Mechanical and electrical aspects of the relaxant action of aminophylline in guinea-pig isolated trachealis.

Abstract

Aminophylline (1-1000 mumol l-1) suppressed the spontaneous tone of guinea-pig isolated trachealis in a concentration-dependent manner. In Krebs solution containing acetylcholine (1 mmol l-1), histamine (200 mumol l-1) or K+ (120 mmol l-1) isolated trachealis muscle developed near-maximal tension. The log concentration-effect curve for aminophylline was shifted 20 fold, 3 fold and 4 fold to the right, respectively, in the presence of these spasmogens. Three K+-channel inhibitors were tested: tetraethylammonium (TEA, 8 mmol l-1) did not modify the action of aminophylline, procaine (5 mmol l-1) shifted the log concentration-effect curve for aminophylline 2 fold to the left and 4-aminopyridine (5 mmol l-1) shifted the curve 2.5 fold to the right. Intracellular electrophysiological recording showed that aminophylline 10 mumol l-1 could cause relaxation in the absence of electrical changes. Higher concentrations of aminophylline (100-1000 mumol l-1) suppressed spontaneous slow waves and hyperpolarized the trachealis cells. In the presence of procaine (5 mmol l-1) or TEA (8 mmol l-1), the hyperpolarization induced by aminophylline (1000 mumol l-1) was significantly reduced but its relaxant effect was unchanged. In trachealis skinned of its plasma membranes, tension development induced by Ca2+ (20 mumol l-1) was unaffected either by aminophylline (1000 mumol l-1) or by isoprenaline (1 mumol l-1). In studies of the efflux of 86Rb+ from muscle-rich strips of trachea, aminophylline (100-1000 mumol l-1) was without effect whereas nicorandil (100 and 1000 mumol l-1) increased the efflux rate constant. It is concluded that aminophylline does not directly reduce the sensitivity of the contractile proteins to cytosolic Ca2+. In low concentration (1-10 mumol l-1) its relaxant action is not accompanied by membrane potential change but towards the upper end of its effective concentration range, aminophylline evokes hyperpolarization. This hyperpolarization may involve the opening of K+-channels which are inhibited by procaine and (to a lesser extent) by TEA. These K+-channels may be impermeable to 86Rb+.