Metamorphosis of wing motor system in the silk moth,Bombyx mori L. (Lepidoptera: Bombycidae): Anatomy of the sensory and motor neurons that innervate larval mesothoracic dorsal musculature,stretch receptors,and epidermis

Anatomy of dorsal mesothoracic structures, such as muscles, sensory organs, and innervation, was studied in the silkworm, Bombyx mori L. (Lepidoptera : Bombycidae), and compared with the adult wing motor system. Musculature and nerve innervation were investigated by dissection and electron micrograph; and central projection of sensory fibers and morphology of somata and dendrites of motor neurons by cobalt back-filling, followed by silver intensification. There are 23 muscle bundles (DLM) and 2 stretch receptors (SR). The DLMs, SRs, and epidermis are innervated by a branch of the dorsal nerve trunk emerging from the mesothoracic ganglion (MSG). The branch bifurcates into a dorsal sensory branch of about 300 sensory fibers and a dorsal motor branch of 14 fibers. The sensory fibers project mainly to a longitudinal portion near the mid line in the ventral neuropil of MSG and the metathoracic ganglion. Several fibers extend into the prothoracic ganglion (PG) and a few into the subesophageal and 1st abdominal ganglia. At least 13 (probably 14) motor neurons send axons to DLMs: 9 (probably 10) in PG, and 4 in MSG. Their dendrites are located mostly on the dorsoipsilateral side of the neuropil, but several branches cross the mid line and give rise to many fine branches on the contralateral side. Comparison between the larval (present study) and adult motor system shows a significant similarity in the musculature, peripheral nerve pattern, and motor neurons with some peculiarities.     

Larval multidendrite neurons survive metamorphosis and participate in the formation of imaginal sensory axonal pathways in the notum of Drosophila

In each hemimesothorax of Drosophila, a cluster of five larval multidendrite neurons that survives metamorphosis is described. The cell bodies of these neurons, initially grouped together, spread out over the medial heminotum during early pupal stages and extend new dendrites. Growing axons from sensory bristle neurons first appear in a defined orientation specific for each macrochaete. They subsequently contact processes from the larval multidendrite neurons and then appear to follow the preestablished axon trajectories of the latter. Ablation of the multidendrite neurons during the larval stage causes bristle axons to adopt abnormal trajectories. We suggest that the persistent larval neurons participate in guiding axons of the bristles on the medial half of the notum to the posterior dorsal mesothoracic nerve leading to the central nervous system.     

Pruning of motor neuron branches establishes the DLM innervation pattern in Drosophila

During the Drosophila life-cycle two sets of neuromuscular junctions are generated: the embryonic/larval NMJs develop during the first half, followed by the period of metamorphosis during which the adult counterpart is generated. Development of the adult innervation pattern is preceded by a withdrawal of larval NMJs, which occurs at the onset of metamorphosis, and is followed by adult-specific motor neuron outgrowth to innervate the newly developing adult fibers. Establishment of the adult innervation pattern occurs in the context of a broader restructuring of the nervous system, which results in the development of neural circuits that are necessary to carry out behaviors specific to the adult. In this article, we follow development of the dorsal longitudinal muscle (DLM) innervation pattern through metamorphosis. We find that the initial period of motor neuron elaboration is followed by a phase of extensive pruning resulting in a threefold reduction of neuromuscular contacts. This event establishes the adult pattern of second order branching. Subsequent higher order branching from the second order "contact" points generates the characteristic multiterminal innervation pattern of the DLMs. Boutons begin to appear after the pruning phase, and are much smaller than their larval counterparts. Additionally, we demonstrate that the DLM innervation is altered in the hyperexcitable double mutant, ether a go-go Shaker, and that the phenotype is suppressed by the hypoexcitable mutant, nap(ts1). Our results demonstrate that electrical activity regulates the patterning of DLM innervation during metamorphosis.     

