Immunoactive iso-ANP/BNP in plasma, tissues and atrial granules of the rat

Identification and mapping of brain natriuretic peptide in the normal ventricular myocardium of a desert-dwelling mammalian model, the camel (Camelus dromedarius): Immunohistochemical and ultrastructural study

Brain natriuretic peptide (BNP) is mainly produced in the ventricular myocardium, where it is released into the circulation, producing rapid volume decrease by diuresis, natriuresis, and water shift into the extracellular space, and vasodilation. The dromedary camel, a mammalian model of the desert nomads, lives under unfavorable physiological stresses during thirst, starvation, desiccation, and hot climate, thus has a special demand for water homeostasis. The present studies characterized BNP in the ventricular myocardium of healthy camels, immunohistochemically with a specific antibody, and ultrastructurally identified the endocrine property of the cardiomyocytes and Purkinje fibers. The paranuclear, granular, immunoreactive material was not restricted to the cardiomyocytes, as it was also visible in the Purkinje fibers and their associated nerve varicosities. The intensity of immunoreactive BNP showed a transmural gradient from the subepicardium to the myocardium. Intense immunoreactivity was also noted among the perivascular cardiomyocytes. At the electron microscopic level, specific granules were demonstrated in the paranuclear cytosol of cardiomyocytes and Purkinje fibers. The current study provides the first immunohistochemical localization pattern of BNP in the camel myocardium and suggests a relationship between the intense subepicardial BNP-immunoexpression and a possible translocation of the active hormone to the pericardial fluid for further paracrine actions on the heart and its coronaries.

Irisin: a potentially candidate marker for myocardial infarction

Myocardial infarction (MI) causes energy depletion through imbalance between coronary blood supply and myocardial demand. Irisin produced by the heart reduces ATP production by increasing heat generation. Energy depletion affects irisin concentration in circulation and cardiac tissues, suggesting an association with MI. We examined: (1) irisin expression immunohistochemically in rat heart, skeletal muscle, kidney and liver in isoproterenol (ISO)-induced MI, and (2) serum irisin concentration by ELISA. Rats were randomly allocated into 6 groups (n=6), (i) control, (ii) ISO (1h), (iii) ISO (2h), (iv) ISO (4h), (v) ISO (6h), and (vi) ISO (24h), 200mg ISO in each case. Rats were decapitated and the blood and tissues collected for irisin analysis. Blood was centrifuged at 1792 g for 5 min. Tissues were washed with saline and fixed in 10% formalin for histology. Serum irisin levels gradually decreased from 1h to 24h in MI rats compared with controls, the minimum being at 2h, increasing again after 6h. Cardiac muscle cells, glomerular, peritubular renal cortical interstitial cells, hepatocytes and liver sinusoidal cells and perimysium, endomysium and nucleoi of skeletal muscle were irisin positive, but its synthesis decreased 1-4h after MI. At all time-points, irisin increased near myocardial connective tissue, with production in skeletal muscle, liver and kidney recovering after 6h, although slower than controls. Unique insight into the pathogenesis of MI is shown, and the gradually decrease of serum irisin might be a diagnostic marker for MI.

Natriuretic peptides in hormonal regulation of hypoxia responses

The possibility that natriuretic peptides' effects are important in hypoxia responses of vertebrates is reviewed. Both the transcription and release of natriuretic peptides are affected by oxygen tension. Furthermore, many of the effects observed in hypoxia, such as diuresis and a reduction of plasma volume, are also caused by treatment of the animal with natriuretic peptides. Also, several clinical observations about changes in natriuretic peptide levels in, e.g., sleep apnea and cyanotic congenital heart disease, are consistent with the idea that hypoxia is involved in the etiology of conditions, in which natriuretic peptide levels increase. Virtually all published information on the relationship between oxygen and natriuretic peptides is based on human studies. Because hypoxic conditions are more common in aquatic than terrestrial environments, future studies about the possible role of natriuretic peptides in hypoxia, as well as the role of hypoxia in the evolution of natriuretic peptides, including the different subtypes, should increasingly involve also aquatic organisms.

