Catecholamine storage vesicle protein expression in genetic hypertension.

Chromogranin A expression is heritable in humans, and both plasma chromogranin A concentration and its releasable adrenal and sympathetic neuronal pools are augmented in established essential (hereditary) hypertension. To evaluate chromogranin A further as a simpler or "intermediate phenotype" in the complex trait of hypertension, we studied chromogranin A expression in the spontaneously hypertensive rat (SHR), a rodent model of essential hypertension. Both plasma (p < 0.0001) and adrenal medullary (p = 0.003 to p < 0.0001) chromogranin A were elevated in the SHR, even at the earliest stages (3-4 weeks of age). In the adult adrenal gland, both chromogranin A (p=0.005) and norepinephrine (p=0.011) were increased in the SHR, while dopamine beta-hydroxylase activity was diminished (p < 0.0001). Chromogranin A mRNA expression was also elevated in the SHR adrenal medulla (p = 0.017). Differences in chromogranin A processing were not noted between SHR and Wistar Kyoto control (WKY) rats. In an SHR x WKY genetic intercross, control of the adrenal chromogranin A phenotype by a single major locus was suggested by comparison of phenotypic variance of the F2 vs F1 generations, and by bimodal frequency histogram (3:1 ratio), confirmed by maximum likelihood analysis (chi2 = 74.6, p < 0.000001) in the F2 generation. However, microsatellite alleles at a surrogate locus (Ighe) 12.7 cM from chromogranin A (Chga), on rat chromosome 6, failed to co-segregate with blood pressure in an F2 generation (F = 0.06, p = 0.94). In another rodent model of hereditary hypertension, the genetically hypertensive mouse (BPH/2), adrenal chromogranin A (p=0.018) and norepinephrine (p = 0.004) were actually diminished. We conclude that over-expression of chromogranin A is a variable feature of mammalian genetic hypertension. In one rodent model (the SHR), over-expression of chromogranin A is largely controlled by a single genetic locus, but the chromogranin A locus itself is not directly linked to determination of the blood pressure elevation of the SHR.

Chromogranin A in human hypertension. Influence of heredity.

Multiple heritable traits are associated with essential (genetic) hypertension in humans. Because chromogranin A is increased in both human and rodent genetic hypertension, we examined the influence of heredity and blood pressure on chromogranin A in humans. In estimates derived from among- and within-pair variance in monozygotic versus dizygotic twins, plasma chromogranin A displayed significant (F15,18 = 2.93, P = .016) genetic variance (sigma 2 g), and its broad-sense heritability was high (h2B = 0.983). Plasma chromogranin A was increased in essential hypertension (99.9 +/- 6.7 versus 62.8 +/- 4.7 ng/mL, P < .001) but was influenced little by genetic risk for (family history of) hypertension (in normotensive or hypertensive subjects), by race, or by several antihypertensive therapies (angiotensin-converting enzyme inhibitor, diuretic, or beta-adrenergic antagonist). In normotensive subjects at genetic risk for essential hypertension, neither basal nor sympathoadrenal stress-evoked chromogranin A differed from values found in subjects not at risk. In established essential hypertension, plasma chromogranin A responses to adrenal medullary (insulin-evoked hypoglycemia) or sympathetic neuronal (dynamic exercise) activation were exaggerated, whereas responses to sympathoadrenal suppression (ganglionic blockade) were diminished, suggesting increased vesicular stores of chromogranin A and an adrenergic origin of the augmented chromogranin A expression in this disorder. We conclude that plasma chromogranin A displays substantial heritability and is increased in established essential hypertension. Its elevation in established hypertension is associated with evidence of increased vesicular stores of the protein and with adrenergic hyperactivity but is influenced little by customary antihypertensive therapies. However, the chromogranin A elevation is not evident early in the course of genetic hypertension.

Nephrogenic ascites: a poorly understood syndrome.

Nephrogenic ascites is a condition characterized by the presence of massive ascites in a patient with ESRD. Neither the exact cause nor the pathogenesis of ascites formation is clearly understood. Patients frequently present with hypertension, moderate to massive ascites, minimal extremity edema, cachexia, and a history of dialysis-associated hypotension. The ascitic fluid is typically an exudate. Although treatment options are limited, continuous ambulatory peritoneal dialysis, peritoneovenous shunt placement, and renal transplantation appear to be effective in controlling ascites formation. Nephrogenic ascites is associated with a grave prognosis, especially if treatment is not instituted. One patient with nephrogenic ascites is described here.

