Disappearance and reformation of synaptic vesicle membrane upon transmitter release observed under reversible blockage of membrane retrieval

The temperature-sensitive mutant of Drosophila, shibire(ts-1), which is normal at 19 degrees C, but in which endocytosis is reversibly blocked at 29 degrees C, was used to deplete synapses of vesicles by inducing transmitter release while membrane retrieval was blocked. When the synapse was kept at 29 degrees C for 8 min, complete vesicle depletion occurred. However, no compensatory increase in the terminal plasma membrane, either as invaginations or evaginations, was observed. Also, no internalized membranous compartment, such as cisternae or coated vesicles, appeared. No invaginations or out-pocketings were seen along the axon between release sites, and no evidence for elongation of the whole axon was found. Thus, the vesicle membrane compartment became unobservable as a result of transmitter release. Depleted synapses were observed by electron microscopy at various times after lowering the temperature, so that the process of synaptic vesicle reformation could be observed. In the first 2–3 min at 19 degrees C, gradually enlarging uncoated invaginations of the plasma membrane were observed. Between 5– 10 min at 19 degrees C, these invaginations pinched off to form large cisternae. Newly formed synaptic vesicles were observed associated with these cisternae by an electron-dense material. Between 10–20 min at 19 degrees C, the number of synaptic vesicles increased, while the size of the cisternae decreased. Within 30 min, the full complement of vesicles had reappeared. No involvement of the coated vesicle pathway in synaptic vesicle reformation was observed. The data suggest that synaptic vesicle membrane is dissembled at the time of transmitter release and then is reassembled at sites along the plasma membrane and internalized in the form of large cisternae, from which new vesicles are formed.

[1]  D. Bodian A new method for staining nerve fibers and nerve endings in mounted paraffin sections , 1936 .

[2]  Changes in the number of vesicles and the size of sympathetic nerve terminals following nerve stimulation. , 1970 .

[3]  Changes in the number of vesicles and the size of sympathetic nerve terminals following nerve stimulation. , 1970, Revue canadienne de biologie.

[4]  A. Mauro,et al.  CHANGES IN THE FINE STRUCTURE OF THE NEUROMUSCULAR JUNCTION OF THE FROG CAUSED BY BLACK WIDOW SPIDER VENOM , 1972, The Journal of cell biology.

[5]  A. Mauro,et al.  DEPLETION OF VESICLES FROM FROG NEUROMUSCULAR JUNCTIONS BY PROLONGED TETANIC STIMULATION , 1972, The Journal of cell biology.

[6]  T. Reese,et al.  EVIDENCE FOR RECYCLING OF SYNAPTIC VESICLE MEMBRANE DURING TRANSMITTER RELEASE AT THE FROG NEUROMUSCULAR JUNCTION , 1973, The Journal of cell biology.

[7]  E. Holtzman,et al.  AXONAL AGRANULAR RETICULUM AND SYNAPTIC VESICLES IN CULTURED EMBRYONIC CHICK SYMPATHETIC NEURONS , 1973, The Journal of cell biology.

[8]  A. Mauro,et al.  TURNOVER OF TRANSMITTER AND SYNAPTIC VESICLES AT THE FROG NEUROMUSCULAR JUNCTION , 1973, The Journal of cell biology.

[9]  R. Wiley,et al.  SYNAPTIC VESICLE DEPLETION AND RECOVERY IN CAT SYMPATHETIC GANGLIA ELECTRICALLY STIMULATED IN VIVO , 1974, The Journal of cell biology.

[10]  R. Birks The relationship of transmitter release and storage to fine structure in a sympathetic ganglion , 1974, Journal of neurocytology.

[11]  T. Reese,et al.  Functional changes in frog neuromuscular junctions studied with freeze-fracture , 1974, Journal of neurocytology.

[12]  S. Hagiwara,et al.  Synaptic transmission reversibly conditioned by single-gene mutation in Drosophila melanogaster , 1976, Nature.

[13]  T. Reese,et al.  Action of brown widow spider venom and botulinum toxin on the frog neuromuscular junction examined with the freeze‐fracture technique. , 1977, The Journal of physiology.

