CARDIAC MUSCLE : Its Ultrastructure in the Finch and Hummingbird with Special Reference to the Sarcoplasmic Reticulum

Cardiac muscle fibers of the hummingbird and finch have no transverse tubules and are smaller in diameter than those of mammalian hearts. The fibers are connected by intercalated discs which are composed of desmosomes and f. adherentes; small nexuses are often interspersed. As in cardiac muscle of several other animals, the junctional SR of the couplings is highly structured in these two birds but, in addition, and after having lost sarcolemmal contact, the junctional SR continues beyond the coupling to extend deep into the interior of the cells and to form belts around the Z-I regions of the sarcomeres. This portion of the sarcoplasmic reticulum, which we have named "extended junctional SR," and which is so prominent and invariant a feature of cardiac cells of hummingbirds and finches, has not been observed in chicken cardiac cells. The morphological differences between these species of birds may be related to respective differences in heart rates characteristic for these birds.     

THE ULTRASTRUCTURE OF FROG VENTRICULAR CARDIAC MUSCLE AND ITS RELATIONSHIP TO MECHANISMS OF EXCITATION-CONTRACTION COUPLING

Frog ventricular cardiac muscle has structural features which set it apart from frog and mammalian skeletal muscle and mammalian cardiac muscle. In describing these differences, our attention focused chiefly on the distribution of cellular membranes. Abundant inter cellular clefts, the absence of tranverse tubules, and the paucity of sarcotubules, together with exceedingly small cell diameters (less than 5 µ), support the suggestion that the mechanism of excitation-contraction coupling differs in these muscle cells from that now thought to be characteristic of striated muscle such as skeletal muscle and mammalian cardiac muscle. These structural dissimilarities also imply that the mechanism of relaxation in frog ventricular muscle differs from that considered typical of other striated muscles. Additional ultrastructural features of frog ventricular heart muscle include spherical electron-opaque bodies on thin filaments, inconstantly present, forming a rank across the I band about 150 mµ from the Z line, and membrane-bounded dense granules resembling neurosecretory granules. The functional significance of these features is not yet clear.     

Entrance of colloidal ThO2 tracer into the T tubules and longitudinal tubules of the guinea pig heart

Summary Colloidal ThO₂ particles (diameter of 60 Å) were used as electron-opaque markers to trace the intracellular compartments continuous with the bulk interstitial fluid of guinea pig ventricular muscle. Beating and quiescent hearts in a Langendorff preparation were perfused for 30 min with oxygenated Ringer solution containing 1% ThO₂. The hearts were immediately fixed by perfusing with glutaraldehyde solution. The colloidal ThO₂ particles entered into many of the T tubules and into longitudinallyrunning tubules. No differences in distribution of ThO₂ were observed in a heart which was not exposed to ThO₂ until after it was fixed. Tracer did not penetrate into the intercalated disk clefts in the guinea pig hearts and one frog heart used for comparison. Tubular profiles filled with ThO₂ were not seen in frog heart, an observation which confirms the absence of T tubules in this amphibian. It is concluded that, in mammalian cardiac muscle, the lumens of the longitudinal tubules are continuous with the lumens of the T tubules, forming an extensively interconnected T-L tubular system. Hence, every myofibril has close access to a fluid-filled space which is continuous with the interstitial fluid and which may be of similar cationic composition; such an arrangement should facilitate excitation-contraction coupling.Supported by grants from the American Heart Association and from the Public Health Service (HE-11155, HE-05815 and HE-10384). The authors wish to acknowledge the expert technical assistance of Mrs. Jan Redick and to thank Dr. James Smith of Marquette University for the supply of Thorotrast used in these studies.     

