Effect of nitric oxide on the maximal velocity of shortening of a mouse skeletal muscle.

Maximum velocity of shortening, Vo, was measured by the method of Edman [J Physiol (Lond) 291:143-159, 1979] on extensor digitorum longus muscles of a mouse in vitro at 20 degreesC. Blockers of nitric oxide synthase, 10 mM nitro-l-arginine or 1 mM 7-nitroindazole, reduced Vo by 18% and 22%, respectively. On removal of the inhibitor, Vo returned to the control value. It was found that 10 mM nitro-d-arginine, an enantiomer of nitro-l-arginine inactive against nitric oxide synthase, did not affect Vo. A donor of nitric oxide, 0.1 mM nitroprusside, increased Vo by 15%. It removed the inhibition caused by nitro-l-arginine. Another donor of nitric oxide, 1 microM (+/-)-S-nitroso-N-acetylpenicillamine (SNAP), increased Vo by 8%. An inhibitor of cGMP synthase, 0.01 mM Ly-83583, decreased Vo by 18%. An analogue of cGMP, 0.1 mM 8-bromo-cGMP, increased Vo by 17%. A general inhibitor of phosphodiesterases, 0.02 mM 3-isobutyl-1-methylxanthine (IBMX), increased Vo by 17%. An inhibitor specific of cGMP phosphodiesterase, 0.01 mM dipyridamole, increased Vo by 8%. The maximal isometric force (F0) was not modified by the drugs, except by 7-nitroindazole and Ly-83583, which depressed F0 by 12%. The cGMP level in tetanized muscles decreased by 12-27% in the presence of blockers of nitric oxide synthase. We conclude that the level of intracellular nitric oxide modulates Vo through the cGMP pathway.

Consequences of the combined deficiency in dystrophin and utrophin on the mechanical properties and myosin composition of some limb and respiratory muscles of the mouse.

The mechanical properties and the myosin isoform composition were studied in three isolated muscles (EDL, soleus, diaphragm) of mutant mice lacking both dystrophin and utrophin (dko). They were compared with the corresponding muscles of the normal and the dystrophin-deficient (mdx) and the utrophin-deficient (uko) mice. In comparison with mdx muscles, dko muscles show a significant reduction of the normalized isometric force, confirmed by the reduced muscular activity of the whole animal. Kinetics parameters (twitch time-to-peak and half-relaxation time) were slightly reduced, and the maximal speed of shortening of soleus, Vmax, was reduced by 30%. The maximal power output (muW/mm3) was reduced by 50% in dko soleus. In the three muscles studied, the relative myosin heavy chains (MHC) composition showed a shift towards slower isoforms. dko EDL presented a dramatic decrease of the resistance ot tetanic contraction with forced lengthenings (eccentric contractions), while muscle lacking only utrophin (uko mutants) display a normal resistance to this exacting mechanical challenge. These experiments suggest that lack of both dystrophin and utrophin is very detrimental to the mice and that mechanical properties of the muscles may explain the overall phenotype. Moreover these results bring some support to the idea that the expression of utrophin in mdx muscle compensates, to some extent, for the lack of dystrophin.

Critical illness myopathy unrelated to corticosteroids or neuromuscular blocking agents.

Acute myopathy occurs in critically ill patients, receiving neuromuscular blocking agents or corticosteroids during intensive care hospitalisation. We report three patients with acute quadriplegic myopathy, two of whom were not exposed to corticosteroids or neuromuscular blocking agents. The first of these latter two patients had a history of generalised anoxia with coma related to surgery, complicated by multiple organ failure and sepsis. The second patient, suffering from acute leukaemia, developed sepsis and acute respiratory distress syndrome with the need for mechanical ventilation in the intensive care unit. Electrophysiological studies and muscle biopsy findings were consistent with the diagnosis of critical illness myopathy with loss of myosin filaments. Selective loss of myosin was confirmed by biochemical analysis of muscle. These findings demonstrate that acute myopathy with loss of myosin filaments may occur in patients with severe systemic illness without exposure to corticosteroids or neuromuscular blocking agents.

Isoforms of myosin in growing muscles of ky (kyphoscoliotic) mice.

