The N-terminus, C-terminus, and vessel dilator of the ANF prohormone are present in the urine and increase with ventricular fibrillation

The N-terminus consisting of amino acids (a.a.) 1-98 (i.e., proANF 1-98), C-terminus (i.e., ANF; a.a. 99-126) and midportion of N-terminus consisting of a.a. 31-67 (proANF 31-67; Vessel Dilator) of the 126 a.a. ANF prohormone were present in the urine in 5-to-8-fold increased concentrations versus their plasma concentrations in 6 dogs under basal conditions. With acute coronary occlusion the right atrial plasma concentrations of these peptides increased two-to-three-fold, while in the urine only proANF 31-67 increased (3.5-fold). Ventricular fibrillation caused a 4-to-10-fold increased secretion into the right atrial chamber with a simultaneous 3-to-4.7-fold increase in the urine of proANF 1-98, proANF 31-67, and ANF. This investigation demonstrates that proANF 1-98, proANF 31-67 and ANF are normally present in urine and increase in the urine with cardiac stimuli that cause their release from the heart.     

Serum-mediated enhancement of ANF accumulation in the culture medium of cardiac atriocytes

Cultured cardiac myocytes provide a useful system for investigating ANF biosynthesis and regulation. It has previously been demonstrated that the predominant form of ANF stored in and released from this myocyte model is the 17 kD prohormone, proANF. We report here that as quantitated both by radioimmunoassay and by SDS-PAGE of intrinsically labelled ANF released from these cardiocytes, the addition of serum promotes a 5-6 fold increase in ANF accumulation in the medium of these cells as compared to ANF accumulation in the presence of a defined chemical medium alone. The stimulating effect of serum is immediate and persists in a linear manner for at least 120 minutes. This effect of serum can be reproduced by the addition of albumin or other proteins to the medium but not by alterations in osmolality. Whether this phenomenon represents enhanced release of proANF or is secondary to inhibition of proANF degradation has yet to be determined.     

A two-site immunoradiometric assay of proatrial natriuretic factor. Application to tissue extracts

A "two-site" immunoradiometric assay (IRMA) was developed to specifically measure ANF (1-126), the precursor of ANF. This assay is based on the simultaneous use of antibodies against two different antigenic determinants: murine monoclonal antibody (2H2), which recognizes positions 101 through 103 of ANF, is linked to Immunobeads and employed to extract any ANF C-terminal; a second antibody, which is directed against positions 11 through 37, is radioiodinated and allows binding to any C-terminal-2H2-Immunobead material which bears the N-terminal antigenic site. A curvilinear relationship was obtained between radioactivity and the amount of proANF (1.5 to 400 fmol) added. Optimisation of IRMA was determined by the amount of 2H2-Immunobeads and labeled antibody used, incubation time as well as possible interference by both ANF (99-126) and ANF (1-98). Tissue extracts were used to validate the assay. proANF was detected in decreasing amounts in heart atria, heart ventricles, lungs, kidneys and adrenal glands. Its presence was further confirmed by reverse-phase HPLC followed by radioimmunoassay. IRMA is a simple and rapid method for the direct measurement of proANF in tissue extracts and chromatographic fractions. The presence of proANF in tissues strongly suggests local synthesis.     

Intra-atrial communication and control of atrial natriuretic factor (ANF) release

Atrial natriuretic factor (ANF) release was studied in isolated perfused atria prepared from rats. When the vein-atrial junction (VAJ) was distended with an inflatable balloon, ANF release into the perfusate was greater in intact atria than in appendectomized atria. It was concluded that distention of the VAJ causes ANF release from the atrial appendage. A cascade experiment was then prepared whereby buffer from one isolated atrium perfused a second atrium. Although the VAJ of the first atrium could be distended by balloon, the atrial appendage was ligated so ANF was not secreted into the perfusate. The second atrium was intact, but no balloon was inserted. Despite the fact that there were no changes in intraluminal pressure, ANF secretion from the second atrium increased when the VAJ of the first atrium was distended. This response was blocked by the endothelin (ET) A receptor antagonist BQ-123. However, no distention-induced changes in ET-1 levels could be found in the perfusate from the first atrium. It is proposed that, in response to changes in distention of the VAJ, ANF is released remotely from the atrial appendage. The mediator does not appear to be ET-1 itself, but rather some factor that stimulates ET-1-induced ANF release within the tissue of the atrial appendage.     

