The tracheal supply and muscle metabolism during muscle growth in the puparium of Calliphora vomitoria

Thirty hours after puparium formation in Calliphora, the larval tracheal system is replaced by an air-filled pupal system. This is characterized initially by many tufts of tracheae and coiled tracheoles lying in the blood. Between the third and fourth day, the sixth dorsal longitudinal flight muscles are practically without attached tracheae and their longitudinal growth can partially occur when oxygen uptake is inhibited with potassium cyanide. Sodium iodoacetate prevents muscle growth. After the fifth day of development the pupal tracheoles spread out over the surface of the developing adult muscles. Between the seventh and ninth day, longitudinal growth and increases in the diameter of the myofibrils are halted by cyanide and iodoacetate. Some longitudinal growth and an increase in the total protein content of the muscles can occur in 1% oxygen. Air filling of the adult tracheae takes place 2–3 hr before the emergence of the adult and is accompanied by an increase in oxygen consumption of the thorax. The metabolism and growth of the muscles is discussed with respect to their changing oxygen supply.     

Intracellular Calcium Movements of Frog Skeletal Muscle during Recovery from Tetanus

Radioautographs of ⁴⁵Ca-labeled frog skeletal muscles have been prepared using freeze-dry and vapor fixation techniques to avoid displacement of the isotope during the preparation of the radioautographs. ⁴⁵Ca has been localized in resting muscles exposed to ⁴⁵Ca Ringer's for 5 min or 5 hr and in isotopically labeled muscles recovering from tetanic stimulation at room temperature or at 4°C. In muscles soaked at rest for 5 min ⁴⁵Ca was present almost exclusively in the terminal cisternae. In all other muscles there were three sites at which the isotope was concentrated: (a) the terminal cisternae, (b) the intermediate cisternae and the longitudinal tubules, and (c) the A band portion of the myofibrils. The terminal cisternae were labeled more rapidly than the myofibrils, but both exchanges were accelerated by electrical stimulation. The amount of ⁴⁵Ca in the longitudinal tubules and the intermediate cisternae decreased with time after a tetanus as the amount in the terminal cisternae increased. It is proposed that electrical stimulation releases calcium from the terminal cisternae and that relaxation occurs from the binding of the released calcium by the longitudinal tubules and the intermediate cisternae. Complete recovery from mechanical activity involves the transport of this bound calcium into the reticulum and its subsequent binding by the terminal cisternae. Resting exchange of calcium occurs primarily between the terminal cisternae and the transverse tubules.     

THE SARCOPLASMIC RETICULUM AND TRANSVERSE TUBULES OF THE FROG''S SARTORIUS

The sarcoplasmic reticulum of the frog's sartorius muscle was examined by electron microscopy following sequential fixation in glutaraldehyde and osmium tetroxide and embedding in Epon. The earlier results of Porter and Palade on Ambystoma muscle were confirmed in the sartorius. In addition, the transverse tubules were observed to be continuous across the width of the fiber, a set of flat intermediate cisternae was seen to connect the terminal cisternae to the longitudinal tubules in the A band, and the continuous reticulum collar at the center of the A band was found to be perforated by circular and elongated pores (the fenestrated collar). The transverse tubules have a volume about 0.3 per cent of the fiber volume, and a surface area about 7 times the outer cylindrical surface area for a fiber 100 µ in diameter. The terminal cisternae, the intermediate cisternae, and the longitudinal tubules together with the fenestrated collar each have a volume of 4 to 5 per cent of the fiber volume and a surface area 40 to 50 times the outer surface area of a fiber 100 µ in diameter. Some evidence for continuity of the transverse tubules with the fiber surface is presented, but this is thought to be not so convincing as evidence presented by others. The results are discussed in terms of a possible mechanism for a role of the transverse tubules and sarcoplasmic reticulum in excitation-contraction coupling, as suggested by their morphology and a variety of physiological studies. In this scheme, the transverse tubules are thought to be electrically coupled to the terminal cisternae, so that depolarization of the fiber surface spreads inward along the transverse tubules and to the terminal cisternae, initiating the release of a contraction-activating substance.     

