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Previous Article | Next Article
Volume 16, Number 17, Issue of September 1, 1996 pp. 5443-5456
Copyright ©1996 Society for NeuroscienceTraffic of Dynamin within Individual Drosophila Synaptic Boutons Relative to Compartment-Specific Markers
Patricia S. Estes1, Jack Roos2, Alexander van der Bliek3, Regis B. Kelly2, K. S. Krishnan4, and Mani Ramaswami1 1 Department of Molecular and Cellular Biology and Arizona Research Labs, Division of Neurobiology, University of Arizona, Tucson, Arizona 85721, 2 Department of Biochemistry and Biophysics and Hormone Research Institute, University of California at San Francisco, San Francisco, California 94143-0534, 3 Department of Biological Chemistry, University of California at Los Angeles, Los Angeles, California 90024, and 4 Molecular Biology Unit, Tata Institute for Fundamental Research, Colaba, Bombay 400005, India
ABSTRACT
Presynaptic terminals contain several specialized compartments, which have been described by electron microscopy. We show in an identified Drosophila neuromuscular synapse that several of these compartments
Key words: neurogenetics; endocytosis; membrane traffic; ultrastructure; temperature-sensitive paralysis; synaptic vesicle recycling; neurotransmitter releasesynaptic vesicle clusters, presynaptic plasma membrane, presynaptic cytosol, and axonal cytoskeleton
INTRODUCTION
Intercellular communication in the nervous system occurs primarily at chemical synapses. The most dramatic phenomenon at nerve terminals is the coupling of electrical depolarization to synaptic vesicle fusion. After fusion, synaptic vesicle membrane is internalized and recycled to form new synaptic vesicles. The speed and high fidelity of these processes are accomplished by a large number of presynaptic proteins with highly specific spatial localizations (Burns and Augustine, 1995; Sudhof, 1995
The nerve terminal is not a static structure. Transient calcium influxes are coupled to synaptic vesicle fusion events. Vesicle collapse into plasma membrane probably results in the lateral diffusion of synaptic vesicle proteins (Heuser and Reese, 1973
The accessibility of identified synapses to morphological and electrophysiological analyses at all stages in development has made the Drosophila larval neuromuscular junction an increasingly important preparation for the analysis of synapse formation and function. Thus, the analysis of Drosophila mutant synapses bearing null or partial loss of function mutations in various genes encoding presynaptic molecules has yielded many unique insights into the molecular mechanisms of transmitter release (Bate and Broadie, 1995
We have exploited the large size of Drosophila presynaptic varicosities and have used confocal microscopy to examine the relative localization of various compartment-specific markers at the nerve terminal. In resting nerve terminals, synaptic vesicles show a distribution pattern quite distinct from presynaptic plasma membrane, presynaptic cytosol, and the axonal cytoskeleton. The distribution of synaptic vesicle membrane proteins is dramatically altered, from an intracellular domain to plasma membrane, in shits1 mutant synapses depleted of synaptic vesicles (van de Goor et al., 1995
MATERIALS AND METHODS
Drosophila culture and stocks. Flies were cultured in standard sugar/agar-containing yeasted medium in vials or bottles at temperatures between 19 and 22°C. Oregon-R and shits1 mutants were from the Krishnan and Ramaswami laboratory stock collection (Ramaswami et al., 1994Larval bodywall muscle preparation. Third-instar larval neuromuscular preparations and the stereotypic pattern of innervation of larval bodywall muscles have been described previously (Jan and Jan, 1976
Organization and morphology of synaptic terminals on larval ventral longitudinal muscles. The organization and structure of synapses on the ventral longitudinal muscles have been described previously at the level of light and electron microscopy (Jan and Jan, 1976
Fig. 5. A, Drosophila dynamin antibodies shi-3 (whole anti-peptide serum), Ab2073, and Ab2074 (affinity-purified antibodies) label dynamin by Western blot analysis. Fifteen milligrams of Drosophila S1 postnuclear supernatant were resolved by SDS-PAGE, transferred to nitrocellulose, and incubated with the indicated antibody. Each antibody specifically labels dynamin, a 92/94 kDa doublet whose individual components are not resolved in this gel (Gass et al., in press). B, Each of the antisera stain type 1b and type 1s varicosities at the larval neuromuscular junction. This image shows a preparation stained with affinity-purified Ab2074. Thus, dynamin is highly enriched at the motor terminal, quite specifically at varicosities (see also Fig. 7). Scale bar, 25 µm.
