapeutic and oncolytic virus GLV-1h68 was studied, including the F14.5L, J2R and A56R loci. The contribution of F14.5L inactivation to the reduced virulence is demonstrated by comparing the virulence data of GLV-1h68 with its F14.5L-null and revertant viruses. The comparison suggests that insertion of a foreign gene expression cassette in a nonessential locus in the viral genome is a practical way to attenuate VACVs, especially if the nonessential locus itself contains a virulence gene. This reduces the virulence of the virus without compromising too much the replication competency of the virus, the key to its oncolytic activity. The reduced pathogenicity of GLV-1h68 was confirmed by our experimental collaboration partners in male mice bearing C6 rat glioma and in immunocompetent mice bearing B16-F10 murine melanoma. In conclusion, bioinformatics and experimental data show that GLV-1h68 is a promising engineered VACV variant for anticancer therapy with tumor-specific replication, reduced pathogenicity and benign tissue tropism.}, subject = {Genanalyse}, language = {en} } @phdthesis{Foerster2010, author = {F{\"o}rster, Frank}, title = {Making the most of phylogeny: Unique adaptations in tardigrades and 216374 internal transcribed spacer 2 structures}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-51466}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {The phylum Tardigrada consists of about 1000 described species to date. The animals live in habitats within marine, freshwater and terrestrial ecosystems allover the world. Tardigrades are polyextremophiles. They are capable to resist extreme temperature, pressure or radiation. In the event of desiccation, tardigrades enter a so-called tun stage. The reason for their great tolerance capabilities against extreme environmental conditions is not discovered yet. Our Funcrypta project aims at finding answers to the question what mechanisms underlie these adaption capabilities particularly with regard to the species Milnesium tardigradum. The first part of this thesis describes the establishment of expressed sequence tags (ESTs) libraries for different stages of M. tardigradum. From proteomics data we bioinformatically identified 144 proteins with a known function and additionally 36 proteins which seemed to be specific for M. tardigradum. The generation of a comprehensive web-based database allows us to merge the proteome and transcriptome data. Therefore we created an annotation pipeline for the functional annotation of the protein and nucleotide sequences. Additionally, we clustered the obtained proteome dataset and identified some tardigrade-specific proteins (TSPs) which did not show homology to known proteins. Moreover, we examined the heat shock proteins of M. tardigradum and their different expression levels depending on the actual state of the animals. In further bioinformatical analyses of the whole data set, we discovered promising proteins and pathways which are described to be correlated with the stress tolerance, e.g. late embryogenesis abundant (LEA) proteins. Besides, we compared the tardigrades with nematodes, rotifers, yeast and man to identify shared and tardigrade specific stress pathways. An analysis of the 50 and 30 untranslated regions (UTRs) demonstrates a strong usage of stabilising motifs like the 15-lipoxygenase differentiation control element (15-LOX-DICE) but also reveals a lack of other common UTR motifs normally used, e.g. AU rich elements. The second part of this thesis focuses on the relatedness between several cryptic species within the tardigrade genus Paramacrobiotus. Therefore for the first time, we used the sequence-structure information of the internal transcribed spacer 2 (ITS2) as a phylogenetic marker in tardigrades. This allowed the description of three new species which were indistinguishable using morphological characters or common molecular markers like the 18S ribosomal ribonucleic acid (rRNA) or the Cytochrome c oxidase subunit I (COI). In a large in silico simulation study we also succeeded to show the benefit for the phylogenetic tree reconstruction by adding structure information to the ITS2 sequence. Next to the genus Paramacrobiotus we used the ITS2 to corroborate a monophyletic DO-group (Sphaeropleales) within the Chlorophyceae. Additionally we redesigned another comprehensive database—the ITS2 database resulting in a doubled number of sequence-structure pairs of the ITS2. In conclusion, this thesis shows the first insights (6 first author publications and 4 coauthor publications) into the reasons for the enormous adaption capabilities of tardigrades and offers a solution to the debate on the phylogenetic relatedness within the tardigrade genus Paramacrobiotus.}, subject = {Phylogenie}, language = {en} } @phdthesis{Vainshtein2010, author = {Vainshtein, Yevhen}, title = {Applying microarray-based techniques to study gene expression patterns: a bio-computational approach}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-51967}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {The regulation and maintenance of iron homeostasis is critical to human health. As a constituent of hemoglobin, iron is essential for oxygen transport and significant iron deficiency leads to anemia. Eukaryotic cells require iron for survival and proliferation. Iron is part of hemoproteins, iron-sulfur (Fe-S) proteins, and other proteins with functional groups that require iron as a cofactor. At the cellular level, iron uptake, utilization, storage, and export are regulated at different molecular levels (transcriptional, mRNA