[14]  W. L. Nastuk,et al.  Reversible depletion of synaptic vesicles induced by application of high external potassium to the frog neuromuscular junction , 1978, The Journal of physiology.

[15]  L. Salkoff,et al.  Temperature-induced seizure and frequency-dependent neuromuscular block in a ts mutant of Drosophila , 1978, Nature.

[16]  C. Basbaum,et al.  Morphological studies of stimulated adrenergic axon varicosities in the mouse vas deferens , 1979, The Journal of cell biology.

[17]  W. P. Hurlbut,et al.  Freeze-fracture studies of frog neuromuscular junctions during intense release of neurotransmitter. II. Effects of electrical stimulation and high potassium , 1979, The Journal of cell biology.

[18]  M. Dennis,et al.  Synaptic vesicle exocytosis captured by quick freezing and correlated with quantal transmitter release , 1979, The Journal of cell biology.

[19]  F. Grohovaz,et al.  Freeze-fracture studies of frog neuromuscular junctions during intense release of neurotransmitter. III. A morphometric analysis of the number and diameter of intramembrane particles , 1980, The Journal of cell biology.

[20]  K. Ikeda,et al.  Organization of identified axons innervating the dorsal longitudinal flight muscle ofDrosophila melanogaster , 1980, Journal of neurocytology.

[21]  K. Ikeda,et al.  Flight pattern induced by temperature in a single-gene mutant of Drosophila melanogaster. , 1980, Journal of neurobiology.

[22]  T. Reese,et al.  Structural changes after transmitter release at the frog neuromuscular junction , 1981, The Journal of cell biology.

[23]  T. Kadota,et al.  Membrane retrieval by macropinocytosis in presynaptic terminals during transmitter release in cat sympathetic ganglia in situ. , 1982, Journal of electron microscopy.

[24]  T. Lentz,et al.  Synaptic vesicle recycling at the neuromuscular junction in the presence of a presynaptic membrane marker , 1982, Neuroscience.

[25]  K. Ikeda,et al.  Reversible blockage of membrane retrieval and endocytosis in the garland cell of the temperature-sensitive mutant of Drosophila melanogaster, shibirets1 , 1983, The Journal of cell biology.

[26]  K. Ikeda,et al.  Possible temperature-dependent blockage of synaptic vesicle recycling induced by a single gene mutation in Drosophila. , 1983, Journal of neurobiology.

[27]  K. Ikeda,et al.  Reversible control of synaptic transmission in a single gene mutant of Drosophila melanogaster , 1983, The Journal of cell biology.

[28]  K. Ikeda,et al.  Evidence for a presynaptic blockage of transmission in a temperature-sensitive mutant of Drosophila. , 1983, Journal of neurobiology.

[29]  J. Heuser,et al.  Endocytosis of synaptic vesicle membrane at the frog neuromuscular junction , 1984, The Journal of cell biology.

[30]  T. Kadota,et al.  TUBULAR NETWORK OF THE SMOOTH ENDOPLASMIC RETICULUM WHICH APPEARS IN THE AXON TERMINAL FOLLOWING STIMULATION OF THE CAT SYMPATHETIC GANGLION IN SITU , 1985 .

[31]  F. Grohovaz,et al.  Temporal coincidence between synaptic vesicle fusion and quantal secretion of acetylcholine , 1985, The Journal of cell biology.

[32]  B. Ceccarelli,et al.  Coated vesicles and pits during enhanced quantal release of acetylcholine at the neuromuscular junction , 1987, Journal of neurocytology.

[33]  J J Pysh,et al.  Time course and frequency dependence of synaptic vesicle depletion and recovery in electrically stimulated sympathetic ganglia , 1987, Journal of neurocytology.

[34]  F. Gonzalez-Aguilar,et al.  Synaptic vesicle relationships with the presynaptic membrane as shown by a new method of fast chemical fixation , 1988, Neuroscience.

[35]  Dean O. Smith Statistical evidence for non-random clustering of synaptic vesicles associated with filamentous interconnections , 1988, Brain Research.

[36]  K. Ikeda,et al.  The relationship between the number of synaptic vesicles and the amount of transmitter released , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.