María S. Balda

Neurogenic hypertension after depletion of norepinephrine in anterior hypothalamus induced by 6-hydroxydopamine administration into the ventral pons: Role of serotonin

Destruction of the ventral noradrenergic pathway elicited by administration of 6-hydroxydopamine (6-OHDA, 5 micrograms into each side of the ventral pons) reduced the content of norepinephrine (NE) in the anterior hypothalamus (-80%) and induced an increase in arterial blood pressure (ABP) and in heart rate. These hypertensive rats, showed hypersensitivity to the hypotensive effect of NE (0.5-2 micrograms) and clonidine (0.75-1.5 micrograms) administered into the anterior hypothalamic preoptic (AH/PO) region. Methysergide (1-2 micrograms) and, to a lesser extent, ketanserin (1-2 micrograms) administered into the anterior hypothalamic preoptic region also reduced the arterial blood pressure in these rats treated with 6-OHDA. Bilateral administration of 5,7-dihydroxytryptamine (5,7-DHT, 8 micrograms) into the median forebrain bundle decreased the content of serotonin (5-HT) in the hypothalamus (-85%) without change in arterial blood pressure but largely prevented the development of hypertension after treatment with 6-OHDA in the ventral pons. These results suggest that neurogenic hypertension is produced after the removal of NE tonic depressor activity in the anterior hypothalamus and that serotonergic mechanisms play a major role in the development of the increased arterial blood pressure in this preparation.

Thyrotropin-releasing hormone increases the number of muscarinic receptors in the lateral septal area of the rat brain

Stereotactic injection of acetylcholine (0.5-2 micrograms) into the lateral septal region of the rat brain produces a long-lasting sympathetic-mediated increase of the arterial blood pressure. This effect is mediated by muscarinic receptors since 1 microgram atropine abolishes this response. In this same brain region, TRH (0.5-4 micrograms) did not elicit any significant change in the arterial blood pressure, but potentiated the effect of acetylcholine. This phenomenon is apparently due to an increase of the number of muscarinic receptors in the lateral septal area of the rat brain.

Serotonin mediates cardiovascular responses to acetylcholine, bradykinin, angiotensin II and norepinephrine in the lateral septal area of the rat brain

The infusion of acetylcholine, bradykinin, angiotensin II, norepinephrine and serotonin into the lateral septal area produced a dose-dependent increase of arterial blood pressure and heart rate. A pattern of inhibition of these cardiovascular responses, produced by pretreatment of the lateral septal area with phentolamine, 6-hydroxydopamine, methysergide and 5,7-dihydroxytryptamine was disclosed. These results suggest that the effects of acetylcholine, bradykinin and partially of angiotensin II, depend on the release of norepinephrine and the actions of this neurotransmitter in turn depend on the integrity of the serotonergic system in the lateral septal area.

Muscarinic M1 receptors in the lateral septal area mediate cardiovascular responses to cholinergic agonists and bradykinin: supersensitivity induced by chronic treatment with atropine.

The infusion of pilocarpine, acetylcholine, bradykinin and the selective M1 muscarinic agonist McNeil-A-343 into the lateral septal area produced a dose-dependent increase of arterial blood pressure and heart rate. The M1 muscarinic agonist carbamylcholine that causes a rise in arterial blood pressure when injected into the anterior lateral ventricles did not produce any cardiovascular effects when infused into the lateral septal area. Chronic treatment with atropine induced supersensitivity to the muscarinic agonists and a significant increase in the number of muscarinic receptors. In this study bradykinin failed to produce any significant change in cardiovascular activity. Pirenzepine, a M1 muscarinic blocking agent, inhibited completely the effect of both muscarinic agonists and bradykinin on cardiovascular activity. In fact, in vitro studies shows that the displacement of the binding of [3H]QNB by pirenzepine is compatible with the presence of the M1 subtype of muscarinic receptor in the lateral septal area, where it may play a major role on cardiovascular regulation.