Scanning and freeze-fracture study of larval nerves and neuromuscular junctions in Manduca sexta

The nerves and nerve terminals to tonic larval muscle fibers in third and fifth instar caterpillars were studied to compare them with those formed by the same motor neurons on phasic flight muscles in adult moths. Scanning micrographs showed a primary nerve branch running the length of each fiber, with secondary nerve branches extending from it at intervals. There was a great deal of variability in both the length of the branches and the distance from the nerve at which the neuromuscular junctions were formed. The rapid increase in muscle fiber size during larval development may be responsible for this variability. The nerves and junctions were often found to be obscure by overlying fibroblasts and tracheoblasts or entering the deep muscle clefts. Those examined were similar in appearance to the adult junctions formed by the same neurons, although some may have formed single branches instead of y-shapes. The membrane specializations of the synapse seen in freeze-fractured specimens were similar to those of the adult junction. However, the overall shape of the nerve terminal within the junction differed. The larval nerve terminals appeared varicose instead of having a uniform diameter. The spacing of the nerve plaques varied, in contrast with the relatively straight alignment and even spacing of plaques found in adult junctions. Such differences could result from an interaction between the motor neuron and the two different types of muscle fiber that it innervates, an intrinsic change in the motor neurons themselves that occurs with metamorphosis, or a plastic functional response that occurs as a result of the different types of motor patterns that are used in the two stages.     

Central and peripheral neurosecretory pathways to an insect flight motor nerve

Ultrastructural examination of the IIN1b nerve to the dorsal longitudinal flight muscle of Manduca sexta L. verified the presence of neurosecretory processes. Subspherical and irregular vesicles were found where the nerve enters the muscle, while spherical vesicles were found in the proximal region only. A dorsal unpaired median (DUM) cell, the median nervous system, and two or more peripheral cells are the sources of these neurosecretory inclusions. Light the electron microscopy CoCl2 backfills of the transverse nerve produced intensification of a peripheral neuron (#1) and processes in nerves IIN1a and IIN1b. Similar backfills of nerve IIN1b produced intensification of a DUM cell, a second peripheral neuron (#2), and processes in the transverse nerve and nerve IIN1a. Neuron #1 contained large spherical electron-dense vesicles while neuron #2 contained smaller subspherical vesicles. These cells were situated upon the link and/or transverse nerves. Based on these results, we suspect central and peripheral neurosecretory processes reach nerve IIN1b as follows: the link nerve projects prothoracic median nervous system and neuron #2 processes, nerve IIN1a projects neuron #1 processes, and nerve IIN1 projects mesothoracic DUM cell processes, although this latter pathway was less clear.     

Postembryonic development of leucokinin I-immunoreactive neurons innervating a neurohemal organ in the turnip moth Agrotis segetum

Summary In the abdominal ganglia of the turnip moth Agrotis segetum, an antibody against the cockroach neuropeptide leucokinin I recognizes neurons with varicose fibers and terminals innervating the perisympathetic neurohemal organs. In the larva, the abdominal perisympathetic organs consist of a segmental series of discrete neurohemal swellings on the dorsal unpaired nerve and the transverse nerves originating at its bifurcation. These neurohemal structures are innervated by varicose terminals of leucokinin I-immunoreactive (LKIR) fibers originating from neuronal cell bodies located in the preceding segment. In the adult, the abdominal segmental neurohemal units are more or less fused into a plexus that extends over almost the whole abdominal nerve cord. The adult plexus consists of peripheral nerve branches and superficial nerve fibers beneath the basal lamina of the neural sheath of the nerve cord. During metamorphosis, the LKIR fibers closely follow the restructuration of the perisympathetic organs. In both larvae and adults the LKIR fibers in the neurohemal structures originate from the same cell bodies, which are distributed as ventrolateral bilateral pairs in all abdominal ganglia. The transformation of the series of separated and relatively simple larval neurohemal organs into the larger, continuous and more complex adult neurohemal areas occurs during the first of the two weeks of pupal life. The efferent abdominal LKIR neurons of the moth Agrotis segetum thus belong to the class of larval neurons which persist into adult life with substantial peripheral reorganization occurring during metamorphosis.     

