Ultrastructural duality of extrafusal fibers in a slow (tonic) skeletal muscle

Summary Ultrastructural and stereological assessment of the mature avian anterior latissimus dorsi (ALD) muscle showed that it contains two kinds of extrafusal fibers. This fine structural dichotomy of fiber types in the ALD correlated well with their previously reported histochemical duality. Distinct differences occur in sarcomere banding, myofibrillar area, sarcotubular and mitochondrial density, and in morphology of motor-nerve terminals. Both myofiber types in this muscle were interpreted as representing varieties of slow or tonic muscle fibers.Both fibers contain myofibrils that, despite differences in cross-sectional area, were large, irregular, and ribbon-shaped, typical of the Felderstruktur appearance of true slow fibers. Whereas the majority of fibers (type-1) are devoid of well-defined M-bands, the minor fiber population (type-2) exhibit prominent M-bands in the center of each sarcomere. In addition, type-1 tonic fibers contain a significantly lower mitochondrial and sarcotubular volume than the tonic fibers of type-2. While both fiber types exhibit motor-nerve terminals that are small, smooth and punctate in appearance, those on the type2 fibers often had a number of shallow postjunctional folds. Whether or not these two classes of extrafusal fiber in this muscle represent two separate and distinct types of motor units remains to be determined functionally.Supported by grants from the Medical Research Council and the Muscular Dystrophy Association of Canada. The author gratefully acknowledges the excellent technical assistance of Susan L. Shinn     

The effect of long-term denervation on the ultrastructure of Pacinian corpuscles in the cat

Summary The ultrastructure of Pacinian corpuscles of the cat located in the crural region and innervated by the interosseous nerve was studied 1 to 14 months after denervation. Both the Pacinian inner core and capsule remained well preserved one month after denervation. However, the denervated inner cores underwent progressive atrophy and wasting, which resulted in a gradual reduction of the amount of inner-core cells and lamellae, widening of interlamellar clefts, formation of empty spaces in the axial region and a considerable increase in the number of collagen fibrils. In spite of the wasting, the inner core still survived 14 months after denervation, but at least half of its volume became occupied by collagen fibrils which surrounded the remaining inner-core cells and lamellae. Collagen fibrils assembled in the denervated core were markedly thinner than those found in the capsule, as is also the case in normal Pacinian corpuscles. In the capsule, discrete focal degeneration, occasional pyknosis of the innermost capsular cells and macrophage infiltration were observed from the first month after nerve section onward, but the number of capsular layers remained within the normal range (30–40) up to 14 months after denervation.     

Cell proliferation in skeletal muscle following denervation or tenotomy

Summary Autoradiographic experiments using ³H-thymidine were designed to analyse cell proliferation which occurs in skeletal muscle after denervation and after tenotomy. In mouse tibialis anterior and tongue muscles during the first 24 h after denervation or tenotomy labelling levels were low and did not differ significantly from sham operated control muscles. By 48 h after denervation and tenotomy of tibialis anterior muscles, increased levels of labelling occurred in both muscle and connective tissue nuclei. Daily pulse labelling for 7 days after denervation produced a labelling level which was 8 times that of sham operated controls, 25–30% of the total nuclear population being labelled. Denervated muscles had twice the level of labelling compared to tenotomised muscles. These results provide conclusive evidence that both denervation and tenotomy stimulate cell proliferation in skeletal muscle and it is suggested that the increased numbers of labelled muscle nuclei are likely to be the result of mitotic activity in muscle satellite cells.     

