Specialized Synapse-Associated Structures within the Calyx of Held

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The Journal of Neuroscience, December 15, 2000, 20(24):9135-9144

Specialized Synapse-Associated Structures within the Calyx of Held
Kevin C. Rowland¹^,³, Nancy K. Irby²^,³, and George A. Spirou¹^,²^,³
Departments of ¹ Physiology and ² Otolaryngology, and ³ Sensory Neuroscience Research Center, West Virginia University School of Medicine, Morgantown, West Virginia 26506-9200

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The calyx of Held exhibits fast glutamatergic neurotransmission at high rates with low temporal jitter and has adapted specializedsynaptic mechanisms to support its functional demands. We reportthe presence in calyces of an atypical arrangement of subcellularorganelles, called the mitochondria-associated adherens complex(MAC). We demonstrate that MACs are located adjacent to synapsesand contain membranous elements linked with coated and uncoatedvesicles. Mitochondria that form MACs have more complex geometriesthan other mitochondria within the calyx and can extend betweenclusters of synapses. We estimate that the calyx contains 1600MACs, 2400 synapses, and 6200 readily releasable vesicles. Wealso identify synaptic vesicle endocytotic regions close to MACsand synapses and hypothesize that calyces are composed of multipleactivity modules, each containing machinery for vesicle releaseandrecycling.

Key words: auditory brainstem; calyx of Held; mitochondria; punctum adherens; synapse; synaptic vesicle recycling

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The calyx of Held is one of the largest nerve terminals in the CNS (Held, 1893). Along with large and modified end-bulbs ofHeld delivered by auditory nerve fibers onto cochlear nucleusneurons (Cant and Morest, 1979; Tolbert and Morest, 1982; Feketeet al., 1984), these complex nerve terminals are key elementsin brainstem circuitry that subserves sound localization (Morest,1968). Spontaneous activity (generated in the absence of sound)can exceed 100 spikes/sec at the calyx terminal, and sound-drivenactivity at the most sensitive frequency of the calyceal neuroncan approach 600 spikes/sec (Spirou et al., 1990). Temporal synchronyof calyceal neurons to a preferred phase of a low-frequency soundexceeds that found in the auditory nerve, and it can entrain (fireon every cycle of the stimulus sinusoid) at rates approaching1 kHz (Joris et al., 1994a,b).

High activity rates place demands on endocytotic mechanisms to maintain a pool of releasable vesicles. Some neurons, suchas retinal bipolar cells, possess specialized structures calledsynaptic ribbons that are involved in vesicle trafficking, andtherefore have unique mechanisms to solve their demands for synapticactivity (von Gersdorff and Matthews, 1999). It is plausible thatthe calyceal terminal, because of its extremely high spike rateand the temporal precision required to accomplish its task ofsound localization, also uses unique structures andmechanisms.

A noteworthy arrangement of organelles, consisting of a mitochondrion located near the presynaptic membrane and tethered viafilaments to a punctum adherens, was first described in nerveterminals of the spinal cord (Gray, 1963). In the auditory system,this structure was noted in large and modified end-bulbs of auditorynerve fibers (Cant and Morest, 1979; Tolbert and Morest, 1982).More recently, we described this structure, which we named themitochondria-associated adherens complex (MAC), in large collateralterminals of calyceal axons that are found in the superior olivarycomplex (Spirou et al., 1998). Given the diversity of cellularelements that comprise the MAC, it could perform various functionsin the nerve terminal, including calcium buffering, supplyingenergy for synaptic vesicle fusion and recycling, processing recycledvesicle membrane, and cell adhesion. The presence of MACs in otherlarge terminals of the auditory brainstem prompted our investigationof their presence in calyceal terminals and a more detailed examinationof their structure and relationship to synapses. In this report,we reveal an intertwined spatial arrangement of MACs and synapticstructures and offer several hypotheses about possible functionsof the structural components of the MAC in synaptictransmission.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Five adult cats were used in this study. Three cats were processed for electron microscopy and two cats were processed forPEP-19 immunocytochemistry. All animals were deeply anesthetizedby an intramuscular injection of xylazine (2 mg/kg) and ketamine(10 mg/kg), followed by a pentobarbital injection (40 mg/kg, i.v.),before transcardial perfusion. The protocol used for PEP-19 immunocytochemistryis described elsewhere (Berrebi and Mugnaini, 1991; Spirou andBerrebi, 1996; Berrebi and Spirou, 1998) and is summarized brieflyhere.

