State of the contractile apparatus in the development of a pathological process in muscle. IV. Effect of Ca2+ on the process of contraction nodule formation and on the ATPase activity of muscle actomyosin in Zenker's necrosis

Using phase-contrast and polarized ultraviolet (UV) fluorescent microscopy, the structure of single muscle fibres was studied in the course of the contraction module formation during Zenker's necrosis. The degree of manifestation of destructive changes in the contractile system was shown to depend upon the concentration of extracellular Ca-ions. With decreasing Ca2+ concentration, the fibre loses the ability to form contraction nodules peculiar to the Zenker necrosis, and the development of this process is interrupted at the stage of sarcomere supercontraction. The UV fluorescent anisotropy pattern of fibre regions, conforming with the contraction nodules, suggests the occurrence of a more pronounced disorganization of contractile system in the presence of Ca2+. The ATPase activity of actomyosin isolated from altered muscle was studied to appreciate the functional state of the contractile system. This actomyosin was found to be inactivated 1.5 times as much as that isolated from muscles treated during Zenker's necrosis in calcium-free media.     

State of the contractile apparatus during the development of a pathological process in the muscles. II. The effect of Ca2+ on the morphology of spreading necrosis caused by UV light]

Using phase-contrast technique and electron microscopy, a study was made of morphological changes of contractile system of striated muscle fibre during the spreading necrosis caused by ultraviolet light damage. It has been shown that the degree of manifestation of destructive changes in the contractile system depends upon Ca2+-ion concentration. The ultrastructural study of the damage region, under condition of muscle fibre stretching, made it possible to reveal the initial stages of formation of this pathological process. A possible contribution of intracellular membranous structures in spreading the destructive process along the muscle fibre is discussed.     

Myofibril breakdown during spreading damage. II. A calcium-free medium]

Peculiarities of Zenker's degeneration (ZD) have been investigated in fast muscle fibres of the frog incubated in a Ringer solution free of Ca++ (R--Ca) with a normal or increased (by 100 mM) concentration of KCl. ZD in these solutions is distinguished by a 10--90 minutes delay of the appearance of the primary contraction knot and cessation of ZD development in the majority of fibres after formation of several (1--5) contraction knots. In the presence of 0.5 mM EDTA in R--Ca, after a few typical contraction knots are formed, fibres commonly fall into large fragments that retain cross-striation. Contracted or super-contracted state of sarcomeres in detached contraction knots and at the necrosis boundary, as well as an increasing lysis of contactile material and proliferation of fibre membrane structures in the region of ZD arrested boundary, are characteristic of ultrastructural changes during ZD in calcium-free solutions.     

Electrophoretic study of the protein makepup of the muscles in Zenker's necrosis]

Changes of protein composition within necrotic areas of muscle at the late stages of Zenker's necrosis (3--5 hours after damage) have been studied using the disc-DSN-electrophoresis method. These changes are presumably associated with a disarrangement of the structure of thick and thin fillaments. The disturbance of the contractile system is accompanied by the loss of water soluble protein specific fractions.     

Study of structural changes of contractile muscle proteins with the aid of polarization ultraviolet fluorescence microscopy. 1. Conformational changes of F-actin in the muscle fiber caused by ATP and its analogs]

Increase of anisotropy of F-actin fluorescence of balanus and rabbit muscle fibers under the influence of ATP, AMP and pyrophosphate in EGTA presence was detected by means of the polarized ultraviolet (UV) fluorescent microscopy methods. The fluorescence anisotropy changes are assumed to be associated with the conformational changes in the actin. ATP cause more noticeable changes of actin structure, than pyrophosphate and AMP. The conformational changes in the actin of balanus and rabbit muscle fibres were similar. ATP and its analogs induced also decrease of UV fluorescence anisotropy of A-band which appears to be associated with conformational changes in myosin. It was siggested that the changes in fluorescence of anisotropy of A-bands are due to structural changes in both HMM and LMM parts of myosin molecule.     