Kyphoscoliotic (ky) mice are spontaneous mutants of the BDL strain whose postural muscles atrophy during post-natal growth, resulting in extensive kyphoscoliosis in adult animals. At 21 days of age, the seven muscles examined were already well differentiated into fast, slow and mixed type on the basis of the proportions of their native myosin isoforms or their subunits. During post-natal growth, from 21 to 120 days of age, the normal pattern of myosin maturation was essentially respected by the ky mutation: fast muscles became faster, slow muscles became slower and mixed muscles specialized in both directions. However, the post-natal increases of myosin heavy chain 2B and fast myosin light chain LC3f were depressed in ky muscles, whilst there was novel expression of slow myosin light chains, LC1s and LC2s in muscles which normally did not express them. Intermediate native myosin IM was absent in adult ky soleus, but it increased in adult ky tibialis anterior. We conclude that the ky mutation depresses the normal post-natal transition towards faster muscles and results in adult muscles whose myosin isoforms are generally shifted in a fast-to-slow direction.

Mechanical power and myosin composition of soleus and extensor digitorum longus muscles of ky mice.

Muscles of ky/ky homozygote mice exhibit neonatal muscle fiber necrosis and regeneration with subsequent motor nerve sprouting and development of a prominent kyphoscoliosis from approximately 100 days onward. Soleus and extensor digitorum longus (EDL) muscles from ky mice weighted < 50% of control muscles from age-matched NMRI mice. Maximal tetanic force was more reduced in soleus than in EDL. In EDL, the velocity constant of the force-velocity relation, maximal velocity, twitch time-to-peak, and isomyosin content were normal at all ages. The early mechanical changes seen in ky soleus muscles (47 day) were not accompanied by significant alterations in isomyosin or myosin heavy- and light-chain composition, since ky and NMRI expressed slow-twitch native myosin 2 (SM2, type I fibers) and intermediate-twitch native myosin (IM, type IIa fibers). Adult ky soleus (172 day) showed wholesale loss of IM and sole expression of SM2. This is sufficient to account for the markedly slowing of the force-velocity relation and the twitches observed in adult ky soleus. We propose that since shifts in muscle type only occurred in soleus, this reflects the persistent requirement to withstand the force of gravity.

The force-velocity relation of the rabbit inferior oblique muscle; influence of temperature.

The contractile properties of the rabbit inferior oblique muscle (IO) were studied in vitro with direct stimulation at temperatures between 20 and 35 degrees C. Isovelocity releases were used to determine the force/velocity relation. Cooling the muscle from 35 degrees C to 20 degrees C increased contraction and half-relaxation times of single twitches with a temperature coefficient (Q10) of 0.4, but did not affect significantly the twitch tension. The tetanic tension increases with increasing temperature (Q10 = 1.32). Cooling decreased the maximum shortening velocity of the IO with a Q10 of 1.6 and the maximum mechanical power with a Q10 of 2.3. At 35 degrees C, the maximum speed of shortening of the muscle (19 +/- 2 muscle lengths/s, mean +/- SEM) corresponded to a maximum shortening velocity of the sarcomeres of 57 +/- 6 microns/s. This value is similar to data obtained for extraocular muscles (EOM) of smaller rodents (mice and rats). In comparison with mammalian limb muscles the isometric and force-velocity properties of mammalian EOM appear to be virtually independent of the size of the animal. Thus, IO is a fast-twitch muscle endowed with a maximum velocity of shortening higher than that of fast-twitch skeletal muscle, but using a tetanic mechanical power lower than that produced by slow-twitch muscle: the combination of these properties makes it ideally suited to move an ocular globe of low mass at high velocity.

Force-velocity relation and isomyosins in soleus muscles from two strains of mice (C57 and NMRI).

We compared soleus muscles from two strains of mice, NMRI and C57. Soleus muscles from NMRI mice produced slower twitches and lower maximum tetanic force (Fo) but higher maximum tetanic stress (So), (owing to their smaller weight). Their Hill's velocity constant (b) was lower, but their force constant (a/So), their maximum velocity of unloaded shortening (Vu) and their maximal mechanical power (Pmax) were similar. All soleus muscles contained two isomyosins (SM2 and IM) and the two myosin heavy chains (MHC1 and MHC2A) corresponding to type I fibres and type IIA fibres; however, soleus muscles from NMRI strain had higher proportions of isomyosin SM2 and of myosin heavy chain 2A. Regression equations were computed between the mechanical variables and the myosin heavy chain content. Using a simple hypothesis, the results were used to estimate the mechanical properties of type I and type IIA fibres. We conclude that type IIA fibres from soleus muscle are mechanically more similar to slow-twitch type I fibres than to fast-twitch type II fibres. The results also suggest a hypothesis to account for the diversity of isomyosins, by a matching diversity of mechanical properties based on a separate physiological control of the three factors that control Pmax.