Baboon/dSmad2 TGF-beta signaling is required during late larval stage for development of adult-specific neurons

The intermingling of larval functional neurons with adult-specific neurons during metamorphosis contributes to the development of the adult Drosophila brain. To better understand this process, we characterized the development of a dorsal cluster (DC) of Atonal-positive neurons that are born at early larval stages but do not undergo extensive morphogenesis until pupal formation. We found that Baboon(Babo)/dSmad2-mediated TGF-beta signaling, known to be essential for remodeling of larval functional neurons, is also indispensable for proper morphogenesis of these adult-specific neurons. Mosaic analysis reveals slowed development of mutant DC neurons, as evidenced by delays in both neuronal morphogenesis and atonal expression. We observe similar phenomena in other adult-specific neurons. We further demonstrate that Babo/dSmad2 operates autonomously in individual neurons and specifically during the late larval stage. Our results suggest that Babo/dSmad2 signaling prior to metamorphosis may be widely required to prepare neurons for the dynamic environment present during metamorphosis.     

Steroid hormone enhancement of neurite outgrowth in identified insect motor neurons involves specific effects on growth cone form and function

Dramatic reorganization of dendrites and axonal terminals is a hallmark of neuronal remodeling during metamorphosis in the hawkmoth, Manduca sexta. The dendritic and axonal arbors of leg motor neurons regress in late larval stages, then regrow during adult development. Ecdysteroids, the insect steroids that trigger metamorphosis, control both regression and outgrowth in vivo and stimulate neuritic growth in cultured pupal leg motor neurons. To identify subcellular targets of ecdysteroid action in these neurons, we examined the dynamic and structural features of branching and their modulation by ecdysteroids in vitro. Delayed treatment of pupal leg motor neurons with ecdysteroid led to a robust enhancement of neuritic branch accumulation accompanied by a subtle effect on total neuritic length. Repeated imaging revealed that branch formation occurred almost exclusively at the growth cone; interstitial branching was extremely rare. Ecdysteroid treatment significantly enhanced both the formation and retention of branches at the growth cone. Branches formed via two distinct processes: engorgement (of fine protrusions) and condensation (of lamellae) with the relative contributions of these mechanisms being unaltered by ecdysteroid. Confocal imaging of the cytoskeleton demonstrated that growth cones consisted of microtubule-based domains fringed by actin-based filopodia. Treated growth cones were larger and displayed increased numbers of microtubule-based branches, whereas filopodial density was unaffected. These findings indicate that ecdysteroid enhances neuritic branching by altering growth cone structure and function, and suggest that hormonal modulation of cytoskeletal interactions contributes significantly to neuritic remodeling during metamorphosis.     

Variations in location and size of identified flight motoneurons in the silk moth,Bombyx mori L. (Lepidoptera : Bombycidae)

Neurons are commonly identified by some specific features. However, recent studies showed variations in identified neurons, which casts doubt on the reliability of neuron identification. This paper tests the anatomical approach that groups of neurons, which look roughly the same in different preparations, really do contain the same neurons; it also tests the reliability of motor neuron identification by cell body size and position of flight motor neurons in the silk moth, Bombyx mori (Lepidoptera : Bombycidae).Soma size and position of 9 motor neurons, which innervate the mesothoracic dorsal longitudinal muscles (DLMs), were quantitatively measured in cobalt back-filled preparations. The neurons were classified into 5 subgroups by soma size and position, and muscle innervation, although neurons in the same subgroup could not be individually identified. The soma size was essentially constant for individual neuron subgroups, but the position varied somewhat. Two subgroups were generally distributed at one position in the ganglion, but others had 2 separate soma areas, and different animals showed different distributions in these 2 areas. These results show that DLM motor neurons can be identified by the soma size and position only when the variation of soma position is examined in advance.     

Drosophila P[Gal4] lines reveal that motor neurons involved in feeding persist through metamorphosis

Two P[Gal4] insertion lines in Drosophila melanogaster, MT11 and MT26, express GAL4 specifically in two to three pairs of pharyngeal motor neurons (PMN) in the suboesophageal ganglion. By using various secondary reporters, the architecture of the PMN, including their efferent axons in the pharyngeal nerve, was visualized. This allowed us to identify a pharyngeal dilator muscle as their target. To study the function of these neurons, we crossed line MT11 with a UAS-tetanus toxin gene construct (TNT-C) that inhibits all synaptic transmission. The offspring shows a reduction in food ingestion of 75% compared to the MT11 and TNT-C controls, demonstrating that PMN control food uptake. More important, lines MT11 and MT26 enabled us to follow PMN and their processes through metamorphosis, since labeling appears in the late third larval instar and persists up to adulthood. The motor axons innervate a pharyngeal muscle in the larva as well and extend through the maxillary nerve, proving that this nerve is homologous to the adult pharyngeal nerve. Efferent arborizations persist throughout metamorphosis, even though the larval muscle histolyzes by 20% of pupal life. Yet, some dedifferentiated structures remain, which may serve as a template for the formation of the adult muscle. Labeling of line MT26 with bromodeoxyuridine at embryonic or larval stages suggests that these neurons undergo their terminal mitosis in the mid to late embryo. © 1998 John Wiley & Sons, Inc. J Neurobiol 37: 237–250, 1998     

