Abstract
ABSTRACTIron is essential for most organisms. However, two problems are associated with the use of iron for aerobically growing organisms: (i) its accumulation leads to the formation of toxic reactive oxygen species and (ii) it is present mainly as the highly insoluble ferric iron which makes the access to iron difficult. As a consequence, a tight regulation of iron homeostasis is required. This regulation is achieved in many bacteria by the ferric uptake repressor Fur. The way how the activity of Fur is controlled, has so far remained elusive. Here, we have identified the Fur antirepressor FurA (previously YlaN) in the model bacteriumBacillus subtilisand describe its function to release Fur from the DNA under conditions of iron limitation. The FurA protein physically interacts with Fur, and this interaction prevents Fur from binding to its target sites due to a complete re-orientation of the protein. Bothin vivoandin vitroexperiments using a reporter fusion and Fur-DNA binding assays, respectively, demonstrate that the Fur-FurA interaction prevents Fur from binding DNA and thus from repressing the genes required for iron uptake. Accordingly, the lack of FurA results in the inability of the cell to express the genes for iron uptake under iron-limiting conditions. This explains why thefurAgene was identified as being essential under standard growth conditions inB. subtilis. Phylogenetic analysis suggests that the control of Fur activity by the antirepressor FurA is confined to, but very widespread in bacteria of the class Bacilli.IMPORTANCEIron is essential for most bacteria since it is required for many redox reactions. Under aerobic conditions, iron is both essential and toxic due to radical formation. Thus, iron homeostasis must be faithfully controlled. The transcription factor Fur is responsible for this regulation in many bacteria; however, the control of Fur activity has remained open. Here we describe the FurA protein, a so far unknown protein which acts as an antirepressor to Fur inBacillus subtilis. This mechanism seems to be widespread inB. subtilisand several important pathogens and might be a promising target for drug development.
Publisher
Cold Spring Harbor Laboratory