Existence of cardiac PNMT mRNA in adult rats: elevation by stress in a glucocorticoid-dependent manner

Phenylethanolamine N-methyltransferase (PNMT) is the enzyme that synthesizes epinephrine from norepinephrine. The aim of this study was to determine potential PNMT gene expression in the cardiac atria and ventricles of adult rats and to examine whether the gene expression of this enzyme is affected by immobilization stress. PNMT mRNA levels were detected in all four parts of the heart, with the highest level in the left atrium. Both Southern blot and sequencing verified the specificity of PNMT detected by RT-PCR. Single immobilization for 2 h increased gene expression of PNMT in both atria and ventricles. In atria, this effect was clearly modulated by glucocorticoids, because either adrenalectomy or hypophysectomy prevented the increase in PNMT mRNA levels in response to immobilization stimulus. This study establishes, for the first time, that PNMT gene expression occurs in cardiac atria and also, to a small extent, in ventricles of adult rats. Immobilization stress increases gene expression in atria and ventricles. This increase requires an intact hypothalamus-pituitary-adrenocortical axis, indicating the involvement of glucocorticoids.     

Cardiac norepinephrine transporter protein expression is inversely correlated to chamber norepinephrine content

The cardiac neuronal norepinephrine (NE) transporter (NET) in sympathetic neurons is responsible for uptake of released NE from the neuroeffector junction. The purpose of this study was to assess the chamber distribution of cardiac NET protein measured using [(3)H]nisoxetine binding in rat heart membranes and to correlate NE content to NET amount. In whole mounts of atria, NET was colocalized in nerve fibers with tyrosine hydroxylase (TH) immunoreactivity. NE content expressed as micrograms NE per gram tissue was lowest in the ventricles; however, NET binding was significantly higher in the left ventricle than the right ventricle and atria (P < 0.05), resulting in a significant negative correlation (r(2) = 0.922; P < 0.05) of NET to NE content. The neurotoxin 6-hydroxydopamine, an NET substrate, reduced NE content more in the ventricles than the atria, demonstrating functional significance of high ventricular NET binding. In summary, there is a ventricular predominance of NET binding that corresponds to a high NE reuptake capacity in the ventricles, yet negatively correlates to tissue NE content.     

Protein kinase C (calcium/phospholipid-dependent protein kinase) in developing chick heart: selective localization to atrium versus ventricle and changes in activity levels during cardiogenesis

Activity levels of calcium/phospholipid-dependent protein kinase were examined in preparations of atria and ventricles from embryonic chick hearts at various stages of development. Activity of protein kinase C was much higher in atria than ventricles. Protein kinase C activity underwent a progressive increase in atria during cardiogenesis, being highest just prior to hatching, followed by a profound decrease in activity after hatching. In contrast, activity of cyclic AMP-dependent protein kinase (protein kinase A), while also higher in atria than ventricles, remained relatively constant at the developmental stages examined, likewise decreasing following hatching. These progressive changes in atrial protein kinase C activity suggest a potential regulatory role for this enzyme in cardiogenesis.     

AMP-deaminase activity in denervation atrophy of the amphibian skeletal muscle

The substrate (AMP) and co-factor (ATP)-dependent kinetic parameters of AMP-deaminase have been studied in the contralateral and denervated gastrocnemius muscles of frog, Rana hexadactyla. An increasing in apparent affinity (Km) and maximal velocity (V) were found with denervated muscle enzyme as compared to the contralateral muscle enzyme. The activation energy (delta E) values were found to be decreased on denervation suggesting increased catalytic efficiency of denervated muscle enzyme.     

Gene expression of the phenylethanolamine N-methyltransferase is differently modulated in cardiac atria and ventricles

Phenylethanolamine N-methyltransferase (PNMT) is a final enzyme in catecholamine synthesizing cascade that converts noradrenaline to adrenaline. Although most profuse in adrenal medulla, PNMT is expressed also in the heart, particularly in cardiac atria and ventricles. In atria, the PNMT mRNA is much more abundant compared to ventricles. In present study we aimed to find out whether there is a difference in modulation of the PNMT gene expression in cardiac atria and ventricles. We used three methodological approaches: cold as a model of mild stress, hypoxia as a model of cardiac ischemic injury, and transgenic rats (TGR) with incorporated mouse renin gene (mREN-2)27, to determine involvement of renin-angiotensin pathway in the PNMT gene expression. We have found that PNMT gene expression was modulated differently in cardiac atria and ventricles. In atria, PNMT mRNA levels were increased by hypoxia, while cold stress decreased PNMT mRNA levels. In ventricles, no significant changes were observed by cold or hypoxia. On the other hand, angiotensin II elevated PNMT gene expression in ventricles, but not in atria. These results suggest that PNMT gene expression is modulated differently in cardiac atria and ventricles and might result in different physiological consequences.     