Confocal-microscopic study of skeletal muscle fibre membrane organelles during Zenker's (spreading) necrosis

The changes of T-system and cellular acidic organelles during spreading (Zenker's) necrosis of frog skeletal muscle fibres have been investigated using laser confocal microscopy and several vital fluorescent dyes acridine orange, RH 414, DiOC6(3), rhodamine 123, fluorescein dextran. The formation of numerous vacuoles as a result of local T-system swelling is most characteristic for initial steps of Zenker's necrosis. Vacuoles can attain tens microns in length. They are located both near nuclear poles and between myofibres. Vacuoles maintain connections with the extracellular space up to the moment of contraction knot rejection, and under definite conditions (glycerol influx to fibre) vacuoles are reversible. They deform nuclei and sarcoplasmic reticulum cisternae. Cellular acidic organelles, accumulating acridine orange (lysosomes, late endosomes, Golgi apparatus cisternae) are situated in direct vicinity with normal and vacuolated T-system. The increase in acidic organelles number and size occur during the pathological process development, and tendency to vacuoles clusterization may be seen. Vacuolation of T-system during necrosis is not followed by vacuole content acidification. The role of cellular acidic organelles and of T-system vacuolation in the development of different muscle pathological changes is discussed.     

The effect of phallotoxins on the structure of F-actin in myosin-free ghost muscle fibres of rabbit

Using polarized UV fluorescent microscopy it has been shown that phallotoxins (phalloidin-sulfone, phalloidin-sulfoxide-B, phalloidin-sulfoxide-A and dithio-phalloidin) cause an increase in tryptophan fluorescence anisotropy of F-actin myofilaments in myosin-free ghost muscle fibres of rabbit. The results obtained are considered to be evidence of conformational changes in F-actin, induced by phallotoxins. These changes are irreversible to a significant extent, which points to a high degree of actin binding to both toxic and nontoxic phallotoxins.     

Effect of triethyl lead on peristaltic contractile activity of the ileum of mice

The effect of triethyl lead (TriEL) as triethyl lead chloride on the rhythmic peristaltic contractile activity of ileum isolated from Swiss white mice was investigated, with the aid of a tensiometer. The response was measured as a change in period duration and force amplitude. TriEL concentrations of < 40 microM did not show any obvious effects on either of the parameters. In the concentration range between 40 and 120 microM, TriEL exclusively affected the rhythm of contractions in a concentration-dependent manner. It induced elongation of the period and reduction of the force amplitude. Concentrations of TriEL above 120 microM induced irreversible dramatic changes in the ileum contractile activity, while 200 microM TriEL induced a strong contracture followed by an irreversible cessation of the oscillatory contractile activity. The results demonstrate that the measurement of rhythmic contractions may be a useful model for a toxicological screening system.     

The contractile apparatus of striated muscle in the course of atrophy and regeneration

Summary The ultrastructure of the contractile apparatus of the rat soleus muscle during the course of denervation atrophy was investigated. It was found that the ratio of thin to thick filaments increased in myofibrils of atrophying muscle fibers. Elevation of the ratio was observed as early as the second day after denervation, and became more pronounced with the progress of atrophy. Parallel measurements of the amounts of actin and myosin in the myofibrils and in the muscle protein extracts revealed a lower proportion of myosin heavy chains to actin in the fractions from denervated muscles, compared with the control values. Both the electron-microscopic observations and the biochemical evaluation of the actin content of the muscle, suggests that the elevated ratio of thin to thick filaments seen in the course of the muscle atrophy appears as the result of an earlier and more intensive disappearance of thick filaments. Thin filaments disappeared more slowly, in parallel to the decrease in muscle weight.On the basis of the results presented a mechanism of progress of simple atrophy of muscle in suggested.     

Periodic organization of the contractile apparatus in smooth muscle revealed by the motion of dense bodies in single cells

To study the organization of the contractile apparatus in smooth muscle and its behavior during shortening, the movement of dense bodies in contracting saponin skinned, isolated cells was analyzed from digital images collected at fixed time intervals. These cells were optically lucent so that punctate structures, identified immunocytochemically as dense bodies, were visible in them with the phase contrast microscope. Methods were adapted and developed to track the bodies and to study their relative motion. Analysis of their tracks or trajectories indicated that the bodies did not move passively as cells shortened and that nearby bodies often had similar patterns of motion. Analysis of the relative motion of the bodies indicated that some bodies were structurally linked to one another or constrained so that the distance between them remained relatively constant during contraction. Such bodies tended to fall into laterally oriented, semirigid groups found at approximately 6-microns intervals along the cell axis. Other dense bodies moved rapidly toward one another axially during contraction. Such bodies were often members of separate semirigid groups. This suggests that the semirigid groups of dense bodies in smooth muscle cells may provide a framework for the attachment of the contractile structures to the cytoskeleton and the cell surface and indicates that smooth muscle may be more well-ordered than previously thought. The methods described here for the analysis of the motion of intracellular structures should be directly applicable to the study of motion in other cell types.     

