Hepcidin Revisited, Disulfide Connectivity, Dynamics, and Structure

Hepcidin is a tightly folded 25-residue peptide hormone containing four disulfide bonds, which has been shown to act as the principal regulator of iron homeostasis in vertebrates. We used multiple techniques to demonstrate a disulfide bonding pattern for hepcidin different from that previously published. All techniques confirmed the following disulfide bond connectivity: Cys¹–Cys⁸, Cys³–Cys⁶, Cys²–Cys⁴, and Cys⁵–Cys⁷. NMR studies reveal a new model for hepcidin that, at ambient temperatures, interconverts between two different conformations, which could be individually resolved by temperature variation. Using these methods, the solution structure of hepcidin was determined at 325 and 253 K in supercooled water. X-ray analysis of a co-crystal with Fab appeared to stabilize a hepcidin conformation similar to the high temperature NMR structure.Regulation of iron levels is critical to the survival of species that live in an oxygen-rich environment (1). In mammals, iron homeostasis is principally regulated by hepcidin, a 25-residue peptide hormone containing a complex network of four disulfide bonds. Hepcidin was discovered by three groups investigating either novel anti-microbial peptides or iron regulation (2–4), and subsequent genetic evidence has shown that mutation of the hepcidin gene can lead to systemic iron overload or hemochromatosis (5). Similarly, mutations in upstream control proteins HFE and hemojuvelin or mutation of the gene for ferroportin, the hepcidin receptor, cause forms of hemochromatosis of varying clinical severity (6–9). Genetic studies in mice have confirmed these relationships, identifying the hepcidin pathway as a critical component in the control of iron metabolism (10–12). Dysfunction of the hepcidin pathway and the resulting iron imbalance may play a role in multiple diseases such as anemia of inflammation (13), atherosclerosis (14), and neurodegenerative disorders (15). In anemia of inflammation, suppression of hepcidin constituted a successful treatment, suggesting that it may be an appropriate therapeutic target in the treatment of disease.³The human hepcidin gene encodes an 84-residue prepropeptide that contains a 24-residue N-terminal signal peptide that is subsequently cleaved to produce pro-hepcidin. Pro-hepcidin is then processed to produce a mature 25-amino acid hepcidin that is detectable in both blood and urine. Mass spectrometry and chemical analysis have revealed that all eight cysteines in hepcidin are involved in disulfide bonds (3) suggesting a highly constrained structure containing a precise disulfide bonding pattern.The NMR solution structure of hepcidin first reported by Hunter et al. (16) revealed a compact fold with β-sheet and β-hairpin loop elements. From structure calculations and dynamic signatures in NMR spectra, the authors inferred a disulfide connectivity of Cys¹–Cys⁸, Cys²–Cys⁷, Cys³–Cys⁶,⁴ and a rare vicinal disulfide bond at Cys⁴–Cys⁵. A later study of bass hepcidin (17) determined essentially the same fold and confirmed the same disulfide connectivity. Both studies, however, were based on incomplete NMR data because the resonances from two adjacent cysteines, Cys-13 and Cys-14 of hepcidin, were not detected, presumably due to exchange broadening.Here we demonstrate a new pattern of disulfide connectivity obtained independently from chemical and spectroscopic analysis. In addition, we present the first complete solution NMR structure of hepcidin and x-ray structure of the peptide in complex with an anti-hepcidin Fab. NMR data obtained at different temperatures reveal that hepcidin exhibits significant conformational dynamics in solution, a problem that likely occluded previous NMR studies. Data presented here show that these dynamics can be almost completely resolved by temperature variation, yielding two distinct structures of hepcidin, one at 325 K and one at 253 K in supercooled water. In addition to inferring disulfide bonds from structure calculations, we present an argument based on probabilistic interpretation of NMR data, which unequivocally establishes the same connectivity as obtained from chemical analysis.Because of the complexity of the disulfide network, hepcidin production is prone to misfolding artifacts. We demonstrate this through biophysical and biological activity characterization of hepcidin samples obtained from different sources. This information is essential for establishing accurate standards for quantitation of hepcidin levels in humans. In our experience, the highest quality material appeared to be critical for the structural studies presented here.