D-amino acid-substituted atrial natriuretic peptide analogs reveal novel receptor recognition requirements

Discovery of O-glycans on atrial natriuretic peptide (ANP) that affect both its proteolytic degradation and potency at its cognate receptor

Atrial natriuretic peptide (ANP) is a peptide hormone that in response to atrial stretch is secreted from atrial myocytes into the circulation, where it stimulates vasodilatation and natriuresis. ANP is an important biomarker of heart failure where low plasma concentrations exclude cardiac dysfunction. ANP is a member of the natriuretic peptide (NP) family, which also includes the B-type natriuretic peptide (BNP) and the C-type natriuretic peptide. The proforms of these hormones undergo processing to mature peptides, and for proBNP, this process has previously been demonstrated to be regulated by O-glycosylation. It has been suggested that proANP also may undergo post-translational modifications. Here, we conducted a targeted O-glycoproteomics approach to characterize O-glycans on NPs and demonstrate that all NP members can carry O-glycans. We identified four O-glycosites in proANP in the porcine heart, and surprisingly, two of these were located on the mature bioactive ANP itself. We found that one of these glycans is located within a conserved sequence motif of the receptor-binding region, suggesting that O-glycans may serve a function beyond intracellular processing and maturation. We also identified an O-glycoform of proANP naturally occurring in human circulation. We demonstrated that site-specific O-glycosylation shields bioactive ANP from proteolytic degradation and modifies potency at its cognate receptor in vitro Furthermore, we showed that ANP O-glycosylation attenuates acute renal and cardiovascular ANP actions in vivo The discovery of novel glycosylated ANP proteoforms reported here significantly improves our understanding of cardiac endocrinology and provides important insight into the etiology of heart failure.

Dexamethasone-dependent modulation of cyclic GMP synthesis in podocytes

Podocytes may be direct target for glucocorticoid therapy in glomerular proteinuric disease. Permeability of podocytes largely depends on their capacity to migrate which involves the contractile apparatus in their foot processes. In this study, we examined the effect of synthetic glucocorticoid dexamethasone (DEX) on the ability of podocytes to produce cyclic guanosine monophosphate (cGMP) in the presence of vasoactive factors, atrial natriuretic peptide (ANP), nitric oxide (NO), and angiotensin II (Ang II). We investigated also the effects of cGMP and DEX on podocyte motility. Primary rat podocytes and immortalized mouse podocytes were pretreated with 1 µM DEX for 4 or 24 h. Glomerular hypertension was mimicked by subjecting the cells to mechanical stress. Total and subcellular cGMP levels were determined in podocytes incubated with 0.1 µM ANP, 1 µM S-nitroso-N-acetyl penicillamine (SNAP), and 1 µM Ang II. Cell motility was estimated by a wound-healing assay. The ANP-dependent production of cGMP increased after 4 h exposition to DEX, but was attenuated after 24 h. Adversely, a 24-h pretreatment with DEX augmented the NO-dependent cGMP synthesis. Ang II suppressed the ANP-dependent cGMP production and the effect was enhanced by DEX in mechanical stress conditions. Mechanical stress reduced total cGMP production in the presence of all stimulators, whereas extracellular to total cGMP ratio increased. 8-Br cGMP enhanced podocyte migration which was accompanied by F-actin disassembly. In the presence of DEX these effects were prevented. We conclude that DEX modulates the production of cGMP in podocytes stimulated with vasoactive factors such as Ang II, ANP, and NO, and the effect is time-dependent. cGMP increases podocyte motility, which is prevented by DEX. This mechanism may account for the antiproteinuric effect of glucocorticoids.

Biology of natriuretic peptides and their receptors

Increasing evidence suggests that natriuretic peptides (NPs) play diverse roles in mammals, including renal hemodynamics, neuroendocrine, and cardiovascular functions. Collectively, NPs are classified as hypotensive hormones; the main actions of NPs are implicated in eliciting natriuretic, diuretic, steroidogenic, antiproliferative, and vasorelaxant effects, important factors in the control of body fluid volume and blood pressure homeostasis. One of the principal loci involved in the regulatory actions of NPs is their cognate plasma membrane receptor molecules, which are activated by binding with specific NPs. Interaction of NPs with their receptors plays a central role in physiology and pathophysiology of hypertension and cardiovascular disorders. Gaining insight into the intricacies of NPs-specific receptor signaling pathways is of pivotal importance for understanding both hormone-receptor biology and the disease states arising from abnormal hormone receptor interplay. During the last decade there has been a surge in interest in NP receptors; consequently, a wealth of information has emerged concerning molecular structure and function, signaling mechanisms, and use of transgenics and gene-targeted mouse models. The objective of this present review is to summarize and document the previous findings and recent discoveries in the field of the natriuretic peptide hormone family and receptor systems with emphasis on the structure-function relationship, signaling mechanisms, and the physiological and pathophysiological significance in health and disease.