Effects of postnatal growth and denervation on characteristics of the saphenous artery in SHR and WKY rats between 3 and 6 weeks of age: an in vitro study

Thigh vessels of spontaneously hypertensive (SHR) and Wistar-Kyoto (WKY) rats were unilaterally surgically denervated at 10 days of age by femoral nerve section. Denervated and contralateral control segments of saphenous arteries from 3- and 6-week-old rats were mounted in a small vessel myograph for study. Both strains showed growth changes in blood pressure, but there was no significant difference between WKY and SHR. Both strains also had significant growth changes in vessel dimensions and the in vitro measurements suggested that SHR vessels had a thicker wall. Denervation did not affect vessel size. Transmural nerve stimulation indicated loss of innervation due to the surgical procedure. In the denervated vessels, both norepinephrine (NE) and 5-hydroxytryptamine (5-HT) dose response curves were shifted to the left, indicating a postjunctional increase in sensitivity. Maximum tension developed was in the order K+ greater than 5-HT greater than NE. In comparing the two strains, vessels from 6-week-old SHR were less sensitive to 5-HT. Relaxation to acetylcholine was significantly decreased in denervated arteries from WKY, whereas in SHR the significant decrease occurred only at 3 weeks. Denervated vessels from both rat strains at 3 weeks showed greater relaxation to beta-receptor activation, but not at 6 weeks of age. Therefore, the absence of functional innervation resulted in altered function of the saphenous artery wall.     

Thyroid hormones differentially affect sarcoplasmic reticulum function in rat atria and ventricles

The present study was undertaken to compare the effects of hypothyroidism and hyperthyroidism on sarcoplasmic reticulum (SR) Ca²⁺-pump activity, together with assessment of the functional role of SR in providing activator Ca²⁺ under these altered thyroid states. In response to a shift from hypothyroid to hyperthyroid state, a 10 fold and 2 fold increase in SR Ca²⁺-pump activity in atria and ventricles, respectively, were observed. This was associated with the 8-9 fold increases in atrial contractility (+dT/dt) and relaxation (-dT/dt), but only with a 3-4 fold increase in their ventricular counterparts. Also, the recirculation fraction of activator Ca²⁺ (RFA) increased to a far greater extent in atria (4 fold) than in papillary muscles, and the relative increment in inhibition of developed tension by ryanodine became 3 times larger in atria than in papillary muscles. A positive force-frequency relationship (FFR) was observed in hypothyroid atria, whereas the hyperthyroid atria, hypothyroid and hyperthyroid papillary muscles showed a negative FFR. These results suggest the greater role of transsarcolemmal (SL) Ca²⁺ and smaller role of SR Ca²⁺ in activating contraction in hypothyroid atria compared to other preparations. Thyroid hormones decrease the contribution of SL and increase that of SR in providing activator Ca²⁺ to the greater extent in atria than in ventricles. This effect of thyroid hormones is based on larger stimulation of SR Ca²⁺-pump in atria compared to ventricles.     

Differential sialylation modulates voltage-gated Na+ channel gating throughout the developing myocardium

