Summary
The adrenergic nerve endings of the rat vas deferens were loaded with 3H-(−)-noradrenaline; COMT was inhibited by the presence of 10 μmol/l U-0521, and all experiments were carried out with calcium-free solution. After 100 min of wash-out a neuronal efflux of tritium was obtained which remained constant with time (when expressed as fractional rate of loss; FRL); it contained more DOPEG than noradrenaline.
The in vitro administration of reserpine-like drugs (reserpine and Ro 4-1284) increased the FRL of tritium, presumably because of an increase in the leakage of noradrenaline from storage vesicles; the efflux of DOPEG increased more than that of noradrenaline, and the ratio NA/DOPEG declined.
Inhibition of the membrane ATPase (by omission of potassium from the medium or by the presence of 3 mmol/l ouabain) increased the FRL of tritium, presumably because of an increase in the net leakage of noradrenaline from the storage vesicles (as a consequence of the fall in the concentration of free axoplasmic noradrenaline; see below).
Veratridine also increased the FRL of tritium, partly because of its known reserpine-like effect (Bönisch et al. 1983); in the presence of 1 μmol/l veratridine, the efflux of DOPEG increased.
Irrespective of the presence or absence of reserpine or Ro 4-1284, inhibition of the membrane ATPase or the presence of veratridine (agents or procedures which increase the axoplasmic sodium concentration) always resulted in a brisk increase of the efflux of noradrenaline that was accompanied by a simultaneous decrease in the efflux of DOPEG (see above for one exception). In all experiments the rise in internal sodium caused the ratio NA/DOPEG to increase.
These results indicate that—as long as the sodium gradient is normal—the axonal membrane functions as a barrier that largely prevents any outward movement of axoplasmic noradrenaline. Consequently, the axoplasmic amine is largely deaminated, and the ratio NA/DOPEG is low. However, when the axoplasmic sodium concentration rises, axoplasmic noradrenaline is transported out of the nerve ending at such high rates that the axoplasmic noradrenaline concentration falls; the fall in the efflux of DOPEG is indicative of a fall in the intraneuronal formation of DOPEG. The results show that changes in the efflux of DOPEG (i.e., of a highly lipophilic metabolite that easily leaves adrenergic nerve endings) can serve as an index of changes in axoplasmic noradrenaline levels.
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Stute, N., Trendelenburg, U. The outward transport of axoplasmic noradrenaline induced by a rise of the sodium concentration in the adrenergic nerve endings of the rat vas deferens. Naunyn-Schmiedeberg's Arch. Pharmacol. 327, 124–132 (1984). https://doi.org/10.1007/BF00500906
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DOI: https://doi.org/10.1007/BF00500906