Douglas Costa Braga scite author profile

We have shown that vasopressinergic projections to dorsal brain stem are activated during exercise and facilitate exercise tachycardia in both trained (T) and sedentary (S) rats (Dufloth DL, Morris M, and Michelini LC. Am J Physiol Regulatory Integrative Comp Physiol 273: R1271-R1282, 1997). In the present study, we investigated whether oxytocinergic projections to the nucleus of the solitary tract (NTS)-dorsal motor nucleus of the vagus (DMV) complex (NTS/DMV) are involved in the differential heart rate (HR) response to exercise in T and S rats. Arterial pressure (AP) and HR responses to dynamic exercise (0.4-1.4 km/h) were compared in S and T pretreated with vehicle (saline), oxytocin (OT; 20 pmol/200 nl) or OT-receptor antagonist (OT(ant); 20 pmol/200 nl) into the NTS/DMV. OT content in specific brain regions and plasma were measured in separate S and T groups at rest and immediately after exercise. Exercise increased OT content in dorsal (4.5-fold) and ventral brain stem (2.7-fold) and spinal cord (3.4-fold) only in T rats. No significant changes were observed in neurosecretory regions or medial eminence and posterior pituitary, but plasma levels of T rats were reduced immediately after exercise. Blockade of NTS/DMV OT receptors did not change basal mean AP (MAP) and HR or the MAP response to exercise. However, OT(ant) potentiated exercise-induced tachycardia (average increase of 26%) only in the T group. Pretreatment with exogenous OT in the NTS/DMV blunted the tachycardic response both in S and T rats without changing the MAP response. Administration of OT-receptor antagonist or OT into the fourth cerebral ventricle had no effect on the cardiovascular response to dynamic exercise. Taken together, the results suggest that oxytocinergic projections to the NTS/DMV are stimulated when T rats exercise and that OT released at this level acts on OT receptors to restrain exercise-induced tachycardia.

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Activity-Dependent Neuroplastic Changes in Autonomic Circuitry Modulating Cardiovascular Control: The Essential Role of Baroreceptors and Chemoreceptors Signaling

Rocha-Santos

Braga

Ceroni

et al. 2020

Front. Physiol.

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Aerobic exercise training improves the autonomic control of the circulation. Emerging evidence has shown that exercise induces neuroplastic adaptive changes in preautonomic circuitry controlling sympathetic/parasympathetic outflow to heart and vessels. The mechanisms underlying neuronal plasticity are, however, incompletely understood. Knowing that sinoaortic denervation blocks training-induced cardiovascular benefits, we investigate whether baroreceptors' and chemoreceptors' signaling are able to drive neuronal plasticity within medullary and supramedullary pathways controlling autonomic outflow. Male Wistar rats submitted to sinoaortic denervation (SAD) or dopamine β-hydroxylase-saporin lesion (DBHx) and respective controls (SHAM) were allocated to training (T) or sedentary (S) protocols for 8 weeks. After hemodynamic measurements at rest, rats were deeply anesthetized for brain harvesting. The density of DBH and oxytocin (OT) cell bodies and terminals were analyzed in brainstem and hypothalamic brain areas (double immunofluorescence reactions, optic and confocal microscopy). In SHAM rats training augmented the density of DBH+ neurons in the nucleus of solitary tract, increased the density of ascending NORergic projections and the number of DBH+ boutons contacting preautonomic OT+ neurons into paraventricular hypothalamic preautonomic nuclei, augmented the density of local OTergic neurons and enhanced the density of OT+ terminals targeting brainstem autonomic areas. These plastic changes occurred simultaneously with reduced sympathetic/increased parasympathetic activity, augmented baroreflex sensitivity and reduced resting heart rate. SAD reduced the density of both DBH+ fibers ascending from brainstem to paraventricular nucleus of hypothalamus and preautonomic OT+ neurons projecting to the brainstem, abrogated training-induced plastic changes and autonomic adaptive responses without changing the treadmill performance. Minor neuroplastic changes with preserved baroreflex sensitivity were observed in trained rats after partial selective disruption of ascending NORergic projections. Our data indicated that afferent inputs conveyed by arterial baroreceptors and chemoreceptors are the main stimuli to drive both inactivity-induced and activity-dependent neuroplasticity within the autonomic circuitry.

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Exercise augments but sinoaortic denervation blocks noradrenergic signaling to PVN in trained normotensive rats (686.5)

et al. 2014

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Exercise training (T) increases ascending NORergic signaling from NTS to PVN, improves baroreflex sensitivity (BrS) and reduces basal heart rate (HR). We evaluate the effects of sinoaortic denervation (SAD) and T on cardiovascular parameters and expression of PVN oxytocinergic (OTergic) and vasopressinergic (VPergic) neurons. SAD and SHAM rats were submitted to low‐intensity T or kept sedentary (S) for 3 month. After hemodynamic measurements, rats were euthanized; perfused brains were post‐fixed and cryoprotected. Sequential PVN slices (30 μm) were processed for OT, VP and dopamine β‐hydroxylase (DBH) immunoreactivity (ir); images were acquired and analyzed by Image J. In SHAM rats T reduced basal HR, increased BrS (328±8 b/min, 2.4±0.2 b/min/mmHg, ‐13% and +25% vs S controls), augmented the density of DBH terminals and OTir in ventromedial PVN and reduced VPir in the magnocelular PVN, without changing DBH signaling to this area. SAD markedly reduced basal OTir and VPir in both PVN areas and blocked functional and T‐induced effects on OTir and VPir. T‐induced afferent signaling, directed preferentially to preautonomic areas, increases the expression of OTergic neurons, contributing to the appearance of beneficial effects in intact T rats. SAD blocks these effects confirming that PVN signaling conveyed by baro‐ and chemoreceptors is essential to maintain neuronal tonicity and to mediate T‐induced effects Grant Funding Source: Supported by FAPESP, CNPq

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