Changes in ANP responsiveness of normal and hypertensive porcine intrapulmonary arteries during maturation

Pulmonary vascular resistance falls rapidly after birth, but endothelium-dependent relaxation is relatively poor during the perinatal period. Atrial natriuretic peptide (ANP) is a potent vasodilator; however, its role in the process of perinatal adaptation is uncertain. Porcine intrapulmonary conduit arteries (IPA) from fetal, newborn (< 5 min), 3-, 6-, and 17-d-old, and adult pigs, and from piglets made hypoxic from 0 to 3, 3 to 6, or 14 to 17 d, were isolated and mounted for isometric force recording. Rings were precontracted with prostaglandin-F2 alpha (PGF2 alpha, 10 microM) or KCl (40 mM). ANP was added cumulatively (10 pM to 100 nM). C-type natriuretic peptide (CNP) was added as a single concentration of 100 nM. Accumulation of cGMP under basal conditions and stimulated by ANP or CNP was measured by radioimmunoassay system. Frozen sections of lung tissue were incubated with 125I-labeled alpha-ANP, and binding site density was assessed on IPA with an image analysis system. ANP relaxed IPA in pigs at all ages, but the effect was significantly greater at 6 and 17 d of age. Hypoxia in animals from 14 to 17 d old impaired ANP-induced relaxation. CNP relaxed IPA poorly: < 12% at all ages. ANP increased cGMP accumulation in both normal and hypoxic animals. CNP did not increase cGMP generation in IPA from normal animals but did so in IPA from 3-d-old hypoxic animals. ANP-specific binding sites were demonstrated on the pulmonary artery smooth muscle cells, with greater binding in the young animals. The increased relaxant responses to ANP during adaptation may be important in maintaining low pulmonary vascular resistance. In contrast, CNP was largely ineffective in relaxing pulmonary arteries.

Kinetic analysis of synthetic analogues of linear-epitope peptides of glycoprotein D of herpes simplex virus type 1 by surface plasmon resonance

The interaction between mAb A16 and glycoprotein D (gD) of herpes simplex virus type 1 was analyzed by studying the kinetics of binding with a surface-plasmon-resonance biosensor. mAb A16 belongs to group VII antibodies, which recognize residues 11-19 of gD. In a previous study, three critical residues, Asp13, Arg16 and Phe17, of this epitope were identified by screening a phage display library that contained a random 15-amino-acid insert with the antibody. The contribution to binding of these residues in the motif DXXRF was further analyzed by an amino-acid-replacement study of the epitope gD-(9-19)-peptide and of a gD-(9-19)-peptide mimotope, previously obtained by screening the phage display library. Amino acid residues of the motif were replaced by a neutral amino acid residue, an amino acid residue with opposite charge and a corresponding D-amino acid residue. Kinetic parameters of peptide analogues were determined with a surface plasmon-resonance biosensor. The kinetic parameters of the peptide analogues were compared with the kinetic parameters of the interaction between mAb A16 and the epitope gD-(9-19)-peptide. The minimal size of the gD epitope for mAb A16 was also determined in this study. The kinetic constants of the resulting gD-(11-17)-peptide were found to be similar to those of entire gD. The kinetic analysis precisely defined the epitope on gD for mAb A16 to residues 11-17, identified Arg16 as an essential residue and suggested that Asp13 and Phe17 are mainly involved in stabilization of the secondary structure of the peptide.

C-type natriuretic peptide

C-type natriuretic peptide is a 22-amino acid peptide that was initially identified in the central nervous system. The distribution of C-type natriuretic peptide, which has structural homology with atrial and brain natriuretic peptides, is wide and includes the endothelium, myocardium, gastrointestinal, and genitourinary tracts. The biological effects of this peptide are being elucidated in a number of sites in a number of species; however, the novel endothelial site of production of C-type natriuretic peptide and the proximal situation of its receptor in vascular smooth muscle suggest that this vascular natriuretic peptide system may play a role in concert with other local systems in the control of vascular tone.

