Insertion sequence-driven evolution of Escherichia coli in chemostats.

Insertion sequence (IS) elements are present in almost all bacterial genomes and are mobile enough to provide genomic tools to differentiate closely related isolates. They can be used to estimate genetic diversity and identify fitness-enhancing mutations during evolution experiments. Here, we determined the genomic distribution of eight IS elements in 120 genomes sampled from Escherichia coli populations that evolved in glucose- and phosphate-limited chemostats by comparison to the ancestral pattern. No significant differential transposition of the various IS types was detected across the environments. The phylogenies revealed substantial diversity amongst clones sampled from each chemostat, consistent with the phenotypic diversity within populations. Two IS-related changes were common to independent chemostats, suggesting parallel evolution. One of them corresponded to insertions of IS1 elements within rpoS encoding the master regulator of stress conditions. The other parallel event was an IS5-dependent deletion including mutY involved in DNA repair, thereby providing the molecular mechanism of generation of mutator clones in these evolving populations. These deletions occurred in different co-existing genotypes within single populations and were of various sizes. Moreover, differential locations of IS elements combined with their transpositional activity provided evolved clones with different phenotypic landscapes. Therefore, IS elements strongly influenced the evolutionary processes in continuous E. coli cultures by providing a way to modify both the global regulatory network and the mutation rates of evolving cells.

IS1 transposition is enhanced by translation errors and by bacterial growth at extreme glucose levels.

Transposition of insertion sequences (IS) is an enzyme-mediated process that only occurs in a minority of cells within a bacterial culture. Transposition is thus a rare event, but transposition frequency may vary depending on experimental conditions. For instance in a rich broth, IS elements are known to transpose during stationary phase but not during exponential growth. Using a reporter system which involves the activation of the cryptic bgl operon in Escherichia coli, we show that the frequency of IS1 transposition is a function of glucose concentration in the growth medium, it is increased by streptomycin amounts that are below minimum inhibitory concentration (sub-MIC) and is inhibited in an rpsL150 strain with high translation accuracy. Since starved cells are known to enhance ribosome frameshifting, our data suggests that growth conditions applied in this study could affect IS1 transposition by increasing translation infidelity.

Improvement of pCVD442, a suicide plasmid for gene allele exchange in bacteria.

Allelic exchange experiments allow investigation of the functions of many unknown genes identified during the sequencing of entire genomes. Isogenic strains differing by only specific mutations can be constructed. Among other tools, suicide plasmids are widely used for this task. They present many advantages because they leave no scars on the chromosome, and therefore allow combining several mutations in the same genetic background. While using the previously described pCVD442 suicide plasmid [Infect. Immun. 59 (1991) 4310], we found untargeted recombination events due to the presence of an IS1 element on this plasmid. The plasmid was therefore improved by removal of the IS1 element. We also replaced the bla gene of pCVD442, conferring ampicillin resistance, by the cat gene conferring chloramphenicol resistance, leading to the new suicide plasmid pDS132. The plasmid was entirely sequenced. We demonstrate that this new vector can be easily used to introduce various types of mutations into different genetics backgrounds: removal of IS elements, introduction of point mutations or deletions. It can be introduced into bacterial strains by either transformation or conjugation.

Genomic comparisons among Escherichia coli strains B, K-12, and O157:H7 using IS elements as molecular markers.

BACKGROUND: Insertion Sequence (IS) elements are mobile genetic elements widely distributed among bacteria. Their activities cause mutations, promoting genetic diversity and sometimes adaptation. Previous studies have examined their copy number and distribution in Escherichia coli K-12 and natural isolates. Here, we map most of the IS elements in E. coli B and compare their locations with the published genomes of K-12 and O157:H7. RESULTS: The genomic locations of IS elements reveal numerous differences between B, K-12, and O157:H7. IS elements occur in hok-sok loci (homologous to plasmid stabilization systems) in both B and K-12, whereas these same loci lack IS elements in O157:H7. IS elements in B and K-12 are often found in locations corresponding to O157:H7-specific sequences, which suggests IS involvement in chromosomal rearrangements including the incorporation of foreign DNA. Some sequences specific to B are identified, as reported previously for O157:H7. The extent of nucleotide sequence divergence between B and K-12 is < 2% for most sequences adjacent to IS elements. By contrast, B and K-12 share only a few IS locations besides those in hok-sok loci. Several phenotypic features of B are explained by IS elements, including differential porin expression from K-12. CONCLUSIONS: These data reveal a high level of IS activity since E. coli B, K-12, and O157:H7 diverged from a common ancestor, including IS association with deletions and incorporation of horizontally acquired genes as well as transpositions. These findings indicate the important role of IS elements in genome plasticity and divergence.

Ralstonia metallidurans CH34 RpoN sigma factor and the control of nitrogen metabolism and biphenyl utilization.

Ralstonia metallidurans CH34 can use biphenyl as carbon and energy source when provided with the catabolic transposon Tn4371. Previous results suggested that this property was dependent on the RNA polymerase subunit sigma(54). The authors sequenced the CH34 rpoN gene and flanking DNA and isolated a CH34 rpoN-deficient strain. Analysis of the sequence revealed a set of features conserved in all rpoN genes and flanking DNA regions previously analysed in other bacterial species. Nevertheless, despite this conservation, CH34 differed even from the closely related strain R. eutropha H16 by one particular ORF. The rpoN null mutation did not affect expression of the Tn4371 bph operon although it did alter the ability of the Tn4371 host strain to grow on biphenyl. The CH34 rpoN mutant had lost the capacity for autotrophic growth and for responding to poor nitrogen sources by a decrease in urease and proline oxidase activity. CH34 RNA polymerase sigma(54) thus positively controls autotrophy as well as nitrogen metabolism but only indirectly affects Tn4371-directed biphenyl utilization.