Ultrastructure of the neurogenic heart of Limulus polyphemus

Summary The ultrastructure of Limulus cardiac muscle was examined. The hearts were fixed in situ by perfusion with isotonic glutaraldehyde solution while in relaxed, contracted, or stretched states. The sarcomeres are relatively long, varying in length from about 2.5 to 6.6 . The average A-band length is 2.46 . M lines are absent, and H zones are poorly distinguished. Thick and thin filament diameters average about 200 Å and 50 Å, respectively; each thick filament is surrounded by 8–12 thin ones. Superficial invaginations of the sarcolemma occur, making contact with the Z lines of the outermost myofibrils. There is an extensive sarcoplasmic reticulum and transverse (T) tubules. Some T tubules run longitudinally and some open into deep sarcolemmal invaginations which extend into the fiber interior. The T tubules swell markedly in hypertonic solution. Single neurons and small bundles of neurons are observed in close apposition with myocardial cells. Intercalated disks are found in Limulus heart at regions of contact between contiguous myocardial cells lying end to end; semitight or gap junctions are essentially absent. Prominent differences in sarcomere lengths sometimes occur across the disk, thus indicating that the disks demarcate cells functionally. Hence, in addition to direct motoneuron activation, there may be some transfer of excitation across the intercalated disks in accord with our previous finding that propagating, overshooting action potentials can be induced in this heart.Supported by grants from the American Heart Association and from the Public Health Service (HE-11155 and HE-05815). I thank Mrs. Jan Redick for expert technical assistance.     

Loss of the plateau of the cardiac action potential in hypertonic solutions

The effect of hypertonicity on the electrical properties of vertebrate myocardial cells was studied in ventricular muscle fibers of guinea pig, cat, frog, and chicken. The latter two species do not have a T-tubule system, whereas the former two do. In hypertonic solutions (2 x isotonic) produced by addition of sucrose or excess of NaCl, cell diameter decreased and there was a slight hyperpolarization and decrease in action potential overshoot. In guinea pig and cat, the hypertonic solution caused a decrease in input resistance and the plateau of the action potential to disappear in some of the cells; contractions of the entire ventricle also became depressed. These effects were reversed by returning the muscle fibers to isotonic solution. Addition of 5 mM SrCl₂ to the hypertonic solution also caused the plateau component and contraction to reappear. In frog and chick cells, loss of the plateau component and contraction never occurred in hypertonic solution, and input resistance increased. Urea and glycerol hyperosmolarity (2 x) caused no loss of the plateau component or contraction. If the frog and chicken ventricular, and guinea pig atrial myocardial cells (all of which lack T tubules) were to serve as an adequate control for possible effects of hypertonicity on the surface membrane and on contractile proteins, then the results suggest that swelling of the T tubules of mammalian myocardial cells leads to loss of the plateau component.     

The ultrastructural effects of triparanol on rat atrial muscle

Summary The atrial musculature of rats given the cholesterol inhibitor triparanol (MER/29) (250 mg/kg daily) for 8 days was examined under the electron microscope and compared with that from untreated animals. The sarcoplasmic core of muscle fibers from animals given triparanol exhibited a new formation of sarcoplasmic granules which displayed a crystalline latticework with opaque lines approximately 40–60 Å separated by clear spaces 50–70 Å. They were partially or completely surrounded by a membrane. The crystalline bodies in cardiac muscle fibers were not as numerous as those observed in adrenocortical, testicular interstitial, or luteal cells as reported earlier by the investigators.This research was supported by USPHS Grants HE 12751, NS 05665, and 00690.Recipient of Career Research Development Award 1 K 3 GM 28064.     

Deduced amino acid sequence and E1-E2 equilibrium of the sarcoplasmic reticulum Ca(2+)-ATPase of frog skeletal muscle. Comparison with the Ca(2+)-ATPase of rabbit fast twitch muscle.

The cDNA encoding a Ca(2+)-transport ATPase of frog (Rana esculenta) skeletal muscle was isolated and characterized. The deduced amino acid sequence, consisting of 994 residues, showed 89% identity to the fast twitch muscle sarcoplasmic reticulum Ca(2+)-ATPases of chicken and rabbit. Northern blot analysis using a fragment of this cDNA as probe detected a 5.0 kb message in frog skeletal muscle but did not detect any mRNA encoding sarcoplasmic reticulum Ca(2+)-ATPase in frog cardiac muscle. The enzymatic properties of the amphibian skeletal muscle Ca(2+)-ATPase were compared with those of the rabbit fast twitch muscle Ca(2+)-ATPase by functional expression of the cDNAs in COS-1 cells. The amphibian Ca(2+)-ATPase displayed a reduced apparent affinity for Ca2+ and an increased apparent affinity for the inhibitors, vanadate and thapsigargin, relative to the mammalian enzyme. This may be explained by a mechanism in which relatively more of the E2 conformation accumulated in the frog Ca(2+)-ATPase than in the mammalian enzyme.     