Fine structure of the Malpighian tubules of chironomus larva in relation to glycogen storage and fate of hemoglobin

The larval Malpighian tubules of Chironomus tentans were studied using light and electron microscopy. The tubules are composed of two cell types: primary and stellate cells. Both cell types lack muscles, tracheoles, and laminate crystals in the cytoplasm and mitochondria in the microvilli. The primary cells exhibit long, wide basal membrane infoldings associated with mitochondria. They have a number of canaliculi and long, closely packed microvilli. The stellate cells possess shorter interconnecting basal infoldings and shorter, well-spaced microvilli. Both cell types are linked by septate and gap junctions. They have cytoplasmic processes and pedicels which enclose narrow slits between them and that are apposed to a basal lamella. In the 'fed' larva, the cells are stuffed with glycogen which is depleted in the 'starved' larva. Both cell types are involved in the vesicular transport of biliverdin. The presence of coated vesicles, tubular elements and various forms of lysosomes in the primary cells suggests they transport and break down functional hemoglobin. Structural modification of basal infoldings, canaliculi and microvilli is strongly correlated with increased secretory activity of the Malpighian tubules in 'fed' versus 'starved' larva.     

Laser Confocal scanning microscopy of the surface membrane/T-tubular system and the sarcoplasmic reticulum in insect striated muscle stained with DiIC18(3)

The structure of the surface membrane/transverse tubular (T-tubular) system and of the sarcoplasmic reticular (SR) of the labial adductor muscle of the honey bee (Apis mellifera) was examined by laser confocal scanning microscopy, after staining with the fluorescent membrane probe DiIC₁₈(3). The following components of the surface membrane/T-tubular system were visualized: transverse tubular networks that are located in the A-band close to the A–I junction and form dyads with the SR, longitudinal tubules that link the T-tubular networks within and between sarcomeres, and surface invaginations of larger diameter that contain tracheoles. The well developed SR forms a dense network of branching and anastomosing tubules in the A-band. A few tubular elements in the interfibrillar space in the 1-band link the SR of adjacent sarcomeres. This study demonstrates the advantages of the laser confocal microscope and lipophilic fluorescent dyes for studying the 3-D structure of cellular membrane systems.     

The fungicide Pristine® inhibits mitochondrial function in vitro but not flight metabolic rates in honey bees

Honey bees and other pollinators are exposed to fungicides that act by inhibiting fungal mitochondria. Here we test whether a common fungicide (Pristine®) inhibits the function of mitochondria of honeybees, and whether consumption of ecologically-realistic concentrations can cause negative effects on the mitochondria of flight muscles, or the capability for flight, as judged by CO₂ emission rates and thorax temperatures during flight. Direct exposure of mitochondria to Pristine® levels above 5 ppm strongly inhibited mitochondrial oxidation rates in vitro. However, bees that consumed pollen containing Pristine® at ecologically-realistic concentrations (≈1 ppm) had normal flight CO₂ emission rates and thorax temperatures. Mitochondria isolated from the flight muscles of the Pristine®-consuming bees had higher state 3 oxygen consumption rates than control bees, suggesting that possibly Pristine®-consumption caused compensatory changes in mitochondria. It is likely that the lack of a strong functional effect of Pristine®-consumption on flight performance and the in vitro function of flight muscle mitochondria results from maintenance of Pristine® levels in the flight muscles at much lower levels than occur in the food, probably due to metabolism and detoxification. As Pristine® has been shown to negatively affect feeding rates and protein digestion of honey bees, it is plausible that Pristine® consumption negatively affects gut wall function (where mitochondria may be exposed to higher concentrations of Pristine®).     

