Article date: May 1993
By: Salvatore Salomone, Théophile Godfraind, in Volume 109, Issue 1, pages 100-106
The present experiments were undertaken in order to characterize further the apparently irreversible inhibition of the contraction of depolarized rat aorta caused by lacidipine, a 1,4‐dihydropyridine calcium antagonist.
We studied the effect of lacidipine on contraction evoked by 100 mm KCl solution in rat aorta, treated by Nω‐nitro‐l‐arginine (0.1 mm), an inhibitor of nitric oxide (NO) synthesis. We compared the effect of prolonged depolarization on lacidipine and (+)‐isradipine inhibition and the reversal of this inhibition after washout in the absence of dihydropyridines. Assuming that the onset of lacidipine‐evoked inhibition was a pseudo‐first order association kinetics, we estimated the dissociation rate constant (k−1 = 0.031 min−1), the association rate constant (k1 = 2.70 × 108m−1 min−1) and the dissociation constant (KD = k−1/k1 = 115 pm) which was close to the IC50 value in steady‐state conditions (160 pm).
The inhibitory effects of lacidipine and (+)‐isradipine on rat aorta contraction were reversibly enhanced after preincubation with the drug in a 40 mm KCl‐solution. Washout with drug‐free 40 mm K+‐depolarizing solution reversed inhibition in the (+)‐isradipine‐treated preparations, but not in the lacidipine‐treated ones.
Radioligand binding studies were performed with [3H]‐lacidipine and [3H]‐isradipine in microsomes from rat aorta and rat ileum. Both ligands bound to a homogeneous population of binding sites (for [3H]‐lacidipine: KD = 23 ± 2.6 pm, Bmax = 380 ± 21 fmol mg−1 protein in membranes from aorta; KD = 23 ± 3.1 pm, Bmax = 790 ± 60 fmol mg−1 protein in membranes from ileum; for [3H]‐isradipine: KD = 140 ± 46 pm, Bmax = 350 ± 64 fmol mg−1 protein in membrane from aorta; KD = 68 ± 14 pm, Bmax = 760 ± 75 fmol mg−1 protein in membranes from ileum). After isotopic dilution, [3H]‐lacidipine and [3H]‐isradipine dissociated according to a monoexponential kinetics. In membranes from ileum, the calculated dissociation rate constants (k−1) were 0.0257 min−1 and 0.0595 min−1, for [3H]‐lacidipine and [3H]‐isradipine, respectively.
The non specific binding of [3H]‐lacidipine and [3H]‐isradipine, was measured in intact rat aorta preparations incubated under the conditions of the functional experiments, in the presence of nifedipine (1 μm). After incubation with [3H]‐lacidipine 77.6 ± 1.9 pm for 2 h the concentration of drug in the tissue was 15.15 ± 1.18 fmol mg−1 w.wt. and still amounted to 7.24 ± 0.61 fmol mg−1 w.wt. after 3.5 h washout in drug‐free solution. After incubation with [3H]‐isradipine 47.2 ± 0.4 pm for 2 h it was 2.26 ± 0.07 fmol mg−1 w.wt. and was undetectable after 3.5 h washout in a drug‐free solution.
It is concluded that lacidipine interacts reversibly with dihydropyridine binding sites and that the apparent irreversible inhibition of contraction in depolarized preparations could be related to a non specific binding in a tissue compartment different from the plasma membrane.
The present experiments were undertaken in order to characterize further the apparently irreversible inhibition of the contraction of depolarized rat aorta caused by lacidipine, a 1,4‐dihydropyridine calcium antagonist.
We studied the effect of lacidipine on contraction evoked by 100 mm KCl solution in rat aorta, treated by Nω‐nitro‐l‐arginine (0.1 mm), an inhibitor of nitric oxide (NO) synthesis. We compared the effect of prolonged depolarization on lacidipine and (+)‐isradipine inhibition and the reversal of this inhibition after washout in the absence of dihydropyridines. Assuming that the onset of lacidipine‐evoked inhibition was a pseudo‐first order association kinetics, we estimated the dissociation rate constant (k−1 = 0.031 min−1), the association rate constant (k1 = 2.70 × 108m−1 min−1) and the dissociation constant (KD = k−1/k1 = 115 pm) which was close to the IC50 value in steady‐state conditions (160 pm).
The inhibitory effects of lacidipine and (+)‐isradipine on rat aorta contraction were reversibly enhanced after preincubation with the drug in a 40 mm KCl‐solution. Washout with drug‐free 40 mm K+‐depolarizing solution reversed inhibition in the (+)‐isradipine‐treated preparations, but not in the lacidipine‐treated ones.
Radioligand binding studies were performed with [3H]‐lacidipine and [3H]‐isradipine in microsomes from rat aorta and rat ileum. Both ligands bound to a homogeneous population of binding sites (for [3H]‐lacidipine: KD = 23 ± 2.6 pm, Bmax = 380 ± 21 fmol mg−1 protein in membranes from aorta; KD = 23 ± 3.1 pm, Bmax = 790 ± 60 fmol mg−1 protein in membranes from ileum; for [3H]‐isradipine: KD = 140 ± 46 pm, Bmax = 350 ± 64 fmol mg−1 protein in membrane from aorta; KD = 68 ± 14 pm, Bmax = 760 ± 75 fmol mg−1 protein in membranes from ileum). After isotopic dilution, [3H]‐lacidipine and [3H]‐isradipine dissociated according to a monoexponential kinetics. In membranes from ileum, the calculated dissociation rate constants (k−1) were 0.0257 min−1 and 0.0595 min−1, for [3H]‐lacidipine and [3H]‐isradipine, respectively.
The non specific binding of [3H]‐lacidipine and [3H]‐isradipine, was measured in intact rat aorta preparations incubated under the conditions of the functional experiments, in the presence of nifedipine (1 μm). After incubation with [3H]‐lacidipine 77.6 ± 1.9 pm for 2 h the concentration of drug in the tissue was 15.15 ± 1.18 fmol mg−1 w.wt. and still amounted to 7.24 ± 0.61 fmol mg−1 w.wt. after 3.5 h washout in drug‐free solution. After incubation with [3H]‐isradipine 47.2 ± 0.4 pm for 2 h it was 2.26 ± 0.07 fmol mg−1 w.wt. and was undetectable after 3.5 h washout in a drug‐free solution.
It is concluded that lacidipine interacts reversibly with dihydropyridine binding sites and that the apparent irreversible inhibition of contraction in depolarized preparations could be related to a non specific binding in a tissue compartment different from the plasma membrane.
DOI: 10.1111/j.1476-5381.1993.tb13537.x
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