Capsaicin-sensitive neural pathway mediates atrial natriuretic factor (ANF) release in response to physiological stimuli

Increases in intravascular volume are detected by mechanoreceptors situated at the junctions of the great veins with the atria. We had previously shown that localized distension of the superior vena caval/right atrial junction, simulating increased cardiac preload, elicits release of ANF remotely from the atrial appendage. We proposed that ANF secretion is stimulated via intrinsic neural pathways running from the venoatrial junctions to the appendage. We developed a technique whereby non-adrenergic, non-cholinergic sensory nerves could be selectively destroyed in the heart of adult rats by instilling capsaicin into the pericardial space. Four days later, the animals were killed, and isolated perfused atria were prepared with small balloons positioned so that the superior vena caval/right atrial junction could be discretely stretched. Immunoreactive ANF secretion into the perfusate was measured. Although distension of the venoatrial junction increased ANF secretion from the control atria, there was no such response in the denervated atria. We conclude (A) that local application of capsaicin to the heart of adult rats induces selective functional neural deficits and (B) that information regarding distension of the junction of the great veins and the atria is normally transmitted across the atrium via these nerves to stimulate ANF secretion from peptide stores located in the atrial appendage. We propose that these pathways are crucial to ensure appropriate ANF secretion in response to an increase in circulating blood volume.     

Atrial natriuretic peptides in the heart and hemolymph of the oyster,Crassostrea virginica: A comparison with vertebrates

• 1.1. The content of atrial natriuretic peptides (ANPs) in the auricles of oysters, Crassostrea virginica, was significantly (P < 0.01) greater than in their ventricles.
• 2.2. High-performance gel permeation chromatography (HP-GPC) followed by ANF radioimmunoassay revealed two peaks in both oyster and vertebrate (rat) hearts—a major peak where the 12.6–14 kDa ANF prohormone elutes and a smaller peak where the pure human form of ANF elutes.
• 3.3. HP-GPC evaluation followed by proANF 31–67 radioimmunoassay revealed only an ANF-like prohormone while HP-GPC followed by proANF 1–30 radioimmunoassay revealed the ANF prohormone and a proANF 1–30-like peptide in oyster and rat hearts.
• 4.4. ANPs concentrations in hemolymph were 940 ± 129, 225 ± 25, and 100 ± 10 pg/ml by the proANF 1–30, proANF 31–67, and ANF radioimmunoassays, respectively.
• 5.5. Atrial natriuretic-like peptides are present in the oyster heart in molecular species similar to vertebrate species and these peptides are also present in hemolymph.

     

Effect of nitric oxide on basal and stretch-induced release of atrial natriuretic factor (ANF) from isolated perfused rat atria

We investigated the effect of the NO donor SNAP (6.7 nM) on basal and stretch-induced ANF release from isolated perfused rat atria. There was no significant difference in basal ANF secretion between the vehicle- and SNAP-infused atria (SNAP: 388+/-63 pg. 100 microl(-1), n = 13 vs. vehicle: 349+/-26 pg. 100 microl(-1), n = 5). Atrial distention caused an increase in ANF secretion in both the buffer- and SNAP-treated groups. SNAP greatly attenuated the stretch-induced increase in ANF (SNAP: 225+/-7 pg. 100 microl(-1), n = 5 vs. vehicle: 448+/-72 pg. 100 microl(-1), n = 13, P < 0.05). The compliance of atria treated with SNAP was lower than that of the vehicle-perfused atria (P < 0.05). Thus, although SNAP appeared to attenuate stretch-induced ANF secretion, there was in fact no significant difference in the ratio of Delta[ANF] to Deltaintraluminal volume (SNAP: 5.8+/-1.3 pg. 100 microl(-1). microl(-1) vs. vehicle: 8.2+/-1.4 pg. 100 microl(-1). microl(-1).). In conclusion, we found no evidence that NO alters the control of basal or stretch-induced ANF secretion. NO can however reduce ANF release by shifting the pressure-volume curve, so that a given increase in atrial pressure is associated with a smaller increase in intraluminal volume and reduced atrial distention.     

