FeS-cluster coordination of vertebrate thioredoxins regulates suppression of hypoxia-induced factor 2α through iron regulatory protein 1

Thioredoxins (Trxs) provide electrons to essential cellular processes such as DNA synthesis. Here, we characterize human and murine Trx1 as new iron-sulfur proteins. The [2Fe-2S] cluster is complexed using cysteinyl side chains 32 and 73 in a dimeric holocomplex. Formation of the holo-dimer depends on small structural changes of the loop connecting helices three and four and is stabilized by the formation of a direct electrostatic interaction between Lys72 and Asp60 of two monomers. The not strictly conserved Cys73 in vertebrates co-evolved with the regulation of cellular iron homeostasis through the iron-regulatory proteins (IRP). Active apo-Trx1 is required for the reduction of cysteinyl residues in IRP1 and its binding to the iron-responsive elements in the mRNA encoding hypoxiainducible factor (HIF) 2α. Depletion of Trx1 increased the mRNA levels of HIF2α, an important target of IRP1. Hence, translation of the HIF2α mRNA requires either sufficient iron-supply or the lack of reducing power of the Trx system under iron-limiting conditions. Only then, HIF2α protein may accumulate under hypoxic conditions to transcriptionally regulate processes like erythropoiesis.Significance StatementThioredoxins are, in general, cofactor-less key proteins in redox regulation and provide electrons to many essential cellular processes such as DNA synthesis. 55 years after its discovery, we show that mammalian thioredoxin 1 coordinates an iron-sulfur cluster using one of its active site cysteinyl residues and a non-conserved additional cysteinyl residue located outside the active site. This particular residue co-evolved with the vertebratespecific iron regulatory system. Our study demonstrates that this system is regulated by thioredoxin 1 at the level of the iron-regulatory protein 1, thus linking redox and iron homeostases.