Corrosion casts as a method for investigation of the insect tracheal system

Summary The tracheal systems of five insect species (two species of ants, worker bee, housefly and the cabbage butterfly) have been studied by scanning electron microscopy of corrosion casts. This technique, which is commonly used for the investigation of vertebrate vasculature, is adapted to demonstrate the ultrastructure of the insect respiratory organ. The problem of filling a blind ending system was solved by injecting the resin Mercox into the evacuated tracheae through a thoracal spiracle. After polymerization of the resin, the tissue was digested enzymatically and chemically. The three-dimensional structure of the tracheal system was investigated by scanning electron microscopy. The technique used here displays for the first time the complex morphology of the entire tracheal system in fine detail, especially the structure of spiracles, airsacs, tracheae and tracheoles. Smooth-walled terminal tracheoles show up in flight muscles. The finest tracheoles that could be identified have diameters of approximately 70 nm. This approaches the finest tracheoles portrayed by transmission electron micrographs.     

High -resolution scanning electron-microscopic studies on the three-dimensional structure of mitochondria and sarcoplasmic reticulum in the different twitch muscle fibers of the frog

Summary The three-dimensional structure of the mitochondria and sarcoplasmic reticulum (SR) in the three types of twitch fibers, i.e., the red, white and intermediate skeletal muscle fibers, of the vastus lateralis muscle of the Japanese meadow frog (Rana nigromaculata nigromaculata Hallowell) was examined by high resolution scanning electron microscopy, after removal of the cytoplasmic matrices.The small red fibers have numerous mitochondrial columns of large diameter, while the large white fibers have a small number of mitochondrial columns of small diameter. In the medium-size intermediate fibers, the number and diameter of the mitochondrial columns are intermediate between those of the red and white fibers.In all three types of fibers, the terminal cisternae and transverse tubules form triads at the level of each Z-line. The thick terminal cisternae continue into much thinner flat intermediate cisternae, through a transitional part where a row of tiny indentations can be observed. Numerous slender longitudinal tubules originating from the intermediate cisternae, extend longitudinally or obliquely and form elongated oval networks of various sizes in front of the A-band, then fuse to form the H-band collar (fenestrated collar) around the myofibrils. On the surface of the H-band collar, small fenestrations as well as tiny hollows are seen. The three-dimensional structure of SR is basically the same in all three muscle fiber-types. However, the SR is sparse on the surface of mitochondria, so the mitochondria-rich red fiber has a smaller total volume of SR than the mitochondria-poor white fiber. The volume of SR of the intermediate fiber is intermediate between other the two.     

A COMPARISON OF THE FINE STRUCTURES OF FROG SLOW AND TWITCH MUSCLE FIBRES

The organisation of the myofibrils and the sarcoplasmic reticulum in frog slow muscle fibres has been compared with that in twitch fibres. It has been found that the filaments have the same length in the two types of fibre, but that there are differences in their packing: (a) in contrast to the regular arrangement of the I filaments near the Z line in twitch fibres, those in slow fibres are irregularly packed right up to their insertion into the Z line; (b) the Z line itself shows no ordered structure in slow fibres; (c) the fine cross-links seen between the A filaments at the M line level in twitch fibres are not present in slow fibres. The sarcoplasmic reticulum in slow fibres consists of two separate networks of tubules. One set of tubules (diameter about 500 to 800 A) is oriented mainly in a longitudinal direction. The tubules of the other network (diameter about 300 A) are oriented either transversely at approximately Z line level or longitudinally, connecting the transverse tubules. Triads are very rarely found, occurring at only every 5th or 6th Z line of each fibril. The central element of these triads is continuous with the thin tubules. Slow fibres from muscles soaked in ferritin-containing solutions contain ferritin particles in the network of thin tubules, the rest of the sarcoplasm remaining free of ferritin.     

