Peripheral chemoreceptors mediate training-induced plasticity in paraventricular nucleus pre-autonomic oxytocinergic neurons.

We showed previously that sino-aortic denervation prevented training-induced plasticity in pre-autonomic oxytocinergic neurons and blocked the beneficial effects of training. In this study, we investigate the combined effect of training and removal of specific chemoreceptor afferents on both cardiovascular parameters and oxytocin (OT) gene and protein expression within the hypothalamic paraventricular nucleus (PVN). Wistar rats and spontaneously hypertensive rats (SHRs) underwent carotid body denervation or sham surgery and were trained or kept sedentary for 3 months. After haemodynamic measurements at rest, rats were anaesthetized for brain perfusion. Fresh (perfused with PBS) and fixed brains (perfused with 4% paraformaldehyde) were processed for PVN OT mRNA (real-time PCR) and OT immunoreactivity within PVN subnuclei. In sham-operated rats, training improved treadmill performance and reduced resting heart rate (Wistar, -8%; SHRs, -10%), with a reduction in blood pressure only in SHRs (-8%). Training was accompanied by increased PVN OT mRNA expression (twofold increase in sham-operated SHRs) and peptide density in the posterior, ventromedial and dorsal cap PVN subnuclei (on average 70% increase in both strains), with significant correlations between OT content and training-induced resting bradycardia in sham-operated groups. Carotid body denervation did not interfere with the performance gain, abolished chemoreflex activation (without changing baroreflex control) and blocked training-induced cardiovascular adaptations and training-induced changes in PVN OT content in both strains. After carotid body denervation, there was no correlation between OT mRNA or OT immunoractivity and resting heart rate. The chronic absence of chemoreceptor inputs uncovers an unknown role of chemoreceptor signalling in driving the plasticity/activity of PVN oxytocinergic pre-autonomic neurons, thus mediating training-induced cardiovascular adaptive responses.

Tyrosine hydroxylase immunoreactivity as indicator of sympathetic activity: simultaneous evaluation in different tissues of hypertensive rats.

Vasomotor control by the sympathetic nervous system presents substantial heterogeneity within different tissues, providing appropriate homeostatic responses to maintain basal/stimulated cardiovascular function both at normal and pathological conditions. The availability of a reproducible technique for simultaneous measurement of sympathetic drive to different tissues is of great interest to uncover regional patterns of sympathetic nerve activity (SNA). We propose the association of tyrosine hydroxylase immunoreactivity (THir) with image analysis to quantify norepinephrine (NE) content within nerve terminals in arteries/arterioles as a good index for regional sympathetic outflow. THir was measured in fixed arterioles of kidney, heart, and skeletal muscle of Wistar-Kyoto rats (WKY) and spontaneously hypertensive rats (SHR) (123 ± 2 and 181 ± 4 mmHg, 300 ± 8 and 352 ± 8 beats/min, respectively). There was a differential THir distribution in both groups: higher THir was observed in the kidney and skeletal muscle (∼3-4-fold vs. heart arterioles) of WKY; in SHR, THir was increased in the kidney and heart (2.4- and 5.3-fold vs. WKY, respectively) with no change in the skeletal muscle arterioles. Observed THir changes were confirmed by either: 1) determination of NE content (high-performance liquid chromatography) in fresh tissues (SHR vs. WKY): +34% and +17% in kidney and heart, respectively, with no change in the skeletal muscle; 2) direct recording of renal (RSNA) and lumbar SNA (LSNA) in anesthetized rats, showing increased RSNA but unchanged LSNA in SHR vs. WKY. THir in skeletal muscle arterioles, NE content in femoral artery, and LSNA were simultaneously reduced by exercise training in the WKY group. Results indicate that THir is a valuable technique to simultaneously evaluate regional patterns of sympathetic activity.

Afferent signaling drives oxytocinergic preautonomic neurons and mediates training-induced plasticity.

We showed previously that oxytocinergic (OTergic) projections from the hypothalamic paraventricular nucleus (PVN) to the dorsal brain stem mediate training-induced heart rate (HR) adjustments and that beneficial effects of training are blocked by sinoaortic denervation (SAD; Exp Physiol 94: 630-640; 1103-1113, 2009). We sought now to determine the combined effect of training and SAD on PVN OTergic neurons in spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats. Rats underwent SAD or sham surgery and were trained (55% of maximal capacity) or kept sedentary for 3 mo. After hemodynamic measurements were taken at rest, rats were deeply anesthetized. Fresh brains were frozen and sliced to isolate the PVN; samples were processed for OT expression (real-time PCR) and fixed brains were processed for OT immunofluorescence. In sham rats, training improved treadmill performance and increased the gain of baroreflex control of HR. Training reduced resting HR (-8%) in both groups, with a fall in blood pressure (-10%) only in SHR rats. These changes were accompanied by marked increases in PVN OT mRNA expression (3.9- and 2.2-fold in WKY and SHR rats, respectively) and peptide density in PVN OTergic neurons (2.6-fold in both groups), with significant correlations between OT content and training-induced resting bradycardia. SAD abolished PVN OT mRNA expression and markedly reduced PVN OT density in WKY and SHR. Training had no effect on HR, PVN OT mRNA, or OT content following SAD. The chronic absence of inputs from baroreceptors and chemoreceptors uncovers the pivotal role of afferent signaling in driving both the plasticity and activity of PVN OTergic neurons, as well as the beneficial effects of training on cardiovascular control.