Effect of myonuclear number and mitochondrial fusion on Drosophila indirect flight muscle organization and size

Mechanisms involved in establishing the organization and numbers of fibres in a muscle are not completely understood. During Drosophila indirect flight muscle (IFM) formation, muscle growth is achieved by both incorporating hundreds of nuclei, and hypertrophy. As a result, IFMs provide a good model with which to understand the mechanisms that govern overall muscle organization and growth. We present a detailed analysis of the organization of dorsal longitudinal muscles (DLMs), a subset of the IFMs. We show that each DLM is similar to a vertebrate fascicle and consists of multiple muscle fibres. However, increased fascicle size does not necessarily change the number of constituent fibres, but does increase the number of myofibrils packed within the fibres. We also find that altering the number of myoblasts available for fusion changes DLM fascicle size and fibres are loosely packed with myofibrils. Additionally, we show that knock down of genes required for mitochondrial fusion causes a severe reduction in the size of DLM fascicles and fibres. Our results establish the organization levels of DLMs and highlight the importance of the appropriate number of nuclei and mitochondrial fusion in determining the overall organization, growth and size of DLMs.     

Coordination between the electrical activity of developing indirect flight muscles and the firing activity of a population of neurosecretory cells in the silkmoth, Bombyx mori

The developing indirect flight muscles of pharate moths are characterized by a rhythmic discharge of a long bout of flight-pattern-like muscle potentials in the absence of contractions. The electrical activity of the dorsal longitudinal flight muscles (DLMs) in the silkmoth, Bombyx mori, was discernible as a cluster of many series of muscle potentials that last for several minutes on day 4 of the pupal period. The duration of the active phases and the period of rhythmic activity gradually increased to a peak value on day 7 or 8 and then declined until the end of the pupal period. Mean duration of the active phases (+/-SD) and the mean period of the rhythmic activity (+/-SD) at the peak were 38.7+/-8.7 min and 74.5+/-7.3 min, respectively. The rhythmic electrical activity of immature DLMs was closely coordinated with the rhythmic (bursting) activity of a population of neurosecretory cells that are known to produce pheromone-biosynthesis activating neuropeptide (PBAN) and its related peptides, which belong to the multifunctional peptide family, pyrokinin/PBAN. The DLMs always became active a few minutes after the neurosecretory cells, and the timing of onset of these two activities appeared to be strictly regulated by a neural mechanism. The implication of the coordinated activity for development and maturation of imaginal tissues, including the flight motor system, and possible functions of the neuropeptides in this development are discussed.     

Electrophysiological Recordings from the Giant Fiber Pathway of D. melanogaster

When startled adult D. melanogaster react by jumping into the air and flying away. In many invertebrate species, including D. melanogaster, the "escape" (or "startle") response during the adult stage is mediated by the multi-component neuronal circuit called the Giant Fiber System (GFS). The comparative large size of the neurons, their distinctive morphology and simple connectivity make the GFS an attractive model system for studying neuronal circuitry. The GFS pathway is composed of two bilaterally symmetrical Giant Fiber (GF) interneurons whose axons descend from the brain along the midline into the thoracic ganglion via the cervical connective. In the mesothoracic neuromere (T2) of the ventral ganglia the GFs form electro-chemical synapses with 1) the large medial dendrite of the ipsilateral motorneuron (TTMn) which drives the tergotrochanteral muscle (TTM), the main extensor for the mesothoracic femur/leg, and 2) the contralateral peripherally synapsing interneuron (PSI) which in turn forms chemical (cholinergic) synapses with the motorneurons (DLMns) of the dorsal longitudinal muscles (DLMs), the wing depressors. The neuronal pathway(s) to the dorsovental muscles (DVMs), the wing elevators, has not yet been worked out (the DLMs and DVMs are known jointly as indirect flight muscles - they are not attached directly to the wings, but rather move the wings indirectly by distorting the nearby thoracic cuticle) (King and Wyman, 1980; Allen et al., 2006). The di-synaptic activation of the DLMs (via PSI) causes a small but important delay in the timing of the contraction of these muscles relative to the monosynaptic activation of TTM (~0.5 ms) allowing the TTMs to first extend the femur and propel the fly off the ground. The TTMs simultaneously stretch-activate the DLMs which in turn mutually stretch-activate the DVMs for the duration of the flight. The GF pathway can be activated either indirectly by applying a sensory (e.g."air-puff" or "lights-off") stimulus, or directly by a supra-threshold electrical stimulus to the brain (described here). In both cases, an action potential reaches the TTMs and DLMs solely via the GFs, PSIs, and TTM/DLM motoneurons, although the TTMns and DLMns do have other, as yet unidentified, sensory inputs. Measuring "latency response" (the time between the stimulation and muscle depolarization) and the "following to high frequency stimulation" (the number of successful responses to a certain number of high frequency stimuli) provides a way to reproducibly and quantitatively assess the functional status of the GFS components, including both central synapses (GF-TTMn, GF-PSI, PSI-DLMn) and the chemical (glutamatergic) neuromuscular junctions (TTMn-TTM and DLMn-DLM). It has been used to identify genes involved in central synapse formation and to assess CNS function.     