Ultrastructure of muscle fibers and cells synthesizing DNA in lymph hearts of developing frogs and chick embryos

Summary The ultrastructure of striated muscle fibers and ³H-thymidine (³HTdr)-labeled cells adjacent to them in the lymph hearts of larvae of Rana temporaria, yearling frogs, and 9- to 13-day-old chick embryos was studied by use of electron-microscopic autoradiography. A comparatively high level of differentiation of lymph-heart muscle fibers was observed not only in yearling frogs but also in larvae. Myosatellites occurred at all stages of development. No mitoses were found in muscle fibers. In 9- to 13-day-old chick embryos the myofibers of lymph hearts were somewhat less differentiated than those of the larvae and yearling frogs. Differentiating sarcomeres were often seen in the sarcoplasm of myofibers of chick embryos. The analysis of the ultrastructure of ³HTdr-incorporating cells shows that 2–4 h after the single ³HTdr administration only mononucleated cells devoid of myofilaments are commonly labeled both in tadpoles and chick embryos. When fixation is postponed by 48–70 h, myonuclei frequently become labeled. Thus, the data obtained support the evidence that proliferation and differentiation processes in the developing muscle tissue of the lymph heart of both species studied are mutually exclusive, similar to the situation in differentiating vertebrate skeletal muscle.     

THE ULTRASTRUCTURE OF THE CAT MYOCARDIUM : I. Ventricular Papillary Muscle

The ultrastructure of cat papillary muscle was studied with respect to the organization of the contractile material, the structure of the organelles, and the cell junctions. The morphological changes during prolonged work in vitro and some effects of fixation were assessed. The myofilaments are associated in a single coherent bundle extending throughout the fiber cross-section. The absence of discrete "myofibrils" in well preserved cardiac muscle is emphasized. The abundant mitochondria confined in clefts among the myofilaments often have slender prolongations, possibly related to changes in their number or their distribution as energy sources within the contractile mass. The large T tubules that penetrate ventricular cardiac muscle fibers at successive I bands are arranged in rows and are lined with a layer of protein-polysaccharide. Longitudinal connections between T tubules are common. The simple plexiform sarcoplasmic reticulum is continuous across the Z lines, and no circumferential "Z tubules" were identified. Specialized contacts between the reticulum and the sarcolemma are established on the T tubules and the cell periphery via subsarcolemmal saccules or cisterns. At cell junctions, a 20 A gap can be demonstrated between the apposed membranes in those areas commonly interpreted as sites of membrane fusion. In papillary muscles worked in vitro without added substrate, there is a marked depletion of both glycogen and lipid. No morphological evidence for preferential use of glycogen was found.     

Structural organization of two fast,rhythmically active crustacean muscles

Summary The organization of the flagellum abductor muscle and of a scaphognathite levator muscle of the green crab, Carcinus maenas, has been compared quantitatively using light and electron microscopy. These muscles are rhythmically active at relatively high frequencies and for long durations. Fibers of both muscles are interconnected to form fascicles of 50 or more fibers within which there is cytoplasmic continuity. A single muscle is made up of 8–12 fascicles. Individual fibers consist of a peripheral rind of densely packed mitochondria, a thick region of glycogen granules, and myofibrils arranged into scattered central islands. Less than half the volume-density of these muscles is contractile material, the balance being largely mitochondria and glycogen. The fibers within a muscle are structurally similar. They have short sarcomeres (about 2 m), thin to thick filament ratios of about 3:1, and junctions between the sarcoplasmic reticulum and the transverse tubules at the M line. Sarcoplasmic reticulum occupies about 10% of the myofibrillar volume-density. A well developed sarcoplasmic reticulum appears to underlie the capacities of these two muscles for high frequency contraction; extensive mitochondria and glycogen stores should confer fatigue resistance under both aerobic and anaerobic conditions.     

