Background: Peripheral arterial chemoreceptors monitor the chemical composition of arterial blood and include both the carotid and aortic bodies (ABs). While the role of the carotid bodies has been extensively studied, the physiological role of the ABs remains relatively under-studied, and its role in hypertension is unexplored. We hypothesized that activation of the ABs would increase coronary blood flow in the normotensive state and that this would be mediated by the parasympathetic nerves to the heart. In addition, we determined whether the coronary blood flow response to stimulation of the ABs was altered in an ovine model of renovascular hypertension. Methods: Experiments were conducted in conscious and anesthetized ewes instrumented to record arterial pressure, coronary blood flow, and cardiac output. Two groups of animals were studied, one made hypertensive using a 2 kidney one clip model (n=6) and a sham-clipped normotensive group (n=6). Results: Activation of the ABs in the normotensive animals resulted in a significant increase in coronary blood flow, mediated, in part by a cholinergic mechanism since it was attenuated by atropine infusion. Activation of the ABs in the hypertensive animals also increased coronary blood flow ( P <0.05), which was not different from the normotensive group. Interestingly, the coronary vasodilation in the hypertensive animals was not altered by blockade of muscarinic receptors but was attenuated after propranolol infusion. Conclusions: Taken together, these data suggest that the ABs play an important role in modulating coronary blood flow and that their effector mechanism is altered in hypertension.
Altered autonomic control or coronary artery blood flow by the aortic body chemoreceptors in conscious normotensive and hypertensive sheep
Peripheral arterial chemoreceptors monitor the chemical composition of the blood. While, the carotid bodies located at the bifurcation of the common carotid arteries have been extensively studied. The physiological role of the aortic bodies located in the walls of the aortic arch remains relatively under-studied, and its role in hypertension is unexplored.We hypothesized that activation of the aortic bodies would increase coronary blood flow in the normotensive state and that the parasympathetic nerves to the heart would mediate this.Experiments were conducted in conscious and anesthetized ewes instrumented to record arterial pressure, coronary blood flow, and cardiac output. Two groups of animals were studied, one made hypertensive using a 2 kidney one-clip model (HTN. n=6) and a sham-clipped normotensive group (Con. n=6). Unilateral renal clipping increased resting mean arterial pressure (Con: 84±5 vs HTN 115±6 mmHg). The aortic body chemoreceptors were stimulated by a bolus infusion of potassium cyanide (KCN; 10-30 μg/kg) into the left ventricle.Activation of the aortic bodies in the normotensive and hypertensive animals resulted in a significant increase in coronary blood flow ( P<0.05, 2-way ANOVA, interaction effect), which was not different between groups. In normotensive sheep, the aortic body chemoreflex-mediated coronary vasodilation was attenuated by atropine infusion. Interestingly, the coronary vasodilation in hypertensive animals was not altered by the blockade of muscarinic receptors but was attenuated after propranolol infusion ( P<0.05, interaction effect). Bilateral vagotomy is not possible in conscious animals; under anesthesia, the coronary blood flow response to aortic body stimulation was significantly attenuated in normotensive sheep. Neither atropine nor propranolol affected the aortic body chemoreflex meditated changes in either group's blood pressure, heart rate, or cardiac output. This data suggests that the aortic bodies play an important role in modulating coronary blood flow and that their effector mechanism is altered in hypertension. Many patients with hypertension are on beta-blockers. Our finding indicates that the aortic bodies modulate coronary blood flow via a beta-adrenergic mechanism in hypertension, which may have important implications for regulating coronary blood flow during exertion in hypertensive patients. Work is supported by the Health Research Council (HRC) of New Zealand. This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