Early stages of flight muscle development in the blowfly Lucilia cuprina: A light and electron microscopic study

In Lucilia cuprina the dorsal longitudinal flight muscles of the adult develop from two sets of three larval muscles. About the end of the first day after puparium formation the three degenerating larval fibres on each side of the thorax cleave longitudinally into six. The numerous neighbouring myoblasts, which multiply by mitotic divisions, fuse gradually with the developing fibres, so the myoblast nuclei become incorporated into the sarcoplasm to form the muscle syncytium. The changes in length of the muscle fibres are not uniform. Between 30 to 56 hr after puparium formation the fibres shorten, but after this they rapidly increase in length. The structures of the tendon-like strands and of the anterior extremity of the growing fibres are described.     

Neural- and endocrine control of flight muscle degeneration in the adult cricket,Gryllus bimaculatus

Neural- and endocrine mechanisms controlling degeneration of a dorsal longitudinal flight muscle, M112a, have been studied in adult Gryllus bimaculatus (Orthoptera: Gryllidae). Decapitation completely prevented muscle degeneration. Implantation of a pair of corpora allata or injection of juvenile hormone III into decapitated crickets caused muscle degeneration. Denervation of M112a resulted in reduction of muscle mass compared with that in sham-operated crickets. Denervation of M112a in decapitated crickets, however, did not affect muscle mass. Birefringence and ultrastructure of M112a showed an obvious regional difference in the onset of degeneration. Fibrillar structures of M112a always disappeared from the ventral to dorsal part. Distribution of axon terminals of motor neurons and mechanical responses to the motor nerve stimuli showed that M112a is composed of five motor units with similar twitch properties. When M112a was fully denervated, regional differences in degeneration disappeared. Partial denervation resulted in denervated muscle fibers losing birefringence earlier than innervated fibers. These results suggest that juvenile hormone causes breakdown of flight muscles, and neural factors control degeneration of flight muscles to some extent under the presence of the juvenile hormone.     

Programmed cell death in flight muscle histolysis of the house cricket

We have characterized the process of flight muscle histolysis in the female house cricket, Acheta domesticus, through analysis of alterations of tissue wet weight, total protein content, and percent shortening of the dorsal longitudinal flight muscles (DLMs). Our objectives were to (1) define the normal course of histolysis in the cricket, (2) analyze the effects of juvenile hormone (JH) removal and replacement, (3) determine the effects of cycloheximide treatment, and (4) examine patterns of protein expression during histolysis. Our results suggest that flight muscle histolysis in the house cricket is an example of an active, developmentally regulated cell death program induced by an endocrine signal. Initial declines of total protein in DLMs indicated the JH signal that induced histolysis occurred by Day 2 and that histolysis was essentially complete by Day 3. Significant reductions in tissue weight and percent muscle shortening were observed in DLMs from Day 3 crickets. Cervical ligation of Day 1 crickets prevented histolysis but this inhibition could be reversed by continual topical treatments with methoprene (an active JH analog) although ligation of Day 2 crickets did not prevent histolysis. A requirement for active protein expression was demonstrated by analysis of synthesis block by cycloheximide and short-term incorporation of (35)S-methionine. Treatment with cycloheximide prevented histolysis. Autofluorographic imaging of DLM proteins separated by electrophoresis revealed apparent coordinated regulation of protein expression.     

