Structure, signaling mechanism and regulation of the natriuretic peptide receptor guanylate cyclase.

Atrial natriuretic peptide (ANP) and the homologous B-type natriuretic peptide are cardiac hormones that dilate blood vessels and stimulate natriuresis and diuresis, thereby lowering blood pressure and blood volume. ANP and B-type natriuretic peptide counterbalance the actions of the renin-angiotensin-aldosterone and neurohormonal systems, and play a central role in cardiovascular regulation. These activities are mediated by natriuretic peptide receptor-A (NPRA), a single transmembrane segment, guanylyl cyclase (GC)-linked receptor that occurs as a homodimer. Here, we present an overview of the structure, possible chloride-mediated regulation and signaling mechanism of NPRA and other receptor GCs. Earlier, we determined the crystal structures of the NPRA extracellular domain with and without bound ANP. Their structural comparison has revealed a novel ANP-induced rotation mechanism occurring in the juxtamembrane region that apparently triggers transmembrane signal transduction. More recently, the crystal structures of the dimerized catalytic domain of green algae GC Cyg12 and that of cyanobacterium GC Cya2 have been reported. These structures closely resemble that of the adenylyl cyclase catalytic domain, consisting of a C1 and C2 subdomain heterodimer. Adenylyl cyclase is activated by binding of G(s)α to C2 and the ensuing 7° rotation of C1 around an axis parallel to the central cleft, thereby inducing the heterodimer to adopt a catalytically active conformation. We speculate that, in NPRA, the ANP-induced rotation of the juxtamembrane domains, transmitted across the transmembrane helices, may induce a similar rotation in each of the dimerized GC catalytic domains, leading to the stimulation of the GC catalytic activity.

Reversibly bound chloride in the atrial natriuretic peptide receptor hormone-binding domain: possible allosteric regulation and a conserved structural motif for the chloride-binding site.

The binding of atrial natriuretic peptide (ANP) to its receptor requires chloride, and it is chloride concentration dependent. The extracellular domain (ECD) of the ANP receptor (ANPR) contains a chloride near the ANP-binding site, suggesting a possible regulatory role. The bound chloride, however, is completely buried in the polypeptide fold, and its functional role has remained unclear. Here, we have confirmed that chloride is necessary for ANP binding to the recombinant ECD or the full-length ANPR expressed in CHO cells. ECD without chloride (ECD(-)) did not bind ANP. Its binding activity was fully restored by bromide or chloride addition. A new X-ray structure of the bromide-bound ECD is essentially identical to that of the chloride-bound ECD. Furthermore, bromide atoms are localized at the same positions as chloride atoms both in the apo and in the ANP-bound structures, indicating exchangeable and reversible halide binding. Far-UV CD and thermal unfolding data show that ECD(-) largely retains the native structure. Sedimentation equilibrium in the absence of chloride shows that ECD(-) forms a strongly associated dimer, possibly preventing the structural rearrangement of the two monomers that is necessary for ANP binding. The primary and tertiary structures of the chloride-binding site in ANPR are highly conserved among receptor-guanylate cyclases and metabotropic glutamate receptors. The chloride-dependent ANP binding, reversible chloride binding, and the highly conserved chloride-binding site motif suggest a regulatory role for the receptor bound chloride. Chloride-dependent regulation of ANPR may operate in the kidney, modulating ANP-induced natriuresis.

Structure of the atrial natriuretic peptide receptor extracellular domain in the unbound and hormone-bound states by single-particle electron microscopy.

Atrial natriuretic peptide (ANP) plays a major role in blood pressure and volume regulation. ANP activities are mediated by a cell surface, single-span transmembrane receptor linked to its intrinsic guanylate cyclase activity. The crystal structures of the dimerized ANP receptor extracellular domain (ECD) with and without ANP have revealed a novel hormone-induced rotation mechanism occurring in the juxtamembrane region that appears to mediate signal transduction [Ogawa H, Qiu Y, Ogata CM & Misono KS (2004) J Biol Chem 279, 28625-28631]. However, the ECD crystal packing contains two major intermolecular contacts that suggest two possible dimer pairs: 'head-to-head' (hh) and 'tail-to-tail' (tt) dimers associated via the membrane-distal and membrane-proximal subdomains, respectively. The existence of these two potential dimer forms challenges the proposed signaling mechanism. In this study, we performed single-particle electron microscopy (EM) to determine the ECD dimer structures occurring in the absence of crystal contacts. EM reconstruction yielded the dimer structures with and without ANP in only the hh dimer forms. We further performed steady-state fluorescence spectroscopy of Trp residues, one of which (Trp74) occurs in the hh dimer interface and none of which occurs in the tt dimer interface. ANP binding caused a time-dependent decrease in Trp emission at 350 nm that was attributable to partially buried Trp74 in the unbound hh dimer interface becoming exposed to solvent water upon ANP binding. Thus, the results of single-particle EM and Trp fluorescence studies have provided direct evidence for hh dimer structures for unbound and ANP-bound receptor. The results also support the proposed rotation mechanism for transmembrane signaling by the ANP receptor.

Structural studies of the natriuretic peptide receptor: a novel hormone-induced rotation mechanism for transmembrane signal transduction.