Sympatho-adrenal secretion in humans: factors governing catecholamine and storage vesicle peptide co-release.

1. In postganglionic sympathetic neurones and adrenal chromaffin cells, catecholamines are co-stored in vesicles with soluble peptides, including chromogranin A (CgA) and neuropeptide Y (NPY), which are subject to exocytotic co-release with catecholamines. 2. Plasma catecholamine, CgA and NPY responses to stimulators and inhibitors of sympatho-adrenal catecholamine storage and release were measured in humans. Short-term, high-intensity dynamic exercise, prolonged low-intensity dynamic exercise, and assumption of the upright posture, in decreasing order of potency, predominantly stimulated noradrenaline (NA) release from sympathetic nerve endings. Only high-intensity exercise elevated CgA and NPY, which did not peak until 2 min after exercise cessation. Stimulated NA correlated with plasma CgA 2 min after exercise, and with NPY 5 min after exercise. 3. Insulin-evoked hypoglycaemia and caffeine ingestion, in decreasing order of potency, predominantly stimulated adrenaline (AD) release from the adrenal medulla. During insulin hypoglycaemia AD and CgA rose, but NPY was unchanged. Neither NPY nor CgA were altered by caffeine. The rise in CgA after intense adrenal medullary stimulation was greater than its rise after intense sympathetic neuronal stimulation (1.4-versus 1.2-fold, respectively). 4. Infusion of tyramine, which disrupts sympathetic neuronal vesicular NA storage, elevated systolic blood pressure and NA, while NPY and CgA were unchanged. After reserpine, another disruptor of neuronal NA storage, NA transiently rose and then fell; NPY and CgA were unaltered. After the non-exocytotic adrenal medullary secretory stimulus glucagon. AD rose while NA, CgA and NPY did not change. After amantadine, an inhibitor of protein endocytosis, both CgA and fibrinogen rose, while NA and NPY remained unaltered. Neither CgA, NPY, nor catecholamines were altered by the catecholamine uptake and catabolism inhibitors desipramine, cortisol, and pargyline. 5. Human sympathetic nerve contained a far higher ratio of NPY to catecholamines than human adrenal medulla, while adrenal medulla contained far more CgA than sympathetic nerve. 6. It is concluded that peptides are differentially co-stored with catecholamines, with greater abundance of CgA in the adrenal medulla and NPY in sympathetic nerve. Activation of catecholamine release from either the adrenal medulla or sympathetic nerves, therefore, results in quite different changes in plasma concentrations of the catecholamine storage vesicle peptides CgA and NPY. Only profound, intense stimulation of chromaffin cells or sympathetic axons measurably perturbs plasma CgA or NPY concentration; lesser degrees of stimulation perturb plasma catecholamines only. Neither CgA nor NPY are released during non-exocytotic catecholamine secretion.

Does chromostatin influence catecholamine release or blood pressure in vivo?

Although the structure of chromogranin A (CgA) is now known, its ultimate physiological role remains elusive. Recently, an interior fragment of CgA [CgA(124-143)], also called chromostatin, was reported to suppress catecholamine release from chromaffin cells in vitro. We therefore explored chromostatin's biological actions when administered in vivo to anesthetized rodents with normal (Wistar-Kyoto rats) or elevated blood pressure (spontaneously hypertensive rats). Neither mean arterial pressure nor plasma epinephrine concentrations were significantly altered following either chromostatin or vehicle administration. Plasma norepinephrine, on the other hand, tended to rise throughout all studies, with the rise reaching statistical significance only in the SHR subgroup receiving chromostatin. We conclude that, unlike its actions in vitro, chromostatin does not appear to suppress catecholamine release or modulate blood pressure in vivo.

Catecholamine secretory vesicles. Augmented chromogranins and amines in secondary hypertension.