Muscle growth and protein synthesis in the puparia of Calliphora vomitoria

The effects of cycloheximide on the development of the dorsal longitudinal flight muscle of 3- to 5-day-old puparia of Calliphora vomitoria have been investigated. One μg of cycloheximide injected into the puparia reduced the incorporation of ¹⁴C phenylalanine and lysine into protein to 5 and 8 per cent of their normal levels. The cycloheximide was found to have produced its maximum effect within 2 hr of its injection and increasing the concentration did not further depress the amount of amino acid incorporation. The sixth dorsal longitudinal muscles continued to increase in length after the injection of cycloheximide and the elongation of the muscle fibres was accompanied by an increase in protein content in normal and cycloheximide-treated animals. An injection of colchicine (which is believed to disrupt microtubules) immediately halted muscle growth. Electron microscopy of the muscle fibre revealed that fibres from cycloheximide-treated animals contained myofilaments, although there were some differences in myofilament structure between normal and treated animals. The formation of the muscle fibres in the absence of protein synthesis is discussed.     

饥饿和交配对小地老虎飞行肌发育的影响

小地老虎Agrotis ypsilon(Rottemburg)成虫飞行肌的发育常受一些因素影响而发生变化,为探讨饥饿和交配行为对飞行肌发育的影响,通过电子显微镜对雌虫飞行肌(背纵肌)的肌原纤维、线粒体结构进行观察,结果显示:4日龄饥饿雌虫,肌原纤维直径、肌节长度、肌原纤维体积均显著(P<0.05)小于取食的。7日龄饥饿雌虫肌原纤维直径、肌节长度、肌原纤维体积分数较4日龄的差异均不显著(P≥0.05),而7日龄饥饿的肌原纤维直径显著(P<0.05)大于7日龄取食的;羽化10 d后,饥饿雌虫肌节长度显著(P<0.05)大于取食雌虫的,而肌纤维体积分数和线粒体体积分数均却小于后者。7、10、13日龄交配雌虫肌原纤维横切直径分别显著(P<0.05)小于同日龄非交配的;7、10、13日龄交配雌虫肌原纤维体积分数显著(P<0.05)小于非交配的,线粒体体积分数虽然无差异(P≥0.05),但是交配雌虫的早在4日龄便已明显(P<0.05)减小。上述结果表明:正常取食的小地老虎飞行肌4日龄后会发生降解现象;饥饿抑制飞行肌前期发育和中期的降解,而促进成虫末期肌原纤维的分解;交配能促进飞行肌的降解。     

The Him gene inhibits the development of Drosophila flight muscles during metamorphosis

During Drosophila metamorphosis some larval tissues escape the general histolysis and are remodelled to form adult tissues. One example is the dorso-longitudinal muscles (DLMs) of the indirect flight musculature. They are formed by an intriguing process in which residual larval oblique muscles (LOMs) split and fuse with imaginal myoblasts associated with the wing disc. These myoblasts arise in the embryo, but remain undifferentiated throughout embryogenesis and larval life, and thus share characteristics with mammalian satellite cells. However, the mechanisms that maintain the Drosophila myoblasts in an undifferentiated state until needed for LOM remodelling are not understood. Here we show that the Him gene is expressed in these myoblasts, but is undetectable in developing DLM fibres. Consistent with this, we found that Him could inhibit DLM development: it inhibited LOM splitting and resulted in fibre degeneration. We then uncovered a balance between mef2, a positive factor required for proper DLM development, and the inhibitory action of Him. Mef2 suppressed the inhibitory effect of Him on DLM development, while Him could suppress the premature myosin expression induced by mef2 in myoblasts. Furthermore, either decreased Him function or increased mef2 function disrupted DLM development. These findings, together with the co-expression of Him and Mef2 in myoblasts, indicate that Him may antagonise mef2 function during normal DLM development and that Him participates in a balance of signals that controls adult myoblast differentiation and remodelling of these muscle fibres. Lastly, we provide evidence for a link between Notch function and Him and mef2 in this balance.     

Neuromuscular junctions and L-glutamate-sensitive sites in the fleshfly, Sarcophaga bullata.

Sites have been located on retractor unguis and trochantal depressor muscle fibres of Sarcophaga which respond to iontophoretic application of l-glutamate. No such sites could be found on flight muscle fibres. Ultrastructural examination of the three muscles reveals differences between the muscles in the positions of the neuromuscular junctions. A correlation can be made between the sites of the neuromuscular junctions and the iontophoretically sensitive sites. The possibility of l-glutamate fulfilling a transmitter rôle in these muscles is discussed.     

