Neurosecretion of Crustacean Hyperglycemic Hormone Evoked by Axonal Stimulation or Elevation of Saline K+ Concentration Quantified by a Sensitive Immunoassay Method

A sandwich-type enzyme-linked immunosorbent assay (ELISA) was utilized to quantify crustacean hyperglycemic hormone (as Carcinus maenas equivalents) released by single X-organ­sinus gland systems of the crab Cardisoma carnifex during continuous perifusion. Basal rates of secretion (20­60 pg min-1) were stable for at least 4 h. Electrical stimulation (600 stimuli in 5 min) of the axon tract increased secretion two- to threefold, but only if it resulted in neural activity that was propagated to the terminals of the sinus gland. No difference was observable when stimuli were given repetitively or as a series of trains. Perifusion with saline having ten times the normal K+ concentration augmented secretion by as much as fivefold. Augmented secretion of crustacean hyperglycemic hormone evoked by either electrical or K+ stimulation appeared abruptly but declined slowly (over tens of minutes) after stimulation was stopped. K+-evoked secretion of crustacean hyperglycemic hormone was maintained without decrement for at least 1 h. Basal secretion increased in saline from which Ca2+ had been omitted, but decreased in saline containing Mn2+. Neither electrical stimulation nor high [K+] augmented secretion in Ca2+-deficient saline or if Mn2+ was present. Introduction of Mn2+ during K+-evoked secretion immediately reduced release to unstimulated levels; secretion resumed promptly upon removal of Mn2+. Tetrodotoxin reversibly blocked both electrical and secretory responses to axonal stimulation, but it did not block basal or K+-evoked secretion. Release of crustacean hyperglycemic hormone by isolated axon terminals was augmented two- to threefold by perifusion with saline having ten times the normal K+ concentration. The responses were similar to those of the intact systems, having a rapid onset, well-maintained secretion and a long 'tail' of secretion after removal of the K+ stimulus.