1. Molecular view of an electron transfer process essential for iron–sulfur protein biogenesis
- Author
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Mario Piccioli, Andrea Giachetti, Ivano Bertini, Maciej Mikolajczyk, Julia Winkelmann, Lucia Banci, Vito Calderone, Simone Ciofi-Baffoni, and Deepa Jaiswal
- Subjects
Iron-Sulfur Proteins ,Models, Molecular ,Molecular model ,Flavin Mononucleotide ,Plasma protein binding ,Biology ,010402 general chemistry ,01 natural sciences ,Redox ,Models, Biological ,Electron Transport ,03 medical and health sciences ,Electron transfer ,Oxidoreductase ,Protein Interaction Mapping ,Protein biosynthesis ,Humans ,030304 developmental biology ,chemistry.chemical_classification ,0303 health sciences ,Multidisciplinary ,Flavoproteins ,Intracellular Signaling Peptides and Proteins ,Electron transport chain ,0104 chemical sciences ,Cell biology ,Protein Structure, Tertiary ,chemistry ,Protein Biosynthesis ,Physical Sciences ,Oxidoreductases ,Biogenesis ,Protein Binding - Abstract
Biogenesis of iron–sulfur cluster proteins is a highly regulated process that requires complex protein machineries. In the cytosolic iron–sulfur protein assembly machinery, two human key proteins—NADPH-dependent diflavin oxidoreductase 1 (Ndor1) and anamorsin—form a stable complex in vivo that was proposed to provide electrons for assembling cytosolic iron–sulfur cluster proteins. The Ndor1–anamorsin interaction was also suggested to be implicated in the regulation of cell survival/death mechanisms. In the present work we unravel the molecular basis of recognition between Ndor1 and anamorsin and of the electron transfer process. This is based on the structural characterization of the two partner proteins, the investigation of the electron transfer process, and the identification of those protein regions involved in complex formation and those involved in electron transfer. We found that an unstructured region of anamorsin is essential for the formation of a specific and stable protein complex with Ndor1, whereas the C-terminal region of anamorsin, containing the [2Fe-2S] redox center, transiently interacts through complementary charged residues with the FMN-binding site region of Ndor1 to perform electron transfer. Our results propose a molecular model of the electron transfer process that is crucial for understanding the functional role of this interaction in human cells.
- Published
- 2013