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Salines. Normal saline was 130 mM NaCl, 36 mM sucrose, 5 mM KCl, 5 mM HEPES, pH 7.3, 2 mM MgCl2, and 2 mM CaCl2 (Jan and Jan, 1976
High-K+ stimulation. Peripheral nerves of insect larvae are surrounded by a glial sheath that protects them from the high-K+ (23 mM in Drosophila) concentration of the hemolymph (Stewart et al., 1994
Generation of antibodies. Rabbit anti-synaptotagmin (DSYT-2) antibody was a generous gift from Troy Littleton and Hugo Bellen (Baylor College of Medicine). Anti-CSP antibody (mAb49) was a gift from Erich Buchner (Universitat Wurzburg) and Konrad Zinsmaier (University of Pennsylvania School of Medicine). FITC-conjugated anti-HRP was purchased from Cappel (West Chester, PA), and monoclonal antibody 22C10 was a gift from Seymour Benzer's laboratory (California Insitute of Technology).
The rabbit antiserum, shi-3, was made against a KLH-conjugated 16 residue peptide from the C-terminal proline-rich sequence of Drosophila dynamin (CRPGGSLPPPMLPSRR). The peptide was made at the Caltech peptide facility, conjugated to KLH, and sent to Pocano Rabbit Farms (Canadensis, Pennsylvania) for antibody production in rabbits. Polyclonal antibodies 2073 and 2074 to Drosophila dynamin were raised against purified recombinant fusion proteins. Fusion proteins used as immunogens were sent to Immuno-Dynamics (La Jolla, CA) for antibody production in rabbits. A 37 kDa fragment of Drosophila dynamin, encompassing amino acids 331-651 (which includes the pleckstrin homology domain of dynamin), was fused to glutathione-S-transferase (GST). This fusion protein was used to generate the serum Ab2073. A 66 kDa fragment of Drosophila dynamin, lacking the N-terminal 241 amino acids (lacking the GTP-binding domain), was fused to the maltose-binding protein (MBP) and used to generate the antiserum Ab2074.
Antibodies were affinity-purified by the method of Smith and Fisher (1984)
Western analysis. Drosophila head postnuclear supernatant (S1) was generated as described previously (van de Goor et al., 1995
Immunohistochemistry. Synaptic vesicle markers DSYT-2 and mAb49 were used at 1:200 and 1:20 dilutions, respectively. The dynamin antiserum shi-3 was used at 1:200, and affinity-purified Ab2073 and Ab2074 were used at 1:200 and 1:500, respectively. Monoclonal antibody 22C10 and FITC-conjugated anti-HRP (Cappel) were used at a 1:50 dilution. Secondary antibodies were from Cappel: FITC or Texas Red-conjugated goat anti-rabbit (or goat anti-mouse) IgGs were used at a 1:200 dilution.
Previous work in adult neuromuscular preparation has shown that application of aldehyde fixative in the presence of calcium results in a burst of motor activity induced by CNS stimulation before complete fixation (Koenig et al., 1989
Biocytin fills of nerve terminals. Third-instar larvae were filleted as described earlier. The anterior anchors of the ventral ganglion were cut away, and the CNS was lifted into a conical Vaseline well made at the anterior end of the larva with a fine Vaseline dispenser. After the well contents were isolated from the bath, the CNS was either crushed or cut away in distilled water to expose the ends of the motor nerves to the contents of the well. The well was filled with saturated biocytin (Sigma) solution in distilled water, and the preparation was kept at room temperature for 3 hr. The preparation was washed in saline, fixed with 3.5% paraformaldehyde solution for 30 min, and subsequently stained with fluorescently conjugated streptavidin (Vector Labs, Burlingame, CA) to visualize biocytin-labeled structures. In general, with a 3 hr incubation, synapses on the anterior segments were stained more brightly, presumably because biocytin required less time to diffuse down the shorter motor nerves.