Purinergic signaling involving adenosine triphosphate (ATP) acting on P2X2/3 receptors modulates physiological carotid body (CB) afferent discharge and chemoreflex activation however, the upregulation of P2X3 receptors on petrosal sensory neurons is partly responsible for aberrant CB tonicity and hyperreflexia, and the increase in blood pressure in the Spontaneously Hypertensive rat (SHR). The enhanced chemoreflex occurs prior to the onset of hypertension and elevated CB activity is thought to contribute to the underlying pathophysiology of the disease but the exact mechanisms remain unclear. We hypothesize that there is greater release of ATP and/or decreased ATP breakdown in the pre‐hypertensive SHR CB compared with that in the Wistar rat, and this evokes an increase in the chemoreflex response and subsequent activation of the sympathetic nervous system. We performed three studies. (i) Using digital droplet PCR (ddPCR), we measured mRNA expression levels of enzymes involved in the breakdown of ATP in CBs extracted from male 4‐week‐old prehypertensive SHR and Wistar rats; these included: ectonucleotide pyrophosphatase/phosphodiesterase 1‐3 (Enpp1‐3), ectonucleoside triphosphate diphosphohydrolase 2‐3 (Entpd2‐3), and ecto‐5’‐nucleotidase (Nt5e). (ii) We quantified ATP release from CBs in vitro during baseline conditions and during cyanide‐evoked ATP release using a colorimetric assay (213‐579‐1 ‐ Millipore), comparing between male 4‐week‐old pre‐hypertensive SHR and Wistar rats. (iii) In an in situ working heart‐brainstem preparation of 4‐week‐old Wistar rats, simultaneous recordings were made from phrenic (PN), hypoglossal (HN), recurrent laryngeal (RLN), abdominal (ABN), and thoracic sympathetic nerves (tSNA). The peripheral chemoreceptors were stimulated with either potassium cyanide (KCN 20‐100 μL, 0.04%) or ATP at varying concentrations (10‐100 µL, 50 µM ‐ 2 mM) delivered via the internal carotid artery. In whole CB extracts, ddPCR revealed increased Enpp2‐3 and Nt5e expression (p<0.05) in pre‐hypertensive SHRs relative to Wistar rats suggesting greater capacity to break down ATP in the pre‐hypertensive SHR CB. There were no differences in the expressions of Enpp1 or Entpd2‐3 between rat strains. However, the amount of ATP released from the CB in both baseline and during cyanide stimulation was two‐fold greater in the pre‐hypertensive SHR (P<0.05). Stimulation of the CB with KCN evoked hyperpnoea, bradycardia and sympathoexcitation at all doses. In contrast, CB injection of low dose ATP increased PN rate with little effect on tSNA, whereas higher doses induced apnea accompanied by repetitive burst discharge of post‐inspiratory activity in the RLN with tonic elevations in the discharge of both ABN and tSNA. In sum, despite the upregulation of several ATP degrading enzymes in the CBs of the SHR, CB release of ATP is higher in this species. We hypothesize that the increase in ATP release in the SHR CB drives the CB hyperexcitability and that the shift towards an upregulation of ATP degrading enzymes even prior ...
ATP acting on P2X2/3 receptors within carotid bodies (CBs) underpins chemoreflex hyperreflexia and hypertonicity of sympathetic activity in Spontaneously Hypertensive rats (SHR). As the exact mechanisms remain elusive, we hypothesized either a greater release and/or decreased breakdown of ATP in CBs of SHR versus Wistar rats, and that high concentrations of exogenous ATP in the CB of normotensive rats would produce the sensitised motor responses portrayed by SHRs. Three experiments were performed to investigate the generation, breakdown and physiological responses of ATP in the CB: First, we sought to quantify the amount of ATP released from CBs of male Wistar and SHRs (N=10 for each strain; 4-5 weeks old) using an in vitro colorimetric technique; second, in both strains (Wistar, N=10; SHR, N=12), we used digital droplet polymerase chain reaction (ddPCR) for quantitative analysis of gene expression of six enzymes, which are all involved with the extracellular metabolism of ATP (Enpp1-3, Entpd 2-3, and Nt5e); we also quantified the levels of gene expression for tyrosine hydroxylase (TH) and Panx-1 channel, which are markers for CB type I (or glomus cells) and type-II cells, respectively. Third, we used the working heart-brainstem preparation (WHBP) for analysis of the CB chemoreflex responses evoked by ATP stimulation in Wistar rats (N= 25, 60-80g). Stimulation of CBs was carried out with local intra-arterial injection of potassium cyanide (KCN 20-100 μL, 0.04%; i.a.), and direct intra-CB injection of ATP (10-100 μL, 50 μM - 5 mM) or α, β-methylene ATP (10 μM, 450 μM, and 5mM).Although no rat strain differences in Enpp1 and Entpd2-3 were detected, Enpp2-3 and Nt5e expression were increased in SHR (p<0.05) versus Wistar rats suggesting greater breakdown of ATP in SHR CBs. However, ATP released from the CB at baseline and with KCN stimulation was two-fold greater in SHR (P<0.05). KCN stimulation of the CB, evoked hyperpnoea, bradycardia and sympathoexcitation in Wistar rats, whereas ATP produced hypopnoea/apnoea, repetitive burst discharge of post-inspiratory activity and elevations in both abdominal motor activity and SNA. We found that the ATP-induced hyponoea/apnoea was prevented by ipsilateral nodosectomy suggesting activation of non-CB afferent/s. Microinjecting either ATP or α, β-methylene ATP directly into the CB produced hyperpnoea and sympathoexcitation. Despite upregulation of some ATP degrading enzymes in the SHR, CB release of ATP is higher in this strain and produces activation of respiratory and sympathetic systems. Health Research Council of New Zealand This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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