@article{MottolaSchwanfelderMorschhaeuser2020, author = {Mottola, Austin and Schwanfelder, Sonja and Morschh{\"a}user, Joachim}, title = {Generation of Viable Candida albicans Mutants Lacking the "Essential" Protein Kinase Snf1 by Inducible Gene Deletion}, series = {mSphere}, volume = {5}, journal = {mSphere}, number = {4}, doi = {10.1128/mSphere.00805-20}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-230524}, year = {2020}, abstract = {The protein kinase Snf1, a member of the highly conserved AMP-activated protein kinase family, is a central regulator of metabolic adaptation. In the pathogenic yeast Candida albicans, Snf1 is considered to be essential, as previous attempts by different research groups to generate homozygous snf1 Delta mutants were unsuccessful. We aimed to elucidate why Snf1 is required for viability in C. albicans by generating snf1 Delta null mutants through forced, inducible gene deletion and observing the terminal phenotype before cell death. Unexpectedly, we found that snf1 Delta mutants were viable and could grow, albeit very slowly, on rich media containing the preferred carbon source glucose. Growth was improved when the cells were incubated at 37 degrees C instead of 30 degrees C, and this phenotype enabled us to isolate homozygous snf1 Delta mutants also by conventional, sequential deletion of both SNF1 alleles in a wild-type C. albicans strain. All snf1 Delta mutants could grow slowly on glucose but were unable to utilize alternative carbon sources. Our results show that, under optimal conditions, C. albicans can live and grow without Snf1. Furthermore, they demonstrate that inducible gene deletion is a powerful method for assessing gene essentiality in C. albicans. IMPORTANCE Essential genes are those that are indispensable for the viability and growth of an organism. Previous studies indicated that the protein kinase Snf1, a central regulator of metabolic adaptation, is essential in the pathogenic yeast Candida albicans, because no homozygous snf1 deletion mutants of C. albicans wild-type strains could be obtained by standard approaches. In order to investigate the lethal consequences of SNF1 deletion, we generated conditional mutants in which SNF1 could be deleted by forced, inducible excision from the genome. Unexpectedly, we found that snf1 null mutants were viable and could grow slowly under optimal conditions. The growth phenotypes of the snf1 Delta mutants explain why such mutants were not recovered in previous attempts. Our study demonstrates that inducible gene deletion is a powerful method for assessing gene essentiality in C. albicans.}, language = {en} } @phdthesis{Xian2014, author = {Xian, Yibo}, title = {Identification of essential genes and novel virulence factors of Neisseria gonorrhoeae by transposon mutagenesis}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-102659}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Neisseria gonorrhoeae is a human-specific pathogen that causes gonorrhea. It is defined as a super bacterium by the WHO due to the emergence of gonococci that are resistant to a variety of antibiotics and a rapidly increasing infection incidence. Genome-wide investigation of neisserial gene essentiality and novel virulence factors is urgently required in order to identify new targets for anti-neisserial therapeutics. To identify essential genes and new virulence factors, a high-density mutant library in N. gonorrhoeae MS11 was generated by in vitro transposon mutagenesis. The transposon library harbors more than 100,000 individual mutants, a density that is unprecedented in gonococcal research. Essential genes in N. gonorrhoeae were determined by enumerating frequencies of transposon insertion sites (TIS) with Illumina deep sequencing (Tn-seq). Tn-seq indicated an average distance between adjacent TIS of 25 bp. Statistical analysis unequivocally demonstrated 781 genes that were significantly depleted in TIS and thus are essential for Neisseria survival. A subset of the genes was experimentally verified to comprise essential genes and thus