Structural basis for targeting human cancer antigen STEAP1 with antibodies

Six-transmembrane epithelial antigen of the prostate (STEAP1) is an integral membrane protein that is highly upregulated on the cell surface of several human cancers, making it a promising therapeutic target. It shares sequence homology with three enzymes (STEAP2-4) that catalyze the NADPH-dependent reduction of iron(III). However, STEAP1 lacks an intracellular NADPH-binding domain and does not exhibit cellular ferric-reductase activity. Thus, both the molecular function of STEAP1 and its role in cancer progression remain elusive. Here, we present a ~3.0 Angstrom cryo-electron microscopy structure of trimeric human STEAP1 bound to three Fab-fragments of the clinically employed antibody mAb120.545. STEAP1 adopts a reductase-like conformation and interacts with the Fabs through its extracellular helices. Enzymatic assays in human cells reveal that STEAP1 promotes iron(III) reduction when fused to the intracellular NADPH-binding domain of its family member STEAP4, implicating STEAP1 as a functional ferric reductase in STEAP hetero-trimers. Our work provides a foundation for deciphering the molecular mechanisms of STEAP1 and will be instrumental in the design of new therapeutic strategies to target STEAP1 in cancer.