Ruthenium-red staining of skeletal and cardiac muscles

Summary The effects of ruthenium red (RR) on amphibian and mammalian skeletal muscles and mammalian myocardium were examined. In skeletal muscle cells, a discrete pattern of staining can be brought about within the lumina of the terminal cisternae (junctional sarcoplasmic reticulum [SR]) by sequential exposure to RR and OsO₄. After prolonged immersion in RR solution, formation of pentalaminar segments (zippering) occurs at various points along the longitudinal (network) SR tubules. Zippering can be elicited in skeletal SR at any stage of preparation prior to postfixation with OsO₄. By means of dispersive X-ray analysis, both ruthenium and osmium were seen to be deposited in skeletal muscle junctional SR, and ruthenium was detected in the myoplasm as well. In skeletal muscles whose T tubules were ruptured by exposure to glycerol, the pattern of SR staining and zippering resulting from ruthenium-osmium treatment was not affected. These findings indicate that RR is capable of passage across the sarcolemma of skeletal muscle and that this passage does not occur solely under conditions in which the plasma membrane is damaged. In contrast, RR does not opacify or modify any region of the SR of cardiac muscle. However, after this treatment, randomly distributed opaque bodies, composed of parallel lamellar structures, appear throughout the myocardial cells. A few of these bodies are associated with lipid droplets, but the rest are of unknown origin. The failure of the SR of cardiac muscle to stain after exposure to ruthenium dye (even though this material enters these cells) suggests that the chemical composition of cardiac SR is significantly different from that of skeletal muscle SR.Supported in part by PHS grant HL-11155 (to N.S.) and American Heart Grant-in-Aid 78-753 (to M.S.F.). The authors are grateful to Drs. David Harder and Lawrence Sellin for their assistance with the preparation of frog skeletal muscle, to Dr. S.K. Jirge for his helpful suggestions and discussions, and particularly to Dr. Kenneth R. Lawless and Ms. Ann Marshall of the Department of Materials Sciences, University of Virginia School of Engineering, and Col. John M. Brady of the United States Army Institute of Dental Research, Walter Reed Army Medical Center, for their help with, and for the use of, the X-ray analysis equipment     

Localization of Mg2+-ATPase in the membranes of the skeletal muscles and myocardium of the frog Rana temporaria

Using differential centrifugation in sucrose density gradient, from muscles of the frog fractions were obtained which contain fragments of sarcolemma, as well as membranes of T-system tubules and sarcoplasmic reticulum. In isolated membrane fractions, studies were made on the activity of cation-stimulated ATPases (Na+, K+-, Ca2+, Mg2+- and Mg2+-ATPases). Enzymic and electrophoretic analyses showed that the highest content of Mg2+-ATPases is typical of the fractions which are located on the surface of 35% sucrose. The data obtained indicate that Mg2+-ATPase is the enzyme which is specific for the membranes of T-system tubules in skeletal muscles of not only birds but amphibians as well. From cardiac muscle of the frog, membrane fraction was isolated which is similar (with respect to its predominant content of Mg2+-ATPase) to the membranes of T-system tubules. It is suggested that the presence of Mg2+-ATPase in these membranes is a common property of phasic striated muscle fibers in all mature vertebrate animals.     

Alterations in myocardial ultrastructure and protein expression after a single injection of isoproterenol

Immunochemical and electron microscopic characterization of rat myocardium was conducted 2 h and 3 weeks after a single injection of isoproterenol in rats. The relative content of several myospecific proteins (KRP – kinase-related protein, desmin), cytoskeletal proteins (tubulin, vinculin, myosin light chain kinase – MLCK) and extracellular matrix protein fibronectin was determined by immunoblotting. Two hours after injection of 50 mg/kg isoproterenol a destruction of some cardiomyocytes, contracture of myofibrils and mild edema of intercellular space was observed. The content of all the studied proteins except KRP decreased below control levels. This situation sustained 3 weeks after injection and paralleled alterations in cardiomyocyte ultrastructure. Areas of myofibrillar contracture and lysis were noted, glycogen granules were sparse; mitochondria contained arrow-like inclusions that are characteristic for calcium overload, also huge mitochondria contacting each other by specialized intermitochondrial contacts were detected. Clumps of unripe elastic fibers in enlarged intercellular space were combined with increased deposition of collagens type I and III forming areas of fibrosis. The smaller dosage of isoproterenol (10 mg/kg) rendered no significant damage in the acute postinjection period but 3 weeks later it induced the thickening of extracellular matrix around cardiac cells and the increase in KRP and tubulin content by 26 and 32%, correspondingly. MLCK levels remained depressed throughout the experiment. The rise in KRP expression was also observed after the addition of isoproterenol to cultured chicken embryo cardiomyocytes. Obtained results indicate that even a single injection of isoproterenol creates long lasting structural alterations in cardiac muscle accompanied by the increased expression of extracellular matrix proteins and several sarcoplasmic proteins apparently involved in hypertrophic response of cardiomyocytes.     

