Dual effects of angiotensin II on calcium currents in neonatal rat nodose neurons.

Angiotensin II (AII) reversibly modulates calcium current in isolated neonatal rat nodose ganglion cells by two different pathways. A maximum inhibitory effect of 43 +/- 6% (n = 25) of the peak calcium current at -10 mV was observed at 10 nM AII. The IC50 of the inhibitory response was 100 pM. Losartan, a specific antagonist for the AT1 type of AII receptor, abolished the AII-induced inhibition, as did preincubation with pertussis toxin (PTX). When omega-conotoxin GVIA (CTX) was added to the bath solution, AII produced no inhibition of the remaining calcium current, indicating that the AII inhibition was mediated through CTX-sensitive calcium channels. Reversible facilitation of calcium current was seen more rarely. The AII-induced facilitation was unaffected by losartan and PTX, indicating that the effect is mediated by a non-AT1 receptor and does not depend upon a PTX-sensitive G-protein. The facilitation is present when the CTX-sensitive current has been blocked and involves activation of a reserve pool of dihydropyridine (DHP)-sensitive channels. In general, a particular neuron exhibited either inhibition or facilitation. However, in some neurons both inhibition and facilitation could be demonstrated in the presence of the appropriate blocking agents.

Bradykinin-activated calcium influx pathway in bovine aortic endothelial cells.

Clusters of electrically coupled endothelial cells were used to characterize a bradykinin (BK)-activated Ca2+ influx pathway. Spatial voltage control of clusters containing three to eight cells, evaluated as the ratio of the voltage response in one cell to a voltage pulse in the most distant cell of the cluster, was 0.96 at a holding potential of 0 mV in normal saline bath and 0.88 in the presence of BK. BK activated an inward current that was carried by either Na+ or Ca2+ when the membrane potential was held at -60 mV. Current was activated within 3 s of application of BK and peaked within 1 min. With Ca2+ as the permeable extracellular ion the current was stable for 1-3 min and then declined over a period of 5-8 min in the continued presence of BK. However, when Na+ carried the current it was sustained over a 10-min test period. The reversal potential of the BK-activated current was near 0 mV, suggesting activation of a nonspecific cation channel(s). The inward current at -60 mV averaged 13 +/- 4.5 pA (n = 9)/cell in Ca2+ and 12.2 +/- 9.3 pA (n = 5)/cell in Na+. Both Na+ and Ca2+ currents were blocked by 200 microM lanthanum.