@phdthesis{Stojic2005, author = {Stojic, Jelena}, title = {Cloning and functional characterization of novel genes expressed preferentially in the human retina}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-13746}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {The human retina is a multi-layered neuronal tissue specialized for the reception and processing of visual information. The retina is composed of a great diversity of neuronal cell types including rod and cone photoreceptors, bipolar cells, ganglion cells, amacrine cells, horizontal cells and M{\"u}ller glia. In response to light, a coordinated series of molecular events, the so-called phototransduction cascade, is triggered in photoreceptor cells and the signals from the photoreceptors are further processed by the bipolar and ganglion cells to the higher centers of the brain. The retina as highly complex system may be greatly susceptible to genetic defects which can lead to a wide range of disease phenotypes. Therefore, isolation and characterisation of the genes active in the human retina will facilitate our deeper understanding of retinal physiology and mechanisms underlying retinal degeneration and provide novel candidates for the retinal disease genes. To identify novel genes that are specifically or predominantly expressed in the human retina, a cDNA library enriched for retina specific transcripts was generated using suppression subtractive hybridization (SSH) technique. In total, 1113 clones were randomly isolated from the retina SSH cDNA library and partially sequenced. On the basis of BLASTN algorithm analysis these clones were classified into four categories including those with I) significant homology to known human genes (766/1113), II) significant homology to partial transcripts and hypothetical gene predictions (162/1113), III) no homology to known mRNAs (149/1113), and IV) vector sequences and clones derived from mitochondrial genes (36/1113). After correcting for redundancy, category I represented 234 known human genes and category II a total of 92unknown transcripts. Clones from category I, were selected for expression analysis by RT-PCR in a great number of human tissues. This resulted in the identification of 16 genes which were expressed exclusively in the retina, 13 which were highly expressed in the retina compared to other tissues, 12 genes which were specifically expressed in neuronal tissues and 48 ubiquitously expressed genes. Thus, our expression analysis resulted in the identification of 29 genes exclusively or abundantly transcribed in the human retina. Of those, retina specific genes L25,L33, L35, L37, L38 and L40 were selected for further analysis. To characterize the complete mRNA sequences of these transcripts a full-length human retina cDNA library was constructed. The analysis of the L25 gene revealed three splicing variants of the ABCC5 gene, consequently named ABCC5_SV1 (SV1), ABCC5_SV2 (SV2) and ABCC5_SV3 (SV3).These isoforms comprise the first five exons of ABCC5 and additional novel exons named 5a, 5b and 5c, generated by differential exon usage. The determined lengths of the three transcripts are 2039 bp, 1962 bp, and 1887 bp in size, respectively. RT-PCR, real-time PCR and Northern blot analysis of ABCC5 as well as the isoforms SV1, SV2 and SV3demonstrated high levels of expression for all transcripts in the retina compared to other tissues. Analysis of their nucleotide sequences revealed that inclusion of exon 5a in splicing variant SV1 produced a frame shift and premature termination codon (PTC). Our data show that this splice variant is the target of nonsense mediated mRNA decay (NMD). This was shown by inhibition of protein synthesis with antibiotics puromycin and anisomycin in human cell lines A-RPE 19 and Y79. Our analysis resulted in an increase of the PTC containing transcript and a decrease of the ABCC5 transcript. Conversely, the amount of both transcripts (SV1 and ABCC5) returned to pre-treatment levels after removal of the inhibitors. Together, our results suggest that alternative splicing of the ubiquitously expressed ABCC5 gene in addition to NMD is involved in retina-specific transcriptional regulation of the mRNA level of ABCC5. In contrast, additional experiments demonstrated that the levels of expression ofSV2 and SV3 isoforms do not appear to influence ABCC5 transcription. Several of the cloned genes were selected for additional genotyping of single nucleotide polymorphisms (SNPs) in order to construct their SNP maps which are going to be used for future association studies of complex disease AMD. Thus, identification of novel retinal genes and their functional characterization will further our elucidation of retinal physiology in general and in the diseased state in particular, by providing candidate retinal disease genes.