Factors determining the duration of a single postsynaptic response in neuromuscular junctions

Parameters of single acetylcholine-activated ionic channels and the time course of miniature end-plate currents (MEPC) were compared in experiments on fast and slow lamprey, frog, chicken, and rat muscle fibers. The mean open time of the channels was shown to be the principal, but not the only factor determining the duration of MEPC. The role of the remaining factors and, in particular, of insufficiency of acetylcholinesterase activity, in slow muscle fibers and also in "giant" MEPC generation, is much greater than in fast fibers or during ordinary MEPC generation. Relatively low acetylcholinesterase activity favors asynchronous interaction between acetylcholine molecules and receptors, which delays the time course of synaptic responses. Mechanisms of acceleration of MEPC decay under the influence of -bungarotoxin and D-tubocurarine, and also the conditions for MEPC generation in different regions of the neuromuscular junction are discussed.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 16, No. 5, pp. 590–602, September–October, 1984.     

Muscle remodeling in adult snapping shrimps via fast-fiber degeneration and slow-fiber genesis and transformation

Bilateral asymmetry of the paired snapper/pincer claws may be reversed in adult snapping shrimps (Alpheus heterochelis). Removal of the snapper claw triggers transformation of the contralateral pincer claw into a snapper and the regeneration of a new pincer claw at the old snapper site. During this process the pincer closer muscle is remodeled to a snapper-type, and these alterations have been examined with the electron microscope. There is selective death of the central band of fast fibers, accompanied by an accumulation of electron-dense crysttaline bodies in the degenerating fibers. Two principal types of hemocytes (amebocytes and coagulocytes) invade the area and the degenerating muscle fibers. New myotubes also appear in this central site. The myotubes are characterized by a prolific network of presumptive sarcoplasmic reticulum and transverse tubules, nascent myofibrils, and crystalline bodies. The myotubes are innervated by many motor nerve terminals, and they subsequently differentiate into long-sarcomere (8–12 m), slow muscle fibers. Remodeling of the central band, therefore, occurs by degeneration of the fast fibers and their replacement by new slow fibers. Remnants of the degenerating fast fibers act as scaffolding for the myotubes which originate from adjacent satellite cells. The crystalline bodies may represent protein stores from the degeneration of the fast fibers, recycled for use in the genesis of new fibers. The invading hemocytes appear to play several roles, initially phagocytosing the fast muscle fibers, transporting the crystalline bodies into the new myotubes, and acting as stem cells for the new muscle fibers. Apart from the central band of fibers, the remaining pincer-type slow fibers with sarcomere lengths of 5–7 m are transformed via sarcomere lengthening into snapper-type slow fibers with sarcomere lengths of 7–12 m. Thus, during claw transformation in adult snapping shrimps, the pincer closer muscle is remodeled into a snapper closer muscle by selective death of the fast-fiber band, replacement of the fast-fiber band by new slow fibers, and transformation of the existing slow fibers to an even-slower variety. Note. This paper is dedicated to the fond memory of Professor M.S. Laverack whose enjoyment of biological research and gentle encouragement of such endeavours touched all those who knew him.     