Optical microscopy and image processing. At least five experiments were conducted for each pair of antibodies, and at least six different hemisegments from each preparation were examined carefully. In general, the number of experiments greatly exceeded this number. For every experiment in which we examined redistribution of antigens in shits1 mutants after vesicle depletion, a wild-type preparation was processed similarly in parallel. Initially, the preparations were labeled in code by one of us and examined ``blind'' by the other, under a conventional fluorescence microscope. We found that shits1 preparations could be identified easily in every case (more than 10 were tested blind): shits1-depleted terminals appeared to be swollen, boutons boundaries were not as distinct, and synaptic vesicle membrane markers appeared to label the axonal plasma membrane. In wild-type or in resting, unstimulated shits1 terminals, synaptic vesicle proteins were never found in the ring-like structures shown in Figures 2C,D, 3C,D, and 7, but rather were found in a compact and dense pattern within presynaptic varicosities. To compare biocytin or dynamin localization with synaptic vesicle markers, we selected boutons to examine in the following manner. For shits1-depleted terminals, we generally looked at synaptic vesicle protein localization through one filter and chose fields of view in which the best optical sectioning could be achieved; in these ideally oriented varicosities, we examined the localization of the second marker. It was not always possible in shits1 preparations to mark clearly the beginning and end of the presynaptic varicosities, perhaps because of swelling of adjacent axonal regions connecting the varicosities. For wild-type terminals in which varicosities were clearly visible, we preferred to analyze terminal synapses on the muscle surface where good optical sectioning was possible. Little additional information was obtained from three-dimensional reconstructions.
Fig. 2. Synaptotagmin is redistributed from an intracellular pool to plasma membrane in shits1 mutant terminals. Each image represents a single optical section. A-C, Wild-type presynaptic terminals stimulated at elevated temperatures. A, Plasma membrane antigens labeled by anti-HRP. B, Synaptic vesicles labeled by anti-synaptotagmin. C, A red-green overlay of the two (green plasma membrane and red synaptic vesicles) shows that the synaptic vesicle marker synaptotagmin is restricted to presynaptic varicosities and surrounded by plasma membrane labeled by anti-HRP. D-F, In shits1 terminals depleted of synaptic vesicles, plasma membrane antigens (D) and synaptic vesicle antigens (E) show almost identical distribution patterns. The red-green overlay (F) indicates that synaptic vesicle membrane protein (red) is trapped on plasma membrane (green). Residual anti-HRP immunoreactivity apparently within wild-type varicosities is not seen in optical sections through shits1-depleted nerve terminals. This phenomenon could reflect swelling of shits1 nerve terminals after substantial addition of synaptic vesicle membrane to the plasmalemma. Such swelling could result in a much higher efficiency of optical sectioning and improved resolution along the Z-axis between the inside of the bouton and the overlying plasma membrane. An alternative possibility we cannot exclude is that anti-HRP may additionally recognize an unidentified component of synaptic vesicle membrane. Scale bar (shown in F): 5 µm.
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Fig. 3. Synaptotagmin and cysteine string protein (csp) are identically localized within synaptic boutons. A, B, Single optical sections through wild-type terminals stimulated at 34°C, stained for csp (A) and synaptotagmin (syt) (B). Identical dense subsynaptic regions are labeled within presynaptic boutons. C, D, In similar sections through shits1-depleted terminals, both csp (C) and syt (D) are redistributed to identical ring-shaped structures probably corresponding to plasma membrane. Scale bar (shown in D): 5 µm.
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Fig. 7. Dynamin is redistributed to hot spots on the plasma membrane in shits1-depleted terminals. Synaptic vesicle proteins (A, D) are redistributed to the plasma membrane in a pattern that is smooth, relative to the punctate distribution of dynamin (B, E). The red-green overlays in C and F emphasize these differences. The arrows in B and E indicate dynamin-rich domains not particularly enriched in the synaptic vesicle marker. Single optical sections. Scale bar, 5 µm.
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We used a Bio-Rad 600 laser-scanning confocal microscope (Bio-Rad, Richmond, CA) and the COMOS software package to acquire all fluorescence images shown in this paper. For FITC and Texas Red double-labeled preparations, images were acquired simultaneously using the K1/K2 filters provided by Bio-Rad. For all of our experiments, we ensured that fluorescence bleedthrough was not a significant problem. To acquire the thin optical sections shown in most of the figures, the aperture was generally set at 0.4, and a 60× 1.4 NA lens was used at high zoom (generally 6). We took Z series where the focal planes were stepped by 0.5-1.0 µM between successive images. The brightest optical section containing most of the immunoreactivity was selected in every case. The split-screen images acquired from the confocal microscope were split exactly into two using a National Institutes of Health Image macro provided by Dr. ChiBin Chien from the University of California San Diego. The split red and green images were scaled independently (linearly) to equal maximal brightness using National Institutes of Health Image. No further processing of the images occurred. National Institutes of Health Image files were subsequently imported into Adobe Photoshop for generation of the red-green overlays shown in the figures.
