@phdthesis{Zdziarski2008,
  author    = {Zdziarski, Jaroslaw Maciej},
  title     = {Bacterial Genome Plasticity and its Role for Adaptation and Evolution of Asymptomatic Bacteriuria (ABU) Escherichia coli Strains},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-32879},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2008},
  abstract  = {Asymptomatic bacteriuria (ABU) represents the long term bacterial colonization of the urinary tract, frequently caused by Escherichia coli (E. coli), without typical symptoms of a urinary tract infection (UTI). To investigate characteristics of ABU E. coli isolates in more detail, the geno- and phenotypes of eleven ABU isolates have been compared. Moreover, consecutive in vivo re-isolates of the model ABU strain 83972 were characterized with regard to transcriptomic, proteomic and genomic alterations upon long term in vivo persistence in the human bladder. Finally, the effect of the human host on bacterial adaptation/evolution was assessed by comparison of in vitro and in vivo-propagated strain 83972. ABU isolates represent a heterologous group of organisms. The comparative analysis of different ABU isolates elucidated the remarkable genetic and phenotypic flexibility of E. coli isolates. These isolates could be allocated to all four major E. coli phylogenetic lineages as well as to different clonal groups. Accordingly, they differed markedly in genome content, i.e., the genome size as well as the presence of typical UPEC virulence-associated genes. Multi locus sequence typing suggested that certain ABU strains evolved from UPEC variants that are able to cause symptomatic UTI by genome reduction. Consequently, the high E. coli genome plasticity does not allow a generalized view on geno- and phenotypes of individual isolates within a clone. Reductive evolution by point mutations, DNA rearrangements and deletions resulted in inactivation of genes coding for several UPEC virulence factors, thus supporting the idea that a reduced bacterial activation of host mucosal inflammation promotes the ABU lifestyle of these E. coli isolates. Gene regulation and genetic diversity are strategies which enable bacteria to live and survive under continuously changing environmental conditions. To study adaptational changes upon long term growth in the bladder, consecutive re-isolates of model ABU strain 83972 derived from a human colonisation study and from an in vitro long term cultivation experiment were analysed with regard to transcriptional changes and genome rearrangements. In this context, it could be demonstrated that E. coli, when exposed to different host backgrounds, is able to adapt its metabolic networks resulting in an individual bacterial colonisation strategy. Transcriptome and proteome analyses demonstrated distinct metabolic strategies of nutrients acquisition and energy production of tested in vivo re-isolates of strain 83972 that enabled them to colonise their host. Utilisation of D-serine, deoxy- and ribonucleosides, pentose and glucuronate interconversions were main up-regulated pathways providing in vivo re-isolates with extra energy for efficient growth in the urinary bladder. Moreover, this study explored bacterial response networks to host defence mechanisms: The class III alcohol dehydrogenase AdhC, already proven to be involved in nitric oxide detoxification in pathogens like Haemophilus influenzae, was shown for the first time to be employed in defending E. coli against the host response during asymptomatic bacteriuria. Consecutive in vivo and in vitro re-isolates of strain 83972 were also analysed regarding their genome structure. Several changes in the genome structure of consecutive re-isolates derived from the human colonisation study implied the importance of bacterial interactions with the host during bacterial microevolution. In contrast, the genome structure of re-isolates from the in vitro long term cultivation experiment, where strain 83972 has been propagated without host contact, was not affected. This suggests that exposure to the immune response promotes genome plasticity thus being a driving force for the development of the ABU lifestyle and evolution within the urinary tract.},
  subject      = {Escherichia coli},
  language  = {en}
}