Caffeine-modulated acetylcholine sensitivity in denervated rat and diseased human muscle.

Surgically denervated muscle exhibits increased sensitivity to acetylcholine and caffeine, and the acetylcholine contracture subsequent to preincubation with caffeine is greatly enhanced. The potentiation of the acetylcholine contracture derives, at least in part, from the direct action of caffeine on the muscle membrane resulting in an augmented and prolonged depolarization. The extent of potentiation depends on the duration of exposure to caffeine, is inhibited by increased extracellular calcium and is not present when cyclic AMP is substituted for caffeine.Biopsied human intercostal muscle shows high acetylcholine sensitivity in myotonic muscular dystrophy and motor neuron disease when compared to normal human or Duchenne dystrophic muscle. We suggest that myotonic dystrophy and motor neuron disease resemble surgical denervation more than Duchenne dystrophy does, and that in the former two diseases, as in denervated muscle, the acetylcholine sensitivity is increased with a concomitant abnormality in calcium-receptor interaction.     

Increased histaminase activity in the atrophic muscle of denervated frog.

Sciatic denervation for 1 month in the frog Rana hexadactyla resulted in progressive atrophy of the gastrocnemius muscle without any change in the total DNA content of the whole muscle. Histamine content of the muscle decreased; glutamic and acid content increased and histidine level remained unaltered on denervation. Histaminase activity localized in the muscle decreased; glutamic acid content increased and histidine level remained unaltered on denervation. Histaminase activity localized in the muscle mitochondria increased on denervation. The histidine-degrading enzymes, histidine ammonia lyase, urocanate hydratase and imidazol-5yl lactate dehydrogenase, are localized in the sarcoplasm of the muscle and their activities are not altered on denervation. The histidine decarboxylase activity localized in the mitochondria is not altered on denervation. The reduction in the histamine content of the atrophied muscle may be due to increased mitochondrial histaminase activity but not due to increased decarboxylation of histidine. The loss of 'trophic influence' due to denervation may be manifested in the impairment of mitochondrial histaminase activity.     

Mechanical properties of denervated amphibian muscle

Denervated amphibian muscle does not show the prolongation of action potential found in mammalian denervated muscle. It was, therefore, predicted that denervated amphibian muscle would not show prolongation of the mechanical twitch. The sartorius muscles in one leg of toads--Xenopus borealis--were denervated for 140-268 days. Isometric twitch time to peak, time to half relaxation and twitch/tetanus ratio were not changed following denervation, confirming our prediction. Twitch tension decreased to 68% and tetanic tension decreased to 75% of control values. The maximum velocity of unloaded shortening (muscle length/s) was also unchanged.     

Increased cyclic GMP in the end-plate region of denervated frog muscle.

Denervated frog sartorius muscles showed an approximately 2--3 fold increase of cyclic GMP in their end-plate rich regions which did not appear up to 5 weeks after denervation in the normally end-plate-free pelvic region. No increase in cyclic AMP was seen in these preparations. The results suggest that the increase of cyclic GMP is related to processes specific to the region in which end plates are normally present.     

Autoradiographic visualization of beta-adrenergic receptors in normal and denervated skeletal muscle.

Autoradiographic localization of beta-adrenergic receptors in rat skeletal muscle in vivo was achieved utilizing [125I]-iodohydroxybenzylpindolol, a potent beta-adrenergic blocker with high affinity and specificity for those receptors. In normal muscle the beta-adrenergic receptors were localized mainly to blood vessels, arterioles greater than venules, with much less concentration of grains over the fascicles of muscle fibers. One week after denervation there was an increase in binding both to blood vessels and muscle fibers, more so in soleus and gactrocnemius than in extensor digitorum longus. While these results parallel in vitro biochemical studies, they dictate caution when inferring cellular localization of beta-adrenergic receptors (and other molecules) solely on the basis of biochemical techniques applied to subcellular fractions of whole-organ homogenates.