Regeneration after free muscle grafting in normal and dystrophic (mdx) mice.

Soleus muscles from C57BL/10 and mdx mice were isotransplanted to induce a cycle of degeneration/regeneration. Sixty days post-surgery, transplanted and contralateral soleus muscles were removed for mechanical and biochemical analyses. The regeneration which occurs after transplantation, induces in both mdx and C57BL/10 soleus muscles a decrease in maximal isometric force, together with an increase of the velocity of contraction. This increase in velocity is accompanied by the expression of typically fast-type myosin heavy chains. Thus degeneration/regeneration of both mdx and normal mice are very similar, causing a shift towards physiologically 'faster' muscle. Previous physiological and biochemical studies of mdx muscles have shown that mdx muscle is shifted towards 'slower' muscle compared to normal mice. One explanation of these findings was that the degeneration/regeneration cycles inherent in dystrophin-deficient mdx muscle causes a shift towards 'slow'. Our results argue against this hypothesis: degeneration/regeneration in both normal and mdx mice causes a shift towards 'fast'.

Force-velocity relation and myosin isozymes of rat muscles.

The proportions of three myosin heavy chains in rat soleus and EDL are used to compute a triple linear regression which predicts correctly the maximal mechanical power and approximately the parameters b and a/Fo of the Hill's equations.

Subunit composition of native myosin isoenzymes of some striated mammalian muscles.

Six "native" isomyosins of characteristic electrophoretic mobility are present in various proportions according to the muscle type (fast, slow or mixed). SM2 and SM1 contain MHC1; IM contains MHC2A; FM1, FM2 and FM3 contain MHC2A and MHC2B. SM2, SM1 and IM contain MLC1s; SM1, IM, FM2 and FM3 contain MLC1f; FM2 and FM1 contain MLC3f. The six isomyosins appear to separate on the base of their myosin light chain content.

The mobility of smooth muscle isomyosins.

The two isomyosins of smooth muscles, G1 and G2, were extracted from various visceral organs of chicken, mice, rats, rabbits and dogs. They were separated by electrophoresis in pyrophosphate polyacrylamide gels. Their mobility was the same for all samples, being higher than the mobility of several isomyosins of striated muscles obtained from leg, eye, middle ear, heart ventricle or newborn rat leg.

Detection and distribution of myosin isozymes in vertebrate smooth muscle.

Crude extracts of taenia coli (guinea-pig), gizzard (chicken), stomach, colon, ureter, bladder, mesenteric vein, mesenteric artery, uterus and vas deferens (dog) were electrophoresed under conditions which do not denature myosin (pyrophosphate gels). Two isozymes (G1 and G2) were observed in all cases. Their mobilities are the same in all organs, but there are some variations in their relative proportions. They have an ATPase activity. Based on electrophoretic mobility the light chains (L20 and L17) seem to be the same for both isozymes whilst the heavy chains are different. Isozyme G2 contains one type of heavy chain of an apparent molecular mass of 230 kDa, whilst isozyme G1 contains two types of heavy chains: one of apparent molecular mass of 230 kDa, and the other of apparent molecular mass of 200 kDa.

The isomyosins of rabbit middle ear muscles.

Isomyosins of the two middle ear muscles of rabbit have been separated by electrophoresis in non-dissociating conditions. Tensor tympani has four isomyosins called MM1 to MM4 by order of decreasing mobility. Stapedius has two isomyosins, similar to MM1 and MM4. MM1 and MM2 have the same mobility than FM2 and FM3, fast isomyosins observed in psoas. MM4 has the same mobility than IM, a slow isomyosin observed in extensor digitorum longus. MM3 is absent in soleus, psoas or extensor digitorum longus. Slow myosin (SM) of soleus and fast myosin (FM1) of psoas are not observed in middle ear muscles.

Isozymes of myosin in growing and regenerating rat muscles.

Native myosin isozymes of rat muscles have been isolated by electrophoreses in non-dissociating conditions. Their mobilities were measured, using taenia coli myosin as an internal standard and their relative concentrations were determined by computer planimetry of the electrophoretograms. Three isozymes were observed in extensor digitorum longus (EDL), two in soleus (SOL), four in neonatal muscles three days before birth. Regenerates of minced EDL or SOL muscles in adult animals had no native myosin the third day after surgery; they were similar to neonatal muscles 15 days after surgery and to adult muscles 60 days after surgery.