Calcium handling in a testosterone responsive skeletal muscle of the MDX mouse

Muscle necrosis in Duchenne muscle dystrophy (DMD) and in the mdx mouse has been related to abnormal calcium homeostasis associated with the lack of dystrophin. We have previously shown that the testosterone-dependent levator ani (LA) muscle of the mdx mouse develops a mild muscle wasting and fiber degeneration compared to the less hormone sensitive diaphragm (DIA) muscle, suggesting a protective effect of androgens. This study assessed the calcium handling mechanisms and cytosolic calcium concentration ([Ca2+]i) in LA muscles of mdx mice at critical stages of muscle disease. Muscle contractures induced by caffeine and 4-chloro-m-cresol (4-CmC), two activators of ryanodine channels, were recorded in LA and DIA muscles of prepubertal (1 month-old), adult (4 month-old) and aged (18 month-old) wild-type (wt) and mdx mice. [Ca2+]i was estimated with the fura-2 fluorescent dye in enzymatically dissociated LA muscle fibers of the same wt and mdx groups. Tetanus tension (TT) in the LA increased proportionately to the muscle weight (4 to 5-fold), but specific TT (TT/mg) did not differ among age-matched wt and mdx groups. Muscle contractures induced by caffeine (3-100 mM) or 4-CmC (0.1-5.0 mM) in the LA were greater in prepubertal than in adult and aged mice, but they did not differ among age-matched wt and mdx groups. The resting [Ca2+]i in mdx LA muscle fibers was not significantly affected at any age. Comparatively, dystrophic DIA presented reduced muscle strength in adult (40%) and aged (45%) mice, whereas the muscle responses to caffeine increased with age (63 to 82%), indicating changes in the Ca2+ handling mechanisms. The results indicated that muscle strength and calcium homeostasis in dystrophic LA muscle fibers were not significantly altered, confirming previous evidence of androgens’ beneficial effects on hormone-sensitive skeletal muscles.

Natural probes for cholinergic sites: L-bebeerine actions on the neuromuscular transmission, the nicotinic receptor/ionic channel complex, and contraction of skeletal muscles

The mechanisms underlying the muscle relaxant of 1-bebeerine (BB), a tertiary alkaloid isolated from the roots of Chondrodendron platyphyllum, were examined in mammalian and amphibian skeletal muscles. Injections of BB (0.05 - 1 g/kg,i.p.) in rats caused a dose-related flaccid paralysis and respiratory arrest at high doses. In isolated rat diaphragmand toad sartorius muscles, BB depressed the indirectly elicited muscles twitches (IC50:228 muM and 5.4 muM, respectively, at 22 degree) and blocked the nerve-elicited muscle action potential. The neuromuscular blockade was not reserved by neostigmine (10 muM). High concentrations of BB (170 and 340 muM) caused muscle contracture unrelated to the junctional blockade, and intensified by increasing the bath temperature. Analysis of the contraction properties showed that BB (40 and 80 muM)increaded the twitch/tetanus ratio (46 percent and 125 percent) and prolonged the relaxation time; the falling phase of the directly elicited action potential in toad sartorius muscle fibers was slower probably by a decreased potasium conductance. BB (0.1 - 340 muM) reduced the binding of [1251]alpha- -bungarotoxin to the junctional AACh receptor of the rat diaphragm (IC50:47.7 muM, at 37 degree. At low concentrations BB (1.5 - 15 muM) induced either opening or blockade of the Ach receptor-ionic channel. The results showed that BB blocked noncompetitively the neuromuscular transmission through a mechanism that affects the Ach recognition site and the ionic channel properties. The alkaloid also produced muscle contracture and changed the contractile properties through its extra-junctional action at the calcium handling by the sarcoplasmic reticulum or the contractile machinery.