Development of the embryonic neuromuscular synapse of Drosophila melanogaster

We have examined the embryonic development of an identified neuromuscular junction (NMJ) of Drosophila melanogaster using whole- cell patch-clamp and a variety of physiological and morphological techniques. Synaptic current at the embryonic NMJ is carried through a large-conductance (200 pS) L-glutamate receptor. Early synaptic communication is characterized by frequent, brief (< 10 msec) currents carried through few (1–10) receptors and relatively rare, prolonged currents (up to seconds) of similar amplitude. The brief currents have a time course similar to the mature larval excitatory junction currents (EJCs), but the prolonged currents are restricted to early stages of synaptogenesis. The amplitude of EJCs rapidly increases, and the frequency of the prolonged currents decreases, after the initial stages of synaptogenesis. Early prolonged (seconds), nonspiking synaptic potentials are replaced with rapid (> 0.10 sec), spiking synaptic potentials later in development. The early synapse appears tenuous, easily fatiguable, and with inconsistent communication properties. Synaptogenesis can be divided into a sequence of progressive stages. (1) Motor axon filopodia begin neurotransmitter expression and concurrent exploration of the myotube surface. (2) Myotubes uncouple to form single-cell units soon after motor axon contact. (3) A small number of transmitter receptors are homogeneously displayed on the myotube surface immediately following myotube uncoupling. (4) Endogenous transmitter release from pioneering growth cones is detected; nerve stimulation elicits postsynaptic EJC response. (5) Motor axon filopodia and transmitter receptors are localized to the mature synaptic zone; filopodial localization is complete in advance of receptor localization. (6) A functional neuromuscular synapse is formed; endogenous muscular activity begins; nerve stimulation leads to muscle contraction. (7) Morphological presynaptic specializations develop; synapse develops mature morphology. (8) A second motor axon synapses on the myotube at the pre-established synaptic zone. (9) Vigorous neuromuscular activity, characteristic of larval locomotory movements, begins. (10) A second stage of receptor expression begins and continues through the end of embryogenesis. In general, Drosophila neuromuscular synaptogenesis appears similar to neuromuscular synaptogenesis in known vertebrate preparations. We suggest that this system provides a model for synaptogenesis in which investigation can be readily extended to a genetic and molecular level.

[1]  B. G. Wallace,et al.  Mechanism of agrin-induced acetylcholine receptor aggregation. , 1992, Journal of neurobiology.

[2]  DJ Wigston Repeated in vivo visualization of neuromuscular junctions in adult mouse lateral gastrocnemius , 1990, Journal of Neuroscience.

[3]  M. Poo,et al.  Studies of nerve-muscle interactions in Xenopus cell culture: analysis of early synaptic currents , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[4]  H. Peng,et al.  Increase in intracellular calcium induced by the polycation-coated latex bead, a stimulus that causes postsynaptic-type differentiation in cultured Xenopus muscle cells. , 1988, Developmental biology.

[5]  RJ Balice-Gordon,et al.  In vivo visualization of the growth of pre- and postsynaptic elements of neuromuscular junctions in the mouse , 1990, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[6]  H. Keshishian,et al.  Stereotypic morphology of glutamatergic synapses on identified muscle cells of Drosophila larvae , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[7]  E. Lieth,et al.  Muscle-derived agrin in cultured myotubes: expression in the basal lamina and at induced acetylcholine receptor clusters. , 1992, Developmental biology.

[8]  P. Usherwood,et al.  Spider toxins as tools for dissecting elements of excitatory amino acid transmission , 1988, Trends in Neurosciences.

[9]  A. Warner,et al.  Gap junctional communication during neuromuscular junction formation , 1991, Neuron.

[10]  H. Keshishian,et al.  Axonal guidance and the development of muscle fiber-specific innervation in Drosophila embryos , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[11]  U. J. McMahan,et al.  Agrin-like molecules in motor neurons. , 1990, Journal de physiologie.

[12]  D. Poulson,et al.  The embryonic development of drosophila melanogaster , 1937 .

[13]  A. Shadiack,et al.  Agrin induces alpha-actinin, filamin, and vinculin to co-localize with AChR clusters on cultured chick myotubes. , 1991, Journal of neurobiology.

[14]  Z. Hall,et al.  Progressive restriction of synaptic vesicle protein to the nerve terminal during development of the neuromuscular junction , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[15]  H. Atwood,et al.  Variation in terminal morphology and presynaptic inhibition at crustacean neuromuscular junctions , 1991, The Journal of comparative neurology.

[16]  L. Okun,et al.  Staining of living presynaptic nerve terminals with selective fluorescent dyes , 1984, Nature.

