Afferent renal inputs to paraventricular nucleus vasopressin and oxytocin neurosecretory neurons

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Afferent renal inputs to paraventricular nucleus vasopressin and oxytocin neurosecretory neurons

John Ciriello

Department of Physiology, Health Sciences Centre, University of Western Ontario, London, Ontario, Canada N6A 5C1

Extracellular single-unit recording experiments were done in pentobarbital sodium-anesthetized rats to investigate the effectsof electrical stimulation of afferent renal nerves (ARN) and renalvein (RVO) or artery (RAO) occlusion on the discharge rate ofputative arginine vasopressin (AVP) and oxytocin (Oxy) neuronsin the paraventricular nucleus of the hypothalamus (PVH). PVHneurons antidromically activated by electrical stimulation ofthe neurohypophysis were classified as either AVP or Oxy secretingon the basis of their spontaneous discharge patterns and responseto activation of arterial baroreceptors. Ninety-eight putativeneurosecretory neurons in the PVH were tested for their responseto electrical stimulation of ARN: 44 were classified as putativeAVP and 54 as putative Oxy neurons. Of the 44 AVP neurons, 52%were excited, 7% were inhibited, and 41% were nonresponsive toARN stimulation. Of the 54 Oxy neurons, 43% were excited, 6% inhibited,and 51% were not affected by ARN. An additional 45 neurosecretoryneurons (29 AVP and 16 Oxy neurons) were tested for their responsesto RVO and/or RAO. RVO inhibited 42% of the putative AVP neuronsand 13% of the putative Oxy neurons. On the other hand, RAO excited33% of the AVP and 9% of the Oxy neurons. No AVP or Oxy neuronswere found to be excited by RVO or inhibited by RAO. These dataindicate that sensory information originating in renal receptorsalters the activity of AVP and Oxy neurons in the PVH and suggestthat these renal receptors contribute to the hypothalamic controlof AVP and Oxy release into thecirculation.

renal mechanoreceptors; renal chemoreceptors; hypothalamus; vasopressin; oxytocin; arterial pressure control; cardiovascular regulation

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