}, subject = {Netzhaut}, language = {en} } @phdthesis{Zhou2005, author = {Zhou, Qingchun}, title = {Molecular analysis of the sex-determining region of the Y chromosome in the platyfish Xiphophorus maculatus}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-13827}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {A large variety of sex determination systems have been described in fish. However, almost no information is available about sex determination in the classical fish models, the zebrafish Danio rerio and the pufferfish Takifugu rubripes. A DNA-binding protein gene called dmrt1bY (or DMY) has been recently described as an outstanding candidate for the primary sex-determining gene in the medaka fish Oryzias latipes. But this gene is not the universal master sex-determining gene in teleost fish, since dmrt1bY is not found in most other fishes. Hence, other fish models need to be examined including the platyfish Xiphophorus maculatus. Xiphophorus maculatus has three types of sex chromosomes (X, Y and W; females are XX, WX or WY; males are XY or YY). Its gonosomes are at an early stage of differentiation. The sex-determining locus on the sex chromosomes is flanked by two receptor tyrosine kinase genes, the Xmrk oncogene and its protooncogenic progenitor gene egfrb, which both delimit a region of about 0.6 centiMorgans. This situation should allow the positional cloning of the sex-determining gene (SD) of the platyfish. For this purpose, Bacterial Artificial Chromosome (BAC) contigs were assembled from a BAC library of XY males constructed in our laboratory, using the oncogene Xmrk, egfrb, as well as a Y-specific pseudogene called ps-criptY as starting points. The ps-criptY sequence was found to be closely linked to the SD gene, since no recombination was observed between SD and ps-criptY in more than 400 individuals tested. Two major BAC contigs for the X chromosome (about 2.5 Mb) and three major BAC contigs for the Y chromosome (about 3.5 Mb) were built up and analyzed by strategic sequencing. These are some of the largest contigs ever assembled for the sex chromosomes of a non-mammalian vertebrate species. The molecular analysis of the ps-criptY contig was the major objective of this work. The Y-specific ps-criptY contig has been extended over 1 Mb in this work with 58 identified molecular markers. Approximatively 700 kb of non-redundant sequences has been obtained from this contig by strategic sequencing. Numerous Y-linked markers from the contig including ps-criptY were also detected on the X chromosome. Nevertheless, major structural differences were observed between the X and Y chromosomes. Particularly, a large region, which is present at one copy on the X chromosome and contains several candidate genes, was found to be duplicated on the Y chromosome. Evidence for an inversion in the sex-determining region and for the Y-specific accumulation of a repeated sequence called XIR was also obtained. Such events might correspond to an initiation of differentiation between both types of gonosomes. Accumulation of transposable elements was also observed in the ps-criptY contig. A DNA transposable element, helitron, was isolated from the sex-determining region of X. maculatus. Three copies of helitron are located on the ps-criptY contig and one copy on the X-linked contig (helitron has roughly 15 copies per haploid genome). No in-frame stop codon, truncation or intron was found in these four copies, which present high nucleotide identities to each other. This suggests that helitron elements might be active or have been recently active in X. maculatus. A consensus open reading frame of helitron was also assembled from medaka (Oryzias latipes) genomic sequences. Two candidate genes from the ps-criptY contig are also located on the W chromosome in the X. maculatus Usumacinta strain (heterogamety). These markers show the relationship between the different types of gonosomes and allow to compare the male and female heterogameties in the platyfish. Several gene candidates were identified in the ps-criptY