Chromogranins A and B are major soluble proteins in chromaffin granules. Their adrenomedullary content is increased in the spontaneously (genetic) hypertensive rat. Is augmented catecholamine vesicular storage of the chromogranins a specific feature of genetic hypertension? To explore this question, we measured chromogranin A immunoreactivity, using a novel, synthetic peptide radioimmunoassay, in rat adrenal medullas 4-6 weeks after induction of the two-kidney, one clip Goldblatt model of renovascular hypertension and in unmanipulated control animals. We also measured messenger RNAs of chromogranins A and B and dopamine beta-hydroxylase by Northern blot. Immunoreactive adrenal chromogranin A was 3.3-fold higher (p < 0.01) in clipped rat adrenals. Adrenal catecholamine concentrations and phenylethanolamine-N-methyltransferase activity were also higher in clipped rats. Adrenal dopamine beta-hydroxylase activity (both membrane-bound and soluble forms) and corticosterone (glucocorticoid) concentration did not significantly differ between the groups. Adrenal medullary chromogranin A messenger RNA levels in clipped rats were 3.2-fold higher (p = 0.029) than those in the control group, and chromogranin B messenger RNA levels were 4.6-fold higher (p = 0.05). Dopamine beta-hydroxylase messenger RNA levels were 2.9-fold higher (p = 0.038). Thus, augmented synthesis and storage of adrenomedullary chromogranins A and B, catecholamines, and their biosynthetic enzymes appear to be characteristic of both acquired and genetic hypertension.

Chromogranin A in neurons of the rat cerebellum and spinal cord: quantification and sites of expression.

Chromogranin A (CGA) is an abundant protein of dense-cored secretory vesicles in endocrine and neuronal cells. The present study, for the first time, compares CGA of neurons of the central nervous system with the CGA of adrenal origin. By S1 nucleus protection assay, we found that the 3' part of the CGA mRNA between exons 5-8 of the cerebellum and the spinal cord of the rat is homologous to that of the adrenal. In situ hybridization histochemistry revealed that CGA mRNA in the cerebellar cortex is present in cell bodies of Purkinje cells and in neurons of the deep cerebellar nuclei. The perikarya of these cells also exhibit CGA-like immunoreactivity. CGA mRNA and CGA-like immunoreactivity are also present in the motoneurons of the ventral, lateral, and dorsal horns of the rat spinal cord. The amounts of CGA, as determined by radioimmunoassay in cerebellum and spinal cord, were about one tenth of the amounts detected in the adrenal, adenohypophysis, or the olfactory bulb. The sites of CGA expression suggest that CGA may be involved in signal transduction in the motor system.

Ultradian variations of chromogranin A in humans.

Chromogranin A (CgA) is an acidic soluble protein exocytotically released from virtually all neuroendocrine secretory vesicles. Here we examined spontaneous variations in CgA and catecholamine concentrations in humans. In normal subjects, basal CgA showed no day-to-day, week-to-week, or diurnal variability. Plasma CgA had significant ultradian variation in normotensives and hypertensives, and in bilaterally adrenalectomized subjects. Gender, but not age or blood pressure, influenced CgA variations, males having fewer (P less than 0.05) peaks per 8 h. Plasma catecholamines had significant ultradian variations in both controls and bilaterally adrenalectomized subjects. Within individuals, neither basal nor peak plasma CgA correlated with catecholamines, nor was there concordance between plasma CgA and catecholamine peaks. Somatostatin, a widespread inhibitor of nonsympathoadrenal neuroendocrine secretion, diminished both the frequency and amplitude of plasma CgA peaks. Thus spontaneous variations in basal CgA are not directly linked to alterations in sympathoadrenal catecholamine secretion. Furthermore, neuroendocrine secretion at sites other than the sympathoadrenal system contributes to spontaneous variations in CgA concentration.

A proposed role for chromogranin A as a glucocorticoid-responsive autocrine inhibitor of proopiomelanocortin secretion.