Proteomic analysis of rat laryngeal muscle following denervation

Laryngeal muscle atrophy induced by nerve injury is a major factor contributing to the disabling symptoms associated with laryngeal paralysis. Alterations of global proteins in rat laryngeal muscle following denervation were, therefore, studied using proteomic techniques. Twenty-eight adult Sprague-Dawley rats were divided into normal control and denervated groups. The thyroarytenoid (TA) muscle was excised 60 days after right recurrent laryngeal nerve was resected. Protein separation and identification were preformed using 2-DE and MALDI-MS with database search. Forty-four proteins were found to have significant alteration in expression level after denervation. The majority of these proteins (57%), most of them associated with energy metabolism, cellular proliferation and differentiation, signal transduction and stress reaction, were decreased levels of expression in denervated TA muscle. The remaining 43% of the proteins, most of them involved with protein degradation, immunoreactivity, injury repair, contraction, and microtubular formation, were found to have increased levels of expression. The protein modification sites by phosphorylation were detected in 22% of the identified proteins that presented multiple-spot patterns on 2-D gel. Significant changes in protein expression in denervated laryngeal muscle may provide potential therapeutic strategies for the treatment of laryngeal paralysis.     

Galectin-1 expression in innervated and denervated skeletal muscle

Galectin-1 is a soluble carbohydrate-binding protein with a particularly high expression in skeletal muscle. Galectin-1 has been implicated in skeletal muscle development and in adult muscle regeneration, but also in the degeneration of neuronal processes and/or in peripheral nerve regeneration. Exogenously supplied oxidized galectin-1, which lacks carbohydrate-binding properties, has been shown to promote neurite outgrowth after sciatic nerve sectioning. In this study, we compared the expression of galectin-1 mRNA and immunoreactivity in innervated and denervated mouse and rat hind-limb and hemidiaphragm muscles. The results show that galectin-1 mRNA expression and immunoreactivity are up-regulated following denervation. The galectin-1 mRNA is expressed in the extrasynaptic and perisynaptic regions of the muscle, and its immunoreactivity can be detected in both regions by Western blot analysis. The results are compatible with a role for galectin-1 in facilitating reinnervation of denervated skeletal muscle.     

Cellular heterogeneity during vertebrate skeletal muscle development

Although skeletal muscles appear superficially alike at different anatomical locations, in reality there is considerably more diversity than previously anticipated. Heterogeneity is not only restricted to completely developed fibers, but is clearly apparent during development at the molecular, cellular and anatomical level. Multiple waves of muscle precursors with different features appear before birth and contribute to muscular diversification. Recent cell lineage and gene expression studies have expanded our knowledge on how skeletal muscle is formed and how its heterogeneity is generated. This review will present a comprehensive view of relevant findings in this field.     

Survival of Pacinian corpuscles after denervation in adult rats

Summary The ultrastructure of Pacinian corpuscles located on the crural interosseous membrane was studied in adult rats 6 h to 10 months after transection of the right sciatic nerve. Axon terminals degenerated one day after transection and were engulfed and resorbed by cells of the inner core within one week. The axial space left after removal of the axonal debris was closed by the lamellae of the inner core. The main structural features of the inner core and capsule remained preserved after denervation throughout the period of study. The denervated inner cores, however, became atrophic 10 months after neurotomy, their mean diameter being reduced by 17.5% compared with that of contralateral control corpuscles. The number of capsular lamellae was unaltered, and perineurial pathways of the peripheral nerve stump remained preserved. Schwann cells proliferated and formed Büngner bands during the first month after denervation, but retracted their processes and became atrophic at later stages after neurotomy.Survival of Pacinian corpuscles after long-term denervation in adult rats is in contrast to their rapid degeneration within several days after nerve section in neonates.     

Effects of long term denervation on smooth muscle of the chicken expansor secundariorum

Summary Denervation of the expansor secundariorum muscle of the adult and 2 week chicken, by sectioning the brachial plexus, resulted in an approximate twofold increase in dry weight over 8 weeks. Unlike skeletal muscle, no ultrastructural changes were exhibited by the smooth muscle cells for a period of up to 5 months post denervation. No evidence of hypertrophy of the individual muscle cells was observed, but following colchicine treatment a definite increase in the number of mitotic figures was noted within muscle bundles indicating that the increase in dry weight of the expansor muscle is due to hyperplasia of the smooth muscle cells. The results are discussed in relation to in vitro studies of the interaction of sympathetic nerves with smooth muscle.     

