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.     

Recovery of Dominant, Autosomal Flightless Mutants of Drosophila Melanogaster and Identification of a New Gene Required for Normal Muscle Structure and Function

To identify further mutations affecting muscle function and development in Drosophila melanogaster we recovered 22 autosomal dominant flightless mutations. From these we have isolated eight viable and lethal alleles of the muscle myosin heavy chain gene, and seven viable alleles of the indirect flight muscle (IFM)-specific Act88F actin gene. The Mhc mutations display a variety of phenotypic effects, ranging from reductions in myosin heavy chain content in the indirect flight muscles only, to reductions in the levels of this protein in other muscles. The Act88F mutations range from those which produce no stable actin and have severely abnormal myofibrillar structure, to those which accumulate apparently normal levels of actin in the flight muscles but which still have abnormal myofibrils and fly very poorly. We also recovered two recessive flightless mutants on the third chromosome. The remaining five dominant flightless mutations are all lethal alleles of a gene named lethal(3)Laker. The Laker alleles have been characterized and the gene located in polytene bands 62A10,B1-62B2,4. Laker is a previously unidentified locus which is haplo-insufficient for flight. In addition, adult wild-type heterozygotes and the lethal larval trans-heterozygotes show abnormalities of muscle structure indicating that the Laker gene product is an important component of muscle.     

Looking into the puparium: Micro‐CT visualization of the internal morphological changes during metamorphosis of the blow fly,Calliphora vicina,with the first quantitative analysis of organ development in cyclorrhaphous dipterans

Metamorphosis of cyclorrhaphous flies takes place inside a barrel‐like puparium, formed by the shrinking, hardening and darkening of the third‐instar larval cuticle. The opacity of this structure hampers the visualization of the morphological changes occurring inside and therefore a full understanding of the metamorphosis process. Here, we use micro‐computed tomography (micro‐CT) to describe the internal morphological changes that occur during metamorphosis of the blow fly, Calliphora vicina Robineau‐Desvoidy 1830 (Diptera: Calliphoridae) at a greater temporal resolution than anything hitherto published. The morphological changes were documented at 10% intervals of the total intra‐puparial period, and down to 2.5% intervals during the first 20% interval, when the most dramatic morphological changes occur. Moreover, the development of an internal gas bubble, which plays an essential role during early metamorphosis, was further investigated with X‐ray images and micro‐CT virtual sections. The origin of this gas bubble has been largely unknown, but micro‐CT virtual sections show that it is connected to one of the main tracheal trunks. Micro‐CT virtual sections also provided enough resolution for determining the completion of the larval‐pupal and pupal‐adult apolyses, thus enabling an accurate timing of the different intra‐puparial life stages. The prepupal, pupal, and pharate adult stages last for 7.5%, 22.5%, and 70% of the total intra‐puparial development, respectively. Furthermore, we provide for the first time quantitative data on the development of two organ systems of the blow fly: the alimentary canal and the indirect flight muscles. There is a significant and negative correlation between the volume of the indirect flight muscles and the pre‐helicoidal region of the midgut during metamorphosis. The latter occupies a large portion of the thorax during the pupal stage but narrows progressively as the indirect flight muscles increase in volume during the development of the pharate adult.     

Fusion of myocytes with larval muscle remnants during flight muscle development in the Colorado beetle

The transformation of the slow contracting larval m. obliquus lateralis caudalis II during metamorphosis into the asynchronous indirect flight muscle, m. obliquus lateralis dorsalis, in the Colorado beetle, Leptinotarsa decemlineata, was examined by electron microscopy. Particular attention was paid to the fate of the larval muscle fibres, the origin and behaviour of the myoblasts for flight muscle development and the change of the myofibrillar filament lattice of the larva into that of the adult. In the pre-pupal period, the larval muscles dedifferentiate and fragment. At pupation, the muscle fibres consist of cell fragments containing very few myofibrils. The sarcoplasmic reticulum and the transverse tubular system are greatly reduced. The number of myoblasts developed from satellite cells by mitosis increases considerably. They penetrate the muscle fibre and surround the cell fragments. The new fibres of the flight muscle develop from myocytes fused with the larval fragments. The larval basal lamina, surrounding the cell fragments and myoblasts, is present in pupae up to 1 day old. In pupae about 2.5 days old new myofibrils appear that have the adult filament lattice. The insect muscle transformation and the repair of vertebrate muscle after injury show striking resemblances.     