Voltage-gated sodium channel function from neonatal and adult rat cardiomyocytes was measured and compared. Channels from neonatal ventricles required an approximately 10 mV greater depolarization for voltage-dependent gating events than did channels from neonatal atria and adult atria and ventricles. We questioned whether such gating shifts were due to developmental and/or chamber-dependent changes in channel-associated functional sialic acids. Thus, all gating characteristics for channels from neonatal atria and adult atria and ventricles shifted significantly to more depolarized potentials after removal of surface sialic acids. Desialylation of channels from neonatal ventricles did not affect channel gating. After removal of the complete surface N-glycosylation structures, gating of channels from neonatal atria and adult atria and ventricles shifted to depolarized potentials nearly identical to those measured for channels from neonatal ventricles. Gating of channels from neonatal ventricles were unaffected by such deglycosylation. Immunoblot gel shift analyses indicated that voltage-gated sodium channel alpha subunits from neonatal atria and adult atria and ventricles are more heavily sialylated than alpha subunits from neonatal ventricles. The data are consistent with approximately 15 more sialic acid residues attached to each alpha subunit from neonatal atria and adult atria and ventricles. The data indicate that differential sialylation of myocyte voltage-gated sodium channel alpha subunits is responsible for much of the developmental and chamber-specific remodeling of channel gating observed here. Further, cardiac excitability is likely impacted by these sialic acid-dependent gating effects, such as modulation of the rate of recovery from inactivation. A novel mechanism is described by which cardiac voltage-gated sodium channel gating and subsequently cardiac rhythms are modulated by changes in channel-associated sialic acids.     

Light and electron microscopic localization of atrial natriuretic peptide in the heart of spontaneously hypertensive rat

Atrial natriuretic peptide (ANP) is a newly discovered peptide hormone present mainly in the atria. We investigated the occurrence and distribution of ANP immunoreactivity in the myocardiocytes of the ventricles of spontaneously hypertensive rats by use of immunocytochemistry at both light and electron microscopic level. ANP immunoreactivity was found in the specific granules in the cytoplasm of the cardiocytes in the subendocardium and the myocardium of the ventricles, as well as in the atria. The specific granules found in the ventricles of hypertensive rats were similar in size, shape, and ANP immunoreactive content to those in the atria. The abundance of ANP immunoreactivity in the left ventricle is greater than that in the right, and appears to increase with increasing severity of hypertension. Conversely, the overall content of ANP in the atria of hypertensive rats was decreased when compared with that in age-matched normotensive rats. The present findings indicate that ventricles may become a major source for ANP synthesis and release during hypertension, and may play important roles in cardiac endocrine pathology and cardiac hypertrophy.     

Catecholamine, dopamine-beta-hydroxylase and atrial natriuretic factor content in separate heart chambers of cardiomyopathic hamsters

Since previous investigations have suggested a relationship between atrial natriuretic factor (ANF) and dopamine-beta-hydroxylation, cardiomyopathic hamsters were studied for atrial and ventricular catecholamine (CA) and dopamine-beta-hydroxylase (D beta H) content as correlates to a parallel finding of markedly decreased atrial but increased ventricular ANF concentrations in these animals. It was noted that, with progressive cardiomyopathy, the reduced tissue norepinephrine (NE) content paralleled the declining D beta H activity in the atria. In the ventricles, however, the progressively-decreasing NE content was associated with an increase of D beta H. These data indicate that the NE depletion is mediated by different mechanisms in the ventricles and atria. They do not support a simple relationship between NE depletion and tissue D beta H activity or between the latter and tissue ANF concentrations.     

Pressor responsiveness in renal prehypertensive rabbits with a denervated kidney

Norepinephrine was infused iv at several doses into four groups of conscious rabbits (six per group), and the pressor responses were recorded. The groups were 3-day sham-operated rabbits; 3-day, two-kidney rabbits with unilateral renal artery stenosis (RAS); 3-day, two-kidney rabbits with unilateral renal denervation; and 3-day, two-kidney rabbits with unilateral renal denervation plus RAS of the denervated kidney. The rabbits with RAS of an innervated kidney and those with RAS of a denervated kidney had the same pressor responses to norepinephrine, which were greater than the pressor responses in the sham-operated rabbits or in the rabbits with a denervated kidney but without RAS. Four additional groups of similarly prepared rabbits were infused with norepinephrine at 800 ng/min/kg body wt, and mean arterial pressure and cardiac output were determined before and during norepinephrine infusion. The rabbits with RAS of an innervated or of a denervated kidney had greater increases in total peripheral resistance as well as in mean arterial pressure during norepinephrine infusion than did the two groups of rabbits without RAS. This indicated that the rabbits with RAS also had increased vascular responses to norepinephrine. The concentration of norepinephrine in six denervated kidneys was extremely low as compared to that of six innervated kidneys. Because renal denervation did not diminish pressor and vascular hyperresponsiveness in 3-day RAS rabbits, the signal that originates in the kidney following RAS and that results ultimately in pressor and vascular hyperresponsiveness is not mediated by renal nerves.     