Utility of brain natriuretic peptide (BNP) measurement in cardiovascular disease

Cardiac failure is a prevalent and costly condition in Western society. The ageing of the population, together with current medical options which improve, rather than eradicate heart failure, lead to the projection that this problem will increase substantially in the foreseeable future. The availability of a simple test to assist the diagnosis and effective management of heart failure would greatly assist the clinical approach to this problem. This review examines the physiological basis for the measurement of natriuretic peptides as markers of the presence or risk of heart failure. It considers its use in the hospital and non-hospital setting and examines the cost-effectiveness of current assays. It is possible that in future natriuretic peptides may offer a form of treatment for heart failure, but this is beyond the scope of this review. Nevertheless, the review highlights the potential benefits of this group of tests in the management of heart failure.

The physiological and pathophysiological modulation of the endocrine function of the heart

Under physiological conditions, the endocrine heart contributes to the maintenance of cardiovascular homeostasis through the polypeptide hormones ANF and BNP, which are members of the natriuretic peptide (NP) family. Given that NPs are of interest from the basic and clinical points of view, the genetic expression and secretion of ANF and BNP as well as the nature of the interaction of these hormones with their receptors has been the subject of extensive studies since the discovery of ANF in 1980. Following hemodynamic overload, increased secretion of NPs by the heart can be seen. This change may occur without an increase in gene expression as observed for atrial NPs following acute volume expansion, or it can occur with an increase in both ANF and BNP gene expression in atria only as seen in mineralocorticoid escape during which it is obvious that a critical decrease in hormone stores must be reached before transcriptional activation occurs. Chronic hemodynamic pressure or volume overload results in increased expression of NPs in atria and ventricles. Under these circumstances, the increased production of BNP by hypertrophic ventricles changes the normal plasma concentration ratio of ANF to BNP, a fact that has clinical diagnostic and prognostic implications. There are exceptions to this rule: chronic, severe L-NAME hypertension, which may occur without left ventricular hypertrophy, does not cause this effect and increased ventricular NP gene expression can occur in mineralocorticoid hypertension before detectable ventricular hypertrophy. Atrial and ventricular NP gene expression appears to be under different transcriptional control because pharmacological treatments such as chronic ACE inhibition or ETA receptor blockade can reverse the increased ventricular NP expression but has no detectable effect on atrial NP gene expression. This is not unlike the myosin heavy chain switch that is observed in certain pathologies, and can be pharmacologically reversed in a manner similar to NPs in the ventricles but it does not occur in atrial muscle. These observations made in vivo or using isolated adult atria often differ strikingly from results obtained using the mixed phenotype afforded by cardiocytes in culture, indicating that the kinds of questions addressed by each approach must be judiciously chosen. G-protein coupled receptor-mediated actions of neurohumors such as endothelin and phenylephrine are normally used to stimulate NP gene expression and release in different in vitro models. The main physiological stimulus for increased ANF release, atrial muscle stretch, also appears to rely on G-protein-coupled mechanisms. Alternative agonists and receptor types at play are suggested by the finding that circulating levels of BNP are selectively increased before and during overt cardiac allograft rejection episodes in human patients. The data suggest that enhanced BNP plasma levels could form a basis for a noninvasive test for cardiac allograft rejection. However, the molecular mechanism by which expression of NPs are regulated in the transplanted heart is not well understood. Conditioned medium from mixed lymphocyte reaction cultures, considered an in vitro model of transplantation immunity, induces specific upregulation of BNP as do individual pro-inflammatory cytokines. Findings such as these suggest that the study of NPs will continue to produce a wealth of information relevant to basic and clinical scientists.Key words: atrial natriuretic factor, hypertension, hypertrophy, heart failure, cytokines.