The atrial natriuretic peptide (ANP) receptor is a single-span transmembrane receptor that is coupled to its intrinsic intracellular guanylate cyclase (GCase) catalytic activity. To investigate the mechanisms of hormone binding and signal transduction, we have expressed the extracellular hormone-binding domain of the ANP receptor (ANPR) and characterized its structure and function. The disulfide-bond structure, state of glycosylation, binding-site residues, chloride-dependence of ANP binding, dimerization, and binding stoichiometry have been determined. More recently, the crystal structures of both the apoANPR dimer and ANP-bound complex have been determined. The structural comparison between the two has shown that, upon ANP binding, two ANPR molecules in the dimer undergo an inter-molecular twist with little intra-molecular conformational change. This motion produces a Ferris wheel-like translocation of two juxtamembrane domains with essentially no change in the inter-domain distance. This movement alters the relative orientation of the two domains equivalent to counter-clockwise rotation of each by 24 degrees . These results suggest that transmembrane signaling by the ANP receptor is mediated by a novel hormone-induced rotation mechanism.

Crystal structure of hormone-bound atrial natriuretic peptide receptor extracellular domain: rotation mechanism for transmembrane signal transduction.

A cardiac hormone, atrial natriuretic peptide (ANP), plays a major role in blood pressure and volume regulation. ANP activities are mediated by a single span transmembrane receptor carrying intrinsic guanylate cyclase activity. ANP binding to its extracellular domain stimulates guanylate cyclase activity by an as yet unknown mechanism. Here we report the crystal structure of dimerized extracellular hormone-binding domain in complex with ANP. The structural comparison with the unliganded receptor reveals that hormone binding causes the two receptor monomers to undergo an intermolecular twist with little intramolecular conformational change. This motion produces a Ferris wheel-like translocation of two juxtamembrane domains in the dimer with essentially no change in the interdomain distance. This movement alters the relative orientation of the two domains by a shift equivalent to counterclockwise rotation of each by 24 degrees. These results suggest that transmembrane signaling by the ANP receptor is initiated via a hormone-induced rotation mechanism.

Constitutive activation and uncoupling of the atrial natriuretic peptide receptor by mutations at the dimer interface. Role of the dimer structure in signalling.

The crystal packing of the extracellular hormone binding domain of the atrial natriuretic peptide (ANP) receptor contains two possible dimer pairs, the head-to-head (hh) and tail-to-tail (tt) dimer pairs associated through the membrane-distal and membrane-proximal subdomains, respectively. The tt-dimer structure has been proposed previously (van den Akker, F., Zhang, X., Miyagi, M., Huo, X., Misono, K. S., and Yee, V. C. (2000) Nature 406, 101-104). However, no direct evidence is available to identify the physiological dimer form. Here we report site-directed mutagenesis studies of residues at the two alternative dimer interfaces in the full-length receptor expressed on COS cells. The Trp74 to Arg mutation (W74R) or D71R at the hh-dimer interface caused partial constitutive guanylate cyclase activation, whereas mutation F96D or H99D caused receptor uncoupling. In contrast, mutation Y196D or L225D at the tt-interface had no such effect. His99 modification at the hh-dimer interface by ethoxyformic anhydride abolished ANP binding. These results suggest that the hh-dimer represents the physiological structure. Recently, we determined the crystal structure of ANPR complexed with ANP and proposed a hormone-induced rotation mechanism mediating transmembrane signaling (H. Ogawa, Y. Qiu, C. M. Ogata, and K. S. Misono, submitted for publication). The observed effects of mutations are consistent with the ANP-induced structural change identified from the crystal structures with and without ANP and support the proposed rotation mechanism for ANP receptor signaling.

Crystallization and preliminary X-ray analysis of the atrial natriuretic peptide (ANP) receptor extracellular domain complex with ANP: use of ammonium sulfate as the cryosalt.

Atrial natriuretic peptide (ANP) plays a major role in blood pressure and volume regulation owing to its natriuretic and vasodilatory activities. The ANP receptor is a single-span transmembrane receptor coupled to its intrinsic guanylyl cyclase activity. The extracellular hormone-binding domain of rat ANP receptor (ANPR) was overexpressed by permanent transfection in CHO cells and purified. ANPR complexed with ANP was crystallized at 301 K by the hanging-drop vapor-diffusion method. The crystals were frozen in 3.4 M ammonium sulfate used as a cryoprotectant. The crystals diffracted to 3.1 A resolution using synchrotron radiation and belonged to the hexagonal space group P6(1), with unit-cell parameters a = b = 100.3, c = 258.6 A.

Natriuretic peptide receptor: structure and signaling.

The ANP receptor is a single-transmembrane sequence receptor coupled to guanylate cyclase (GCase). It belongs to a family of GCase-coupled receptors that share a common overall molecular configuration. Collectively, theses GCase-coupled receptors belong to a larger family of single-transmembrane sequence receptors that include growth hormone and cytokine receptors. The signal transduction mechanism of these receptors has not been thoroughly understood. Receptor dimerization (or oligomerization) has been suggested as the mechanism. However, at least for the ANP receptor, dimerization has been seen to occur in the absence of the ligand, suggesting that an additional, as yet unknown effect of hormone binding is responsible for receptor activation. To understand the signaling mechanism, some of the functions and subsites of the ANP receptor critical for signaling have been identified, including the binding stoichiometry, receptor self-association, the juxtamembrane hinge structure containing a signature motif critical for GCase signaling, ANP-binding site residues, chloride-dependence of ANP binding, disulfide linkages, and glycosylation structures. These structures and the functional sites have been identified in the crystal structure of dimerized recombinant extracellular domain of the ANP receptor. The intracellular domain contains a kinase-homologous domain that regulates the activity of the GCase domain responding to ANP binding and also to binding of the allosteric effector ATP. Moreover, this regulatory role of the kinase-homologous domain is modulated by its own phosphorylated state. Although considerable data have been accumulated, the mechanism of ANP receptor signaling has not been well defined. Further studies are necessary to understand how ANP binds to the receptor, what conformational effect is caused by ANP binding, how this effect is transduced across the cell membrane, and how this transmembrane effect leads to stimulation of the GCase catalytic activity.