Assessment of skeletal muscle damage in successive biopsies from strength-trained and untrained men and women

The effects of repeated biopsy sampling on muscle morphology was qualitatively and quantitatively assessed in strength-trained and untrained men and women. College-age men (13) and women (8) resistance trained twice a week for 8 weeks. A progressive resistance-training program was performed consisting of squats, leg presses, and leg extensions. Nontraining men (7) and women (5) served as controls. Muscle biopsy specimens and fasting bloods were obtained at the beginning and every 2 weeks and histochemical, biochemical, and ultrastructural methods were employed to assess the type and amount of damage. Except for a few scattered atrophic fibers in 2 of the 33 biopsy samples, all initial specimens were normal. In contrast, many of the subsequent biopsy samples from both untrained and resistance-trained men and women contained evidence of damage. Ultrastructural analysis confirmed that degenerative-regenerative processes were occurring in both groups. However, training subjects had a four-fold greater number of damaged fibers than nontraining subjects (8.53% vs 2.08%). In addition, only biopsy samples from training individuals contained fibers with internal disorganization (e.g., Z-line streaming, myofibrillar disruption). Calpain II levels in the biopsy samples and serum creatine kinase activity were not significantly affected supporting the light and electron microscopic observations that most of the damaged fibers were normal in appearance except for their small diameter. In summary, focal damage induced by the biopsy procedure is not completely repaired after 2 weeks and could affect the results, particularly cross-sectional area measurements. Moreover, resistance training appears to cause additional damage to the muscle and may delay repair of the biopsied region.     

Protamine induced intracellular uptake of horseradish peroxidase and vacuolation in mouse skeletal muscle in vitro

Summary The uptake in vitro of horseradish peroxidase (HRP) in mouse skeletal muscle was examined by electron microscopy and chemical determination.In muscles exposed to an HRP solution for 60 min at +37°C, HRP infiltrated the basal lamina of muscle fibres and caused an intense labelling of their sarcolemma. In addition HRP was found within the transverse tubules. Exposure to HRP for 30 min at +37°C followed by HRP together with a polycationic protein (protamine) for 30 min at +37°C caused an intracellular vesicular uptake of HRP. Intracellular HRP was found in numerous vesicles, membrane limited bodies and vacuoles. Protamine also induced focal autophagic vacuolation with progressive muscle fibre degeneration. An intracellular HRP uptake or muscle cell vacuolation could not be detected in the absence of protamine or when the incubation temperature was + 4°C. Chemical determination of HRP uptake was in general agreement with the morphological results. The uptake of HRP in the presence of protamine was stimulated at +31°C and blocked at +4°C.The results suggest that in skeletal muscle in vitro intracellular uptake of macromolecules occurs by endocytosis.     

Lactate: a substrate for reptilian muscle gluconeogenesis following exhaustive exercise