Extraction of human alpha atrial natriuretic peptide and its physiological validation

A very sensitive and specific radioimmunoassay for human alpha atrial natriuretic peptide (hANP) and a novel extraction method for hANP, have been developed. Antiserum to hANP showed no cross-reactivity with related analogues (e.g., brain natriuretic peptide). The radioimmunoassay can detect 1.2 fmol ANP/assay tube. Using a commercially available tracer, the antiserum binds 0.7 fmol of radioligand at a final dilution of 1:96,000. Production of ANP tracer, using 125I, Iodogen and reversed-phase HPLC separation, produces two products. The first has identical properties to the commercial reagent resulting in an identical antibody titre. The second, however, is more reactive with the antiserum which can be employed at a final dilution of 1:192K. These products represent oxidised and reduced peptides, respectively, inferring that the commercial tracer is oxidised. The recovery of synthetic hANP from plasma over the range of 0-1000 ng/l through Sep-Pak C18 cartridges, using an extraction method of acetic acid-acetonitrile (4:96) was 89%. Inter- and intra-assay coefficients of variation were 9.5% and 8.2%, respectively. The radioimmunoassay was validated in man by measuring plasma ANP (ng/l) following change of posture and exercise in normal man. Plasma ANP rose from 13.2 (1.0; S.D.) to 20.1 (1.6) from supine to sitting position. Plasma ANP increased to 20.1 (1.6) at rest (sitting) to 34 (2.7) ng/l at peak of exercise, but decreased from 31.2 (2.5) to 21.4 (0.1) ng/l at 3 and 6 min after exercise, respectively. These results confirm that the assay is capable of differentiating changes of concentrations within the physiological range.

Heme oxygenase activity and immunohistochemical localization in bovine pulmonary artery and vein

Recent studies suggest that carbon monoxide (CO) derived from heme oxygenase (HO)-catalyzed metabolism of heme plays a role in the regulation of cell function and communication. In blood vessels, CO may regulate vascular smooth-muscle tone through the activation of soluble guanylyl cyclase, in a manner similar to that of nitric oxide. The objective of this study was to determine the relation between HO enzymatic activity and localization of HO protein in bovine pulmonary blood vessels. HO enzymatic activity was determined by quantitating the rate of CO formation in the microsomal fraction of homogenates of bovine pulmonary artery (BPA) and vein (BPV). HO protein was localized by immunohistochemical analysis of paraformaldehyde-fixed tissue by using polyclonal antibodies to inducible HO (HO-1) and noninducible HO (HO-2). HO enzymatic activity was measured in BPA and BPV, which correlated with the presence of HO protein. In BPA, HO enzymatic activity was found in the adventitia and medial layer; HO protein was localized in the nerves and vasa vasorum of the adventitia and was found throughout the smooth-muscle cells in the medial layer. The data clearly demonstrate the presence of HO enzymatic activity for the formation of CO in blood vessels that contain HO protein.

Expression and differential regulation of natriuretic peptides in mouse macrophages

The coexpression of the natriuretic peptides ANP, BNP and CNP as well as their differential regulation in mouse macrophages was demonstrated by quantitative PCR, HPLC analysis, and specific radioimmunoassays. Exposure of peritoneal- and bone marrow-derived macrophages to various immunomodulators revealed that bacterial LPS strikingly increases (up to 300-fold) the mRNA coding for CNP as does zymosan (up to 15-fold). In this respect, neither the phorbol ester PMA nor the glucocorticoid dexamethasone had any effect. Examination of macrophages for ANP mRNA showed a similar response to LPS and zymosan, though only a three- to sixfold increase, confirming previous data. In contrast, the concentration of mRNA coding for brain natriuretic peptide in these cells was reduced by dexamethasone (up to twofold) as well as LPS (two- to fivefold). No change was observed upon challenge with zymosan or PMA. The findings at the mRNA level are complemented by their corresponding peptide products. Incubation of macrophages with LPS resulted in a two- and fivefold elevation of intracellular ANP and CNP immunoreactivity, respectively. The amount of peptides released from cells under these conditions was found increased for ANP (threefold) and CNP (10-fold). No changes were observed for both intra- and extracellular brain natriuretic peptide. The coexpression of natriuretic peptides in macrophages as well as their different regulations by immunomodulators suggest discrete functions of these peptides within the immune system.