Contributions of the interdomain loop, amino terminus, and subunit interface to the ligand-facilitated dimerization of neurophysin: crystal structures and mutation studies of bovine neurophysin-I.

Current evidence indicates that the ligand-facilitated dimerization of neurophysin is mediated in part by dimerization-induced changes at the hormone binding site of the unliganded state that increase ligand affinity. To elucidate other contributory factors, we investigated the potential role of neurophysin's short interdomain loop (residues 55-59), particularly the effects of loop residue mutation and of deleting amino-terminal residues 1-6, which interact with the loop and adjacent residues 53-54. The neurophysin studied was bovine neurophysin-I, necessitating determination of the crystal structures of des 1-6 bovine neurophysin-I in unliganded and liganded dimeric states, as well as the structure of its liganded Q58V mutant, in which peptide was bound with unexpectedly increased affinity. Increases in dimerization constant associated with selected loop residue mutations and with deletion of residues 1-6, together with structural data, provided evidence that dimerization of unliganded neurophysin-I is constrained by hydrogen bonding of the side chains of Gln58, Ser56, and Gln55 and by amino terminus interactions, loss or alteration of these hydrogen bonds, and probable loss of amino terminus interactions, contributing to the increased dimerization of the liganded state. An additional intersubunit hydrogen bond from residue 81, present only in the liganded state, was demonstrated as the largest single effect of ligand binding directly on the subunit interface. Comparison of bovine neurophysins I and II indicates broadly similar mechanisms for both, with the exception in neurophysin II of the absence of Gln55 side chain hydrogen bonds in the unliganded state and a more firmly established loss of amino terminus interactions in the liganded state. Evidence is presented that loop status modulates dimerization via long-range effects on neurophysin conformation involving neighboring Phe22 as a key intermediary.

NMR investigation of main-chain dynamics of the H80E mutant of bovine neurophysin-I: demonstration of dimerization-induced changes at the hormone-binding site.

Neurophysins are hormone-binding proteins composed of two partially homologous domains. Ligand-binding (localized to the amino domain) and dimerization (involves both domains) are cooperatively linked by an as yet undefined allosteric mechanism. To help define this mechanism, we investigated the backbone dynamics of the unliganded monomeric state of the H80E mutant of bovine neurophysin-I by (15)N NMR. Model-free analysis of the NMR relaxation parameters indicated significantly greater flexibility in the carboxyl domain than in the amino domain, particularly at their dimerization interface segments. Amino domain residues critical to hormone binding were highly structured, constraining potential allosteric mechanisms. Model-free analysis additionally demonstrated chemical exchange effects, manifest as R(ex) terms, in 16 residues, 14 of which are located in the amino domain at, or immediately adjacent to, either the dimerization interface or the hormone-binding site. The chemical exchange process was further characterized using relaxation-compensated CPMG measurements, the results allowing assignment of the process to monomer-dimer exchange and calculation of the exchange kinetics, which were slow on the NMR time scale. An apparently different concentration-dependent process, distinguished from normal dimerization by its fast exchange behavior and pH-independence, also principally involved a subset of residues at and immediately adjacent to either the hormone-binding site or the amino domain dimerization interface. The data represent the first direct demonstration of an effect of dimerization in the unliganded state on neurophysin's hormone-binding site, the effect particularly involving residues that interact with hormone residue 2, and specifically identify Ser25 and Ile26 as likely intermediaries between the sites of dimerization and of hormone binding. Consistent with recent views of the role of anchor residues in protein interactions, we propose that dimerization proceeds by a fast pH-independent association of the well-structured amino domain interface that is rapidly communicated to the binding site for hormone residue 2, followed by a rate-determining pH-dependent interaction of the less structured carboxyl domain interface.

Properties of human vasopressin precursor constructs: inefficient monomer folding in the absence of copeptin as a potential contributor to diabetes insipidus.

These studies were aimed at an initial characterization of the human vasopressin precursor and the evaluation of factors leading to misfolding by the pathological 87STOP mutation. This mutation deletes the precursor's glycosylated copeptin segment, which has been considered unnecessary for folding, and the last seven neurophysin residues. We investigated the role in folding of the last seven neurophysin residues by comparing the properties of the 87STOP precursor and its derivative neurophysin with those of the corresponding wild-type proteins from which copeptin had been deleted, leading to the following conclusions. First, despite modulating effects on several protein properties, the last seven neurophysin residues do not make a significant net thermodynamic contribution to precursor folding; stabilities of the mutant and wild-type precursors to both guanidine denaturation and redox buffer unfolding are similar, as are in vitro folding rates. Second, the monomeric forms of both precursors are unstable and predicted to fold inefficiently at physiological pH and temperature, as evidenced by precursor behavior in redox buffers and by thermodynamic calculations. Third, both precursors are significantly less stable than the bovine oxytocin precursor. These results, together with earlier studies elsewhere of vasopressin precursor behavior within rat neurons, are shown to represent a self-consistent argument for a role for glycosylated copeptin in vasopressin precursor folding in vivo, copeptin most probably assisting refolding by facilitating interaction of misfolded monomers with the calnexin/calreticulin system. This hypothesis provides an explanation for the absence of copeptin in the more stable oxytocin precursor and suggests that the loss of copeptin contributes to 87STOP pathogenicity. Reported cell culture studies of rat precursor folding are also discussed in this context. Most generally, the results emphasize the significance of monomer stability in the folding pathways of oligomeric proteins.

NMR analysis of the monomeric form of a mutant unliganded bovine neurophysin: comparison with the crystal structure of a neurophysin dimer.

Determination of the structure of the unliganded monomeric state of neurophysin is central to an understanding of the allosteric relationship between neurophysin peptide-binding and dimerization. We examined this state by NMR, using the weakly dimerizing H80E mutant of bovine neurophysin-I. The derived structure, to which more than one conformer appeared to contribute, was compared with the crystal structure of the unliganded des 1-6 bovine neurophysin-II dimer. Significant conformational differences between the two proteins were evident in the orientation of the 3,10 helix, in the 50-58 loop, in beta-turns, and in specific intrachain contacts between amino- and carboxyl domains. However, both had similar secondary structures, in independent confirmation of earlier circular dichroism studies. Previously suggested interactions between the amino terminus and the 50-58 loop in the monomer were also confirmed. Comparison of the observed differences between the two proteins with demonstrated effects of dimerization on the NMR spectrum of bovine neurophysin-I, and preliminary investigation of the effects of dimerization on H80E spectra, allowed tentative distinction between the contributions of sequence and self-association differences to the difference in conformation. Regions altered by dimerization encompass most binding site residues, providing a potential explanation of differences in binding affinity between the unliganded monomeric and dimeric states. Differences between monomer and dimer states in turns, interdomain contacts, and within the interdomain segment of the 50-58 loop suggest that the effects of dimerization on intrasubunit conformation reflect the need to adjust the relative positions of the interface segments of the two domains for optimal interaction with the adjacent subunit and/or reflect the dual role of some residues as participants both at the interface and in interdomain contacts.