Pulmonary vasodilatory response to neurohypophyseal peptides in the rat.

Experiments were performed on isolated salt-perfused rat lungs to determine the receptor type(s) responsible for the pulmonary vascular effects of the neurohypophyseal peptides arginine vasopressin (AVP) and oxytocin. Bolus administration of AVP to lungs preconstricted with the thromboxane mimetic U-46619 resulted in a dose-dependent vasodilatory response (approximately 65% reversal of U-46619-induced vasoconstriction at the highest dose tested) that was blocked by pretreatment with a selective V1- but not by a selective V2-vasopressinergic receptor antagonist. Administration of a selective V1-agonist to the preconstricted pulmonary vasculature resulted in a vasodilatory response similar to that observed with AVP (approximately 55% reversal of U-46619 vasoconstriction), which was blocked by prior administration of the selective V1-receptor antagonist. Administration of the selective V2-receptor agonist desmopressin to the preconstricted pulmonary vasculature resulted in a small (approximately 8% reversal of U-46619 vasoconstriction) vasodilatory response that was, nevertheless, greater than that produced by addition of vehicle alone and was attenuated by pretreatment with a selective V2-receptor antagonist. Finally, oxytocin also caused vasodilation in the preconstricted pulmonary vasculature; however, the potency of oxytocin was approximately 1% of AVP, and the vasodilation produced by oxytocin was blocked by prior administration of a selective V1-receptor antagonist, suggesting that oxytocin acts via V1-vasopressinergic receptor stimulation. We conclude from these experiments that AVP and oxytocin dilate the preconstricted pulmonary vasculature primarily via stimulation of V1-vasopressinergic receptors. V2-receptor stimulation results in a minor vasodilatory response, although its physiological significance is unclear.     

Adrenergic Regulation of the Reduction in Acetyl Coenzyme A: Arylamine 7V-Acetyltransferase Activity in the Rat Pineal

Abstract: Pharmacologically active agents were employed to study the mechanisms that control the reduction in levels of acetyl-coA: arylamine N-acetyltransferase activity (NAT) (EC 2.3.1.5) in the rat pineal. Pretreatment of rats with phenoxybenzamine or phentolamine prevented the rapid light-mediated decrease in NAT activity, although pretreatment with yohimbine or atropine did not alter this effect of light. Administration of mecamylamine resulted in a rapid reduction in enzyme activity prior to light exposure. When clonidine was administered intraperitoneally to animals with elevated NAT levels, there was a rapid decrease in enzyme activity, mimicking the effects of light. However, intraperitoneal injections of norepinephrine, methoxamine and phenylephrine into similar groups of animals had no significant effect on enzyme acitivity. When clonidine and norepinephrine were administered intraventricularly, there was a rapid reduction in enzyme activity. On the other hand, intraventricular administration of phenylephrine did not result in reduced enzyme activity. Pretreatment of animals with phenoxybenzamine failed to block the reduction in NAT activity precipitated by low doses of clonidine. This clonidine-mediated reduction in enzyme activity was, however, blocked by yohimbine. When animals were simultaneously exposed to light and administered clonidine, the rapid reduction in NAT activity was affected only when animals were pretreated with both yohimbine and phenoxybenzamine. In contrast to the decrease in pineal NAT activity observed in in vivo preparations, incubation of pineals with clonidine in an organ culture system produced a moderate, but consistent, rise in enzyme activity. These results suggest that stimulation of a receptor with α-adrenergic characteristics mediates the reduction in NAT activity produced by light. Stimulation of yet a second adrenergic-like receptor appears to mediate a reduction in pineal NAT activity precipitated by clonidine. Our evidence suggests that one or both of these receptors are located within the central nervous system.     

Developmental delays in exploration and locomotor activity in male rats exposed to low level lead

Delays in the development of exploratory and locomotor behavior in neonatal male rats (up to 21 days of age) are shown to accrue as a consequence of low level lead exposure. Cross fostering experiments indicate that these delays are primarily due to prenatal exposure. These Pb induced behavioral modifications appear to be associated with the delays in synaptogenesis and biochemical development of the cerebral cortex reported previously (4, 18). A new behavioral bioassay for detecting delays in brain development is described.