contig. However, some of them such as msh2, cript, igd and acr probably correspond to pseudogenes. Interestingly, a novel gene, called swimy, is exclusively expressed in spermatogonia of the adult testis. Swimy is a gene encoding a DNA-binding protein with several putative DNA-binding domains. The data suggest that swimy is a very promising candidate for the master SD gene. Another novel gene, which is called fredi and encodes a novel helix-turn-helix protein, is predominately expressed in the adult testis and currently under scrutiny. There is no doubt that the master SD gene of X. maculatus will be identified by positional cloning. Further molecular analysis of the contigs built in this work will shed new light on the molecular mechanism of sex determination and the evolution of sex chromosomes in fish.}, subject = {Platy}, language = {en} } @phdthesis{ElMasri2005, author = {El-Masri, Harun}, title = {A genetic analysis of somitogenesis in the Medaka (Oryzias latipes)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-14515}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2005}, abstract = {Somites are repeated epithelial segments that are generated in a rhythmic manner from the presomitic mesoderm (PSM) in the embryonic tailbud. Later, they differentiate into skeletal muscle, cartilage and dermis. Somitogenesis is regulated by a complex interplay of different pathways. Notch/Delta signaling is one of the pathways well characterized in zebrafish through mutants affected in its different components. Previous work in mouse, chicken and zebrafish has shown that also additional components are required during somitogenesis, most importantly through an FGF and Retinoic acid (RA) gradient, as well as Wnt signaling. However, no zebrafish mutants with defects in these pathways showing specific somite malformations are described. This was explained by functional redundancies among related genes that have resulted from a whole genome duplication which occurred in a teleost fish ancestor 350 million years ago. As distinct duplicates exist in different teleost species, a large scale mutagenesis screen in the medaka (Oryzias latipes) has been performed successfully in Kyoto, Japan. I analyzed nine of the isolated medaka mutants that show variable aspects of somitic phenotypes. This includes a complete or partial loss of somite boundaries (e.g. bms and sne), somites with irregular sizes and shapes (e.g. krz and fsl) or partially fused and enlarged somites (e.g. dpk). Although some of these medaka mutants share characteristics with previously described zebrafish somite mutants, most of the mutants represent unique phenotypes, not obtained in the zebrafish screens. In-situ hybridization analyses with marker genes implicated in the segmentation clock (e.g. her7), establishment of anterior-posterior (A-P) polarity (e.g. mesp) and differentiation of somites (e.g. myf5, lfng) revealed that the medaka mutants can be separated into two classes. Class I shows defects in tailbud formation and PSM prepatterning, and lateron somite boundary formation was impaired in these mutants. A unique member of this class with a novel phenotype is the doppelkorn (dpk) mutant that has single fused or enlarged somites. This phenotype has not been reported till now in zebrafish somite mutants. In-situ analyses on dpk showed that stabilization of the cyclically expressed somitogenesis clock genes must be affected in this mutant. This is accompanied by a disrupted regulation of A-P polarity genes like mesp. This suggests that dpk is a mutant deficient in the wave front, which is necessary for the down-regulation of oscillating genes in the anterior PSM. Furthermore, as the initiation of oscillation of all three cyclic her genes was unaffected in dpk embryos, I could exclude that this mutant in affected in the Notch/Delta pathway. Another mutant that belongs to this class is the samidare (sam) mutant. Morphologically, sam mutants are similar to zebrafish after eight (aei). In both cases, the first 7-9 somites are formed properly, but after this somite formation ceases. Different to the situation in aei, sam mutant embryos presented an additional defect in the mid-hindbrain boundary (MHB) region. Similar MHB defects were described in the zebrafish fgf8 mutant acerebellar (ace). In ace zebrafish mutant, somites were only slightly defective, although FGF signaling has been shown to be important for somite formation