Abstract
Six-transmembrane epithelial antigen of the prostate 3 (Steap3) is the major ferric reductase in developing erythrocytes. Steap family proteins are defined by a shared transmembrane domain that in Steap3 has been shown to function as a transmembrane electron shuttle, moving cytoplasmic electrons derived from NADPH across the lipid bilayer to the extracellular face where they are used to reduce Fe(3+) to Fe(2+) and potentially Cu(2+) to Cu(1+). Although the cytoplasmic N-terminal oxidoreductase domain of Steap3 and Steap4 are relatively well characterized, little work has been done to characterize the transmembrane domain of any member of the Steap family. Here we identify high affinity FAD and iron biding sites and characterize a single b-type heme binding site in the Steap3 transmembrane domain. Furthermore, we show that Steap3 is functional as a homodimer and that it utilizes an intrasubunit electron transfer pathway through the single heme moiety rather than an intersubunit electron pathway through a potential domain-swapped dimer. Importantly, the sequence motifs in the transmembrane domain that are associated with the FAD and metal binding sites are not only present in Steap2 and Steap4 but also in Steap1, which lacks the N-terminal oxidoreductase domain. This strongly suggests that Steap1 harbors latent oxidoreductase activity.
Highlights
Steap metalloreductases are critical to metal homeostasis and linked to multiple diseases
We found that Six-transmembrane epithelial antigen of the prostate 3 (Steap3) expression was enhanced when valproic acid was added to the transfection medium
We wished to analyze the ferric reductase activity of the bimolecular fluorescence complementation (BiFC) dimer; the Steap3.VN173 and Steap3.VC155 fusions were cloned into the pIRES dual expression vector. This ensured the presence of both constructs in each transfected cell. Using this dual expression vector, we found that the specific activity of the BiFC pair was 9.9 pmol of Fe3ϩ reduced/min/fluorescence unit, which is greater than the specific activity of cells transfected with Steap3.Venus
Summary
Steap metalloreductases are critical to metal homeostasis and linked to multiple diseases. The sequence motifs in the transmembrane domain that are associated with the FAD and metal binding sites are present in Steap and Steap and in Steap, which lacks the N-terminal oxidoreductase domain. The daily production of 200 billion erythrocytes accounts for nearly 80% of the total iron demand in humans [1] To meet this need, developing erythrocytes utilize the transferrin cycle to import iron into the cell. The transmembrane domains of the Steap, ferric reductase, and NADPH oxidase protein families place each of these within the greater “ferric reductase domain” (FRD) superfamily [9]. In this light, members of the ferric
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