The zona pellucida (ZP) domain is a bipartite protein structural element comprised of ZP-N and ZP-C regions. Most notable for its ability to mediate protein polymerization, many ZP proteins polymerize and assemble into long fibrils that form specialized extracellular matrices. Other ZP proteins (namely, betaglycan and endoglin) do not polymerize but serve as important membrane coreceptors for ligands in the transforming growth factor-β (TGF-β) superfamily. Here, we present the 2.0-Å resolution crystal structure of the betaglycan ZP-C region in combination with a downstream region known as the external hydrophobic patch (EHP). Similar to the ZP-N region, the ZP-C region also adopts an immunoglobulin-like fold, despite sharing no sequence homology and possessing different disulfide linkages. The EHP region, which was previously thought to be external to the ZP region, is integral to the ZP-C domain and corresponds to the ZP-C G strand. Our structure also indicates that the critical maturation cleavage of ZP proteins, a process that activates nascent ZP proteins for polymerization, occurs within the immunoglobulin domain at the FG loop. Nonpolymerizing ZP proteins such as betaglycan and endoglin do not contain this cleavage site. Finally, our structure suggests that the AB loop and the convex surface pocket are regions important for TGF-β ligand binding.reproductive biology | signaling | inhibin T he zona pellucida (ZP) domain is a structural element found in the extracellular region of many eukaryotic proteins (1, 2). This structural element is characterized by a set of eight highly conserved cysteines and predicted to exist as a bipartite structure corresponding to ZP-N and ZP-C regions tethered by a linker (3, 4). The crystal structure of the ZP-N region has been solved and shown to adopt an immunoglobulin-like fold (5), suggesting that the ZP-C region is likely also a distinct domain by itself and that the so-called ZP domain, the collective structural element comprised of distinct ZP-N and ZP-C domains, may be more aptly referred to as the ZP region.The ZP region is important for protein polymerization and protein-protein interactions (6, 7). Many ZP proteins polymerize to become long fibrils that form specialized extracellular matrices. The best-known example is the pericellular matrix known as zona pellucida or vitelline envelope that surrounds mammalian and nonmammalian oocytes, respectively, to ensure speciesspecific fertilization and prevent polyspermy. This matrix is composed from homologues of ZP1, ZP2, ZP3, and in some species, ZP4 proteins, all of which contain a single ZP region in the ectodomain (1). In Drosophila melanogaster, two ZP proteins, Piopio and Dumpy, contribute to the apical extracellular matrix and play crucial roles in tracheal development and tubulogenesis (8). In mammals, other well-characterized polymerizing ZP proteins include uromodulin (also known as Tamm-Horsfall protein) that likely forms the water-impermeable layer around the thick ascending loop of Henle in the kidney (9) and...
