Secondary structures as predictors of mutation potential in the lacZ gene of Escherichia coli.

Four independent nonsense mutations were engineered into the Escherichia coli chromosomal lacZ gene, and reversion rates back to LacZ(+) phenotypes were determined. The mutation potential of bases within putative DNA secondary structures formed during transcription was predicted by a sliding-window analysis that simulates successive folding of the ssDNA creating these structures. The relative base mutabilities predicted by the mfg computer program correlated with experimentally determined reversion rates in three of the four mutants analysed.

The effect of promoter strength, supercoiling and secondary structure on mutation rates in Escherichia coli.

Four mutations resulting in opal stop codons were individually engineered into a plasmid-borne chloramphenicol-resistance (cat) gene driven by the lac promoter. These four mutations were located at different sites in secondary structures. The mutations were analysed with the computer program mfg, which predicted their relative reversion frequencies.

Increased transcription rates correlate with increased reversion rates in leuB and argH Escherichia coli auxotrophs.

Escherichia coli auxotrophs of leuB and argH were examined to determine if higher rates of transcription in derepressed genes were correlated with increased reversion rates. Rates of leuB and argH mRNA synthesis were determined using half-lives and concentrations, during exponential growth and at several time points during 30 min of amino acid starvation. Changes in mRNA concentration were primarily due to increased mRNA synthesis and not to increased stability.

Predicting mutation frequencies in stem-loop structures of derepressed genes: implications for evolution.

This work provides evidence that, during transcription, the mutability (propensity to mutate) of a base in a DNA secondary structure depends both on the stability of the structure and on the extent to which the base is unpaired. Zuker's DNA folding computer program reveals the most probable stem-loop structures (SLSs) and negative energies of folding (-DeltaG) for any given nucleotide sequence. We developed an interfacing program that calculates (i) the percentage of folds in which each base is unpaired during transcription; and (ii) the mutability index (MI) for each base, expressed as an absolute value and defined as -follows: MI = (% total folds in which the base is unpaired) x (highest -DeltaG of all folds in which it is unpaired).

Hypermutable bases in the p53 cancer gene are at vulnerable positions in DNA secondary structures.

A DNA folding analysis indicates that the most hypermutable bases in exons 5, 7, and 8 of the p53 tumor suppressor gene are located immediately next to stems in stable DNA stem-loop structures. On the basis of the highest negative energy (-DeltaG) value of the structures containing each mutable bases and on the extent to which each base is unpaired during transcription, their relative mutabilities are calculated using a new computer algorithm. These predicted mutation frequencies correlate well with those observed in 14,000 human cancers (R(2) = 0.