Patterning Muscles Using Organizers: Larval Muscle Templates and Adult Myoblasts Actively Interact to Pattern the Dorsal Longitudinal Flight Muscles of Drosophila

Pattern formation in muscle development is often mediated by special cells called muscle organizers. During metamorphosis in Drosophila, a set of larval muscles function as organizers and provide scaffolding for the development of the dorsal longitudinal flight muscles. These organizers undergo defined morphological changes and dramatically split into templates as adult fibers differentiate during pupation. We have investigated the cellular mechanisms involved in the use of larval fibers as templates. Using molecular markers that label myoblasts and the larval muscles themselves, we show that splitting of the larval muscles is concomitant with invasion by imaginal myoblasts and the onset of differentiation. We show that the Erect wing protein, an early marker of muscle differentiation, is not only expressed in myoblasts just before and after fusion, but also in remnant larval nuclei during muscle differentiation. We also show that interaction between imaginal myoblasts and larval muscles is necessary for transformation of the larval fibers. In the absence of imaginal myoblasts, the earliest steps in metamorphosis, such as the escape of larval muscles from histolysis and changes in their innervation, are normal. However, subsequent events, such as the splitting of these muscles, fail to progress. Finally, we show that in a mutant combination, null for Erect wing function in the mesoderm, the splitting of the larval muscles is aborted. These studies provide a genetic and molecular handle for the understanding of mechanisms underlying the use of muscle organizers in muscle patterning. Since the use of such organizers is a common theme in myogenesis in several organisms, it is likely that many of the processes that we describe are conserved.     

Origin and development of the tergotrochanteral muscle in Chironomus (Diptera: Nematocera)

The origin and the development of the tubular tergo-trochanteral muscle (TTD) was studied by light and electron microscopy in Chironomus (Diptera: Nematocera). Unlike the flight muscles, the TTD was found to develop from myoblasts located around a larval axon, without contribution from a larval muscle. The myoblasts fuse together to form myotubes. Innervation of the TTD arises from the larval axon. The myotubes send out sarcoplasmic extensions towards the axon branches issued from the larval axon. The first differentiated synapses are described. The TTD begins to grow later than the flight muscles. The implications of this developmental lag are discussed.     

Demonstration of functional connectivity of the flight motor system in all stages of the locust

Summary The development of the flight motor pattern was studied by recording from the thoracic muscles of locusts of various developmental stages. In response to a short wind stimulus, larval locusts generate unpatterned motor activity, whereas newly moulted adults generate the flight pattern (Fig. 1A). The latter is equivalent to the mature adult flight pattern, although more irregular and of lower frequency. Experiments with highly deafferentated locusts indicate that the switch from the larval tonic to adult phasic flight pattern and subsequent increase in frequency are not dependent on phasic peripheral feedback from moving body structures (Fig. 1B). By using octopamine, flight motor activity could be released without need of the wind stimulus (Fig. 2). This corresponded to the normal wind released flight pattern of intact locusts, although the frequency was lower (Fig. 8). Following octopamine treatment, the response to wind stimulation was enhanced. Wind then released in deafferentated adults long flight sequences of significantly elevated frequency (Fig. 3). Although flight is essentially an adult specific behaviour, octopamine was finally found to release flight motor activity in all larval stages (Fig. 7).We conclude that major steps in the development of the flight motor circuitry are completed by the end of embryogenesis. Thus, in contrast to previous assumptions (cf. Bentley and Hoy 1970; Kutsch 1974a; Altman 1975), postembryonic changes in neither the central, nor peripheral nervous system appear to be of major importance for the ontogeny of the locust flight motor program. Whether developmental changes in the wind sensory system of the head, or levels of neurohormones such as octopamine, are related to the newly acquired responsiveness of freshly moulted adult locusts to the normal flight releasing stimulus is discussed.     