Penetration of horseradish peroxidase into the terminal cisternae of frog skeletal muscle fibers and blockade of caffeine contracture by Ca++ depletion

Summary Horseradish peroxidase, an extracellular marker, was given intravenously to frogs, and 40 min later the sartorius muscles were removed. The isolated muscles were exposed for an additional hour to Ringer solution containing peroxidase, then fixed with glutaraldehyde. Peroxidase activity was found in the T tubules, in some of the terminal cisternae (TC) of the SR, and occasionally in the longitudinal tubules of the SR. In transverse sections, the structures containing tracer formed a pattern of approximately parallel columns reaching to the cell surface; the statistical distribution of their spacing was nearly the same as that of the interdistances between the current-sensitive spots on the Z-line which triggered localized contraction (Huxley and Taylor, 1958). The caffeine contracture of frog sartorius muscles remained unchanged in isotonic Ringer solutions which were Ca⁺⁺-free or contained Mn⁺⁺ or La⁺⁺⁺; however, contracture was blocked by prior exposure of the muscles to the same solutions made 2 × hypertonic with sucrose (known to produce swelling of T tubules and (TC). Since Mn⁺⁺ and La⁺⁺⁺ are known to depress Ca⁺⁺ influx, these results suggest that washout of Ca⁺⁺ from the TC, and penetration of La⁺⁺⁺ or Mn⁺⁺ into it, occur more rapidly due to the swelling of T tubules and TC associated with hypertonicity. It is concluded that at least some of the terminal cisternae are open to the interstitial fluid via the T tubules. Thus, depolarization of the T tubules could readly depolarize the cisternae and lead to Ca⁺⁺ influx into the myoplasm.Supported by grants from the Public Health Service (HE-11155, HE-05815, and HE-10384) and from the American Heart Assocation. The authors are indebted to Mrs. Jan Redick for expert technical assistance.     

Penetration of horseradish peroxidase into the terminal cisternae of frog skeletal muscle fibers and blockade of caffeine contracture by Ca++ depletion

Summary Horseradish peroxidase, an extracellular marker, was given intravenously to frogs, and 40 min later the sartorius muscles were removed. The isolated muscles were exposed for an additional hour to Ringer solution containing peroxidase, then fixed with glutaraldehyde. Peroxidase activity was found in the T tubules, in some of the terminal cisternae (TC) of the SR, and occasionally in the longitudinal tubules of the SR. In transverse sections, the structures containing tracer formed a pattern of approximately parallel columns reaching to the cell surface; the statistical distribution of their spacing was nearly the same as that of the interdistances between the current-sensitive spots on the Z-line which triggered localized contraction (Huxley and Taylor, 1958). The caffeine contracture of frog sartorius muscles remained unchanged in isotonic Ringer solutions which were Ca⁺⁺-free or contained Mn⁺⁺ or La⁺⁺⁺; however, contracture was blocked by prior exposure of the muscles to the same solutions made 2 × hypertonic with sucrose (known to produce swelling of T tubules and (TC). Since Mn⁺⁺ and La⁺⁺⁺ are known to depress Ca⁺⁺ influx, these results suggest that washout of Ca⁺⁺ from the TC, and penetration of La⁺⁺⁺ or Mn⁺⁺ into it, occur more rapidly due to the swelling of T tubules and TC associated with hypertonicity. It is concluded that at least some of the terminal cisternae are open to the interstitial fluid via the T tubules. Thus, depolarization of the T tubules could readly depolarize the cisternae and lead to Ca⁺⁺ influx into the myoplasm.Supported by grants from the Public Health Service (HE-11155, HE-05815, and HE-10384) and from the American Heart Assocation. The authors are indebted to Mrs. Jan Redick for expert technical assistance.     