CARDIAC MUSCLE : A Comparative Study of Purkinje Fibers and Ventricular Fibers

With light and electron microscopy a comparison has been made of the morphology of ventricular (V) and Purkinje (P) fibers of the hearts of guinea pig, rabbit, cat, dog, goat, and sheep. The criteria, previously established for the rabbit heart, that V fibers are distinguished from P fibers by the respective presence and absence of transverse tubules is shown to be true for all animals studied. No evidence was found of a permanent connection between the sarcoplasmic reticulum and the extracellular space. The sarcoplasmic reticulum (SR) of V fibers formed couplings with the sarcolemma of a transverse tubule (interior coupling) and with the peripheral sarcolemma (peripheral coupling), whereas in P fibers the SR formed only peripheral couplings. The forms of the couplings were identical. The significance, with respect to excitation-contraction coupling, of the difference in the form of the couplings in cardiac versus skeletal muscle is discussed together with the electrophysiological implications of the differing geometries of bundles of P fibers from different animals.     

Muscle tissue histogenesis of the lymph hearts of chick embryos

By means of electron microscope autoradiography, the ultrastructure of muscle fibers, and the capacity if muscle of cell nuclei of 3H-thymidine (3H-T) incorporating of were studed in developing lymph hearts of 0-13 day old chick embryos, rather active sarcomerogenesis developing lymph hearts of 9-13 day old chick embryos, a rather active sarcomerogenesis being observed. Filament of intermediate size microtubules, Golgi complexes, centrioles, and numbers free ribosomes and polysomes were observed in the sarcoplasm. The sarcoplasmic reticulum channels were not numerous, their terminal cisterns often formed "subsarcolemmal cisternae". Between muscle fibers, cell junctions of fasciae adherentes type were observed. Two hours after 3H-T administrations, only mononuclear cells without myofilaments were labeled. If fixation was made 70 hours after 3H-T administration, then the label was found in addition on muscle fiber nuclei. These data evidence that the lymph heart muscle tissue histogenesis undergoes the same patterns of development as does the somatic muscle tissue.     

THE ULTRASTRUCTURE OF THE CAT MYOCARDIUM : II. Atrial Muscle

The ultrastructure of the cells specialized for contraction in the atrium and ventricle of young adult cats are compared. The cells specialized for conduction are not included. In addition to possessing distinctive atrial granules, the cells of the atrium are smaller in diameter (5–6 µ) than ventricular cells (10–12 µ) and have strikingly fewer T tubules. These latter differences are discussed in terms of their possible significance for the rate of conduction of the action potential. It is suggested that the very small number of T tubules in atrial cells may compensate for the small cell diameter, and thus permit rapid conduction of the action potential across the surface of the atrium. Coated dense vesicles found in association with the sarcoplasmic reticulum at the level of the Z line in ventricular muscle are more evident in atrial cells. In the virtual absence of T tubules in atrial cells, the sub-sarcolemmal cisternae of the sarcoplasmic reticulum are almost exclusively at the cell periphery. The ends of the cells and their processes in ventricular muscle are rectilinear with the interdigitated portions of the intercalated discs oriented transversely, whereas those of the atrium are often oblique to the myofilament axis. This difference may be related to the lower mechanical tension on atrial cells.     

Evidence for the presence of calsequestrin in two structurally different regions of myocardial sarcoplasmic reticulum

Localization of calsequestrin in chicken ventricular muscle cells was determined by indirect immunofluorescence and immuno-Protein A-colloidal gold labeling of cryostat and ultracryotomy sections, respectively. Calsequestrin was localized in the lumen of peripheral junctional sarcoplasmic reticulum, as well as in the lumen of membrane-bound structures present in the central region of the I-band, while being absent from the lumen of the sarcoplasmic reticulum in the A-band region of the cardiac muscle cells. Since chicken ventricular muscle cells lack transverse tubules, the presence of calsequestrin in membrane bound structures in the central region of the I-band suggests that these cells contain nonjunctional regions of sarcoplasmic reticulum that are involved in Ca2+ storage and possibly Ca2+ release. It is likely that the calsequestrin containing structures present throughout the I-band region of the muscle cells correspond to specialized regions of the free sarcoplasmic reticulum in the I-band called corbular sarcoplasmic reticulum. It will be of interest to determine whether Ca2+ storage and possibly Ca2+ release from junctional and nonjunctional regions of the sarcoplasmic reticulum in chicken ventricular muscle cells are regulated by the same or different physiological signals.