The adult abdominal neuromuscular junction of Drosophila: a model for synaptic plasticity

During its life cycle, Drosophila makes two sets of neuromuscular junctions (NMJs), embryonic/larval and adult, which serve distinct stage-specific functions. During metamorphosis, the larval NMJs are restructured to give rise to their adult counterparts, a process that is integrated into the overall remodeling of the nervous system. The NMJs of the prothoracic muscles and the mesothoracic dorsal longitudinal (flight) muscles have been previously described. Given the diversity and complexity of adult muscle groups, we set out to examine the less complex abdominal muscles. The large bouton sizes of these NMJs are particularly advantageous for easy visualization. Specifically, we have characterized morphological attributes of the ventral abdominal NMJ and show that an embryonic motor neuron identity gene, dHb9, is expressed at these adult junctions. We quantified bouton numbers and size and examined the localization of synaptic markers. We have also examined the formation of boutons during metamorphosis and examined the localization of presynaptic markers at these stages. To test the usefulness of the ventral abdominal NMJs as a model system, we characterized the effects of altering electrical activity and the levels of the cell adhesion molecule, FasciclinII (FasII). We show that both manipulations affect NMJ formation and that the effects are specific as they can be rescued genetically. Our results indicate that both activity and FasII affect development at the adult abdominal NMJ in ways that are distinct from their larval and adult thoracic counterparts     

Possibilities for flight in the carabid beetle Nebria brevicollis (F.)

Summary The carabid beetle Nebria brevicollis (F.), despite being macropterous, has a very low flight potential. Only a few percent of the beetles has functional flight muscles, flight motivation is low, and the period favourable for flight is short. The inability to fly is caused mainly by arrested development of the flight muscles. Dispersers are formed only under favourable conditions in the larval stages as shown by laboratory experiments (much food, short daylength). In N. brevicollis dispersal by flight cannot be considered as a reaction to deteriorating conditions but just the other way round. Because of the usually low numbers of potential dispersers conditions during larval development are apparently suboptimal. However, N. brevicollis is widespread and abundant in our area. The choice of using energy for the metabolic costs of larval growth, and only secondarily for the building up of flight muscles does not prevent the species from fully exploiting the habitat.Communication No. 320 of the Biological Station, Wijster, The Netherlands     

DAAM Is Required for Thin Filament Formation and Sarcomerogenesis during Muscle Development in Drosophila

During muscle development, myosin and actin containing filaments assemble into the highly organized sarcomeric structure critical for muscle function. Although sarcomerogenesis clearly involves the de novo formation of actin filaments, this process remained poorly understood. Here we show that mouse and Drosophila members of the DAAM formin family are sarcomere-associated actin assembly factors enriched at the Z-disc and M-band. Analysis of dDAAM mutants revealed a pivotal role in myofibrillogenesis of larval somatic muscles, indirect flight muscles and the heart. We found that loss of dDAAM function results in multiple defects in sarcomere development including thin and thick filament disorganization, Z-disc and M-band formation, and a near complete absence of the myofibrillar lattice. Collectively, our data suggest that dDAAM is required for the initial assembly of thin filaments, and subsequently it promotes filament elongation by assembling short actin polymers that anneal to the pointed end of the growing filaments, and by antagonizing the capping protein Tropomodulin.     

Mode of formation of the flight muscles in a butterfly Pieris brassicae

The formation and development of the dorsal longitudinal flight muscles of the butterfly Pieris brassicae L have been studied by electron and light microscopy. These imaginal muscles arise from two symmetrical pairs of mesothoracic larval muscles, which are morphologically indistinguishable from the other wall muscles at the beginning of the 5th larval instar. However, 2 days before the end of this instar an accumulation of myoblasts is observed at the median region of these muscle fibres. The muscle fibres are penetrated by the myoblasts and broken into fragments. Progressive dedifferentiation of the larval fibrillar material in each of the muscle fragments is observed during the first days of the pupal development. The myoblasts within the basal lamina of the original larval muscle fibres remain associated with the muscle fragments. Myoblasts then fuse with the larval muscle fragments, which simultaneously fuse with each other. This results in the formation of rudimentary imaginal muscle fibres. The development of these fibres, particularly myofibrillogenesis, is studied until the emergence of the imago.     

Pre-imaginal flight motor pattern in Locusta

In a wind stream, larval stages of Locusta usually show a tonic muscle activity but they can also exhibit a rhythmic motor output. With ageing such a pattern can be released sooner, the trains become longer. The basic rhythm of 10 Hz does not change. The initial co-contraction of specific muscles is substituted later in development by an antagonistic recruitment. This activity resembles the flight motor pattern of young locusts which lack phasic sensory feedback from the wing region. Azadirachtin, an insect growth regulator, has been used to produce a permanent 5th larval instar. However, the extension of the last larval stage does not lead to a further development of the motor pattern to a level comparable to mature animals.     