in chicken, mouse and zebrafish. This was explained by functional redundancy between fgf8 and fgf24 ligands in the tailbud of zebrafish. Thus, it is interesting to suggest that the sam mutant, based on the parallel defects in somites and MHB, is a potential member of the FGF signaling pathway muatnts. It was shown that FGF plays a crucial role during MHB formation in medaka. In addition, I showed that fgf8 acts non-redundantly during tailbud formation and somitogenesis in medaka. Furthermore, I showed that FGF signaling regulates somite size also in medaka and that fgfr1 is the only FGF receptor expressed in the tailbud and somites. In class II medaka somite mutants, PSM prepatterning appears normal, whereas A-P polarity, boundary formation, epithelialization or the later differentiation of somites appears to be affected. Such mutants have not been isolated so far in zebrafish, mice or chicken. Therefore, medaka class II somite mutants seem to be a novel group of mutants that opens new perspectives to analyze A-P polarity regulation, determination and boundary formation in the presence of a normally functioning clock in the PSM. Identifying the encoding genes for all analyzed medaka somite mutants will contribute to the understanding of the molecular interactions of different signaling pathways involved during somitogenesis, and is expected to result in the identification of new components.}, subject = {Japank{\"a}rpfling}, language = {en} } @phdthesis{Braasch2009, author = {Braasch, Ingo}, title = {Evolution by genome duplication: insights from vertebrate neural crest signaling and pigmentation pathways in teleost fishes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-35702}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2009}, abstract = {Gene and genome duplications are major mechanisms of eukaryotic genome evolution. Three rounds of genome duplication have occurred in the vertebrate lineage, two rounds (1R, 2R) during early vertebrate evolution and a third round, the fish-specific genome duplication (FSGD), in ray-finned fishes at the base of the teleost lineage. Whole genome duplications (WGDs) are considered to facilitate speciation processes and to provide the genetic raw material for major evolutionary transitions and increases in morphological complexity. In the present study, I have used comparative genomic approaches combining molecular phylogenetic reconstructions, synteny analyses as well as gene function studies (expression analyses and knockdown experiments) to investigate the evolutionary consequences and significance of the three vertebrate WGDs. First, the evolutionary history of the endothelin signaling system consisting of endothelin ligands and receptors was reconstructed. The endothelin system is a key component for the development of a major vertebrate innovation, the neural crest. This analysis shows that the endothelin system emerged in an ancestor of the vertebrate lineage and that its members in extant vertebrate genomes are derived from the vertebrate WGDs. Each round of WGD was followed by co-evolution of the expanding endothelin ligand and receptor repertoires. This supports the importance of genome duplications for the origin and diversification of the neural crest, but also underlines a major role for the co-option of new genes into the neural crest regulatory network. Next, I have studied the impact of the FSGD on the evolution of teleost pigment cell development and differentiation. The investigation of 128 genes showed that pigmentation genes have been preferentially retained in duplicate after the FSGD so that extant teleost genomes contain around 30\% more putative pigmentation genes than tetrapods. Large parts of pigment cell regulatory pathways are present in duplicate being potentially involved in teleost pigmentary innovations. There are also important differences in the retention of duplicated pigmentation genes among divergent teleost lineages. Functional studies of pigment synthesis enzymes in zebrafish and medaka, particularly of the tyrosinase family, revealed lineage-specific functional evolution of duplicated pigmentation genes in teleosts, but also pointed to anciently conserved gene functions in vertebrates. These results suggest that the FSGD has facilitated the evolution of the teleost pigmentary system, which is the most complex and diverse among vertebrates. In conclusion, the present study supports a major role of WGDs for phenotypic evolution and biodiversity in vertebrates, particularly in fish.