Degree of correspondence between contractile and oxidative capacities in horse muscle fibres: a histochemical study

Samples taken from the middle gluteal muscle of 95 untrained adult horses of different ages and sex were subjected to histochemical analysis using the myosin adenosine triphosphatase (m-ATPase) and nicotinamide adenine dinucleotide tetrazolium reductase (NADH-TR) staining techniques. Fibres were classified into types I, IIA and IIB according to m-ATPase activity after preincubation at pH 4.4. The percentage of FT (Fast-Twitch Glycolytic) fibres and the proportion of IIB fibres with "high" and "low" oxidative capacity were determined in serial sections stained for NADH-TR. Statistical analysis revealed a significantly higher proportion of IIB fibres than FT fibres (P less than 0.001), though both percentages were correlated. Thus, 72.2 +/- 17.6% of type IIB fibres showed low oxidative capacity, but the remaining 27.8 +/- 17.6% showed high aerobic potential, and thus did not correspond to FT fibres. These results confirm that the contractile capacity of a muscle fibre does not determine its oxidative profile. The different types of muscle fibre should thus be classified solely according to m-ATPase activity, since this characteristic is related to the molecular structure of contractile proteins. Oxidative capacity should be assessed separately, and not be used as a criterion for fibre classification in horses.     

Elastic fibres are an essential component of human placental stem villous stroma and an integrated part of the perivascular contractile sheath

The stroma of human placental stem villi is believed to consist only of reticular and collagen fibres. In the present study we were able to show for the first time by light (orcein staining) and electron microscopy large amounts of elastic fibres in the stem villous stroma. Electron microscopically, homogeneous elastin was found alone or in association with microfibrils. In addition, microfibrils were observed forming long bands. These three structures, generally known to form elastic connective tissue, were seen in close connection with placental extravascular smooth muscle cells, which belong to the perivascular contractile sheath (PVCS) of stem villi. Elastin was associated with these smooth muscle cells and connected to collagen fibres via microfibrils. Collagen fibres were additionally interconnected by spike-like structures. Extravascular smooth muscle cells revealed numerous adhesion plaques which occupied conspicuously long cytoplasmic faces of the plasma membrane. In cryostat sections, immunoreactivity of talin, an attachment protein of adhesion plaques linking intracellular α-actin filaments with extracellular fibronectin, was detected in extravascular and vascular (media) smooth muscle cells. The arrangement of placental extravascular smooth muscle cells, elastic and collagen fibres suggests a functional myofibroelastic unit within the PVCS, which surrounds the large foetal blood vessels possibly contributing to elasticity and supporting tensile and/or contracting forces within the stem villi. Received: 2 May 1995 / Accepted: 7 August 1995     

Transforming growth factor-beta 1 specifically induce proteins involved in the myofibroblast contractile apparatus

Transforming growth factor-beta(1) (TGF-beta(1)) induces alpha-smooth muscle actin (alpha-SMA) and collagen synthesis in fibroblast both in vivo and in vitro and plays a significant role in tissue repair and the development of fibrosis. During these processes the fibroblasts differentiate into activated fibroblasts (so called myofibroblasts), characterized by increased alpha-SMA expression. Because TGF-beta(1) is considered the main inducer of the myofibroblast phenotype and cytoskeletal changes accompany this differentiation, the main objective of this investigation was to study how TGF-beta(1) alters protein expression of cytoskeletal-associated proteins. Metabolic labeling of cell cultures by [(35)S]methionine, followed by protein separation on two-dimensional gel electrophoresis, displayed approximately 2500 proteins in the pI interval of 3-10. Treatment of TGF-beta(1) led to specific spot pattern changes that were identified by mass spectrometry and represent specific induction of several members of the contractile apparatus such as calgizzarin, cofilin, and profilin. These proteins have not previously been shown to be regulated by TGF-beta(1), and the functional role of these proteins is to participate in the depolymerization and stabilization of the microfilaments. These results show that TGF-beta(1) induces not only alpha-SMA but a whole set of actin-associated proteins that may contribute to the increased contractile properties of the myofibroblast. These proteins accompany the induced expression of alpha-SMA and may participate in the formation of stress fibers, cell contractility, and cell spreading characterizing the myofibroblasts phenotype.     