Segmentally distributed metamorphic changes in neural circuits controlling abdominal bending in the hawkmoth Manduca sexta

During the metamorphosis of Manduca sexta the larval nervous system is reorganized to allow the generation of behaviors that are specific to the pupal and adult stages. In some instances, metamorphic changes in neurons that persist from the larval stage are segment-specific and lead to expression of segment-specific behavior in later stages. At the larval-pupal transition, the larval abdominal bending behavior, which is distributed throughout the abdomen, changes to the pupal gin trap behavior which is restricted to three abdominal segments. This study suggests that the neural circuit that underlies larval bending undergoes segment specific modifications to produce the segmentally restricted gin trap behavior. We show, however, that non-gin trap segments go through a developmental change similar to that seen in gin trap segments. Pupal-specific motor patterns are produced by stimulation of sensory neurons in abdominal segments that do not have gin traps and cannot produce the gin trap behavior. In particular, sensory stimulation in non-gin trap pupal segments evokes a motor response that is faster than the larval response and that displays the triphasic contralateral-ipsilateral-contralateral activity pattern that is typical of the pupal gin trap behavior. Despite the alteration of reflex activity in all segments, developmental changes in sensory neuron morphology are restricted to those segments that form gin traps. In non-gin trap segments, persistent sensory neurons do not expand their terminal arbors, as do sensory neurons in gin trap segments, yet are capable of eliciting gin trap-like motor responses. Accepted: 10 January 1997     

The thoracic muscular system and its innervation in third instar Calliphora vicina Larvae. II. Projection patterns of the nerves associated with the pro‐ and mesothorax and the pharyngeal complex

We describe the anatomy of the nerves that project from the central nervous system (CNS) to the pro‐ and mesothoracic segments and the cephalopharyngeal skeleton (CPS) for third instar Calliphora larvae. Due to the complex branching pattern we introduce a nomenclature that labels side branches of first and second order. Two fine nerves that were not yet described are briefly introduced. One paired nerve projects to the ventral arms (VAs) of the CPS. The second, an unpaired nerve, projects to the ventral surface of the cibarial part of the esophagus (ES). Both nerves were tentatively labeled after the structures they innervate. The antennal nerve (AN) innervates the olfactory dorsal organ (DO). It contains motor pathways that project through the frontal connectives (FC) to the frontal nerve (FN) and innervate the cibarial dilator muscles (CDM) which mediate food ingestion. The maxillary nerve (MN) innervates the sensory terminal organ (TO), ventral organ (VO), and labial organ (LO) and comprises the motor pathways to the mouth hook (MH) elevator, MH depressor, and the labial retractor (LR) which opens the mouth cavity. An anastomosis of unknown function exists between the AN and MN. The prothoracic accessory nerve (PaN) innervates a dorsal protractor muscle of the CPS and sends side branches to the aorta and the bolwig organ (BO) (stemmata). In its further course, this nerve merges with the prothoracic nerve (PN). The architecture of the PN is extremely complex. It innervates a set of accessory pharyngeal muscles attached to the CPS and the body wall musculature of the prothorax. Several anastomoses exist between side branches of this nerve which were shown to contain motor pathways. The mesothoracic nerve (MeN) innervates a MH accessor and the longitudinal and transversal body wall muscles of the second segment. J. Morphol. 271:969–979, 2010. © 2010 Wiley‐Liss, Inc.     