The ultrastructure of the striated muscles of Derocheilocaris typica (Mystacocarida,Crustacea)

The striated muscles of Derocheilocaris typica consist of mononucleated cells, each containing one filament bundle. Large muscles consist of two or more cells adjacent to each other. The mitochondria line up along the filament bundle on one side. The nucleus is situated in the mitochondrial row and has a small cytoplasmic area around it filled with glycogen. The sarcomeres are between 3 and 6 μm long. The Z-line and H band are present. Six thin filaments surround one thick filament. All muscles belong to the phasic type. The tubular system emanates from the ends of the muscle cell and penetrates the whole cell. The tubules are formed as cisterns, which also open at the cell membrane at the level of the I bands. They have sarcoplasmic cisterns on both sides forming a continuous triad system. Partially transformed epidermal cells mediate muscle insertions on the cuticle. Tendons are formed with the transformed epidermal cells being supplemented by fibroblasts forming collagen fibers. Dorsal and ventral abdominal muscles are innervated from the dorso-lateral nerve arising from the nerve chain. Each muscle cell receives one axon, which forms one synapse on the mitochondrial-free side of the muscles. Axons form terminal spines, which make axo-axonal synapses.     

Nerve-muscle networks in the accessory gland tubules of a male insect: Structural and physiological properties

The accessory gland tubules of the cockroach Leucophaea maderae, (F.) are innervated by the phallic nerves which arise from the terminal ganglion. Tubule preparations stained with methylene blue showed that a fine network of nerve fibres covers the entire surface of the tubule with putative nerve cells at various points. Muscle fibres of the tubules were arranged in an irregular lattice and appeared as flattened elipses approx 8–10 μm across and 1.5 μm in thickness. These muscles were monomyofibrillar with a poorly developed T-tubule system and a diffuse Z band. Innervation of the muscles showed abundant evidence of neurosecretomotor-type terminals. Clear evidence was also obtained for a multiterminal-type innervation. Accessory gland tubules had a basic wave-like pattern of motion in vitro which showed a wide variation in the time-course of each swing (1–50 s). A twisting and curling motion of the tubules was also recorded. Spontaneous junctional potentials were observed in accessory gland preparations isolated from the terminal ganglion. The duration for junction potential ranged between 30–140 ms. Action potentials recorded from muscles had a slower rise time and a longer duration (230–530 ms).     

Die Feinstruktur kristalloider Einschlüsse in Mitochondrien von Porterioochromonas stipitata

Summary The matrix of the mitochondria of Porterioochromonas stipitata Lewin (Chrysophyceae) often contains crystalloid inclusion bodies that are composed of hexagonally packed fibrils (or tubules). The fibrils have a diameter of 10 nm, their center-to-center spacing is 13,5 nm.     

Neural activity pattern is not necessary for the development of adult ultrastructure in katydid (Neoconocephalus robustus) singing muscles

Summary The singing muscles of the katydid Neoconocephalus robustus develop adult ultrastructure late in the last nymphal instar and during the first few days of adult life. The ultrastructural changes during early adulthood were not affected by unilateral axotomy shortly after the adult molt. Both denervated and innervated muscles developed adult proportions of mitochondria, myofibril, and sarcoplasmic reticulum and transverse tubules.     

Characteristics of functioning of succinate dehydrogenase from flight muscles of the bumblebee Bombus terrestris (L.)

It was found that the succinate oxidation rate in mitochondria of flight muscles of Bombus terrestris L. increased by a factor of 2.15 after flying for 1 h. An electrophoretically homogenous preparation of succinate dehydrogenase with a specific activity of 7.14 U/mg protein and 81.55-fold purity was isolated from B. terrestris flight muscles. It is shown that this enzyme is represented in the muscle tissue by only one isoform with R _f = 0.24. The molecular weight of the native molecule and its subunits A and B was determined. The kinetic characteristics of succinate dehydrogenase (K _m = 0.33 mM) and the optimal concentration of hydrogen ions (pH 7.8) were established, and the effect of salts on the enzyme activity was studied. The role of succinate as a respiratory substrate in stress and the structural and functional characteristics of the succinate dehydrogenase system in the flight muscles of insects are discussed.     