support the outcome of the study. The hereby identified candidate essential genes thus may constitute excellent targets for the development of new antibiotics or vaccines. In a second study, the transposon mutant library was applied in a genome-scale "negative-selection strategy" to identify genes that are involved in low phosphate-dependent invasion (LPDI). LPDI is dependent on the Neisseria porin subtype PorBIA which acts as an epithelial cell invasin in absence of phosphate and is associated with severe pathogenicity in disseminated gonococcal infections (DGI). Tn-seq demonstrated 98 genes, which were involved in adherence to host cells and 43 genes involved in host cell invasion. E.g. the hypothetical protein NGFG_00506, an ABC transporter ATP-binding protein NGFG_01643, as well as NGFG_04218 encoding a homolog of mafI in N. gonorrhoeae FA1090 were experimentally verified as new invasive factors in LPDI. NGFG_01605, a predicted protease, was identified to be a common factor involved in PorBIA, Opa50 and Opa57-mediated neisserial engulfment by the epithelial cells. Thus, this first systematic Tn-seq application in N. gonorrhoeae identified a set of previously unknown N. gonorrhoeae invasive factors which demonstrate molecular mechanisms of DGI.}, subject = {Neisseria gonorrhoeae}, language = {en} } @phdthesis{Valchanova2006, author = {Valchanova, Stamatova Ralitsa}, title = {Functional analysis of the murine cytomegalovirus genes m142 and m143}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-20215}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2006}, abstract = {Human cytomegalovirus (HCMV) infection causes clinical symptoms in immunocompromised individuals such as transplantant recipients and AIDS patients. The virus is also responsible for severe complications in unborn children and young infants. The species specificity of HCMV prevents the direct study of mechanisms controlling the infection in animal models. Instead, the murine cytomegalovirus (MCMV) is used as a model system. Human and murine CMVs have large double-stranded DNA genomes, encoding nearly 170 genes. About 30\% of the genes are committed to essential tasks of the virus. The remaining genes are involved in virus pathogenesis or host interaction and are dispensable for virus replication. The CMV genes are classified in gene families, based on sequence homology. In the present work, the function of two genes of the US22 gene family was analyzed. The MCMV genes m142 and m143 are the only members of this family that are essential for virus replication. These genes also differ from the remaining ten US22 gene family members in that they lack 1 of 4 conserved sequence motifs that are characteristic of this family. The same conserved motif is missing in the HCMV US22 family members TRS1 and IRS1, suggesting a possible functional homology. To demonstrate an essential role of m142 and m143, the genes were deleted from the MCMV genome, and the mutants were reconstituted on complementing cells. Infection of non-complementing cells with the deletion mutants did not result in virus replication. Virus growth was rescued by reinsertion of the corresponding genes. Cells infected with the viral deletion mutants synthesized reduced amounts of viral DNA, and viral late genes were not expressed. However, RNA analyses showed that late transcripts were present, excluding a role of m142 and m143 in regulation of gene transcription. Metabolic labelling experiments showed that total protein synthesis at late times postinfection was impaired in cells infected with deletion mutants. Moreover, the dsRNA-dependent protein kinase R (PKR) and its target protein, the translation initiation factor 2\&\#945; (eIF2\&\#945;) were phosphorylated in these cells. This suggested that the m142 and m143 are required for blocking the PKR-mediated shut-down of protein synthesis. Expression of the HCMV gene TRS1, a known inhibitor of PKR activation, rescued the replication of the deletion mutants, supporting the observation that m142 and m143 are required to inhibit this innate immune response of the host cell.