Cellular signals regulating the release of ANF.

Atrial natriuretic factor (ANF), a peptide hormone that regulates salt and water balance and blood pressure, is synthesized, stored, and secreted from mammalian myocytes. Stretching of atrial myocytes stimulates ANF secretion, but the cellular processes involved in linking mechanical distension to ANF release are unknown. We reported that phorbol esters, which mimic the action of diacylglycerol by acting directly on protein kinase C and the Ca2+ ionophore A23187, which introduces free Ca2+ into the cell, both increase basal ANF secretion in the isolated perfused rat heart. Phorbol ester also increased responsiveness to Ca2+ channel agonists, such as Bay k8644, and to agents that increase cAMP, such as forskolin and membrane-permeable cAMP analogs. In neonatal cultured rat atrial myocytes, protein kinase C activation by 12-O-tetradecanoylphorbol 13-acetate stimulated ANF secretion, whereas the release was unresponsive to changes in intracellular Ca2+. Endothelin, which stimulates phospholipase C mediated hydrolysis of phosphoinositides and activates protein kinase C, increased both basal and atrial stretch-induced ANF secretion from isolated perfused rat hearts. Similarly, phorbol ester enhanced atrial stretch-stimulated ANF secretion, while the increase in intracellular Ca2+ appeared to be negatively coupled to the stretch-induced ANF release. Finally, phorbol ester stimulated ANF release from the severely hypertrophied ventricles of hypertensive animals but not from normal rat myocardium. These results suggest that the protein kinase C activity may play an important role in the regulation of basal ANF secretion both from atria and ventricular cells, and that stretch of atrial myocytes appears to be positively modulated by phorbol esters.     

Endothelial cells stimulate ANF secretion from atrial myocytes in co-culture

Using a novel in vitro co-culture system, we investigated the possible influence of vascular endothelial cells on the secretion of atrial natriuretic factor (ANF) from atrial myocytes. Co-culture of bovine aortic endothelial cells grown on Cytodex-3 microcarrier beads with primary monolayer cultures of neonatal rat myocytes induced a 2.1-fold increase in immunoreactive ANF (irANF) in the medium, compared with irANF in medium from atrial cultures alone. This increase did not appear to be the result of processing of prohormone to more immunoreactive species, and could be inhibited by 47% with 10 microM acetylcholine. The endothelium-derived vasoconstrictor peptide, endothelin, elicited a dose-dependent increase in ANF secretion from atrial cultures, but, contrary to vasopressin, was incapable of further stimulating release from atrial-endothelial co-cultures. These experiments suggest that endothelium stimulates the release of ANF from myocytes, possibly by the action of the peptide endothelin.     

Regulation of atrial natriuretic factor-(99-126) secretion from neonatal rat primary atrial cultures by activators of protein kinases A and C