Electron microscopy. We examined approximately 20 presynaptic boutons on muscles 6 and 7 in abdominal segment A2 or A3 in three shits1 and two wild-type larvae. After wild-type and shits1 larvae neuromuscular preparations were stimulated at elevated temperatures, they were fixed for 30 min at 34°C, followed by 90 min at room temperature, and overnight at 4°C in freshly prepared fixative containing 4% paraformaldehyde (Sigma) and 1% or 6% glutaraldehyde (Sigma) in 100 mM cacodylate buffer, pH 7.2, 2 mM sucrose, and 0.5 mM EGTA. After fixation, the tissue was rinsed three times in 100 mM cacodylate buffer with 264 mM sucrose. Right and left hemisegments from A2 and A3 were separated from the larval fillet at this stage and postfixed with 1% OsO4 in 100 mM cacodylate buffer for 2 hr. Some preparations were stained en bloc for 1 hr (the shi preparation shown was not stained en bloc) with 1% uranyl acetate in 70% EtOH before dehydration in an ethanol series. The tissue was embedded in Epon (Embed 812; Electron Microscopy Sciences), and longitudinal ultrathin sections were made on an LKB ultramicrotome using a diamond knife. Grids were poststained with 2% uranyl acetate and 1% lead citrate and examined with a Jeol 1200EX electron microscope.
RESULTS
High-temperature stimulation depletes synaptic vesicles in larval shits1 Type 1b terminals
Previous electron microscopic (EM) studies on synaptic vesicle depletion in shi mutants have been performed at adult synapses, which are not as convenient as larval synapses for studies of synaptic transmission. To establish that shits1 larval nerve terminals may be arrested similarly at a specific stage in synaptic vesicle recycling, we used EM studies to examine the ultrastructure of wild-type and shits1 larval type Ib synaptic boutons on the ventral longitudinal muscles 6 and 7 after high-K+ stimulation at elevated temperatures.Under the electron microscope, a substantial depletion of synaptic vesicles was observed in shits1 but not in control, wild-type terminals stimulated at 34°C. Figure 1, A and B, shows the typical wild-type and shits1 terminals that we observed. As in adult shits1 animals, larval shits1 nerve terminals depleted by stimulation at elevated temperatures contain collared-pit structures, as shown in the inset of Figure 1B. Thus, stimulation of shits1 larval neuromuscular preparations with high-K+ saline at elevated temperatures causes depletion of synaptic vesicles and the accumulation of collared pits on presynaptic membrane, as expected from the previous studies of adult synapses (Kosaka and Ikeda, 1983
Fig. 1. Synaptic vesicles are depleted in type 1b synaptic varicosities of shits1 larval muscles 6 and 7 by high-K+ stimulation at elevated temperatures. A, Synaptic vesicles are not depleted in a control wild-type synaptic bouton stimulated for 5 min at 34°C. B, Vesicles are depleted in identically stimulated shits1 nerve terminals. The inset shows a collared pit trapped in the shits1 larval terminal. m, Mitochondrion; ssr, subsynaptic reticulum; v, synaptic vesicle; mt, microtubule. Arrowhead indicates a collar on the nascent endocytotic vesicle. Scale bars: A, B, 200 nm; inset, 50 nm.
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Two synaptic vesicle proteins are identically redistributed in vesicle-depleted terminals
The best marker for Drosophila synaptic vesicles is synaptotagmin, an integral membrane protein shown to be associated with synaptic vesicles by biochemical, morphological, and genetic criteria (DiAntonio et al., 1993subunit of the Na+/K+ ATPase (Sun and Salvaterra, 1995
To confirm that csp and synaptotagmin may be used interchangeably as morphological markers for synaptic vesicle membrane, we used confocal microscopy to assess systematically the relative distributions of synaptotagmin, csp, and anti-HRP in wild-type and shits1-depleted Type 1b nerve terminals (see Materials and Methods). First, we examined Drosophila neuromuscular junctions double-stained for synaptotagmin and anti-HRP immunoreactivity. In wild-type synapses stimulated for 5 min at 34°C, the relative distribution of plasma membrane and synaptic vesicles was not altered significantly from resting terminals: synaptic vesicles were in dense and compact structures specifically localized within presynaptic varicosities surrounded by plasma membrane (Fig. 2A-C). In vesicle-depleted shits1 nerve terminals, synaptotagmin is redistributed dramatically compared with wild-type or resting shi terminals. After synaptic vesicle depletion, synaptic vesicle membrane appears almost indistinguishable from plasma membrane by confocal microscopy (Fig. 2D-F).