}, subject = {Molekulare Evolution}, language = {en} } @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{Batzilla2011, author = {Batzilla, Julia}, title = {Complete genome sequence of Yersinia enterocolitica subspecies palearctica serotype O:3: Identification of novel virulence-associated genes and evolutionary aspects}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-69668}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Yersinia enterocolitica subsp. palearctica Serobiotyp O:3/4 ist verantwortlich f{\"u}r 80-90 \% aller Yersiniosen beim Menschen in Deutschland und Europa. Y. enterocolitica Infektionen zeigen vielf{\"a}ltige Krankheitsbilder wie Gastroenteritis, Lymphadenitis und verschiedene Sp{\"a}tkomplikationen wie reaktive Arthritis. Das wichtigste Tierreservoir stellt das Hausschwein dar. Rohes Schweinefleisch in Metzgereien in Deutschland und anderen Regionen in Nord-Ost Europa ist h{\"a}ufig mit Yersinien kontaminiert (Bayern: 25 \%). Da sich Serobiotyp O:3/4-St{\"a}mme geografisch und phylogenetisch deutlich von dem bisher sequenzierten Serobiotyp O:8/1B Stamm 8081 unterscheiden, wurde eine komplette Genomsequenzierung des europ{\"a}ischen Serobiotyp O:3/4 DSMZ Referenzstammes Y11 (aus Patientenstuhl isoliert) durchgef{\"u}hrt. Um einen genaueren Einblick in die Y. enterocolitica subsp. palearctica Gruppe zu erhalten, wurden zus{\"a}tzlich zwei weitere Serobiotyp O:3/4 Isolate (Stamm Y8265, Patientenisolat, und Stamm Y5307, mit reaktiver Arthritis assoziiertes Patientenisolat), sowie ein eng verwandtes Y. enterocolitica subsp. palearctica Serobiotyp O:5,27/3 Isolat, Stamm Y527P, und zwei Biotyp 1A Isolate (ein Isolat nosokomialer Herkunft (Serogruppe O:5) und ein Umwelt-Isolat (O:36)) unvollst{\"a}ndig sequenziert. Die nicht mausvirulenten St{\"a}mme wurden mit dem mausvirulenten Y. enterocolitica subsp. enterocolitica Serobiotyp O:8/1B Stamm 8081 verglichen, um genetische Besonderheiten von Stamm Y11 und der Y. enterocolitica subsp. palearctica Gruppe zu identifizieren. Besonderer Fokus lag hierbei auf dem pathogenen Potential von Stamm Y11, um neue potentielle Virulenz Faktoren und Fitnessfaktoren zu identifizieren, darunter vor allem solche, die eine Rolle bei der Wirtsspezifit{\"a}t von Serobiotyp O:3/4 spielen k{\"o}nnten. Y. enterocolitica subsp. palearctica Serobiotyp O:3/4 St{\"a}mmen fehlen einige der Charakteristika der mausvirulenten Gruppe Y. enterocolitica subsp. enterocolitica, beispielsweise die Yersiniabactin kodierendeā€š High-Pathogenicity Island (HPI), das Yts1 Typ 2 Sekretionssystem und das Ysa Typ 3 Sekretionssystem. Die Serobiotyp O:3/4-St{\"a}mme haben ein anderes Repertoir von Virulenz Faktoren erworben, darunter Gene bzw. genomische Inseln f{\"u}r das Ysp Typ 3 Sekretionssystem, Rtx-{\"a}hnliches putatives Toxin, Insektizid-Toxine und ein funktionelles PTS System f{\"u}r die Aufnahme von N-acetyl-galactosamin, dem aga-Operon. Nach dem Transfer des aga-Operons in Y. enterocolitica subsp. enterocolitica O:8/1B konnte Wachstum auf N-acetyl-galactosamin festgestellt werden. Neben diesen Genen k{\"o}nnen m{\"o}glicherweise auch zwei Prophagen (PhiYep-2 und PhiYep-3) und eine asn tRNA assoziierte genomische Insel (GIYep-01) zur Pathoadaptation von Y. enterocolitica subsp. palearctica Serobiotyp O:3/4 beitragen. Der PhiYep-3 Prophage und die GIYep-01 Insel weisen Rekombinationsaktivit{\"a}t auf, und PhiYep-3 wurde nicht in allen untersuchten Serobiotyp O:3/4 St{\"a}mmen gefunden. Y. enterocolitica subsp. palearctica Serobiotyp O:5,27/3 Stamm Y527P ist genetisch eng verwandt zu allen Serobiotyp O:3/4 Isolaten, wohingegen die Biotyp 1A Isolate ein mehr Mosaik-artiges Genom aufweisen und potentielle Virulenzgene sowohl mit Serobiotyp O:8/1B als auch O:3/4 gemeinsam haben, was einen gemeinsamen Vorfahren impliziert. Neben dem pYV Virulenz-Plasmid fehlen den Biotyp 1A Isolaten klassische Virulenzmarker wie das Ail Adhesin, das YstA Enterotoxin und das Virulenz-assoziierte Protein C (VapC). Interessanterweise gibt es keine betr{\"a}chtlichen Unterschiede zwischen den bekannten Virulenzfaktoren des nosokomialen Isolats und dem Umweltisolat der Biotyp 1A-Gruppe, abgesehen von einem verk{\"u}rzten Rtx Toxin-{\"a}hnlichem Genkluster und {\"U}berresten eines P2-{\"a}hnlichen Phagen im Krankenhausisolat der Serogruppe O:5.}, subject = {Genanalyse}, language = {en} }