Atrial natriuretic factor (ANF) is stored in atrial myocytes as a prohormone (ANF-(1-126] and is cosecretionally processed to the circulating ANF-related peptides, ANF-(1-98) and ANF-(99-126). Recently, we have shown that the cosecretional processing of ANF can be replicated in primary cultures of neonatal rat atrial myocytes maintained under serum-free conditions and that glucocorticoids are responsible for supporting this processing activity. Activators of protein kinase C (phorbol esters and alpha-adrenergic agonists) and of protein kinase A (cAMP analogs, forskolin, and beta-adrenergic agonists) were tested for their abilities to alter the rate of ANF secretion from the primary cultures. ANF secretion was stimulated approximately 4-fold after a 1-h incubation of the cultures with the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA); maximal release occurred at about 100 nM TPA. Reversed-phase high performance liquid chromatography analysis of secreted material indicated that the cells efficiently cosecretionally processed ANF under both basal and TPA-stimulated conditions. However, incubating the cultures for more than 1 h with TPA resulted in a blunted secretory response to further TPA challenge and a 40-50% decrease in the quantity of ANF in the cells. The alpha-adrenergic receptor agonist phenylephrine was also capable of stimulating ANF secretion by about 4-fold at a half-maximal dose of about 1 microM. Phenylephrine-stimulated ANF secretion was inhibited by the alpha 1-adrenergic antagonist prazosin with half-maximal inhibition occurring at approximately 1 nM. Forskolin, 8-bromoadenosine 3':5'-cyclic monophosphate, and N6-2(1)-O-dibutyryladenosine 3':5'-cyclic monophosphate inhibited basal, TPA- and phenylephrine-stimulated ANF secretion. The beta-adrenergic agonist isoproterenol partially inhibited phenylephrine-stimulated ANF secretion with the maximal effect occurring at 1 nM. These results indicate that ANF secretion from the neonatal rat atrial cultures is enhanced by activators of protein kinase C, and decreased by activators of protein kinase A, and that these secretory effects may be mediated through the actions of alpha- and beta-adrenergic receptors, respectively.     

Atrial natriuretic factor: radioimmunoassay and effects on adrenal and pituitary glands

A simple and sensitive radioimmunoassay was developed for measurement of immunoreactive atrial natriuretic factor (IR-ANF) in rat and human plasma and in rat atria. The two atria contain about 20 micrograms ANF per rat. The right atrium contained 2.5 times more ANF than did the left. Ether anesthesia and morphine markedly increased IR-ANF in rat plasma. The concentration of IR-ANF in plasma of clinically normal human subjects was 65.3 +/- 2.5 pg/ml. Paroxysmal tachycardia and rapid atrial pacing significantly increased IR-ANF in human plasma. Two- to seven-fold higher concentrations were found in coronary sinus blood than in the peripheral circulation. In the plasma of rats and humans, circulating ANF is probably a small-molecular-weight peptide. ANF acts on the adrenal and the pituitary. ANF inhibits aldosterone secretion from rat zona glomerulosa and steroid secretion by bovine adrenal zona glomerulosa and fasciculata. ANF stimulated the basal secretion of arginine vasopressin (AVP) in vitro and inhibited KCl-stimulated release of AVP.     

Atrial natriuretic factor-like peptide and its prohormone within single cell organisms.

The present investigation was designed to determine if the atrial natriuretic peptide hormonal system is present within single cell organisms. Paramecium multimicronucleatum were examined with 3 sensitive and specific radioimmunoassays which recognize the N-terminus [amino acids 1-98; proANF(1-98)], the midportion of the N-terminus [amino acids 31-67; proANF(31-67)] and C-terminus (amino acids 99-126; ANF) of the 126 amino acid atrial natriuretic factor (ANF) prohormone. ProANF(1-98), proANF(31-67), and ANF-like peptides were all present within these unicellular organisms at concentrations of 460 +/- 19 pg/ml, 420 +/- 15 pg/ml, and 14.5 +/- 2 pg/ml, respectively. These concentrations are similar to their respective concentrations in the plasma of the rat (Rattus norvegicus). These results suggest that even single cell organisms contain the atrial natriuretic peptide-like hormonal system.     

Peptides from the N-terminus of the atrial natriuretic factor prohormone enhance guanylate cyclase activity and increase cyclic GMP levels in a wide variety of tissues

