Isolation of E. coli mutants containing multiple transpositions of IS sequences

The ancestry of insertion sequences common to Escherichia coli and Salmonella typhimurium

Despite very restricted gene exchange between Escherichia coli and Salmonella typhimurium, both species harbor several of the same classes of insertion sequences. To determine whether the present-day distribution of these transposable elements is due to common ancestry or to horizontal transfer, we determined the sequences of IS1 and IS200 from natural isolates of S. typhimurium and E. coli. One strain of S. typhimurium harbored an IS1 element identical to that originally recovered from E. coli, suggesting that the element was recently transferred between these two species. The level of sequence divergence between copies of IS200 from E. coli and S. typhimurium ranged from 9.5 to 10.7%, indicating that IS200, unlike IS1, has not been repeatedly transferred between these enteric species since E. coli and S. typhimurium diverged from a common ancestor. Levels of variability in IS1 and IS200 for strains of E. coli and S. typhimurium show that each class of insertion sequence has a characteristic pattern of transposition within and among host genomes.

Construction of stable, single-copy luciferase gene fusions in Escherichia coli

A ColE1-based plasmid for transcriptional gene fusions was constructed that contains both the promoterless luxAB genes of Vibrio harveyi and a tet marker within the inverted repeats of a left end-truncated Tn5 element. Introduction of this plasmid into an Escherichia coli strain containing a plasmid (pTF421) that over-produces ColE1 RNA1 (and thus inhibits replication of the ColE1 plasmid) allowed selection for cells that had a single copy of the luxAB operon transposed into the chromosome beginning 5 days post-transformation. The long latent period necessary for Tn5 transposition is analogous to that found in other systems, where transposition frequencies and mutation rates increase in a time-dependent manner when selected for upon prolonged incubation on Petri dishes under bacteriostatic conditions.

Transposable genetic elements, spontaneous mutations and the doubling-dose method of radiation genetic risk evaluation in man

The principal aspects of the 'doubling-dose method' currently used by the United Nations Scientific Committee on the Effects of Atomic Radiation (UNSCEAR) and the Committee on the Biological Effects of Ionizing Radiation (BEIR) of the U.S. National Academy of Sciences, for the evaluation of genetic radiation hazards in man are briefly reviewed. With this method, which is primarily applicable to autosomal dominant and X-linked disorders, the expected increase in risk from radiation is expressed as a fraction of the current prevalence of these disorders, and thus in relation to an understandable frame of reference. Since the doubling dose is estimated as a ratio of spontaneous to induction rates of mutations, its magnitude is susceptible to changes in either the numerator (spontaneous rate) or the denominator (induction rate). Studies during the past 20 years or so with a number of experimental systems have demonstrated the existence of mobile DNA sequences in the genome and their causal role in the origin of spontaneous mutations, although the proportion of the latter among all spontaneous mutations is not known for any species. If a major proportion of spontaneous mutations in man is mediated by these mobile DNA sequences, and if their mobility is unaltered by radiation exposures, the calculation of the doubling dose in the manner mentioned above, and its use in risk evaluations becomes questionable. However, considerations based on the organization of the human genome would suggest that it is unlikely that a major fraction of spontaneous mutations that lead to disease states in man is due to mobile genetic elements. Consequently, the use of the doubling-dose method for the evaluation of genetic radiation hazards in man would appear to be valid at the present time.

Multiple IS10 rearrangements in Escherichia coli

We have investigated the occurrence of multiple transposon-promoted chromosomal rearrangements in Escherichia coli K12 strains containing transposon Tn10. We show that a single Tn10 element, with its two closely spaced insertion sequence (IS10) elements, frequently gives rise to complex rearrangements that can be accounted for as the sum of two "classical" IS10 events. Using a strain containing differentially marked Tn10 elements at widely separated locations, we have investigated the possibility that IS10-promoted rearrangements occur in cell-wide "bursts", as expected if cells could occasionally undergo brief periods when all IS10 transposition events were activated, interspersed with longer periods of relative quiescence. We find no evidence for strong (greater than 60-fold), periodic cell-wide activation under our experimental conditions. The sensitivity of this experiment has been evaluated using an expression for the accumulation of double mutations in populations with heterogeneous, fluctuating mutation rates (see Appendix). We discuss several mechanisms by which two closely linked IS10 elements could undergo coupled double events without cell-wide activation: local activation of small chromosomal regions, periodic bursts of synthesis of cis-acting transposase protein, and/or a propensity for elements that have actually engaged in one rearrangement event to initiate a second successive event immediately thereafter. We favor the last possibility.

Transposable elements as mutator genes in evolution

Strains of the bacterium Escherichia coli harbouring genes that increase mutation rates are known to have an evolutionary advantage in chemostat competition over otherwise isogeneic strains with lower mutation rates. This advantage is frequency-dependent, the mutator strain being favoured only above a starting ratio of approximately 5 x 10(-5), and it results from the fact that the necessary beneficial mutations cannot be generated in a mutator population below a certain size. Here we consider the possibility that the mutagenic properties of transposable elements confer an advantage in the same manner as mutator genes. A previous report has shown that the transposon Tn5 increases the fitness of E. coli in chemostats, although the reason for this effect has not been established. Our results show that the transposon Tn10 also confers an advantage in chemostats. In addition, we find that (1) this advantage, like that associated with mutator genes, is frequency-dependent, (2) whenever the Tn10 strains win, a segment of Tn10, probably its IS10 sequences, has undergone transposition to a new site, (3) the new insertions converge into a site contained within a 3.2 kilobase (kb) PvuII fragment of the genome, and (4) no transpositions are detected when the Tn10 population loses. We conclude that Tn10 confers an advantage by increasing the mutation rate of the host bacterium.

Gamma delta-mediated deletions of chromosomal segments on F-prime plasmids

Deleted derivatives of F lac+ proC+ tsx+/- purE+ plasmids ORF203 and F13 were isolated and physically characterized. Among 31 deletions, 24 were adjacent to the gamma delta element on F, four were associated with IS2 or IS3 elements normally present on F, and three displayed additional DNA rearrangements. With the genetic selection employed, the deletion endpoints in the chromosomal segment could fall anywhere within a 210 kb (5 min) region between proC and lac. The distribution of endpoints in this region was not random: the endpoints primarily occurred in an extended region near purE, and a 50 kb segment between tsx and purE was devoid of deletion endpoints. Deletion termini for mutants obtained from F13, which contains an additional 48 kb-segment interposed between gamma delta and the target region on ORF203, displayed a distribution similar to that seen for ORF203. Among simple deletions, there was no marked tendency for the chromosomal deletion endpoints to fall at IS1, IS3, or IS5 elements normally present in this chromosomal region. Point mutations and mutations caused by gamma delta or IS transposition into lac appeared in a small proportion of all plasmids studied.