Superoxide scavengers augment contractile but not energetic responses to hypoxia in rat diaphragm.

Acute exposure to severe hypoxia depresses contractile function and induces adaptations in skeletal muscle that are only partially understood. Previous studies have demonstrated that antioxidants (AOXs) given during hypoxia partially protect contractile function, but this has not been a universal finding. This study confirms that specific AOXs, known to act primarily as superoxide scavengers, protect contractile function in severe hypoxia. Furthermore, the hypothesis is tested that the mechanism of protection involves preservation of high-energy phosphates (ATP, creatine phosphate) and reductions of P(i). Rat diaphragm muscle strips were treated with AOXs and subjected to 30 min of hypoxia. Contractile function was examined by using twitch and tetanic stimulations and the degree of elevation in passive force occurring during hypoxia (contracture). High-energy phosphates were measured at the end of 30-min hypoxia exposure. Treatment with the superoxide scavengers 4,5-dihydroxy-1,3-benzenedisulfonic acid (Tiron, 10 mM) or Mn(III)tetrakis(1-methyl-4-pyridyl) porphyrin pentachloride (50 microM) suppressed contracture during hypoxia and protected maximum tetanic force. N-acetylcysteine (10 or 18 mM) had no influence on tetanic force production. Contracture during hypoxia without AOXs was also shown to be dependent on the extracellular Ca(2+) concentration. Although hypoxia resulted in only small reductions in ATP concentration, creatine phosphate concentration was decreased to approximately 10% of control. There were no consistent influences of the AOX treatments on high-energy phosphates during hypoxia. The results demonstrate that superoxide scavengers can protect contractile function and reduce contracture in hypoxia through a mechanism that does not involve preservation of high-energy phosphates.     

Ultraslow contractile inactivation in frog skeletal muscle fibers

After a contracture response, skeletal muscle fibers enter into a state of contractile refractoriness or inactivation. Contractile inactivation starts soon after membrane depolarization, and causes spontaneous relaxation from the contracture response. Here we demonstrate that contractile inactivation continues to develop for tens of seconds if the membrane remains in a depolarized state. We have studied this phenomenon using short (1.5 mm) frog muscle fibers dissected from the Lumbricalis brevis muscles of the frog, with a two-microelectrode voltage-clamp technique. After a contracture caused by membrane depolarization to 0 mV, from a holding potential of -100 mV, a second contracture can be developed only if the membrane is repolarized beyond a determined potential value for a certain period of time. We have used a repriming protocol of 1 or 2 s at -100 mV. After this repriming period a fiber, if depolarized again to 0 mV, may develop a second contracture, whose magnitude and time course will depend on the duration of the period during which the fiber was maintained at 0 mV before the repriming process. With this procedure it is possible to demonstrate that the inactivation process builds up with a very slow time course, with a half time of approximately 35 s and completion in greater than 100 s. After prolonged depolarizations (greater than 100 s), the repriming time course is slower and the inactivation curve (obtained by plotting the extent of repriming against the repriming membrane potential) is shifted toward more negative potentials by greater than 30 mV when compared with similar curves obtained after shorter depolarizing periods (10-30 s). These results indicate that important changes occur in the physical state of the molecular moiety that is responsible for the inactivation phenomenon. The shift of the inactivation curve can be partially reversed by a low concentration (50 microM) of lanthanum ions. In the presence of 0.5 mM caffeine, larger responses can be obtained even after prolonged depolarization periods, indicating that the fibers maintain their capacity to liberate calcium.     

Histochemical and contractile responses of rat medial gastrocnemius to 2 weeks of complete disuse.

We studied the histochemical and in situ contractile changes in a rat ankle extensor, medial gastrocnemius, in which activation of muscle fibres by motoneurones was blocked for 14 days, using the sodium channel blocker tetrodotoxin applied to the sciatic nerve. Muscles were atrophied and showed slower twitch responses, greater fusion at subtetanic frequencies of stimulation, and higher twitch/tetanic ratios. Tetanic force/mm2 of fibre area and fatiguability were unchanged. Type II fibres were more atrophied and showed greater decreases in mitochondrial succinate dehydrogenase activity than type I fibres. The contractile changes resulting from complete disuse do not occur in models in which weight-bearing alone has been removed (space flight, hindlimb suspension), suggesting that the residual motoneurone activity reported in models of weightlessness is sufficient to prevent these responses. Similarly, the finding of a greater type II fibre susceptibility to complete disuse, which differs from the pattern seen in models of weightlessness, suggest that this residual motoneurone activity in the latter influences atrophic responses in a manner that is variable among motor unit types, to produce the reported preferential type I atrophy characteristic of removal of weight-bearing.     