The 98 amino acid (a. a.) N-terminus of the 126 a. a. atrial natriuretic factor (ANF) prohormone contains three peptides consisting of a. a. 1–30 (proANF 1–30), a. a. 31–67 (proANF 31–67) and a. a. 79–98 (proANF 79–98) with blood pressure lowering, sodium and/or potassium excreting properties similar to atrial natriuretic factor (a. a. 99–126, C-terminus of prohormone). ProANF 1–30 and proANF 31–67 have separate and distinct receptors from ANF in both vasculature and in the kidney to help mediate the above effects. At the cellular level proANFs 1–30, 31–67, and 79–98 as well as ANF's effects are mediated by enhancement of the guanylate cyclase (EC 4.6.1.2) — cyclic GMP system in vasculature and in the kidney. These peptides from the N-terminus of the ANF prohormone circulate normally in man and in all animal species tested. The object of the present investigation was to determine if these peptides have the ability to enhance either guanylate cyclase and/or adenylate cyclase in a variety of other tissues in addition to kidney and vasculature. ProANF 1–30, proANF 31–67, proANF 79–98, and ANF all increased rat lung, liver, heart and testes, but not spleen, particulate guanylate cyclase 2- to 3-fold at their 100 nM concentrations. Dose response curves revealed that maximal stimulation of particulate guanylate cyclase activity by these newly discovered peptides was at their 1 M concentrations, with no further increase in activity above their 1 M concentrations. Half-maximal (EC₅₀) enhancement of particulate guanylate cyclase occurred at 0.15 ± 0.01, 0.3 ± 0.02, 0.5 ± 0.03, and 0.9 ± 0.03 nM for proANF 1–30, proANF 31–67, proANF 79–98 and ANF, respectively. ProANFs 1–30, 31–67, 79–98, and 99–126 (i.e., ANF) each increased cyclic GMP but not cyclic AMP levels in tissue slices of liver, lung, small intestine, heart, and testes. None of these peptides enhanced either adenylate cyclase or the soluble 100,000 G form of guanylate cyclase. The ability of these N-terminal peptides to enhance particulate guanylate cyclase activity in a wide variety of tissues suggests that they may have effects in a much wider variety of tissues than presently thought.     

Thirty years of research on atrial natriuretic factor: historical background and emerging concepts

The discovery of the natriuretic properties of atrial muscle extracts pointed to the existence of an endocrine function of the heart that is now known to be mediated by the polypeptide hormones atrial natriuretic factor (ANF) and brain natriuretic peptide (BNP). On the basis of such a finding, approximately 27 000 publications to date have described a wide variety of biological properties of the heart hormones as well as their application as therapeutic agents and biomarkers of cardiac disease. Stimulation of secretion of ANF and BNP from the atria is mediated through mechanisms involving G proteins of the G(q) or G(o) types. We showed that the latter type underlies the transduction of muscle stretch into stimulated secretion and that it is more highly abundant in atria than in ventricles. The Gα(o)()-1 subunit appears to play a key role in the biogenesis of atrial granules and in the intracellular targeting of their contents. Protein interaction studies using a yeast two-hybrid approach showed interactions between Gα(o)()-1, proANF, and the intermediate conductance, calcium-activated K(+) channel SK4. Pharmacological inhibition of this channel decreases ANF secretion. Unpublished studies using in vitro knockdowns suggest interdependency in granule protein expression levels. These studies suggest previously unknown mechanisms of intracellular targeting and secretion control of the heart hormones that may find an application in the therapeutic manipulation of circulating ANF and BNP.     

Discovery of atrial natriuretic factor in the brain: Its characterization and cardiovascular implication

1. We have devised a radioimmunoassay for atrial natriueretic factor (ANF). Its application to rat brain extract led to the discovery of ANF in the brain. In addition to the hypothalamus and the pontine medullary region, it was widely distributed. 2. ANF in the brain is stored in a low molecular weight form, in contrast to pro-ANF in the atria. Thus, the processing of pro-ANF in the bran neuronal cells is different from that in the atria. 3. ANF was found in the anterior and posterior lobes of the pituitary, the peripheral ganglia, adrenergic neurons, and the adrenal medulla. 4. Brain ANF suppressed stimulated dipsogenesis, basal and stimulated vasopressin release, and angiotensin II-stimulated pressor effects. 5. ANF in the peripheral neuronal system inhibits catecholamine synthesis and release. Thus, central ANF functions to reduce the peripheral fluid volume and vascular tone in concert with the peripheral ANF.     

Studies of ANF processing and secretion using a primary cardiocyte culture model.