}, subject = {Maus}, language = {en} } @phdthesis{Knuth2004, author = {Knuth, Karin}, title = {Identifizierung von essentiellen Genen in Salmonella typhimurium und Listeria monocytogenes durch Genom-weite Insertions-Duplikations-Mutagenese}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-10003}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {Die in dieser Arbeit etablierte Insertions-Duplikations-Mutagenese IDM erm{\"o}glicht es, das Genom von pathogenen Bakterien zu mutagenisieren und die so generierte Mutantenbank im high-throughput-Format auf Gene zu untersuchen, die unter bestimmten Bedingungen f{\"u}r das infekti{\"o}se Potential oder f{\"u}r das {\"U}berleben dieser Keime von Bedeutung sind. Die Grundlage von IDM bildet ein konditional replizierender Vektor, in den eine Genbank des Wirtsorganismus kloniert wird und der unter nicht-permissiven Replikationsbedingungen mittels homologer Rekombination ins Chromosom integriert und dadurch einen Gen-Knockout bedingt. Das IDM-Verfahren weist gegen{\"u}ber der Transposon-Mutagenese den Vorteil auf, dass das Genom nach dem Zufallsprinzip saturierend mutagenisiert werden kann und dass keine hot spots f{\"u}r die Insertion auftreten. Dar{\"u}ber hinaus kann der mutierte Genlocus nach Screening der Mutanten schnell per PCR identifiziert werden, indem die Exzision des Vektors induziert und das klonierte, homologe Fragment sequenziert wird. Die Insertion des Vektors ins Chromosom und damit der Gen-Knockout ist selbst ohne Selektionsdruck sehr stabil, so dass die Mutanten im Zellkultur- oder Tier-System untersucht werden k{\"o}nnen. IDM wurde im Rahmen dieser Arbeit erfolgreich auf Salmonella enterica Serovar typhimurium und Listeria monocytogenes angewandt. Die Applikation von IDM auf S. typhimurium hatte zum Ziel, Gene zu identifizieren, deren Produkte f{\"u}r das {\"U}berleben dieses Gram-negativen Keims in Vollmedium unter Laborbedingungen essentiell sind. Ausgehend von 14.000 S. typhimurium Fragmentbank-Klonen konnten durch Induktion der Integration des Vektors 262 Klone identifiziert werden, f{\"u}r welche die Mutation zu einem lethalen Ph{\"a}notyp f{\"u}hrte. 116 der 262 entsprechenden Proteine konnte durch IDM erstmalig eine essentielle Funktion f{\"u}r die Vitalit{\"a}t von S. typhimurium zugewiesen werden. Darunter befinden sich sowohl Proteine, die homolog sind zu Proteinen anderer klinisch-relevanter Keime, als auch Proteine, die Salmonella-spezifisch sind. Der gr{\"o}ßte Teil der identifizierten Proteine ist in die Speicherung und Weitergabe von Information (Transkription, Translation, DNA-Reparatur etc.) involviert, viele sind allerdings auch Proteine unbekannter Funktion. Die Essentialit{\"a}t der durch IDM identifizierten Gene konnte durch die Konstruktion von konditional lethalen Mutanten best{\"a}tigt werden. IDM ist demnach das erste Mutagenese-Verfahren, welches das essentielle Gen-Set von S. typhimurium f{\"u}r das {\"U}berleben in Vollmedium zu definieren vermochte. Basierend auf den IDM Daten konnte es auf 511 Gene, d.h. auf 11 \% des Gesamt-Genoms beziffert werden. Bei der Applikation von IDM auf L. monocytogenes lag der Fokus auf der Identifizierung von Genen, die f{\"u}r das {\"U}berleben dieses Gram-positiven Bakteriums im Zytosol von eukaryontischen Zellen von Bedeutung sind. Im Screening von bis dato 720 der 1491 L. monocytogenes Insertionsmutanten auf ein attenuiertes Replikationsverhalten in Caco-2 Zellen konnten 69 Mutanten selektioniert werden. In diesen Mutanten sind Gene ausgeknockt, deren Produkte haupts{\"a}chlich wichtige Funktionen in der N{\"a}hrstoffbereitstellung, in der Energiesynthese und im Metabolismus inne haben. Mit der Insertions-Duplikations-Mutagenese IDM steht ein molekulares Werkzeug zur Verf{\"u}gung, welches f{\"u}r die Identifzierung neuer targets f{\"u}r sowohl Breitband- als auch Spezies-spezifische Antiinfektiva eingesetzt werden kann und welches unbekannten Proteinen eine biologische Funktionen zuweisen kann.}, subject = {Salmonella typhimurium}, language = {de} }