Circulating vasopressin influences area postrema neurons

Abstract

Extracellular single-unit recordings were obtained from 107 area postrema and 74 nucleus tractus solitarius neurons in sodium pentobarbitol anaesthetized rats. Systemic administration of vasopressin (1–10 ng) decreased the firing frequency of 45.8% of area postrema neurons and 58.1% of nucleus tractus solitarius neurons tested while the firing frequency of 38.3% of area postrema neurons and 21.6% of nucleus tractus solitarius neurons was increased by this peptide. To determine whether these neurons were specifically influcenced by vasopressin or the accompanying pressor response, the effects of α-adrenergic agonists on neuronal activity were also determined. Cells that responded similarly to vasopressin and the change in blood pressure elicited by a-adrenergic agonists were classified as “blood pressure-sensitive”, whereas those neurons that responded differently to both agents were classified as “vasopressin-sensitive” neurons. The majority (85.2%) of area postrema cells that decreased firing frequency in response to vasopressin were determined to be “vasopressin-sensitive”, while 68.8% of area postrema neurons responding to vasopressin with increases in firing frequency were classified as “blood pressure-sensitive”. In contrast, 78.6% of nucleus tractus solitarius neurons that decreased firing frequency in response to vasopressin and 55.5% of those that increased firing frequency were classified as “blood pressure-sensitive” neurons. To determine whether the actions of vasopressin in the area postrema were mediated by V 1 receptors the effect of vasopressin after V 1 receptor blockade was examined in seven “vasopressin-sensitive” area postrema neurons. All seven neurons tested showed no response to vasopressin after such V 1 receptor blockade. These data suggest that there exists a population of area postrema neurons specifically responsive to circulating vasopressin as a result of actions of this peptide at V 1 receptors. They also implicate these neurons in the physiological mechanisms through which circulating vasopressin acts in the area postrema to influence baroreceptor reflex sensitivity.