Summary The pattern of lactate and glycogen metabolism in red and white muscle fibers was examined in fasted, cannulated lizards (Dipsosaurus dorsalis) run on a treadmill to exhaustion. The white and red portions of the iliofibularis (wIF, rIF) muscle of the hindlimb were analyzed post-exercise and at intervals over 120 min of recovery for lactate and glycogen changes. Five min of exercise resulted in lactate concentrations of from 35 mM (rIF) to 48 mM (wIF) while blood lactate concentrations were elevated to 21 mM from resting levels of 1.8 mM. Glycogen depletion was significant (p<0.05) in whole hindlimb (–30%) and in wIF (–42%) but not in rIF (–25%). Metabolite changes were consistent with a pattern of fiber type recruitment favoring fast-twitch glycolytic (FG) fibers during high intensity locomotion. Glycogen replenishment during recovery was fiber typespecific. After 2 h recovery, whole hindlimb glycogen concentration had increased 24% above pre-exercise levels (p<0.05). Rates of glycogen resynthesis during recovery were significant only in oxidative fibers of the red iliofibularis. Animals were infused with either [U-¹⁴C]-lactate or [U-¹⁴C]-glucose at the point of exhaustion, and label incorporation into muscle glycogen was used to estimate the substrate preference for glycogenesis during recovery. Lactate uptake and incorporation occurred in both wIF and rIF. Glucose uptake and incorporation into glycogen was greatest in the rIF, where it equalled 9% of the rate of lactate incorporation. The rate of lactate incorporation could account for 67% of the rate of glycogen synthesis that occurred in oxidative fibers of the rIF. The data indicate that in contrast to mammalian muscle, reptilian muscle replenishes glycogen while it removes lactate, utilizing lactate directly as a gluconeogenic substrate. The data also suggest that lactate produced by FG fibers during exercise is utilized by oxidative fiber types post-exercise to synthesize glycogen in excess of pre-exercise levels.Abbreviations wIF, rIF white, red portions of iliofibularis muscle - FG fast-twitch, glycolytic muscle fiber - FOG fast-twitch, oxidative, glycolytic muscle fiber - HPLC high performance liquid chromatography - SA specific activity - [LA] lactate concentration - GLU glucose - ANOVA analysis of variance - C.I. confidence interval     

Diversification of the myofibrillar M-band in rat skeletal muscle during postnatal development

Summary The fine structure of the M-band in soleus (SOL) and extensor digitorum longus (EDL) muscles in newborn and four-week-old rats was studied using electron-microscopic techniques. In newborn rats, all myotubes and fibres in both muscles had an identical myofibrillar appearance. A five-line M-band pattern was seen in longitudinal sections and distinct M-bridges in cross-sections. The Z-discs were of medium width. On the other hand, in four-week-old rats, different muscle fibre types were observed on the basis of their myofibrillar pattern. In SOL two fibre types were distinguished in longitudinal sections. One had a four-line M-band pattern and very broad Z-discs, whereas the other type had five lines in the M-band and broad Z-discs. In EDL, three different myofibrillar patterns were observed. The M-bands were composed of three, four or five lines. Fibres had either thin, broad or medium Z-disc widths, respectively. In cross-sections of the SOL muscle one group of fibres showed indistinct M-bridges, whereas distinct M-bridges were seen in the other fibres and in all observed EDL muscle fibres. We conclude that initially there seems to be a single intrinsic program for M-band genesis; this program becomes modified upon the induction of functionally differentiated fibres.     

Primary cultures of endothelial cells of the rat liver

Summary In the soleus muscle of the normal rat the number of cells containing fast troponin I decreased and those containing slow troponin I increased after birth until less than 10% stained for the fast form in the adult muscle. On denervation of soleus muscle this pattern of change was reversed with the result that the majority of cells stained for fast troponin I. The change was more rapid when denervation was carried out at 12 weeks rather than at 52 weeks of age. Denervation of extensor digitorum longus and tibialis anterior muscles produced little change in the distribution of fast and slow troponin I over a period of 12 weeks. After long periods (>24 weeks) of denervation of these fast muscles, fast troponin I was observed in cells in which originally only slow troponin I could be detected. Similar results to those obtained with troponin I in both fast and slow muscles were obtained using antibodies to the fast and slow forms of troponin C and troponin T.     

The fiber composition of the semitendinosus muscle of the rabbit

Summary The semitendinosus muscle of the rabbit is composed of a homogeneous fiber population. Fiber typing was carried out by means of light and electron microscopy according to which this muscle exhibits structural features that are either characteristic for both red and white fibers, or that do not allow for any classification according to the A-, B-, C-fiber system. Hence the long-held assumption that the semitendinosus muscle of the rabbit represents a classical paradigm of a red muscle should be revised in light of the present results.     

