Influences of bacterial DNA base-ratios and amino acid composition of the gene product on the consequences of frameshift mutations

Role of premature stop codons in bacterial evolution

When the stop codons TGA, TAA, and TAG are found in the second and third reading frames of a protein-encoding gene, they are considered premature stop codons (PSC). Deinococcus radiodurans disproportionately favored TGA more than the other two triplets as a PSC. The TGA triplet was also found more often in noncoding regions and as a stop codon, though the bias was less pronounced. We investigated this phenomenon in 72 bacterial species with widely differing chromosomal GC contents. Although TGA and TAG were compositionally similar, we found a great variation in use of TGA but a very limited range of use of TAG. The frequency of use of TGA in the gene sequences generally increased with the GC content of the chromosome, while the frequency of use of TAG, like that of TAA, was inversely proportional to the GC content of the chromosome. The patterns of use of TAA, TGA and TAG as real stop codons were less biased and less influenced by the GC content of the chromosome. Bacteria with higher chromosomal GC contents often contained fewer PSC trimers in their genes. Phylogenetically related bacteria often exhibited similar PSC ratios. In addition, metabolically versatile bacteria have significantly fewer PSC trimers in their genes. The bias toward TGA but against TAG as a PSC could not be explained either by the preferential usage of specific codons or by the GC contents of individual chromosomes. We proposed that the quantity and the quality of the PSC in the genome might be important in bacterial evolution.

The consequences of base-pair substitution mutations in AT- and GC-rich bacteria

The likely consequences, in terms of premature stop codons, detectable missense mutants, silent missense mutants, and degenerate codon changes, have been determined for all 12 individual base substitution changes. This has been done for the full, 61 sense codon, genetic code and also for the much more limited codon availabilities of AT- or GC-rich DNA. The specificities and outcomes of individual base substitutions are likely to be rather different at AT- or GC-rich extremes, and also from the situation at an intermediate DNA base-ratio where all 61 sense codons are available. In particular, at DNA base-ratio extremes many mutations will be to non-utilized codons, which may well act as nonsense mutants. These in turn will give novel classes of suppressor-containing revertants. Even in bacteria with intermediate DNA base-ratios, particular codons for a given amino acid may be favoured, over alternatives, because their use maximizes, or minimizes, the mutational consequences of one, or more, base substitution changes.