Chromogranin A (CgA) is a 50 kilodalton (kDa) acidic glycoprotein that is costored and cosecreted from secretory granules with endogenous hormone from diverse endocrine cell types. The physiological role(s) of CgA is yet to be defined. In this study we used the AtT-20 mouse corticotropic cell line, which produces both CgA and POMC-derived peptides, to study 1) the regulation of CgA and POMC synthesis and secretion, and 2) the influence of CgA on POMC secretion. To study regulation of CgA and POMC biosynthesis and secretion, cells were treated with dexamethasone (DEX) or CRF for 48 h and CgA and POMC messenger RNAs and proteins were analyzed. Exposure to DEX for 48 h (10 nM) inhibited secretion of the 16 K fragment of POMC by 60% while stimulating CgA secretion 500% of control value. Consonant with these changes in protein, POMC mRNA levels fell to 40% of control levels while CgA mRNA levels increased to 250% of control values with DEX treatment. DEX treatment had no effect on the sizes of the CgA [2.1 kilobase (kb)] and POMC (1.0 kb) mRNAs. CRF (100 nM) stimulated secretion of both CgA (4-fold) and ACTH (2.5-fold) above basal values. By contrast, CRF increased POMC mRNA levels but had no effect on levels of CgA mRNA. Changes in total peptide production paralleled the changes in mRNA levels. Because DEX differentially regulated CgA and POMC synthesis and secretion, we questioned whether CgA could function as an autocrine inhibitor of hormone secretion. CgA inhibited CRF-stimulated secretion of 16 K fragment in a concentration-dependent manner (100% at 100 nM) without affecting basal 16 K fragment secretion. Moreover, anti-CgA antiserum, but not nonimmune serum, increased basal 16 K fragment secretion 2-fold and CRF-stimulated 16 K fragment secretion 1.5-fold. These results suggest that CgA plays an autocrine role as a glucocorticoid responsive inhibitor of POMC-derived peptide secretion.

Suppression of chromogranin-A release from neuroendocrine sources in man: pharmacological studies.

Chromogranin-A (CgA) is an acidic soluble protein with a virtually ubiquitous occurrence in normal human neuroendocrine tissues. Of the many potential tissue sources of CgA immunoreactivity, which contribute to basal (unstimulated) circulating CgA? To explore this question we studied the effects of selective and nonselective suppression of secretion at several sites within the neuroendocrine system. Selective disruption of sympathetic outflow by trimethaphan decreased basal CgA by 25%, suggesting that sympathetic neurons contribute to circulating CgA. Plasma CgA in patients with unilateral and bilateral adrenalectomy fell within the range observed in normal subjects, weighing against the adrenal medulla as a major source of basal circulating CgA. Selective suppression of a variety of anterior and posterior pituitary cell types decreased plasma levels of the usual resident peptide hormones, but left plasma CgA unperturbed. After propranolol treatment, plasma CgA remained unaltered. Secretin suppressed plasma PTH and calcitonin, but did not alter plasma CgA levels. On the other hand, widespread nonselective suppression of a variety of neuroendocrine secretory cells by somatostatin decreased plasma CgA by 48%. Plasma catecholamines were unaltered by somatostatin infusion, suggesting that somatostatin inhibited CgA release from nonsympathoadrenal sources. During the infusion of somatostatin, the plasma epinephrine increment in response to insulin-induced hypoglycemia was maintained, and plasma CgA did not fall, nor did it rise after somatostatin cessation. Taken together, these findings suggest that somatostatin did not inhibit transport of stimulation-released CgA from the adrenal medulla to the circulation. In conclusion, although the adrenal medulla is the major tissue source of CgA immunoreactivity in man, other neuroendocrine sites, including sympathetic axons and multiple endocrine glands, appear to influence the basal circulating concentration of CgA.

Chromogranin A: posttranslational modifications in secretory granules.

The primary structure of chromogranin A indicates multiple domains which might be subject to posttranslational modification. We explored chromogranin A's proteolytic cleavage, glycosylation, and possible intermolecular disulfide links, using biochemical and cell biological approaches. Anti-chromogranin A region-specific immunoblots on chromaffin granules suggested bidirectional endoproteolytic cleavage of chromogranin A; control experiments ruled out artifactual cleavage during granule isolation or lysis. Isolation of chromogranin A-derived peptides by gel filtration chromatography or sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), followed by N-terminal amino acid sequencing, established several cleavage sites, including at least two at dibasic sites. Secretion of chromogranin A from bovine chromaffin cells did not initiate further cleavage, nor did prolonged exposure of secreted chromogranins to the secretory cells. The chromogranin A cleavage pattern was qualitatively similar in other neuroendocrine tissues, though cleavage was more complete in adrenal medullary than in anterior pituitary hormone storage vesicles, and N-terminal fragments of 45 and 55 kilodaltons were more prominent in the hypothalamus. A similar cleavage pattern was seen in human pheochromocytoma granules, as judged by chromogranin A region-specific immunoblots, fragment isolation by SDS-PAGE, and microsequencing. The presence of full-length chromogranin A as the core protein of a chromaffin granule soluble proteoglycan was suggested in bovine (but not human) chromaffin granules by glycoprotein staining, chondroitinase ABC digestion, chemical deglycosylation, and region-specific immunoblotting. Human (but not bovine) chromogranin A displayed intermolecular disulfide crosslinks on SDS-PAGE gels and immunoblotting. These results document diverse structural paths that the chromogranin A molecule may take in endocrine secretory cells after its translation.

