Expression and mutagenesis of the dpsA gene of Synechococcus sp. PCC7942, encoding a DNA-binding protein involved in oxidative stress protection

The Dps family of proteins are a diverse group of bacterial stress-inducible polypeptides that bind DNA and likely confer resistance to peroxide damage during periods of oxidative stress and long-term nutrient limitation. Some members of the Dps protein family have been shown to form abundant, large (∼150 kD) hexameric complexes that bind chromosomal DNA with little sequence specificity. Previous work from this lab has demonstrated that the Dps proteins are divergent members of the bacterioferritin/bacterioferritin superfamily, and that the Synechococcus sp. PCC7942 Dps homolog, named DpsA, is a DNA-binding hemoprotein having heme-dependent catalytic activity. We speculated that this protein may yield a peroxide-consuming mechanism located on the chromosomal DNA, and we also suggested that this activity may be a necessary feature to handle the endogenous oxidative stresses associated with oxygenic photosynthesis. Current work has examined the expression of dpsA both under nutrient stress and during the growth phase; whereas dpsA mRNA is detectable in the exponential phase, transition to stationary phase yields a 20-fold increase in steady-state mRNA levels. Mapping the promoter region identifies a TAGAAT −10 sequence likely recognized by a cyanobacterial RpoS homolog. Lastly, site-directed mutants lacking dpsA function exhibit a severe phenotype impaired under all conditions yielding photooxidative stress; these include high light and treatment with paraquat. This supports our contention that the DpsA protein serves an important protective function in an obligate photoautotroph.