In contrast to most other endocrine peptides ANF is stored in the heart as part of a larger prohormone, often called pro-ANF, yet is found in the circulation as a 28 amino acid peptide, called ANF. It has been shown that the conversion of the 126 amino acid pro-ANF to ANF occurs in the heart. This paper summarizes studies from our laboratory that have used a primary neonatal rat heart cell culture system to investigate the location and mechanism of this relatively unusual processing event. We have found that in culture the maintenance of the cells in a glucocorticoid-containing serum-free medium is required to observe processing as occurs in vivo. The cells contain the prohormone while ANF accumulates in the medium. Various experiments with protease inhibitors, pulse-chase biosynthetic labeling, incubation of cells with ANF-related peptides, and enrichment of cultures for myocytes have resulted in our conclusion that the processing of pro-ANF takes place most likely within the cardiac myocyte just prior to, but in concert with secretion. We have expanded on the use of this processing-competent atrial myocyte culture system to investigate mechanisms of stimulated ANF secretion. It has been shown that the activation of several phospholipase C-coupled receptors (e.g., alpha 1-adrenergic and endothelin receptors) produces a robust release of ANF, but only in cultures that have been maintained under appropriate conditions. Further, it is apparent that the phenylephrine- or endothelin-mediated release of ANF depends in part on influx of extracellular calcium (Ca2+o), while the remaining component of stimulated release may depend on mobilization of intracellular calcium. It also appears that these agonists produce an initial phase of stimulated release, occurring within the first 5 min of agonist exposure, independent of Ca2+o, and a sustained phase that persists as long as the agonists remain on the cells, and depends on the presence of Ca2+o and thus calcium influx. Taken together our studies indicate that the hormonal environment may be an important factor directing the development of differentiated endocrine functions by atrial myocytes and may be involved in the regulation of ANF expression, biosynthesis, and secretion.     

Proatrial natriuretic factor is phosphorylated by rat cardiocytes in culture

Proatrial natriuretic factor (proANF) is phosphorylated in primary cultures of neonatal rat cardiocytes. Rittenhouse et al. (Rittenhouse, J., Moberly, L., O'Donnell, M. E., Owen, N. E., and Marcus, F. (1986) J. Biol. Chem. 261, 7607-7610) observed that cyclic AMP-dependent protein kinase phosphorylated synthetic peptides related to atrial natriuretic factor (ANF) and that phosphorylated ANF peptides were more effective in stimulating Na/K/Cl cotransport in smooth muscle cells than nonphosphorylated forms. In our studies, rat cardiocytes in culture were incubated with [32P]orthophosphoric acid, and ANF-related peptides in cell extracts and culture media were isolated using antisera to ANF. Both atrial and ventricular cardiocytes contained and secreted phosphorylated proANF, a 126-amino acid precursor of ANF. Phosphorylated and nonphosphorylated isoforms of proANF were resolved by isoelectric focusing; approximately 35% of the proANF secreted by cardiocytes was phosphorylated. proANF is phosphorylated on a serine residue localized to a 42-amino acid tryptic fragment (proANF residues 26-67). We conclude that proANF is phosphorylated by rat cardiocytes but not within the portion of the molecule destined to become ANF (proANF residues 99-126). Phosphorylation may have a role in the cellular mechanisms of proANF storage and secretion or in the modulation of potential biological activities of the circulating amino-terminal portion of proANF.     

Calcium dependence of phenylephrine-, endothelin-, and potassium chloride-stimulated atrial natriuretic factor secretion from long term primary neonatal rat atrial cardiocytes