Chromogranin A storage and secretion: sensitivity and specificity for the diagnosis of pheochromocytoma.

Chromogranin A, co-stored and co-released with catecholamines from adrenal medullary and sympathetic neuronal vesicles, is elevated in the plasma of patients with pheochromocytoma. The usefulness of the hormone in the differential diagnosis of hypertension is examined. An elevated level of chromogranin A had comparable diagnostic sensitivity (83%, 24/29) to, but greater diagnostic specificity (96%, 86/90) than the level of plasma catecholamines when subjects with pheochromocytoma (n = 29) were evaluated in comparison to several reference groups, including normotensive controls (n = 49), subjects with essential hypertension (n = 28), subjects with renovascular hypertension (n = 5), and subjects with primary aldosteronism (n = 3). Subjects with signs or symptoms suggesting pheochromocytoma, but in whom the diagnosis was ultimately ruled out (n = 5) had normal plasma levels of chromogranin A. A modest rise in chromogranin A in those with essential hypertension, and correlation of chromogranin A with diastolic blood pressure in normotensive patients and patients with essential hypertension did not impair the diagnostic usefulness of chromogranin A for pheochromocytoma. Renal failure was associated with an elevated plasma chromogranin A independently of blood pressure. Plasma chromogranin A correlated with tumor mass, tumor chromogranin A content, tumor norepinephrine content, and urinary vanillylmandelic acid excretion; it did not correlate with plasma or urinary catecholamines, nor with blood pressure in patients with pheochromocytoma. Plasma chromogranin A levels did not differ in subjects with pheochromocytoma when stratified by age, sex, tumor location, or tumor pathology. Several drugs used in the diagnosis or treatment of pheochromocytoma (clonidine, metoprolol, phentolamine, and tyramine) had little effect on plasma chromogranin A concentration. Within the pheochromocytoma, chromogranin A was localized along with catecholamines to the soluble core of chromaffin granules, where it accounted for 18 +/- 5% of vesicle soluble protein. We conclude that 1) chromogranin A emerges along with catecholamines from pheochromocytoma chromaffin granules; 2) plasma chromogranin A is a sensitive and specific diagnostic tool in evaluation of actual or suspected pheochromocytoma; 3) plasma chromogranin A predicts pheochromocytoma tumor size and overall catecholamine production; and 4) drugs commonly employed in the diagnosis or treatment of pheochromocytoma have little effect on plasma chromogranin A level, preserving the usefulness of chromogranin A in evaluating pheochromocytoma. Thus, measurement of chromogranin A provides a useful adjunct to the diagnosis of pheochromocytoma.

Neuroendocrine sources of chromogranin-A in normal man: clues from selective stimulation of endocrine glands.