stability, translational, and posttranslational). Iron regulatory proteins (IRPs) 1 and 2 post-transcriptionally control mammalian iron homeostasis by binding to iron-responsive elements (IREs), conserved RNA stem-loop structures located in the 5'- or 3'- untranslated regions of genes involved in iron metabolism (e.g. FTH1, FTL, and TFRC). To identify novel IRE-containing mRNAs, we integrated biochemical, biocomputational, and microarray-based experimental approaches. Gene expression studies greatly contribute to our understanding of complex relationships in gene regulatory networks. However, the complexity of array design, production and manipulations are limiting factors, affecting data quality. The use of customized DNA microarrays improves overall data quality in many situations, however, only if for these specifically designed microarrays analysis tools are available. Methods In this project response to the iron treatment was examined under different conditions using bioinformatical methods. This would improve our understanding of an iron regulatory network. For these purposes we used microarray gene expression data. To identify novel IRE-containing mRNAs biochemical, biocomputational, and microarray-based experimental approaches were integrated. IRP/IRE messenger ribonucleoproteins were immunoselected and their mRNA composition was analysed using an IronChip microarray enriched for genes predicted computationally to contain IRE-like motifs. Analysis of IronChip microarray data requires specialized tool which can use all advantages of a customized microarray platform. Novel decision-tree based algorithm was implemented using Perl in IronChip Evaluation Package (ICEP). Results IRE-like motifs were identified from genomic nucleic acid databases by an algorithm combining primary nucleic acid sequence and RNA structural criteria. Depending on the choice of constraining criteria, such computational screens tend to generate a large number of false positives. To refine the search and reduce the number of false positive hits, additional constraints were introduced. The refined screen yielded 15 IRE-like motifs. A second approach made use of a reported list of 230 IRE-like sequences obtained from screening UTR databases. We selected 6 out of these 230 entries based on the ability of the lower IRE stem to form at least 6 out of 7 bp. Corresponding ESTs were spotted onto the human or mouse versions of the IronChip and the results were analysed using ICEP. Our data show that the immunoselection/microarray strategy is a feasible approach for screening bioinformatically predicted IRE genes and the detection of novel IRE-containing mRNAs. In addition, we identified a novel IRE-containing gene CDC14A (Sanchez M, et al. 2006). The IronChip Evaluation Package (ICEP) is a collection of Perl utilities and an easy to use data evaluation pipeline for the analysis of microarray data with a focus on data quality of custom-designed microarrays. The package has been developed for the statistical and bioinformatical analysis of the custom cDNA microarray IronChip, but can be easily adapted for other cDNA or oligonucleotide-based designed microarray platforms. ICEP uses decision tree-based algorithms to assign quality flags and performs robust analysis based on chip design properties regarding multiple repetitions, ratio cut-off, background and negative controls (Vainshtein Y, et al., 2010).}, subject = {Microarray}, language = {en} } @phdthesis{Arumugam2010, author = {Arumugam, Manimozhiyan}, title = {Comparative metagenomic analysis of the human intestinal microbiota}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-55903}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {The human gut is home for thousands of microbes that are important for human life. As most of these cannot be cultivated, metagenomics is an important means to understand this important community. To perform comparative metagenomic analysis of the human gut microbiome, I have developed SMASH (Simple metagenomic analysis shell), a computational pipeline. SMASH can also be used to assemble and analyze single genomes, and has been successfully applied to the bacterium Mycoplasma pneumoniae and the fungus Chaetomium thermophilum. In the context of the MetaHIT (Metagenomics of the human intestinal tract) consortium our group is participating in, I used SMASH to validate the assembly and to estimate the assembly error rate of 576.7 Gb metagenome sequence obtained using Illumina Solexa technology from fecal DNA of 124 European individuals. I also estimated the completeness of the gene catalogue containing 3.3 million open reading frames obtained from these metagenomes. Finally, I used SMASH to analyze human gut metagenomes of 39 individuals from 6 countries encompassing a wide range of host properties such as age, body mass index and disease states. We find that the variation in the gut microbiome is not continuous but stratified into enterotypes. Enterotypes are complex host-microbial symbiotic states that are not explained by host properties, nutritional habits or possible technical biases. The concept of enterotypes might have far reaching implications, for example, to explain different responses to diet or drug intake. We also find several functional markers in the human gut microbiome that correlate with a number of host properties such as body mass index, highlighting the need for functional analysis and raising hopes for the application of microbial markers as diagnostic or even prognostic tools for microbiota-associated human disorders.}, subject = {Darmflora}, language = {en} }