A putative interaction between angiotensin II (Ang II) and the sympathetic nervous system within the kidney has been reported. We tested the hypothesis in conscious rats that endogenous Ang II modulates the renal effects of a stress-induced increase in sympathetic nerve activity. We recorded mean arterial blood pressure, heart rate, renal sympathetic nerve activity, renal hemodynamics, urine volume, and urinary sodium content in conscious rats. We used the Ang II type 1 receptor blocker ZD 7155 to inhibit the effects of endogenous Ang II. Ten minutes of air-jet stress increased renal sympathetic nerve activity by 98 +/- 4% (n = 6) without changing systemic hemodynamics. Air-jet stress reduced urine volume (from 31 +/- 3 to 8 +/- 4 microL/min per gram kidney weight, P < .05, n = 12) and sodium excretion (from 4.3 +/- 0.9 to 1.2 +/- 0.3 mumol/min per gram kidney weight, P < .05, n = 12). After renal denervation, air-jet stress had no effect on either parameter. Six micrograms of the Ang II type 1 receptor inhibitor ZD 7155 blunted the decrease in urine volume and sodium excretion in response to air-jet stress, although the increase in renal sympathetic nerve activity during air-jet stress and the pressor response to exogenous Ang II were not affected. Glomerular filtration rate and renal plasma flow were also not affected. Higher doses of 30 and 60 micrograms ZD 7155 inhibited the pressor response to exogenous Ang II and abolished the changes in urine volume and sodium excretion in response to air-jet stress. None of the ZD 7155 doses affected urinary sodium excretion permanently. Hence, the Ang II type 1 receptor antagonist ZD 7155 impaired or abolished the renal nerve-mediated antinatriuresis and anitidiuresis in response to air-jet stress. We conclude that endogenous Ang II modulates the renal effects of centrally mediated changes of sympathetic nerve activity in conscious rats.
Bradykinin may be generated in the heart during ischemia and is involved in nociception. We tested the hypothesis that bradykinin elicits a sympathoexcitatory reflex in rats by stimulating cardiac afferent nerve fibers. Rats were implanted with femoral catheters for measurement of blood pressure and heart rate, a bipolar electrode for measurement of renal sympathetic nerve activity, and a pericardial catheter for intrapericardial injection of substances. Rats were slightly anesthetized with hexobarbital so pain reactions were prevented. Graded doses of bradykinin (2.5, 12, 25 micrograms) were injected intravenously or intrapericardially into control rats, intrapericardially after vagotomy, intrapericardially after intrapericardial pretreatment with the bradykinin B2 receptor antagonist Hoe 140, and intrapericardially after cardiac autonomic blockade (intrapericardial pretreatment with 10% procaine). For comparison, the serotonin 5-HT3 agonist phenylbiguanide, a substance known to elicit sympathoinhibitory reflexes by cardiac vagal afferents, and adenosine, putatively inducing sympathoexcitatory responses via the heart, were applied intrapericardially. Bradykinin increased blood pressure when administered intrapericardially but decreased blood pressure when injected intravenously; both intrapericardial and intravenous bradykinin increased renal sympathetic nerve activity. Intrapericardial adenosine had no effect on circulatory control. Intrapericardial pretreatment with the B2 receptor antagonist Hoe 140 completely inhibited the increases of blood pressure and renal sympathetic nerve activity in response to intrapericardial bradykinin but did not affect the responses to intrapericardial phenylbiguanide. Bilateral cervical vagotomy abolished the decreases of blood pressure, heart rate, and renal sympathetic nerve activity after intrapericardial phenylbiguanide but did not influence the responses to intrapericardial bradykinin. Cardiac autonomic blockade with intrapericardial procaine abolished all responses to bradykinin and phenylbiguanide. We conclude that cardiac bradykinin elicits a sympathoexcitatory reflex by epicardial B2 receptors in rats. The afferent portion of the reflex is most likely contained within sympathetic cardiac afferent fibers. Bradykinin may contribute to increased sympathetic nerve activity in pathophysiological situations of coronary artery disease and cardiac ischemia.