Disruption of myofibrils during spreading degeneration. I. Increased Ca2+ concentration]

The breakdown of sarcomeres of frog's twitch skeletal muscles during Zenker's (spreading) degeneration has been studied. The speed of propagation of the destruction process was accelerated by increasing CaCl2 concentration in Ringer's solution up to 8mM. An hour after local injury, the fibres were fixed just before separation of the next retraction clot or at the stage of granular destruction (Fig. 1). The dominating features of the ultrastructure of a fibre at the necrotic boundary are the coagulation of small bundles of supercontracted myofibrils and breakdown of uncontracted sarcomeres into separate A- and I-bands and then into small bundles of A- and I-protofibrils (Fig. 2,3). The same breakdown of sarcomers is observed in several small regions at a distance of about 100 micron from the necrotic boundary (Fig. 5). Besides this, fusion of a few myofibrils followed by the disappearence of M- and Z-bands occurs in the same region of the fibre (Fig. 4, 6). The diameter of the majority of myofibrils decreases towards the necrotic boundary due to longitudinal splitting and loss of peripheral protofibrils, presumably, as a result of lysis (Fig. 7).     

The effects of space flight on the contractile apparatus of antigravity muscles: implications for aging and deconditioning

Previous studies have shown that the unloading of skeletal muscle, as occurring during exposure to space flight, exerts a profound effect on both the mass (cross sectional area) of skeletal muscle fibers and the relative expression of protein isoforms comprising the contractile system. Available information suggests that slow (type I) fibers, comprising chiefly the antigravity muscles of experimental animals, in addition to atrophying, undergo alterations in the type of myosin heavy chain (MHC) expressed such that faster isoforms become concomitantly expressed in a sub-population of slow fibers when insufficient force-bearing activity is maintained on the muscle. Consequently, these transformations in both mass and myosin heavy chain phenotype could exert a significant impact on the functional properties of skeletal muscle as manifest in the strength, contractile speed, and endurance scope of the muscle. To further explore these issues, a study was performed in which young adult male rats were exposed to zero gravity for six days, following which, the antigravity soleus muscle was examined for a) contractile properties, determined in situ and b) isomyosin expression, as studied using biochemical, molecular biology, and histochemical/immunohistochemical techniques.     

Mucosubstances in the human skeletal muscles.

With histomchemical, and electronmicroscopic-histochemical methods two types of human skeletal muscle fibres were established. The first type of muscle fibres does not contain acidic mucosubstances. The staining reactions and cellulase digestion indicate that, the neutral polysaccharides are cellulose-like substances. The second type of fibres contains only acidic mucosubstances, hyaluronic acid and chondroitine sulphate. The author suggests that the mucosubstances have joint function. These polysaccharides contributed to the jointing both of myofibrils and sarcomers. The polysaccharides can be exhibited in the joint points of contractile elements. In mechanical injury this point became disintegrated.     

Histochemistry and ultrastructure of nerve fibres and contractile cells in the tunica albuginea of the rat testis

Whole-mounted preparations of the tunica albuginea of the rat testis were studied using light microscopy techniques for demonstration of cholinergic nerve fibres (Karnovski-Root method), catecholaminergic nerve fibres (De la Torre's method) and actin filaments (avidin-biotin-peroxidase method). An ultrastructural study of different regions of the albuginea was also performed. Cholinergic fibres were seen to penetrate into the albuginea with the testicular artery to form a broad network in the mediastinum testis, many fibres ending beneath the rete testis epithelium. Catecholaminergic fibres penetrated through the middle part of the cauda epididymis and formed a plexus in the albuginea covering the inferior testicular pole. This plexus gave rise to straight fibres which formed varicosities, some of them appeared related with mast cells. Actin-containing cells were only found beneath the rete testis epithelium. These cells were similar to myofibroblasts. The location of both cholinergic fibres and contractile cells among the rete testis channels suggests that these cells may be involved in the pumping of semen towards the ductuli efferentes and that their contractility may be regulated by cholinergic fibres.