Semaphorin 6C expression in innervated and denervated skeletal muscle

Semaphorins are secreted or transmembrane proteins important for axonal guidance and for the structuring of neuronal systems. Semaphorin 6C, a transmembrane Semaphorin, has growth cone collapsing activity and is expressed in adult skeletal muscle. In the present study the expression of Semaphorin 6C mRNA and immunoreactivity has been compared in innervated and denervated mouse hind-limb and hemidiaphragm muscles. Microscopic localization of immunoreactivity was studied in innervated and denervated rat skeletal muscle. The results show that Semaphorin 6C mRNA expression and immunoreactivity on Western blots are down-regulated following denervation. The mRNA of Semaphorin 6C as well as immunoreactivity determined by Western blots are expressed in extrasynaptic as well as perisynaptic regions of muscle. Immunohistochemical studies, however, show Semaphorin 6C-like immunoreactivity to be concentrated at neuromuscular junctions. The results suggest a role for Semaphorin 6C in neuromuscular communication.     

Effect of denervation on pigeon slow skeletal muscle

Summary The slow anterior latissimus dorsi muscle (ALD) of the pigeon was denervated surgically and examined after varying post-operative intervals. Muscles were studied with respect to changes in weight, histological and ultrastructural alterations, and changes in size and number of fibers. The weights of the denervated muscles increased over the contralateral control, reaching a maximum hypertrophy in the first 18 days, but the hypertrophy persisted for several months. The fibers of the denervated muscle did not hypertrophy. They showed a gradation in size from the posterior to the anterior border, with the fibers in the anterior third of the muscle being the smallest. After measuring cross-sectional sizes from the anterior, middle, and posterior thirds of the muscle, the overall fiber change was one of atrophy.Morphologically, the fibers showed various signs of pathological changes, including nuclear proliferation, swelling and migration away from the sarcolemmal position, vacuolation, myofibril degeneration, connective-tissue infiltration and replacement of the fibers, and regenerative activities in the form of budding and myoblast formation. A condition termed a peripheral rim of degeneration is described. Although many abnormal conditions were found in these denervated muscles, much of the muscle appeared normal; the neurotrophic relationship of slow muscle is discussed.This investigation was supported in part by a Public Health Service Fellowship, 2 F 2 NB 35, 582, from the National Institute of Neurological Diseases and Stroke, and by an Ohio University Research Grant to R. Hikida; and a grant 5 RO 1 AN 10856 from the National Institute of Arthritis and Metabolic Diseases to W. Bock.The authors wish to acknowledge gratefully the skillful technical assistance of Mr. Lawrence Mezza and Miss Sally Mitchell.     

Effects of colchicine and vinblastine on neurotubules of the sciatic nerve and cholinesterases in the developing myoneural junction of the rat

Summary Colchicine (0.1 M) or vinblastine (0.01 M) was locally applied on the sciatic nerves of newborn rats. Both colchicine and vinblastine caused reversible disappearance of axonal neurotubules and appearance of increased amounts of neurofilaments at the site of application. Subsequent morphogenesis of myoneural junctions in the tibialis anterior muscle was studied after histochemical demonstration of acetylcholinesterase (AChE; E.C. 3.1.1.7) and non-specific cholinesterase (Ns. ChE; E.C. 3.1.1.8) activity in the myoneural area.Development of the postsynaptic muscle plasma membrane of the myoneural junction was arrested in the ipsilateral, but not in the contralateral control side, for a period of about three weeks following treatment with the test substances. After this delay the myoneural morphogenesis continued normally and neurotubules were seen in the axoplasm.Since disruption of neurotubules is likely to cause blockage of the intratubular axoplasmic transport system, it seems possible that the neurotrophic influence responsible for the development of the postsynaptic muscle membrane is mediated through a secretory product transported along axons intratubularly to the nerve endings.