CHOLINE ACETYLTRANSFERASE AND CHOLINESTERASE IN SKELETAL MUSCLE REGENERATION

—The activities of choline acetyltransferase and cholinesterase have been measured in homogenates of rat anterior tibial muscles following intramuscular injection of the myotoxic agent Marcaine (plus hyaluronidase). Marcaine causes rapid degeneration of skeletal muscle followed by complete regeneration. By the first day after administration of Marcaine the activities of both enzymes decreased markedly. The activities then increased concomitantly with regeneration of drug-treated muscles. Choline acetyltransferase attained the control level by the 19th day following Marcaine treatment. Cholinesterase activity became greater than the control value by the seventh day and decreased to control activity by the 19th day following injection of Marcaine. The results are discussed in terms of the relationship between nerve and muscle during Marcaine induced degeneration and regeneration.     

Effect of juvenile hormone on acid phosphatases in the degenerating flight muscles of the Douglas-fir beetle, Dendroctonus pseudotsugae

Changes in acid phosphatase activity were used to estimate flight muscle degeneration in Dendroctonus pseudotsugae. Acid phosphatase positive sites increased numerically as well as in size in flight muscles of beetles attacking the host logs and those maintained on host bark chips. Topical treatment of beetles with a juvenile hormone analogue further increased the phosphatase activity. Juvenile hormone produced similar effects when applied to insects injected with eserine. An increase in the activity of acid phosphatases was also observed after incubation in culture medium with added juvenile hormone. The rôle of nerves and hormones in the degenerating muscles of D. pseudotsugae is compared with that in the permanently degenerating muscles during metamorphosis of some moths.     

Electrical Stimulation of Coleopteran Muscle for Initiating Flight

Some researchers have long been interested in reconstructing natural insects into steerable robots or vehicles. However, until recently, these so-called cyborg insects, biobots, or living machines existed only in science fiction. Owing to recent advances in nano/micro manufacturing, data processing, and anatomical and physiological biology, we can now stimulate living insects to induce user-desired motor actions and behaviors. To improve the practicality and applicability of airborne cyborg insects, a reliable and controllable flight initiation protocol is required. This study demonstrates an electrical stimulation protocol that initiates flight in a beetle (Mecynorrhina torquata, Coleoptera). A reliable stimulation protocol was determined by analyzing a pair of dorsal longitudinal muscles (DLMs), flight muscles that oscillate the wings. DLM stimulation has achieved with a high success rate (> 90%), rapid response time (< 1.0 s), and small variation (< 0.33 s; indicating little habituation). Notably, the stimulation of DLMs caused no crucial damage to the free flight ability. In contrast, stimulation of optic lobes, which was earlier demonstrated as a successful flight initiation protocol, destabilized the beetle in flight. Thus, DLM stimulation is a promising secure protocol for inducing flight in cyborg insects or biobots.     

Development of catabolic pathways in insect flight muscles. A comparative study

Activities of enzymes representative of glycolytic and β-oxidative pathways and citric acid and glycerophosphate cycles were measured in the developing flight muscles of three species: Calliphora erythrocephala, Locusta migratoria, and Philosamia cynthia. The activities were measured in vitro under optimal conditions.The enzyme pattern of young flight muscles is quite different from the adult pattern. In the second half of the developmental period final differentiation towards the adult metabolic pattern takes place, in Calliphora leading to exclusively carbohydrate-oxidizing capacities, in Locusta to properties enabling both aerobic glycolytic and β-oxidative processes, whereas Philosamia becomes oriented to fatty acid oxidation. This differentiation starts after a temporary rise of lactate dehydrogenase activity, a phenomenon that seems to be connected with invagination of tracheoblasts into the muscle fibres. This tracheolization might be necessary for differentiation towards the species specific metabolic properties of the adult flight muscle.Theoretical aspects of the enzyme activities, as they were measured in the in vitro assays, are discussed and related to the physiological qualities of the flight muscles of the three species investigated.     

