Abstract
Proteins from the ISC operon of E. coli constitute the machinery used for the synthesis of iron‐sulfur clusters and their delivery to recipient apo‐proteins. [2Fe‐2S] cluster transfer from the holo‐scaffold protein IscU depends on ATP hydrolysis in the nucleotide‐binding domain (NBD) of HscA, a specialized Hsp70 chaperone. HscB, an Hsp40‐type co‐chaperone, binds to HscA and stimulates ATP hydrolysis to promote cluster transfer. However, the interactions between HscA and HscB have remained uncharacterized, and, moreover, the role of HscA’s interdomain linker in modulating ATPase activity has not been explored. We have created three variants of the isolated HscA NBD truncated at different residues within the linker, and have shown that the linker binds to the NBD and autoactivates ATP hydrolysis. Using solution‐state NMR spectroscopy and chemical shift perturbations, we mapped the apo‐HscA, HscA‐ADP and HscA‐ATP binding sites onto HscB. Our NMR data provide the first evidence of a structural role for the ubiquitously conserved J‐domain residues HPD of HscB, which we found selectively bind to the ATP‐bound form of HscA. Additionally, we have identified and characterized a previously unreported interaction between HscA and IscA, an iron‐binding protein putatively involved in [4Fe‐4S] cluster transfer, which competes with HscB for binding to HscA.Grant Funding Source: Supported by NIH grants U01 GM094622 and P41 GM103399
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