Circadian rhythm and neural regulation of rat pineal angiotensin converting enzyme

Angiotensin converting enzyme was detectable in rat pineal gland and exhibited a circadian rhythm in activity with maximum at the end of the light phase of daily photoperiod. Superior cervical ganglionectomy (SCGx) or exposure to light for 6 days increased enzyme activity and obliterated morning-evening differences, whereas injection of the beta-agonist isoproterenol depressed the high values observed in SCGx animals. These results indicate that angiotensin converting enzyme in the pineal gland is under negative control by the norepinephrine released from pineal sympathetic nerves.

Interaction between acetylcholine and bradykinin in the lateral septal area of the rat brain: Involvement of muscarinic receptors in cardiovascular responses

The lateral septal area was used as a model to study the interaction between acetylcholine (Ach) and bradykinin on arterial blood pressure, since both mediators are present in this region. In the lateral septal area, the administration of the peptide or Ach produced a long-lasting, sympathetic-mediated increase of arterial blood pressure which was blocked by atropine. Pretreatment of the lateral septal area with hemicholinium-3, which depletes stores of acetylcholine, partially blocked the pressor effect of bradykinin but not that of Ach. Captopril--an inhibitor of kininase II--enhanced the pressor effects of bradykinin and Ach. Synaptosomal studies showed that bradykinin increased sodium-dependent, high-affinity uptake of choline and the conversion of [3H]choline to [3H]acetylcholine. Competition experiments using the highly specific muscarinic antagonist [3H]quinuclidinyl benzilate, demonstrated that bradykinin displaced the muscarinic antagonist from its receptor-ligand complexes. These results suggest that in the lateral septal area acetylcholine and bradykinin interact in a positive feed-back which amplifies pressor responses.

Saralasin Blocks the Effect of Angiotensin II and Extracellular Fluid Saline Expansion on the Na-K-ATPase Inhibitor Release in Rats

A low molecular weight substance which behaves like ouabain as inhibitor of brain membrane Na-K-ATPase and 3H-ouabain binding was found in plasma after saline expansion of extracellular fluid or angiotensin II infusion into the third brain ventricle in the rat. Intracerebroventricular infusion of angiotensin II antagonist, saralasin, blocks the increase of the Na-K-ATPase inhibitor produced by infusion of angiotensin II into the third ventricle or extracellular fluid saline expansion.

INCREASE IN MUSCARINIC RECEPTORS IN RAT INTESTINE BY THYROTROPIN RELEASING HORMONE (TRH)

The effect of Thyrotropin Releasing Hormone (TRH) on the contractile activity elicited by acetylcholine and electric stimulation in the rat ileus terminalis was investigated. TRH did not show any intrinsic contractile activity but, after a 30 minute latency period, the peptide caused a shift to the left of the dose-response curve for both acetylcholine and electric stimulation. The binding of 3H-quinuclidinylbenzilate (3H-QNB) assayed on ileum slices disclosed that the addition of TRH increased the number of muscarinic cholinergic receptors without changes in affinity when incubation was performed at pH 7.8, but no effect TRH was demonstrated at pH 7.4. Therefore, in spite of its neural and direct actions on intestine motor activity, TRH may affect the acetylcholine induced contraction by increasing the number of muscarinic receptors at a specific pH.

Angiotensin Converting Enzyme Activity in the Amygdaloid Complex in A Neurogenic Hypertensive Model

The bilateral destruction of the ventral noradrenergic pathway induced by 6-hydroxydopamine (6-OHDA) administration into the ventral pons led to an increase in arterial blood pressure (ABP) and norepinephrine depletion in the amygdaloid complex, nucleus accumbens, septal area and olfactory bulb. Specific angiotensin converting enzyme (ACE) activity was significantly increased only in the amygdaloid complex (Control: 4.56 +/- 0.95; Vehicle: 4.08 +/- 1.07; 6-OHDA: 11.76 +/- 1.84). A significant correlation between arterial blood pressure and specific ACE activity levels in the amygdaloid complex was observed (r: 0.775; p less than 0.002). These results suggest that an increase in specific ACE activity of the amygdaloid complex after norepinephrine depletion could play a role in the development of hypertension in this model.