The developmental profile of paramyosin and other myofibrillar proteins of larval and imaginal thoracic muscles of Lepidoptera

The synthesis of paramyosin and other myofibrillar proteins of the thoracic muscles of the tobacco hornworm Manduca sexta was studied by immunological and electrophoretical methods during the histolysis of the larval thoracic muscles and the differentiation of the indirect flight muscles. Antigens of the myofibrillar proteins in the thoracic muscles of the last-larval stage cross reacted with those in the flight muscles of the adults against polyspecific antibodies from actomyosin and monospecific antibodies from paramyosin. After the breakdown of the larval thoracic muscles (2 days from larval-pupal ecdysis) these antigens can no longer be detected in the thorax. The results indicate an almost complete removal of the larval thoracic muscles. Paramyosin could be identified again in a homogenate of the thoracic muscles of animals on the 13th day from larval-pupal ecdysis. Paramyosin is the first protein found during the differentiation of the flight muscles. The other myofibrillar proteins could be identified in thoracic homogenates of pharate adults of Manduca sexta on the 14th and 15th day from larval-pupal ecdysis. On the 14th day from larval-pupal ecdysis the dorso-longitudinal muscle and the tergosternal muscles show cross-striation, and the appearance of most of the electrophoretical results are in accordance with immunological and morphological findings. The myofibrillar proteins of the indirect flight muscles of Manduca sexta are synthesized de novo during metamorphosis.     

Constitutive Expression of Yes-Associated Protein (Yap) in Adult Skeletal Muscle Fibres Induces Muscle Atrophy and Myopathy

The aim of this study was to investigate the function of the Hippo pathway member Yes-associated protein (Yap, gene name Yap1) in skeletal muscle fibres in vivo. Specifically we bred an inducible, skeletal muscle fibre-specific knock-in mouse model (MCK-tTA-hYAP1 S127A) to test whether the over expression of constitutively active Yap (hYAP1 S127A) is sufficient to drive muscle hypertrophy or stimulate changes in fibre type composition. Unexpectedly, after 5–7 weeks of constitutive hYAP1 S127A over expression, mice suddenly and rapidly lost 20–25% body weight and suffered from gait impairments and kyphosis. Skeletal muscles atrophied by 34–40% and the muscle fibre cross sectional area decreased by ≈40% when compared to control mice. Histological analysis revealed evidence of skeletal muscle degeneration and regeneration, necrotic fibres and a NADH-TR staining resembling centronuclear myopathy. In agreement with the histology, mRNA expression of markers of regenerative myogenesis (embryonic myosin heavy chain, Myf5, myogenin, Pax7) and muscle protein degradation (atrogin-1, MuRF1) were significantly elevated in muscles from transgenic mice versus control. No significant changes in fibre type composition were detected using ATPase staining. The phenotype was largely reversible, as a cessation of hYAP1 S127A expression rescued body and muscle weight, restored muscle morphology and prevented further pathological progression. To conclude, high Yap activity in muscle fibres does not induce fibre hypertrophy nor fibre type changes but instead results in a reversible atrophy and deterioration.     

Ultrastructural study of experimental muscle degeneration and regeneration in the adult rat

Summary Methyl-bupivacaine is a local anaesthetic with a selective myotoxic action. A single subcutaneous injection of the drug into the hind leg of adult rats produces a uniform, complete and irreversible destruction of superficial layers of fibres in the underlying extensor digitorum longus muscle. The degeneration of muscle fibres is followed by phagocytosis and a rapid and complete regeneration.The first stage in the regeneration process is the appearance of presumptive myoblasts within the original basement membrane of the sarcolemmal tube. On the second day after injury aggregates of myoblasts are present and fusion is observed between the cells. The myotubes thus formed increase in size by fusing with additional myoblasts. Myotubes are also observed to fuse with one another. On the fifth day after injury the regeneration process has proceeded to the stage of early muscle fibres with fully differentiated myofibrils with typical sarcomere structures. By ten days only mature muscle fibres of about normal size are present and regeneration appears complete.In previously denervated and methyl-bupivacaine treated muscles the stages of regeneration are similar to those observed in innervated muscles, the only apparent difference being a slowing of cell differentiation and incomplete maturation.An electrophysiological study shows that the motor nerve at the third day after injury forms synaptic contacts with regenerating muscle cells. At that stage of myogenesis the myotubes are highly sensitive to applied acetylcholine.1 (1-n-butyl-DL-piperidine-2-carboxylic acid-2,6-dimethyl-anilide-hydrochloride); Marcaine®, manufactured by AB Bofors, Nobel-Pharma, Mölndal, Sweden.The study was carried out under the auspicies of The Czechoslovak Academy of Sciences and the Royal Academy of Sciences in Sweden.