Vagal afferent activity and renal nerve release of dopamine

To investigate the involvement of vagal afferents in renal nerve release of catecholamines, we compared norepinephrine, dopamine, and epinephrine excretion from innervated and chronically denervated kidneys in the same rat. The difference between innervated and denervated kidney excretion rates was taken as a measure of neurotransmitter release from renal nerves. During saline expansion, norepinephrine excretion from the innervated kidney was not statistically greater than from denervated kidneys. Vagotomy increased norepinephrine release from renal nerves. Thus vagal afferents participated in the suppression of renal sympathetic nerve activity during saline expansion. No significant vagal control of dopamine release by renal nerves was detected under these conditions. Bilateral carotid ligation stimulated renal nerve release of both norepinephrine and dopamine in saline-expanded rats. The effects of carotid ligation and vagotomy were not additive with respect to norepinephrine release by renal nerves. However, the baroreflex-stimulated renal nerve release of dopamine was abolished by vagotomy. Electrical stimulation of the left cervical vagus with a square wave electrical pulse (0.5 ms duration, 10 V, 2 Hz) increased dopamine excretion exclusively from the innervated kidney of hydropenic rats. No significant change in norepinephrine excretion was observed during vagal stimulation. Increased dopamine excretion during vagal stimulation was associated with a larger natriuretic response from the innervated kidney than from its denervated mate (p less than 0.05). We conclude that under appropriate conditions vagal afferents stimulate renal release of dopamine and produce a neurogenically mediated natriuresis.     

Effects of renal denervation on the renal responses of anesthetized rats to cyclohexyladenosine

In the present experiments, we tested the hypothesis that renal denervation would attenuate or abolish some of the renal effects of cyclohexyladenosine, a nonmetabolized adenosine receptor agonist. A paired design (left kidney sham-denervated or denervated versus the innervated right kidney) was used in anesthetized rats. Intravenous cyclohexyladenosine (2.3 nmol/min) reduced para-aminohippurate and inulin clearances in both denervated and sham-denervated kidneys; these effects were increased rather than decreased in denervated kidneys. Similarly, cyclohexyladenosine decreased the excretion of Na+ and K+ more in denervated than in innervated kidneys. Renal plasma flow was decreased by cyclohexyladenosine, without a corresponding increase in the arteriorenal venous difference in plasma renin concentrations, and arterial plasma renin concentration decreased in all rats given cyclohexyladenosine, suggesting inhibition of renin secretion. No differences in the latter variables were noted in denervated versus sham-denervated kidneys. Since cyclohexyladenosine produced effects in denervated kidneys which were equal to or greater than the effects in sham-denervated kidneys, it is concluded that these effects are mediated by direct actions, rather than by inhibition of transmitter release from the renal nerves.     

Potentiation of the halothane-cooling contractures of mammalian muscles by denervation

Denervation potentiated the cooling-induced contractures and the halothane-cooling contractures of isolated extensor digitorum longus and soleus muscles of the mouse. These effects were more striking in extensor digitorum longus than in soleus muscles. Significant increases in the peak amplitudes of the halothane-cooling contractures of both muscles and of the cooling contractures of soleus muscle were observed within 2 and 7 days of denervation. The potentiation of the contractures persisted for 90 days, the period of this study. Denervation (greater than 2 days) endowed extensor digitorum longus with the ability to generate cooling contractures in the absence of halothane. The rate of tension development of cooling-induced contractures in the absence or presence of halothane was significantly greater in denervated (2-90 days) than in innervated muscles. Denervation also reduced the effectiveness of procaine in inhibiting the halothane-cooling contractures. It is proposed that the potentiation of cooling-induced contractures in denervated muscles results primarily from an increase in the rate of efflux and in the quantity of Ca2+ released from the sarcoplasmic reticulum, upon cooling and (or) when challenged with halothane.     