Constancy and variation of the serotonin-like immunoreactive neurons in the metamorphosing ventral nerve cord of the meal beetle,Tenebrio molitor L. (Coleoptera : Tenebrionidae)

Serotonin-like immunoreactive neurons were mapped in the larval, prepupal, pupal, and adult ventral nerve cord (VNC) of the beetle, Tenebrio molitor L. (Coleoptera: Tenebrionidae). The alterations of the shape of these neurons during metamorphosis were analysed. The stage-specific interindividual variability of the examined serotonin-like immunoreactive neurons is low. Serotonin-like immunoreactive neurons of the abdominal and thoracic ganglia behave differently during metamorphosis. Only in thoracic ganglia was an obvious change in the pattern of serotonin-like immunoreactive neurons observed. The shape of the dendritic trees of serotonin-like immunoreactive neurons varies in thoracic., but not in abdominal ganglia. During postlarval development, new emerging neurons that react with the anti-serotonin antibody are found only in the thoracic ganglia. Serotonin-like immunoreactive neurons are serially homologous in the larval ventral nerve cord. The basic organization of the serotonin-like immunoreactive neurons is maintained up to the adult stage. Some aspects of the metamorphosis of the nervous system are discussed with respect to the transformation of the set of immunoreactive neurons from larval to adult stage. The results are compared to those obtained in the study of serotonin-immunoreactive neurons in cockroaches, dipterans and locusts.     

Organization of the larval pre-ecdysis motor pattern in the tobacco hornworm,Manduca sexta

The tobacco hornworm, Manduca sexta, undergoes several larval molts before transforming into a pupa and then an adult moth. Each molt culminates in ecdysis, when the old cuticle is shed. Prior to each larval ecdysis, the old cuticle is loosened by pre-ecdysis behavior, which consists of rhythmic compressions that are synchronous along the abdomen and on both body sides, and rhythmic retractions of the abdominal prolegs. Both pre-ecdysis and ecdysis behaviors are triggered by a peptide, eclosion hormone. The aim of the present study was to investigate the neural circuitry underlying larval preecdysis behavior. The pre-ecdysis motor pattern was recorded in isolated nerve cords from eclosion hormone-treated larvae, and the effects of connective transections and ionic manipulations were tested. Our results suggest that the larval pre-ecdysis compression motor pattern is coordinated and maintained by interneurons in the terminal abdominal ganglion that ascend the nerve cord without chemical synaptic relays; these interneurons make bilateral, probably monosynaptic, excitatory connections with identified pre-ecdysis motor neurons throughout the abdominal nerve cord. This model of the organization of the larval pre-ecdysis motor pattern should facilitate identification of the relevant interneurons, allowing future investigation of the neural basis of the developmental weakening of the pre-ecdysis motor pattern that accompanies the larval-pupal transformation.Abbreviations A3, A4... abdominal ganglia 3, 4... - AT terminal abdominal ganglion - ALE anterior lateral external muscle - DN dorsal nerve - DN_A anterior branch of the dorsal nerve - DN_L lateral branch of the dorsal nerve - DN_P posterior branch of the dorsal nerve - EH eclosion hormone - TP tergopleural muscle - VN ventral nerve - VN_A anterior branch of the ventral nerve - VN_L lateral branch of the ventral nerve - VN_P posterior branch of the ventral nerve     

Neuronal control of heart reversal in the hawkmoth Manduca sexta

Cardiograms demonstrate that heart activity of Manduca sexta changes from larva, to pupa, to adult. The larval heart has only anterograde contractions. During metamorphosis, heart activity becomes a cyclic alternation of anterograde and retrograde contractions. Thus, the adult heart has both an anterograde and a retrograde pacemaker. External stimuli also can initiate cardiac reversal. Cardiac reversal is blocked by tetrodotoxin, indicating that reversal is under neuronal control. A branch of each dorsal nerve 8 innervates the posterior chamber of the heart, the location of the anterograde pacemaker. Only retrograde contractions occur when dorsal nerves 8 are cut. Stimulation of ml(-1) 8 initiates anterograde contractions; when stimulation ceases, the heart reverses to retrograde contractions. These experiments indicate that the anterograde pacemaker receives neural input that makes it the dominant pacemaker. In the absence of neural input this pacemaker is inactive, and the retrograde pacemaker becomes active. Application of crustacean cardioactive peptide accelerates the heart but does not eliminate cardiac reversal. The terminal chamber of the heart is also innervated by a branch of each dorsal nerve 7; stimulation of this nerve increases the strength of contraction of the terminal chamber but has no effect on contractions of the remainder of the heart or on cardiac reversal.     