Development of an indirect flight muscle in a muscle-specific mutant of Drosophila melanogaster

Stripe (sr) is a highly specific mutant affecting only one of the indirect flight muscles, the dorsal longitudinal muscle (DLM). In the homozygous condition the DLM is reduced in size. In the hemizygous condition (sr/Df(3)sr) no DLM is present in the adult, though all other thoracic muscles are present. In the early stages of pupation, DLM development in sr/Df(3)sr is no different from that in wild type. Adult myocytes collect around target larval muscles and fuse to form myotubes; myofilaments are synthesized. Subsequently (35-hr pupa) the DLM commences to degenerate, forming random clumps of vacuolated muscle tissue. Adjacent muscles are unaffected and develop normally. In the adult a neuroma-like mass of nerve tissue is maintained where the DLM would normally be located. In this mass many abnormal synapses (hemisynapses) are seen: presynaptic specializations occur in the absence of any postsynaptic structure. Small remnants (less than 16-microns diameter) of muscle tissue are sometimes found in the neuroma-like mass. Such remnants resemble slow muscle, not the normal fast type of DLM. These data suggest a possible muscle origin from primary and secondary myotubes. The DLM motor axons are present in the neuroma-like mass, persisting even with the virtual degeneration of their end target. Thus, motoneurons and presynaptic specializations can survive independently of postsynaptic targets.     

Origin and development of the dorso-ventral flight muscles in Chironomus (Diptera; Nematocera)

The origin and development of the dorso-ventral flight muscles (DVM) was studied by light and electron microscopy in Chironomus (Diptera; Nematocera). Chironomus was chosen because unlike Drosophila, its flight muscles develop during the last larval instar, before the lytic process of metamorphosis. Ten fibrillar DVM were shown to develop from a larval muscle associated with myoblasts. This muscle is connected to the imaginal leg discso that its cavity communicates with the adepithelial cells present in the disc; but no migration of myoblasts seems to take place from the imaginal leg disc towards the larval muscle or vice versa. At the beginning of the last larval instar, the myoblasts were always present together with the nerves in the larval muscle. In addition, large larval muscle cells incorporated to the imaginal discs were observed to border on the area occupied by adepithelial cells, and are probably involved in the formation of 4 other fibrillar DVM with adepithelial cells. Three factors seem to determine the number of DVM fibres: the initial number of larval fibres in the Anlage, the fusions of myoblasts with these larval fibres and the number of motor axons in the Anlage. The extrapolation of these observations to Drosophila, a higher dipteran, is discussed.     

Fine structure of flight muscles in different Notch mutants of Drosophila melanogaster reared at different temperatures

Summary The fine structure of the indirect flight muscles was studied by electron microscopy in the following Notch locus mutants of Drosophila melanogaster reared at 18° C or 29° C for 6 days after eclosion: Ax ¹⁶¹⁷²/Ax¹⁶¹⁷², Ax²⁸/ Ax²⁸, l(1)N^ts1/l(1)N^ts1,l(1)N^ts1/Y and in wild-type controls. The flies were raised up to eclosion at 25° C or 18° C. It was observed that the l(1)N^ts1 flies gradually became flightless within a few days if reared at 29° C as adults, and gross changes in the fine structure of the flight muscles were also observed in flies of this genotype. Peripheral myofilaments of myofibrils were disarranged and the mitochondria diminutive. At 18° C the flight muscles remained normal. In all of the Abruptex (Ax) combinations the flight muscles remained similar to the wild-type controls at both 18° C and 29° C, i.e. they were normal. The results suggest that the Notch gene is active in adult flies in addition to its activity during embryonic, larval and pupal stages, and is directly or indirectly involved in the adult development of the muscle tissue.     

Development and Degeneration of Flight Muscles in Neochetina eichhorniae (Coleoptera; Curculionidae), Potential Biocontrol Agent of the Aquatic Weed, Eichorniae crassipes

The water hyacinth weevil, Neochetina eichhorniae, is an effective biological control agent of the aquatic weed Eichorniae crassipes. The adults under field conditions have degenerated indirect flight muscles that explains their inability to fly. A study on the factors initiating flight muscle development in adults was carried out. Among the various abiotic factors studied, density of weevils per plant and high temperature in presence of food initiated and accelerated flight muscle development. Absence of food did not influence muscle development. No inter-relationship between flight muscle development and degeneration could be observed.