ABSTRACT
Frataxin homologues are important iron chaperones in eukarya and prokarya. Using a native proteomics approach we were able to identify the structural frataxin homologue Fra (formerly YdhG) of Bacillus subtilis and to quantify its native iron-binding stoichiometry. Using recombinant proteins we could show in vitro that Fra is able to transfer iron onto the B. subtilis SUF system for iron-sulfur cluster biosynthesis. In a four-constituents reconstitution system (including SufU, SufS, Fra and CitB) we observed a Fra-dependent formation of a [4 Fe-4 S] cluster on SufU that could be efficiently transferred onto the target apo-aconitase (CitB). A Δfra deletion mutant showed a severe growth phenotype associated with a broadly disturbed iron homeostasis; this indicates that Fra is a central component of intracellular iron channeling in B. subtilis.
Subject(s)
Bacillus subtilis/metabolism , Iron-Binding Proteins/metabolism , Iron/metabolism , Bacillus subtilis/genetics , Iron-Binding Proteins/chemistry , Iron-Binding Proteins/genetics , Mass Spectrometry , Molecular Chaperones/metabolism , Proteomics , FrataxinABSTRACT
Iron-sulfur cluster biosynthesis in Gram-positive bacteria is mediated by the SUF system. The transfer of sulfide from the cysteine desulfurase SufS to the scaffold protein SufU is one of the first steps within the assembly process. In this study, we analyzed the interaction between Bacillus subtilis SufS and its scaffold SufU. The activity of SufS represents a Ping-Pong mechanism leading to successive sulfur loading of the conserved cysteine residues in SufU. Cysteine 41 of SufU is shown to be essential for receiving sulfide from SufS, while cysteines 66 and 128 are needed for SufS/SufU interaction. In conclusion, we present the first step-by-step model for loading of the essential scaffold component SufU by its sulfur donor SufS.