Catabolite repression of SOS-dependent and SOS-independent spontaneous mutagenesis in stationary-phase Escherichia coli

Abstract

Previous work in our laboratory established that a spontaneous mutagenesis process operating in stationary-phase Escherichia coli cells undergoing selection is subject to regulation by the global regulatory mechanism known as catabolite repression (formerly also called glucose-repression). Here, we set out to determine the identity of this hitherto unknown catabolite-repressible spontaneous mutation generation mechanism(s). We used two different spontaneous mutation detection assays, reversion of a Lac(-) (lacI33OmegalacZ) frameshift marker and forward mutation to valine-resistance, and tested the effects of varying the nature of the carbon source(s) present in the selective plating medium on the mutability of bacterial cells carrying known defects in the recA, umuDC and dinB genes, three well-known SOS response genes, whose products are important for mutagenesis in E. coli. Consistent with the results of our previous Lac(-)-->Lac(+) assay using otherwise SOS-proficient bacterial cells, we found that the overall numbers of spontaneous Lac(+)E. coli revertants were highest when the selective medium contained lactose and lowest when it contained lactose plus the non-utilizable but strongly catabolite-repressing glucose analogue, methyl-alpha-d-glucopyranoside (alphaMG). In contrast, we found that the numbers of Lac(+) revertants appearing on the lactose and lactose+alphaMG selection plates were greatly diminished and not significantly different when the bacterial cells concerned carried either a DeltarecA or DeltadinB mutation. Furthermore, introducing the DeltadinB mutant allele into bacterial cells over-expressing the recA gene reduced the numbers of Lac(+) mutations to those being recovered with the DeltadinB cells. These results appear to suggest that (i) the DinB-dependent mutation generation pathway is alone responsible for spontaneous reversion of the lacI33OmegalacZ frameshift marker, and (ii) the varying numbers of Lac(+) colonies that we recover on the lactose and lactose+alphaMG plates provide a direct measure of the differential effects of these particular carbon compounds on the overall expression of the dinB gene. Interestingly, the yields of spontaneous Val mutations arising in wild-type, DeltarecA, DeltadinB and DeltaumuDC cells were found to be similar, but always tended to be highest when the medium contained only a non-repressing carbon source (glycerol) and lowest when it had been supplemented with a strong catabolite repressor such as glucose or alphaMG. Together, our results would seem to establish that stationary-phase E. coli cells exposed to strong selection pressures can accumulate spontaneous mutations via SOS-dependent and SOS-independent mutation generation pathways whose levels of expression are regulated by catabolite repression.