Cardiopulmonary reflexes with vagal afferents may control volume homeostasis by influencing renal nerve activity. Such reflexes can be stimulated mechanically and chemically, e.g., by serotonin 5-HT). We have demonstrated that stimulation of epicardial 5-HT3 receptors inhibits renal sympathetic nerve activity (RSNA) by a cardiorenal reflex. We now tested the hypothesis that pulmonary 5-HT3-sensitive vagal afferent fibers participate in the control of renal nerve activity. Two sets of experiments were performed. First, the responses of multifiber RSNA, heart rate (HR), and blood pressure (BP) to the 5-HT3-receptor agonist phenylbiguanide (PBG; 10 microg iv) were recorded in the presence of intact pulmonary afferents. Abdominal afferents were removed by subdiaphragmatic vagotomy. Cardiac afferents were blocked by intrapericardial injection of 10% procaine. Second, the responses of 25 single vagal pulmonary afferent C fibers to PBG were assessed. PBG decreased BP, HR, and RSNA (-90 +/- 8%). When cardiac afferents were blocked by procaine, BP and HR failed to decrease in response to PBG; however, the RSNA decrease was still -48 +/- 8%. Single fibers generally responded to PBG by a slight increase in firing rate. A distinct subset of fibers (5 of 25) showed an activity increase of >15 Hz that preceded changes in BP and HR. The decreased RSNA in the absence of cardiac and abdominal vagal afferents and the strong response of 20% of pulmonary single fibers to intravenous PBG suggest that pulmonary fibers play a role in a 5-HT3 serotenergic reflex. Thus pulmonary serotonin could influence the neural control of renal function.
Vagal afferent C-fibres from the heart constitute an important input to the neurogenic cardiovascular regulation. These fibres respond to altered cardiac filling pressures and to chemical stimuli. In rats, we tested whether cardiac vagal afferent C-fibres react exclusively to one stimulus (chemical or mechanical) or whether the fibres are bimodal, i.e. responsive to either kind of stimulus. As a mechanical stimulus, an indwelling balloon was inflated in the aorta to increase left ventricular end-diastolic pressure. The serotonin 5HT(3) receptor agonist phenylbiguanide was injected into the pericardial sac as a chemical stimulus. An increase of fibre activity by more than two standard deviations compared with control was considered a response to a stimulus. Most fibres (42 out of 57) responded to both stimuli and were categorized as bimodal, 9 fibres were solely mechanosensitive and 6 were solely chemosensitive. Hence, the majority of cardiac vagal C-fibres are likely to be bimodal, responding to both cardiac filling pressure and serotonin 5HT(3) receptor stimulation. Our results emphasize the potential role of endogenous mediators in the afferent limb of cardiac reflexes.
In contrast to other sympathetic outflow tracts, renal sympathetic nerve activity (RSNA) decreases in response to hypotensive hemorrhage. The functional significance of this "paradox" is not known. We tested the hypothesis that RSNA modulates renal perfusion and thus erythropoietin (EPO) release after transient hypotensive hemorrhage in anesthetized rats. Plasma EPO was measured before and after 30 min of transient hypotensive hemorrhage (i.e., -40 mmHg from mean baseline blood pressure, followed by reinfusion of shed blood) and 120 min thereafter in sham-denervated rats, and after renal denervation (DNX) or bilateral cervical vagotomy (VX) to abolish/blunt the RSNA decrease mediated by a cardiopulmonary reflex. RSNA, renal Doppler flow, renal vascular resistance (RVR), resistance index, and oxygen delivery/uptake (Do(2)/Vo(2)) were measured. RSNA decreased in intact animals (-40 +/- 5% from baseline, P < 0.05). This was blunted by VX. With intact nerves, EPO level did not increase. In DNX rats, EPO was increased at minute 120 (49 +/- 3 vs. 74 +/- 2 mU/ml; P < 0.05), in VX rats this (47 +/- 2 vs. 62 +/- 4 mU/ml; P < 0.05) was less pronounced. Do(2) in DNX rats was lower compared with intact and VX rats (0.25 +/- 0.04 vs. 0.51 +/- 0.06 and 0.54 +/- 0.05 ml O(2)/min; P < 0.05) due to lower Doppler flow and increased RVR. RVR and Do(2) were similar in intact and VX rats, but resistance index differed between all groups (0.70 +/- 0.02 vs. 0.78 +/- 0.02 vs. 0.85 +/- 0.02; P < 0.05, intact vs. VX vs. DNX), indicating differential reactivity of renal vasculature. Vo(2) was unaffected by VX and DNX. Renal sympathoinhibition during hypotensive hemorrhage might help to preserve sufficient oxygenation of renal tissue by modulation of hemodynamic mechanisms that act to adapt renal oxygen availability to demand.
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