Chromogranin-A (CgA), as measured in the circulation by RIA, has emerged as a useful probe of exocytotic sympathoadrenal activity in man as well as of the presence and extent of neuroendocrine neoplasia. Here we studied, using a sensitive RIA, the distribution of CgA immunoreactivity in normal human neuroendocrine tissues. Furthermore, to investigate whether these normal tissue sources measurably contribute to plasma CgA, we measured plasma CgA, catecholamine, and other polypeptide hormone responses to selective stimuli of secretion at several sites within the neuroendocrine system. Immunoreactive CgA was ubiquitous in human neuroendocrine tissues, in rank order of concentration (micrograms per g wet wt): adrenal medulla greater than pituitary greater than pancreas greater than stomach greater than small intestine (jejunoileum) greater than brain (frontal cortex) greater than parathyroid greater than thyroid. Quantitatively, neuroendocrine tissues other than the adrenal medulla possessed only 0.04-25% of the immunoreactivity found in the adrenal medulla. Insulin-induced hypoglycemia, a potent stimulus of adrenomedullary secretion, resulted in 1.7- and 14-fold rises in plasma CgA and epinephrine, respectively. However, insulin-induced hypoglycemia failed to perturb plasma CgA in three bilaterally adrenalectomized patients, suggesting that the adrenal medulla is the source of plasma CgA elevation during hypoglycemia in normal subjects. Cell type-selective secretagogue stimulation of normal endocrine secretory cells other than the adrenal medulla (pituitary, pancreas, gut, thyroid, and parathyroid) induced measurable increments in the concentrations of the resident peptide hormones, but left plasma CgA unperturbed. Nonselective stimulation of a wide variety of endocrine secretory cells with pentagastrin elevated plasma CgA 1.4-fold. However, restriction of pentagastrin's targets by coinfusion of calcium abolished the effect on plasma CgA. Hence, within the normal human neuroendocrine system, only selective stimulation of the adrenal medulla is likely to elevate plasma CgA under physiological or pharmacological circumstances. This is consistent with our finding of the adrenal medulla as the quantitatively major normal neuroendocrine tissue source of CgA immunoreactivity.

Chromogranin A. Storage and release in hypertension.

The chromogranins/secretogranins are a family of acidic, soluble proteins with widespread neuroendocrine distribution in secretory vesicles. Although the precise function of the chromogranins remains elusive, knowledge of their structure, distribution, and potential intracellular and extracellular roles, especially that of chromogranin A, has greatly expanded during recent years. Chromogranin A is coreleased with catecholamines by exocytosis from vesicles in the adrenal medulla and sympathetic nerve endings. Thus, measurement of its circulating concentration by radioimmunoassay may be a useful probe of exocytotic sympathoadrenal activity in humans, under both physiological and pathological conditions. Here, we explore the storage, structure, and function of chromogranin A, and parameters that influence its circulating levels. We have also measured plasma chromogranin A concentrations in different groups of patients with hypertension, including those with pheochromocytoma.

Is physiologic sympathoadrenal catecholamine release exocytotic in humans?

In cultured cells and isolated perfused organs, catecholamines are coreleased with chromogranin A (CgA) from adrenal chromaffin cells and sympathetic neurons. The corelease suggests that exocytosis is the mechanism of catecholamine secretion. To investigate whether physiologic catecholamine secretion is exocytotic in humans, we measured plasma norepinephrine, epinephrine, and CgA responses to differentiated stimuli of sympathoadrenal discharge. The CgA radioimmunoassay antibody recognized authentic CgA in normal human adrenal chromaffin vesicles. Insulin-induced hypoglycemia and caffeine ingestion, in decreasing order of potency, selectively stimulated epinephrine release from the adrenal medulla. During hypoglycemia, plasma levels of epinephrine and CgA rose, and peak plasma levels of epinephrine and CgA correlated, suggesting that gradations in epinephrine release represented gradations in exocytosis. However, significant increments in plasma CgA were not observed after caffeine ingestion. Furthermore, the rise of CgA levels during hypoglycemia lagged 60 minutes behind those of epinephrine. A less-pronounced temporal dissociation between CgA and epinephrine release was also shown in isolated chromaffin cells in vitro. Selective adrenal vein catheterization suggested a barrier to CgA transport across the adrenal capillary wall. Short-term, high-intensity dynamic exercise, assumption of the upright posture, prolonged low-intensity dynamic exercise, and smoking, in decreasing order of potency, stimulated norepinephrine release from sympathetic nerve endings. Only the first sympathetic neuronal stimulus resulted in significant increments in plasma CgA, increments considerably less than those attained during adrenal medullary activation by insulin hypoglycemia. During high-intensity exercise, peak plasma norepinephrine and CgA levels correlated, suggesting that gradations in norepinephrine release represented gradations in exocytosis. The human adrenal medulla was a far more prominent tissue source of CgA than human sympathetic nerves--adrenal medullary homogenates contained 97-fold more CgA (micrograms/g) than sympathetic nerve homogenates. In conclusion, catecholamine secretion during selective stimulation of either sympathetic nerves or the adrenal medulla is, at least in part, exocytotic. Furthermore, stimulation of the former results in comparatively modest changes in plasma CgA compared with changes attained during stimulation of the latter. CgA appears to be transported by a route different from that of catecholamines from adrenal medullary chromaffin cells to the circulation in vivo.