Subcellular Ca2+ transport in different areas of dog heart

Calcium transport and ATPase activities were determined in the heavy and mitochondrial fractions isolated from the left and right atria as well as ventricles of dogs. Ultrastructural distribution of these organelles in different areas of the myocardium was also examined. Calcium binding, calcium uptake, and calcium ATPase activities of the atrial microsomes were lower than those of the ventricles. On the other hand, mitochondrial calcium binding and uptake activities in the right atrium were higher than those in other areas. The mitochondrial total ATPase activities in the atria were also higher than those in the ventricles. Mitochondrial as well as microsomal yields from ventricles were significantly higher. Size and number of mitochondria in the ventricles were greater whereas no striking difference in the distribution of sarcoplasmic reticulum was apparent in different areas of the heart. Poorly developed calcium transport functions in the atrial microsomes may be one of the factors responsible for the generation of lower contractile force in this tissue in comparison with the ventricle.     

Atrial granules in the dog heart after cardiac denervation

Summary Because the increase in sodium excretion during left atrial distension in conscious dogs is abolished after chronic cardiac denervation, we have investigated whether this is a result of the disappearance of specific atrial granules. Electron microscopy and light-microscopical and ultrastructural immunohistochemistry of canine atria show that atrial granules displaying immunoreactivity for cardiac hormones of the cardiodilatin/atrial natriuretic polypeptide (CDD/ANP) family are still present in denervated left and right atria, although reduced in quantity. It is concluded that the atrial-induced natriuresis is not only related to the existence of specific atrial granules. The functional link between atrial-induced natriuresis provoked by atrial distension and the release of atrial polypeptide hormones remains uncertain because the denervated heart can secrete CDD although the diuretic-natriuretic effect is altered.     

Differential tissue expression and developmental regulation of guanine nucleotide binding regulatory proteins and their messenger RNAs in rat heart

The expression and developmental regulation of the alpha and beta subunits of the guanine nucleotide binding regulatory proteins, Gi and Go, were examined in rat atria and ventricles. Protein levels were determined by quantitative immunoblot analysis using affinity purified monospecific antibodies. Northern blot and dot blot analyses were used to characterize and quantitate relative amounts of mRNA encoding these G protein subunits. The concentrations of Go alpha, Gi alpha, and beta subunit protein were found to be greater in adult atrial than in adult ventricular membranes (5.2-, 1.5-, and 2.8-fold, respectively). A corresponding 3.4-fold difference in Go alpha mRNA level was also observed, as well as a 1.3-fold difference in Gi alpha-3 mRNA level. No difference was seen between the amount of beta, Gi alpha-1, Gi alpha-2 mRNA in adult atria and adult ventricles. Comparison of neonatal and adult tissues revealed a developmental decrease in ventricular Gi alpha protein and Gi alpha-2 mRNA levels (70 and 47%, respectively). Developmental decreases were also observed in the amount of mRNA encoding beta and Go alpha in ventricles (47 and 61%, respectively), and beta and Gi alpha-2 in atria (40 and 36%, respectively), while a developmental increase in atrial Gi alpha-3 mRNA levels was observed (57%). These results demonstrate differences in the expression of G protein subunits in rat atria and ventricles, as well as regulation of the levels of these subunits during cardiac development.     

Dysfunction of supramedullary alpha-adrenergic mechanisms following sino-aortic denervation in Kyoto Wistar rats

Central α-adrenergic mechanisms of blood pressure regulation were investigated by injecting norepinephrine or bradykinin into the carotid input of the cross-circulated head preparations of normotensive Wistar Kyoto rats (WKY). Rats were divided into three groups: sham-operated (sham), carotid sinuses denervated (SD) and carotid sinuses and aortic nerves debuffered (SAD). Norepinephrine, 5 μg, produced vasodepression in all rats, accompanied by corresponding decreases in sympathetic nerve activity recorded in some rats. Magnitude of vasodepression was largest in SAD rats. In sham rats, bradykinin, 1 μg, produced a biphasic response:initial vasodepression followed by a sustained pressor phase. This was accompanied by corresponding changes in peripheral sympathetic nerve activity recorded in some rats. In both SAD and SD rats bradykinin-induced vasodepression was abolished, while the magnitude of the pressor phase became more prominent. The increase in the pressor phase was greater in SAD than in SD rats. In similar studies of spontaneously hypertensive rats (SHR), responses to both α-adrenergic agonist and bradykinin are augmented, suggesting a dysfunction of hypothalamic α-adrenergic mechanisms. Since in the present study it has been shown that sino-aortic denervation produces effects similar to those seen in SHR, dysfunction of buffer nerves may account for the deficient central α-adrenergic mechanisms in SHR.