dHb9 expressing larval motor neurons persist through metamorphosis to innervate adult‐specific muscle targets and function in Drosophila eclosion

The Drosophila larval nervous system is radically restructured during metamorphosis to produce adult specific neural circuits and behaviors. Genesis of new neurons, death of larval neurons and remodeling of those neurons that persistent collectively act to shape the adult nervous system. Here, we examine the fate of a subset of larval motor neurons during this restructuring process. We used a dHb9 reporter, in combination with the FLP/FRT system to individually identify abdominal motor neurons in the larval to adult transition using a combination of relative cell body location, axonal position, and muscle targets. We found that segment specific cell death of some dHb9 expressing motor neurons occurs throughout the metamorphosis period and continues into the post‐eclosion period. Many dHb9 > GFP expressing neurons however persist in the two anterior hemisegments, A1 and A2, which have segment specific muscles required for eclosion while a smaller proportion also persist in A2–A5. Consistent with a functional requirement for these neurons, ablating them during the pupal period produces defects in adult eclosion. In adults, subsequent to the execution of eclosion behaviors, the NMJs of some of these neurons were found to be dismantled and their muscle targets degenerate. Our studies demonstrate a critical continuity of some larval motor neurons into adults and reveal that multiple aspects of motor neuron remodeling and plasticity that are essential for adult motor behaviors. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 76: 1387–1416, 2016     

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     

Crustacean cardioactive peptide-immunoreactive neurons in the ventral nerve cord and the brain of the meal beetle Tenebrio molitor during postembryonic development

Summary By use of an antiserum against the crustacean cardioactive peptide (CCAP) several types of bilaterally symmetrical neurons have been mapped quantitatively in the ventral nerve cord and in the brain of the meal beetle, Tenebrio molitor. The general architecture of these neurons was reconstructed from peroxidase-antiperoxidase-labelled whole-mount preparations. From the subesophageal to the seventh abdominal ganglia two types of neurons show a repetitive organization of contralateral projection patterns in each neuromere. The first type has few branches in the central neuropil and a distinct peripheral projection. The second type is characterized by an elaborate central branching pattern, which includes ascending and descending processes. Some of its peripheral branches were found to supply peripheral neurohemal areas. In the protocerebrum, 10 CCAP-immunoreactive neurons occur with projections into the superior median protocerebrum and the tritocerebrum. Immunopositive neurons were mapped in larval and various pupal stages, as well as in the adult. All types of identified neurons were found to persist throughout metamorphosis maintaining their essential structural and topological characteristics. The CCAP-immunoreactive neurons of T. molitor are compared with those described for the locust. Putative structural homologies of subsets of neurons in both species are discussed.     

Sexual differentiation in the CNS of the moth,Manduca sexta. II. Target dependence for the survival of the imaginal midline neurons

While majority of the neurons in the adult nervous system of the moth Manduca sexta are produced postembryonically, little is known about how these cells interact with their targets during development. Few of these cells are motor neurons; most of Manduca's adult motor neurons are respecified larval motor neurons do develop postembryonically, including a large class of mixed neurosecretory and motor neurons called the imaginal midline neurons (IMNs). A subset of these cells show an unusual pattern of sex-specific development and survival (Thorn and Truman, 1994, J. Neurobiol. in press), which led us to suspect that factors extrinsic to the cells were controlling their fates. We analyzed one such potential factor by altering the contacts between a subset of these developing IMNs and their adult-specific target, the male sperm duct. When we transected the nerve that innervated the sperm duct in the pupa, we observed a loss of many sperm duct IMNs. In contrast, a transection of the same nerve in larvae showed no neuron loss. Immunocytochemistry showed that the pupal nerve transections were accompanied by a loss of axon endings on the sperm duct, while the larval nerve transections showed no such loss. Using local hormone application to slow the development of the sperm duct while leaving the nerve intact still resulted in a loss of IMNs. These results suggest that these IMNs need contact with a robust developing target in the pupa to survive metamorphosis. 1994 John Wiley & Sons, Inc.     

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.