[17]  M. Bennett Development of neuromuscular synapses. , 1983, Physiological reviews.

[18]  A. Warner,et al.  Low resistance junctions between mesoderm cells during development of trunk muscles. , 1976, The Journal of physiology.

[19]  H. Sink,et al.  Location and connectivity of abdominal motoneurons in the embryo and larva of Drosophila melanogaster. , 1991, Journal of neurobiology.

[20]  N. Patel,et al.  Molecular genetics of neuronal recognition in Drosophila: evolution and function of immunoglobulin superfamily cell adhesion molecules. , 1990, Cold Spring Harbor symposia on quantitative biology.

[21]  Y. Jan,et al.  Antibodies to horseradish peroxidase as specific neuronal markers in Drosophila and in grasshopper embryos. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[22]  M. Milner,et al.  The growth and differentiation in vitro of leg and wing imaginal disc cells from Drosophila melanogaster , 1988 .

[23]  C. Goodman,et al.  Fasciclin III: A novel homophilic adhesion molecule in Drosophila , 1989, Cell.

[24]  M. Anderson,et al.  Nerve‐induced and spontaneous redistribution of acetylcholine receptors on cultured muscle cells. , 1977, The Journal of physiology.

[25]  In vitro analysis of specificity during nerve-muscle synaptogenesis. , 1988, Ciba Foundation symposium.

[26]  J. Connor,et al.  Perforated Patch Recording , 1991 .

[27]  R Latorre,et al.  L‐Glutamate activates excitatory and inhibitory channels in Drosophila larval muscle , 1989, FEBS letters.

[28]  M. Westerfield,et al.  Pathfinding and synapse formation in a zebrafish mutant lacking functional acetylcholine receptors , 1990, Neuron.

[29]  T. Jessell,et al.  Cell adhesion molecules in vertebrate neural development. , 1988, Physiological reviews.

[30]  L. Landmesser,et al.  Polysialic acid as a regulator of intramuscular nerve branching during embryonic development , 1990, Neuron.

[31]  H. Keshishian,et al.  Identification of the neuropeptide transmitter proctolin in Drosophila larvae: characterization of muscle fiber-specific neuromuscular endings , 1988, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[32]  M. Bate,et al.  The embryonic development of larval muscles in Drosophila. , 1990, Development.

[33]  H. Peng,et al.  The influence of AChR clustering stimuli on the formation and maintenance of AChR clusters induced by polycation-coated beads in Xenopus muscle cells. , 1990, Developmental biology.

[34]  S A Berman,et al.  Differential expression of acetylcholine receptor mRNA in nuclei of cultured muscle cells. , 1989, Proceedings of the National Academy of Sciences of the United States of America.

[35]  B. Ganetzky,et al.  Neurogenetics of membrane excitability in Drosophila. , 1986, Annual review of genetics.

[36]  P. Usherwood,et al.  Rapid activation and desensitization by glutamate of excitatory, cation-selective channels in locust muscle , 1988, Neuroscience Letters.

[37]  M. Bate,et al.  Development of larval muscle properties in the embryonic myotubes of Drosophila melanogaster , 1993, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[38]  B. G. Wallace The mechanism of agrin-induced acetylcholine receptor aggregation. , 1992, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[39]  T. Lentz,et al.  Development of the myotomal neuromuscular junction in Xenopus laevis: an electrophysiological and fine-structural study. , 1977, Developmental biology.

[40]  H. Keshishian,et al.  Growth cone behavior underlying the development of stereotypic synaptic connections in Drosophila embryos , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[41]  Y. Zhong,et al.  Altered synaptic plasticity in Drosophila memory mutants with a defective cyclic AMP cascade. , 1991, Science.

[42]  Miriam M. Salpeter,et al.  Nicotinic acetylcholine receptors in vertebrate muscle: Properties, distribution and neural control , 1985, Progress in Neurobiology.

[43]  Y. Jan,et al.  L‐glutamate as an excitatory transmitter at the Drosophila larval neuromuscular junction. , 1976, The Journal of physiology.

[44]  S. Schuetze Embryonic and adult acetylcholine receptors: molecular basis of developmental changes in ion channel properties , 1986, Trends in Neurosciences.

[45]  M. Dennis,et al.  Development of neuromuscular junctions in rat embryos. , 1981, Developmental biology.

[46]  J. Buchanan,et al.  Studies of nerve-muscle interactions in Xenopus cell culture: fine structure of early functional contacts , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[47]  Alain Marty,et al.  Tight-Seal Whole-Cell Recording , 1983 .