THE ORGANIZATION OF FLIGHT MUSCLE IN AN APHID, MEGOURA VICIAE (HOMOPTERA) : With a Discussion on the Structure of Synchronous and Asynchronous Striated Muscle Fibers

The organization of the indirect flight muscle of an aphid (Hemiptera-Homoptera) is described. The fibers of this muscle contain an extensive though irregularly disposed complement of T system tubules, derived as open invaginations from the cell surface and from the plasma membrane sheaths accompanying the tracheoles within the fiber. The sarcoplasmic reticulum is reduced to small vesicles applied to the T system surfaces, the intermembrane gap being traversed by blocks of electron-opaque material resembling that of septate desmosomes. The form and distribution of the T system and sarcoplasmic reticulum membranes in flight muscles of representatives of the major insect orders is described, and the extreme reduction of the reticulum cisternae in all asynchronous fibers (to which group the aphid flight muscle probably belongs), and the high degree of their development in synchronous fibers is documented and discussed in terms of the contraction physiology of these muscle cells.     

Intramembranous particles in the form of ridges,bracelets or assemblies in arthropod tissues

Non-junctional intramembranous particle arrays in the form of ridges, bracelets or rectilinear assemblies have been found by freeze-fracturingin the cytoplasmic half or P face of the plasma membrane in a variety of arthropod tissues. These tissues include both excitable cells, nerve and muscle, and such other cells as those from the intestinal tract, the tracheal system and the connective tissue. The intramembranous ridges are short rows of fused particles about 10 nm in diameter; comparable particles comprise the bracelets and the rectilinear aggregates, although the former are of lower profile. In cells sending out cytoplasmic projections during migration and development, for example, axons in embryonic, newly hatched or pupal tissues, tracheoles or fibroblasts, the intramembranous ridges are always aligned parallel to the longitudinal axis of the cellular process. The physiological significance of these may be that they play some role in recognition during development, perhaps by contact guidance. The ridges and rectilinear arrays found in the gut could also be involved in recognition and/or adhesion. In muscle, bead-like ridges are intimately associated with the transverse tubular system and may have a receptor function. Irregular and circular low-profile ridges occur in the tissues of the horseshoe crab, Limulus, and ‘bracelet’ forms are found in the inner membrane of insect pupal tracheae. The latter may play a part in the initiation and development of small tracheoles.     

The fate of proline in the African fruit beetle Pachnoda sinuata

Metabolic pathways of proline consumption in working flight muscles and its resynthesis were investigated in the African fruit beetle, Pachnoda sinuata.Mitochondria isolated from flight muscles oxidise proline, pyruvate and α-glycerophosphate, but not palmitoyl-carnitine. At low proline concentrations, the respiration rate during co-oxidation of proline and pyruvate is additive, while at high proline concentrations it is equal to the respiration rates of proline oxidation.Flight muscles have high activities of alanine aminotransferase and NAD⁺-dependent malic enzyme which are involved in proline metabolism. Glycogen phosphorylase and glyceraldehyde-3-phosphate dehydrogenase (carbohydrate breakdown) also display high activities, whilst 3-hydroxyacyl-CoA dehydrogenase (fatty acid oxidation) showed low activity.During the oxidation of proline, mitochondria isolated from flight muscles produce equimolar amounts of alanine. The rates of oxygen consumption by the mitochondria during this process lead to the conclusion that proline is partially oxidised. This is confirmed by the incorporation of radiolabel from pre-injected [U-¹⁴C] proline into alanine during a flight experiment with P. sinuata.Proline is resynthesised, in vitro, from alanine and acetyl-CoA in the fat body. High activities of enzymes catalysing such pathways (alanine aminotransferase, 3-hydroxyacyl-CoA dehydrogenase and NADP⁺-dependent malic enzyme) were found. The in vitro production of proline from alanine is equimolar suggesting that resynthesis of one proline molecule is accomplished from one alanine molecule and one acetyl-CoA molecule. One source of the acetyl-CoA for the in vitro synthesis of proline is the lipid stores of the fat body.Proline synthesis by fat body tissue is controlled by feedback. Alanine aminotransferase is competitively inhibited by high proline concentrations.