After establishing that synaptotagmin redistributes to plasma membrane in shits1-depleted larval motor terminals, we examined the relative distributions of synaptotagmin and csp. The images shown in Figure 3A,B compare synaptotagmin and csp localization within wild-type presynaptic varicosities, which have been stimulated with high-K+ saline for 5 min at 34°C. Images in Figure 3C,D show an identically treated shits1 preparation. At the level of resolution afforded by light microscopy, the distributions of synaptotagmin and csp are indistinguishable within wild-type or vesicle-depleted presynaptic varicosities.
Our results establish that csp and synaptotagmin immunoreactivity can be used as reference points to mark synaptic vesicles within resting Type 1b larval nerve terminals. In shits1 terminals depleted of synaptic vesicles, csp and synaptotagmin may serve as good morphological markers for presynaptic plasma membrane. An additional observation we wish to underscore is that two synaptic vesicle antigens show identical distributions in our experimental system. This apparent absolute identity is an important point, because it serves to emphasize the differences we have subsequently observed between localizations of dynamin and synaptic vesicle markers.
Almost the entire mature nerve terminal is accessible to a small soluble molecule
The nerve terminal contains synaptic vesicle clusters, mitochondria, and various cytoskeletal elements in addition to soluble cytoplasmic material. Previous EM studies have shown that in Drosophila, frog, and mammals, synaptic vesicles do not occupy the entire motor nerve terminal. Optical microscopy has also been used to demonstrate synaptic vesicle subdomains at the frog and mammalian neuromuscular junction, which may be distinguished from domains rich in mitochondria (Lichtman et al., 1989The relative distribution of biocytin and synaptotagmin in filled wild-type terminals is shown in Figure 4. The optical sections in Figure 4, A and B, show that biocytin can be easily visualized in the axonal regions connecting presynaptic varicosities, whereas synaptotagmin is restricted to the varicosity itself. Although in these images biocytin appears to fill the entire bouton, in the images shown in Figure 4, C and D, there appears to be a small region within the varicosity relatively inaccessible to both biocytin and synaptic vesicles. It is possible that this biocytin-inaccessible region contains mitochondria, a hypothesis we have not tested in this study. Our major conclusion from the biocytin-fill experiments is that a freely diffusible molecule in nerve terminals must show two properties. (1) It must be found in the axonal tracts connecting presynaptic varicosities, and (2) it should appear smoothly distributed within a presynaptic varicosity, not in a patchy or punctate pattern.
Fig. 4. A small freely diffusible molecule has access to most of the nerve terminal. Wild-type presynaptic boutons were filled with biocytin (a small diffusible molecule), and the relative distributions of biocytin and synaptic vesicles are compared in the same optical sections. A, Biocytin is found in the axonal regions (marked by an arrow) connecting varicosities in addition to the entire varicosity itself. B, In the same sample shown in A, synaptic vesicles are found tightly localized to specific subsynaptic regions within individual varicosities. C and D show a different preparation from A and B. Here a small central region of the presynaptic bouton (indicated by an arrow), which does not contain synaptic vesicle marker (D), is relatively inaccessible to biocytin. The axonal region is not seen in this optical section. Scale bar, 2 µm.
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Dynamin is restricted to synaptic varicosities in a pattern different from synaptotagmin
To compare the distribution of dynamin relative to our compartment-specific markers, we generated three independent antisera against Drosophila dynamin: shi-3 antibody was raised against a C-terminal peptide, and the antisera Ab2073 and Ab2074 were raised against bacterial fusion proteins containing different domains of fly dynamin (for more details, see Materials and Methods). In Western blots against proteins from fly head lysates, all three antibodies labeled a ~92/94 kDa doublet, the appropriate size for the Drosophila dynamin (Gass et al., in press) (Fig. 5A). When affinity-purified against a fusion protein including the complete dynamin protein, all three of the antisera recognized this protein exclusively. Unpurified shi-3 antiserum, affinity-purified 2073, and affinity-purified 2074 antisera strongly labeled both type 1b and type 1s presynaptic varicosities at the larval neuromuscular junction (Fig. 5B). Having established that the antibodies recognize a presynaptically concentrated Drosophila dynamin, we used them to localize dynamin at a fine level relative to other compartment-specific markers at the fly nerve terminal. Indistinguishable results were obtained with all three independent antisera.In resting wild-type terminals, dynamin, like the synaptic vesicle marker csp, is localized within presynaptic varicosities and absent from axonal regions between the varicosities (Fig. 6A-C). Because this is not the distribution expected for a freely diffusible molecule like biocytin, we suggest that an active mechanism must exist to restrict its diffusion into axonal regions between synaptic sites. In higher-resolution images comparing dynamin localization with csp (Fig. 6D-F), dynamin has a patchy distribution, quite different from synaptic vesicles labeled by anti-csp. The differences in the observed localization patterns of dynamin, csp, and biocytin suggest that in resting terminals, dynamin occupies a region of the presynaptic terminal distinct from compartments labeled by biocytin and csp. This dynamin-rich domain is not likely to be a specialized region of presynaptic plasma membrane, because anti-HRP immunoreactivity surrounds the dynamin-containing regions of synaptic boutons (data not shown).