Since calcium is involved in both excitation-secretion and excitation-contraction coupling, it was of interest to evaluate its involvement in atrial natriuretic factor (ANF) release from atrial cardiocytes. In medium containing physiological levels of calcium (1.4 mM), the secretion of ANF from primary atrial cells was stimulated from 3- to 6-fold by a variety of agents including KCl, phenylephrine, and endothelium (ET). However, in medium containing 2 nM calcium, KCl was incapable of increasing ANF secretion above basal levels, while the stimulatory effects of phenylephrine and ET were only partially diminished. Nifedipine or verapamil could mimic the effects of the 2 nM calcium medium on KCl-, phenylephrine-, and ET-stimulated ANF secretion. Kinetic studies indicated that during the initial 5 min of ET-stimulated secretion the cells exhibited little requirement for extracellular calcium; however, the requirement was more apparent during the sustained secretion observed between 10 min and 2 h of secretagogue exposure. Additionally, the stimulation of ANF secretion by ET increased to a maximum of about 15-fold over basal by 10-min after ET application; subsequent to this time there was an apparent functional desensitization wherein the rate of secretion decreased by approximately 3-4-fold and remained at this level for the duration of secretagogue exposure up to 2 h. All forms of stimulated secretion could be inhibited through ionomycin-mediated depletion of intracellular calcium pools. Taken together, these results indicate that atrial cardiocytes require both extracellular and intracellular calcium to support maximal rates of stimulated ANF secretion, and that intracellular calcium pools may be used during the early phase of secretion, while the extracellular source of calcium may be important for the sustained phase of secretion.     

Expression, purification, and in vivo activity of atrial natriuretic factor prohormone produced in Escherichia coli

Atrial muscles of the heart are known to produce polypeptide hormones called atrial natriuretic factors (ANF) which have potent diuretic and hypotensive action. These hormones are synthesized as a larger protein precursor called pro atrial natriuretic factor or proANF which contains the biologically active ANF sequences at its C-terminus. Rat proANF (representing amino acids -1 to 128 of the coding sequence) was expressed in a soluble form in Escherichia coli. A simple purification procedure was developed which consists of boiling E. coli cell extracts in 1 M acetic acid and subjecting the supernatant to reversed-phase HPLC. The effect of intravenous administration of the purified recombinant proANF on mean arterial blood pressure was examined. The displacement dose-response curves obtained demonstrated that proANF exhibits similar, albeit less potent, physiological activity than ANF.     

Food Intake and Body Positional Change Alter the Circadian Rhythm of Atrial Natriuretic Peptides Excretion into Human Urine

The 98 amino acid (a.a.) N-terminus of the 126 a.a. atrial natriuretic factor prohormone contains two natriuretic and vasodilatory peptides consisting of a.a. 1–30 (proANF 1–30) and a.a. 31–67 (proANF 31–67). The N-terminus and C-terminus (a.a. 99–126, i.e., ANF–also a vasodilatory peptide) circulate normally in humans with a circadian peak at 04:00 h in plasma. To determine if the N-terminus and C-terminus of the ANF prohormone are present in urine and possibly have a circadian variation in urine, six healthy volunteers had urine samples hourly while awake and every 3 h during sleep for five consecutive days obtained for radioimmunoassay. The sleep-awake pattern was varied so that after 2 days of normal sleep (supine)-awake (upright) positions, these volunteers were supine from 15:00 h on the third day until 10:00 h of the fourth day. They were then upright until 19:00 h that day when they became supine again until 02:30 h, and then were upright until 10:00 h of day 5. Three radioimmunoassays that immunologically recognize (a) the whole N-terminus (i.e., amino acids 1–98), (b) the midportion of the N-terminus (amino acids 31–67), and (c) the C-terminus of the ANF prohormone were utilized. ProANF 1–98, proANF 31–67, and the ANF radioimmunoassays each detected their respective peptides in urine. A circadian peak for each of these peptides was detected at 04:00 to 05:00 h whether the person was supine or upright during the night, which were significantly (p < 0.001) higher than their concentrations in the afternoon of the previous days. Assuming a supine position during the day caused a significant (p < 0.01) two- to threefold increase in these peptides in the urine. Food intake also increased the concentrations of proANF 1–98, proANF 31–67, and ANF in urine (p < 0.001). Fluid intake when abstaining from food throughout the day lowered the concentration of these peptides in the urine. It was concluded that there is a circadian rhythm in both the N-terminus and C-terminus of the ANF prohormone excretion into urine with a peak at 04:00 h irrespective of posture, but that both posture and food and fluid intake throughout the day significantly influence the excretion of these peptides into the urine, with supine posture and food increasing their concentrations in the urine while fluid intake decreases their concentrations in the urine.