Identification of renal natriuretic peptide receptor subpopulations by use of the non-peptide antagonist, HS-142-1

1. The renal actions of natriuretic peptides are dictated by the distribution of guanylyl cyclase-linked (NPRA and NPRB) and non-guanylyl cyclase-linked (NPRC) receptors. Natriuretic peptide receptors have previously been distinguished on the basis of their differential affinity for peptide fragments and analogues; however, most of the available ligands are not fully selective. We have used the specific guanylyl cyclase-linked receptor antagonist, HS-142-1, to investigate the differential distribution of natriuretic peptide receptor subtypes in the human, bovine and rat kidney. 2. Specific, high affinity 3-([125I]-iodotyrosyl)-rat-ANP-(1-28)([125I]-rANP1-28) binding sites were identified in all three species, localized to glomeruli, inner medulla, intrarenal arteries and regions in the outer medulla corresponding to vasa recta bundles. Binding sites were also identified in the smooth muscle lining of the hilar region in the bovine and rat kidney. 3. In the rat, [125I]-rANP1-28 binding was inhibited by unlabelled peptide sequences with a rank order of potency (rANP1-28 > pCNP1-22 > C-ANP4-23). The glomeruli exhibited a heterogeneous population of binding sites, C-ANP4-23 and pCNP1-22 producing a significantly better fit to a two component inhibition curve compared to the single component curve for rANP1-28. 4. Competitive inhibition experiments with the receptor selective ligands, C-ANP4-23 and HS-142-1, suggested that, like the rat, human and bovine glomeruli possessed a heterogeneous population of binding sites, whilst those in the inner medulla and intrarenal arteries of all three species represented a homogeneous population. Rat glomeruli exhibited a high proportion (>80%) of the NPRc receptor subtype whereas in human and bovine glomeruli this receptor represented less than 20% of the total population, the majority of binding sites being HS-142-1-sensitive.5. C-ANP4-23 exhibited a significantly higher inhibitory potency for binding sites in rat glomeruli compared to those in human and bovine kidney whilst HS-142-1 was significantly more potent in the rat and bovine kidney compared to man. No evidence was found to suggest the presence of a renal NPRBreceptor subtype.6. The relative density, affinity and proportion of natriuretic receptor subtypes in the kidney exhibit significant species differences. HS-142-1 may be a valuable tool in further elucidating the localization and function of these receptors, but heterogeneity between species should be considered when selecting experimental models.

D-Val22 containing human big endothelin-1 analog, [D-Val22]Big ET-1[16-38], inhibits the endothelin converting enzyme

Endothelin converting enzyme (ECE) is essential for generation of the biological effects of endothelin-1 (ET-1) from a precursor, big endothelin-1 (Big ET-1). We synthesized four analogs of human Big ET-1[16-38], substituted with single D-amino acids at P1, P2, P1' and P2' positions. ECE activity was determined using an ET-1 specific radioimmunoassay system. None of the D-amino acid containing Big ET-1 analogs were apparently cleaved by ECE, however, one of the synthetic peptides, [D-Val22]Big ET-1[16-38], strongly inhibited the ECE activity. Furthermore, when this D-Val22 containing peptide was preadministered to rat striatum, it was found to inhibit the dopamine release induced by Big ET-1. This result suggests that the D-Val22 containing peptide inhibits the ECE activity in vivo. The D-Val22 containing inhibitor offers hope of developing more potent and highly specific ECE inhibitors of therapeutic significance.

Pharmacological activities of brain natriuretic peptides of human, porcine and rat origin

The pharmacological activities of synthetic mammalian brain natriuretic peptides (BNP) from the human, pig and rat were examined in rats. These peptides all elicited diuresis and hypotension, relaxed isolated rat aorta, augmented cyclic GMP concentration in cultured rat vascular smooth muscle cells, and bound to the cells with a high affinity. Pig and rat BNPs were as active as atrial natriuretic peptides from the human and the rat (alpha-hANP and alpha-rANP) for the diuretic and hypotensive effects as well as for cyclic GMP augmentation, while human BNP was about 10 times less potent. Rat BNP was not as active as the other peptides in competing with the binding of [125I]alpha-hANP to rat vascular smooth muscle cells. Thus, the BNPs did not have identical pharmacological profiles although the potencies of the peptides for cyclic GMP augmentation correlated well to those for vasorelaxation.

Cyclic GMP and the second messenger hypothesis

A plasma membrane form of guanylate cyclase appears to contain a single transmembrane domain that divides the protein into a highly conserved intracellular domain and a variable extracellular domain. Various extracellular peptides can bind directly to guanylate cyclase to increase the production of the second messenger, cyclic GMP.