Fig. 6. Dynamin is localized in presynaptic varicosities to subdomains that do not correspond to synaptic vesicles. A-C, Lower-resolution images of resting wild-type 1b boutons labeled with anti-dynamin (B), anti-csp (A), and a red (dynamin)-green (csp) overlay of the two images (C) show that like synaptic vesicles, dynamin is restricted to presynaptic varicosities. D-F, Higher-resolution images showing that dynamin (E) has a different distribution from synaptic vesicles (D) within individual boutons. This is emphasized in the red-green overlay (F). Note in Figure 4, A and B, the identity between csp and synaptotagmin localization in a similar preparation. Single optical sections. Scale bar, 5 µm.
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Although the distribution pattern of dynamin is distinct from that of synaptic vesicles, dynamin immunoreactive regions overlap spatially with synaptic vesicle-containing regions. In addition to synaptic vesicles, this region of the bouton is likely to contain a complex cytoskeletal matrix that is not easily revealed by conventional EM studies. One function of this presynaptic cytoskeleton is to hold synaptic vesicles close to synaptic sites (Rosahl et al., 1995
In vesicle-depleted shits1 boutons, dynamin redistributes to plasma membrane subdomains
Previous biochemical experiments on mammalian synaptosomes have shown that an apparently soluble pool of dynamin is mobilized rapidly to a membrane-bound pool by synaptosome stimulation (Robinson et al., 1994S (Takei et al., 1995
In shits1-depleted type 1b presynaptic varicosities, almost all of the synaptic vesicle marker csp redistributes to plasma membrane (Figs. 3, 7A,D). This distribution of csp on the plasmalemma is relatively smooth. Under similar conditions, dynamin, like csp, is redistributed to the plasma membrane, and little residual cytoplasmic dynamin can be seen within the bouton (Fig. 7B,E). Unlike csp, however, dynamin immunoreactivity shows a strikingly punctate distribution. It is tightly concentrated in specific regions of the plasma membrane that are not necessarily enriched in the synaptic vesicle marker (see arrows in Fig. 7B,E). The functional implication of these dynamin hot spots is considered in the Discussion.
DISCUSSION
Compartment-specific markers for the Drosophila larval motor terminal
Immunofluorescence microscopy has become an increasingly powerful tool for the study of cellular structure and membrane traffic. The most valuable feature of this technique is that it enables direct observation of the relative distributions of as many as three different antigens at a whole-cell level, to 300 nm resolution. Thus, it allows comparison of the distributions of an unknown antigen relative to one or more ``markers'' that serve as reference points. One concern in the interpretation of immunofluorescence images is the innate complexity of eukaryotic cells. For instance, different Golgi compartments, Golgi-associated vesicles, and various endosomal structures are not necessarily distinguishable by optical microscopy. Not only can marker specificity be a problem in a naturally dynamic cell, but different structures labeled by the marker may be very closely associated (Griffiths et al., 1993Single presynaptic varicosities at the Drosophila larval neuromuscular junction may be the same size as yeast cells. The relatively few cellular structures found at nerve terminals may also allow less ambiguous identification of labeled structures viewed under the light microscope. For these reasons, immunofluorescence microscopy promises to be an important and useful tool for studying membrane dynamics at these nerve terminals. The availability of genetic mutants, functional assays for synaptic transmission, and a large collection of identified presynaptic molecules form an especially attractive context for such analyses in Drosophila. Some recent studies have begun to exploit the convenience of Drosophila motor terminals for high-resolution optical microscopy (Kurdyak et al., 1994