Circulating chromogranin A as a diagnostic tool in clinical chemistry.

Chromogranin A, measured in the circulation by radioimmunoassay, has emerged as a useful tool in the evaluation of exocytotic sympathoadrenal activity in man, as well as the diagnosis of the presence and extent of neuroendocrine neoplasia. Here we present current thoughts on the structure and function of chromogranin A, and describe known parameters affecting its plasma concentration.

Behaviour and hypertension: a pathophysiological puzzle.

Patients with borderline hypertension typically show enhanced sympathetic and decreased parasympathetic tone, characteristic personality traits (submissiveness, hostility) and hyperreactivity to mental stress. It has been proposed that the hypertensive personality results in a persistent 'defence reaction', enhancing sympathetic outflow from the central nervous system and reactivity to stress. But evidence from pharmacological intervention trials suggests that blood pressure reactivity is controlled independently of average baseline blood pressure. A study comparing the effects of the centrally-acting alpha 2-agonist, clonidine, and the selective beta 1-blocker, atenolol, demonstrated that both drugs had a comparable antihypertensive action on baseline blood pressure. However, neither agent affected stress responses to mental arithmetic, submaximal isometric handgrip exercise or cold pressor testing. We conclude that studies of stress reactivity, while of interest to students of circulatory control, are unlikely to yield insights into the causes of human hypertension.

Selective alpha-blockade versus angiotensin-converting enzyme inhibition as initial antihypertensive therapy. Effects on circulating lipoproteins.

This study evaluated the overall efficacy and safety of two specific vasodilators--the alpha-blocker prazosin and the angiotensin-converting enzyme inhibitor captopril--in the treatment of mild-to-moderate essential hypertension. Because the current approach to antihypertensive treatment should consider possible drug-related changes in circulating lipid fractions, the present study investigated the effects of these two drugs on lipid parameters as well. Used either as single agents or in combination with hydrochlorothiazide, both drugs effectively reduced high blood pressure. Neither drug had adverse effects on the lipid profile in general, although there were significant differences between the effects of prazosin and captopril on total cholesterol, low-density lipoprotein cholesterol, and apolipoprotein B.

Antihypertensive and hypotensive effects of atrial natriuretic factor in men.

Synthetic atrial natriuretic factor (ANF) was administered in ascending doses (0.03, 0.20, 0.45 microgram/kg/min) to eight mildly essential hypertensive men on high (200 mEq/day) or low (10 mEq/day) sodium diets. Responses of blood pressure, heart rate, urinary volume and electrolyte excretion, renin, and aldosterone were measured. For the entire group, ANF lowered blood pressure and increased heart rate during the 0.20 and 0.45 microgram/kg/min infusions, and the antihypertensive effect of the peptide persisted for at least 2 hours after the infusions ended. Four patients (2 at 0.20 microgram/kg/min and 2 at 0.45 microgram/kg/min) experienced sudden bradycardia and hypotension at the end of or shortly after completion of ANF infusion. Renal excretion of water, sodium, chloride, calcium, and phosphorus increased in a dose-dependent fashion in response to infused ANF. Patients on the 200 mEq/day sodium diet had greater increases in urinary volume (11.1 +/- 2.8 vs 3.0 +/- 2.0 ml/min; p less than 0.05), sodium (870 +/- 134 vs 303 +/- 27 microEq/min; p less than 0.05), and chloride (801 +/- 135 vs 176 +/- 75 microEq/min; p less than 0.02) compared with patients on the low sodium diet. The apparent direct suppressive effect of a 0.03 microgram/kg/min infusion of ANF on renin and aldosterone levels was overcome at higher doses by counterregulation provoked by the depressor action. Renin was slightly (-12%) suppressed during the 0.03 microgram/kg/min infusion of ANF but increased at the 0.20 (+50%) and 0.45 microgram/kg/min (+90%; p less than 0.03) rates. Aldosterone declined significantly during the 0.03 microgram/kg/min infusion (-45%; p less than 0.01) of ANF but not during the two higher dose infusions.(ABSTRACT TRUNCATED AT 250 WORDS)