Fig. 8. A, The monoclonal antibody 22C10 labels a component of the axonal cytoskeleton. Scale bar, 5 µm. B, A cartoon showing various compartment-specific markers in type 1b presynaptic boutons. **Our data do not exclude the possibility that anti-HRP recognizes a component of synaptic vesicle membrane in addition to the presynaptic plasma membrane. An additional marker not characterized in our study is 4-di-2-Asp, which labels mitochondria (Magrassi et al., 1987
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Synaptic vesicles, plasma membrane, and presynaptic cytosol The images shown in Figures 2, 3, and 4 indicate that synaptic vesicles labeled by either anti-csp antibody or anti-synaptotagmin antibody are localized spatially in a pattern clearly distinguishable from plasma membrane stained by the anti-HRP antibody and presynaptic cytosol labeled by intracellular fills of biocytin. The appropriateness of anti-csp and DSYT-2 antibodies to mark Drosophila synaptic vesicles and of anti-HRP antibodies to mark presynaptic plasma membrane have been discussed here and in an earlier report (van de Goor et al., 1995
Localization of dynamin in resting nerve terminals
This is the first report to show a concentration of dynamin at neuromuscular synapses. Our data show that dynamin is localized not only to synaptic sites at motor terminals but is also found in a distribution different from all compartment-specific markers that we have analyzed. We consider the relevance of these observations in the light of current knowledge of nerve-terminal architecture and dynamin function. Dynamin is restricted to synaptic sites In resting Drosophila motor terminals, dynamin is localized to synaptic varicosities. This observation suggests the existence of a mechanism to restrict free diffusion of presynaptic dynamin.The state of dynamin in resting nerve terminals from mammalian brain has been examined by biochemical methods (for review, see Robinson et al., 1994
Dynamin may associate with a presynaptic cytoskeleton Because synapses in primary hippocampal cultures are very small in size, optical microscopy has not been used to obtain fine-resolution images for dynamin localization within individual synaptic sites. Our results show that within individual Drosophila presynaptic boutons, dynamin is localized in the same approximate region as synaptic vesicles but in a clearly distinct pattern. One possibility is that dynamin is distributed in a complex manner among different presynaptic compartments. A more attractive possibility is that dynamin in resting synapses is associated with a specific presynaptic compartment not characterized in our study. What might such a compartment be?A vast body of EM studies has shown that this region of the presynaptic terminal in all species examined contains relatively few cellular structures. These include endosomes and dense-core vesicles, but predominantly presynaptic cytosol, synaptic vesicles, and a cytoskeletal meshwork not easily visualized by conventional EM studies (Burns and Augustine, 1995
At least one synapse-specific protein, synapsin, is known to interact with this cytomatrix (Ceccaldi et al., 1995
Redistribution of dynamin in shits1 mutants
A specific intermediate stage in synaptic vesicle recycling is trapped in shits1 mutants Dynamin may undergo a series of transitions while participating in sequential membrane rearrangements during the different stages of vesicle internalization (Morris and Schmid, 1995In perforated synaptosomes incubated with GTP
Redistribution of dynamin to plasma membrane in shits1-depleted terminals Our observation that an intracellular pool of dynamin in resting synapses is redistributed in shits1 mutants is consistent with biochemical studies on mammalian synaptosomes but contrasts with biochemical studies of dynamin from whole Drosophila head homogenates (Robinson et al., 1994In shits1 larval nerve terminals stimulated at elevated temperatures, dynamin is dramatically redistributed to plasma membrane. Under these conditions, intracellular dynamin is reduced to a level too low for detection by our immunofluorescence technique. This almost quantitative redistribution of dynamin must be discussed in the context of a mutant nerve terminal in a nonphysiological state.
The total surface area of synaptic vesicle membrane in resting terminals may exceed the area of presynaptic plasma membrane (Koenig and Ikeda, 1989
What may be the mechanism of the observed redistribution of dynamin? Biochemical observations of mammalian synaptosomes suggest that calcium entry after membrane depolarization results in calcium-dependent dephosphorylation of dynamin. Dephosphorylated dynamin is predominantly membrane-associated, whereas phospho-dynamin is found in the soluble fraction of homogenized synaptosomes. Both dephosphorylation and membrane association of dynamin seem to be inhibited by cyclosporine, an inhibitor of the calcium-dependent phosphatase calcineurin (Robinson et al., 1994
Dynamin hot spots on the plasma membrane Although we anticipated a redistribution of dynamin to plasma membrane in shits1-depleted terminals, the observation that dynamin was enriched at specific hot spots on the membrane was entirely unexpected. Because three independent antibodies against different domains of dynamin gave qualitatively identical results, the observed pattern of dynamin localization is not likely to be artifactual. Thus, in shits1-depleted nerve terminals, subdomains of plasma membrane exist that are enriched for at least one component of the endocytotic machinery. We do not yet know how these hot spots are located relative to electron-dense bodies that mark active zones for synaptic vesicle exocytosis. It is worth noting that the subsynaptic distribution of clathrin, clathrin-associated proteins, and other likely components of the endocytotic machinery are unknown at this level of resolution. Our observations suggest that other molecules involved in synaptic vesicle endocytosis will be found enriched in these dynamin hot spots at shits1-depleted nerve terminals.The existence of dynamin ``hot spots'' suggests that dynamin-containing collared-pit structures are enriched in specific regions of the presynaptic plasma membrane. How might such hot spots arise, and what might be their functional relevance? We suggest two models: one, that they are generated in a temporal fashion made evident in shits1 synapses, and two, that they mark specialized zones for synaptic vesicle endocytosis. In model 1, we propose that membrane proteins from the first synaptic vesicles to fuse are trapped in collared pits. Because of obvious structural constraints, collared-pit structures may diffuse very slowly in the plane of the membrane. Once the available endocytotic machinery has been depleted, membrane proteins from still-fusing synaptic vesicles diffuse freely in the presynaptic plasma membrane away from the regions containing collared pits. (If one assumes a diffusion coefficient D = 2 × 10
10 cm2/sec, a synaptic vesicle membrane protein is capable of diffusing up to 45 µm within the 5 min period of high-K+ stimulation). In this first model, the spatial distribution of dynamin hot spots is controlled by the spatial distribution of synaptic vesicle fusion sites and the low rate of diffusion of collared-pit structures.
The second model derives from classical freeze-fracture studies of the frog neuromuscular synapse (Heuser and Reese, 1973
Although no Schwann cell-like processes have been described at the Drosophila neuromuscular junction, active zones for membrane retrieval may exist nevertheless. Specialized sites for endocytosis spatially distinct from fusion sites may serve an important cellular function. Unless synaptic vesicle membrane proteins are cleared away rapidly, the addition of synaptic vesicle membrane proteins would alter the biochemical composition of fusion sites and hence the efficiency of subsequent fusion events. Distinct zones for endocytosis may permit continuous transmitter release to occur with only marginal loss of efficiency due to alterations in presynaptic plasma membrane. Thus, in our second model, dynamin hot spots correspond to the spatially distinct active zones for synaptic vesicle endocytosis that have not been revealed previously by molecular markers.
Note added in proof: A paper describing Drosophila synapsins has been published since this manuscript was submitted: Klagges BRE, Heimbeck G, Godenschwege TA, Hofbauer A, Pflugfelder GO, Reifegerste R, Reisch D, Schaupp M, Buchner S, Buchner E (1996) Invertebrate synapsins: a single gene codes for several isoforms in Drosophila.
FOOTNOTES
Received April 30, 1996; revised June 11, 1996; accepted June 12, 1996.
This work was funded by a National Science Foundation grant to M.R. and National Institutes of Health grants to A.v-d.B. and R.B.K. J.R. is a postdoctoral fellow supported by National Institutes of Health Training Grant T32-HD07397. M.R. is a Sloan Research Fellow and a McKnight Neuroscience Scholar. We thank Christos Consoulas from Richard Levine's lab for introducing us to the biocytin fill technique. We acknowledge Patty Jansma for patient assistance with electron microscopy and for her efficient management of the Arizona Research Labs (ARL) microscopy facility, Gina Zhang of the EM Core Facility at the University of Arizona's Department of Anatomy for thin sections, and Charles (Chip) Hedgcock, Registered Biological Photographer, for help with EM micrographs. Most of the microscopy was performed using a Bio-Rad 600 confocal microscope and a Jeol 200EX electron microscope belonging to the ARL Division of Neurobiology. We thank Troy Littleton and Hugo Bellen for anti-syt antibodies, Erich Buchner and Konrad Zinsmaier for anti-csp antibodies, and Seymour Benzer for the monoclonal antibody 22C10. This manuscript was improved substantially by comments from Sam Ward, Jane Robinson, Alison Adams, members of the Ramaswami lab, and an anonymous reviewer.
Correspondence should be addressed to Mani Ramaswami, Department of Molecular and Cellular Biology, Life Sciences South, University of Arizona, Tucson, AZ 85721.
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