Immunocytochemistry. Two animals were perfused transcardially with 0.9% saline solution, followed by 1 l of fixative (4% formaldehyde,0.5% zinc dichromate, 0.1% glutaraldehyde in 0.75% saline, pH4.8), then by 1 l of the same fixative with glutaraldehyde removed.Brains were dissected after 1 hr and immersed in 30% sucrose insaline for cryoprotection. After cryoprotection, frozen sectionstaken at 25-40 µm thickness were immersed in blocking and detergentsolution for 1 hr (5% normal donkey serum, 0.5% Triton X-100 in0.5 M Tris buffer). Sections were incubated in rabbit polyclonalantiserum to PEP-19 protein (diluted to 1:2000 in 1% normal donkeyserum and 0.1% Triton X-100), which was revealed by using thestandard Elite avidin-biotin peroxidase method (Vector Laboratories,Burlingame, CA) or the peroxidase/anti-peroxidase method (Sternberger,1979).

Electron microscopy. The animals used for electron microscopy were perfused transcardially with an initial calcium-free Ringer'ssolution followed by a mixture of 2% paraformaldehyde and 2.5%glutaraldehyde in 0.1 M phosphate buffer. The brainstem was cutinto 150 µm sections in the coronal plane, post-fixed with osmiumtetroxide (0.5%), and stained en bloc with aqueous uranyl acetate(2%), dehydrated, and flat-embedded in Epon. Tissue containingthe medial nucleus of the trapezoid body (MNTB), which is innervatedby calyces of Held, was re-embedded and trimmed for cutting ultrathinsections (60-70 nm). Sequential sections were collected and stainedwith 0.5% uranyl acetate and 3% lead citrate using an automaticgrid stainer (Leica, Nussloch,Germany).

Construction of en face diagrams. Individual calyces of Held were tracked in serial ultrathin sections and photographed byusing a Jeol 1010 electron microscope at 80 kV with magnificationsof 4,000-20,000×. To create en face diagrams, presynaptic membranesand mitochondria were traced from electron micrographs onto transparenciesand coded as either synaptic junctions or punctum adherens. Marksfor registration of serial sections were added to the tracingby visual determination of the best alignment of all mitochondriaon adjacent sections. Synapses were identified as clusters ofsynaptic vesicles directly associated with dense projections ofthe presynaptic membrane. Punctum adherens were identified bysymmetrically distributed membrane densities without associationof synaptic vesicles. Tracings of the coded presynaptic membranewere scanned into a computer and measured using NIH Image. Totalsurface areas of synaptic junctions and puncta adherentia werecalculated by summing their lengths on individual sections andby multiplying by the section thickness. En face diagrams werecreated by mapping the location of synapses and punctum adherensrelative to register marks (as measured in NIH Image) using graphingsoftware (Excel, Microsoft). The locations of the vesicular chainor mitochondrial plaque of each MAC were plotted on the en facediagram by placing a symbol over its corresponding punctum adherens.Distances from the edges of the vesicular chain or mitochondrialplaque to the nearest synapse were measured on the en face diagramby using NIH Image. Data are reported as mean ± SD unless indicatedotherwise.

Mitochondria morphology. To create three-dimensional models of mitochondria, electron micrographs were scanned and importedinto software for alignment of serial sections (Align, KristenHarris), and outlines of the mitochondria were marked using software(Trace, Kristen Harris; synapses.bu.edu). Virtual reality modelinglanguage files were created (Trace) and viewed with a three-dimensionalgraphics program (Amapi3D,TGS).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The calyx of Held is organized into distinct segments

The calyx of Held is a complex nerve terminal composed of numerous branches linked to swellings of various sizes that, incomposite, envelope the postsynaptic cell body. A camera lucidadrawing of a calyx and a photomicrograph through a single focalplane (Fig. 1A, inset) are shown in Figure 1A. Leading to thecalyx is a large axon, 5-10 µm diameter in cats, which at thebase of the terminal branches into two to four thick stalks (each3-5 µm diameter; labeled st in Fig. 1A,B) that extend along thepostsynaptic cell body surface to the opposite pole of the cell(Fig. 1B). These stalks usually terminate abruptly, but give risealong their distance to thin processes termed necks (Lenn andReese, 1966) (labeled n in Fig. 1A,E), which connect in seriesto large and small swellings (labeled sw in Fig. 1A,E). The neckshave varying lengths (2.83 ± 2.0 µm; n = 70) but a relativelyconsistent diameter of ~1 µm (0.99 ± 0.42 µm; n = 70).

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Figure 1. The calyx of Held is a large, complex nerve terminal that envelops the postsynaptic neuron and has multiple synaptic sites. A, Camera lucida and light micrograph (inset) of a calyx revealed by antibodies against the putative calcium binding protein PEP-19. The calyceal axon (ax) branches into four stalks (st, two of which are labeled), which themselves branch through narrow necks (n) of varying length into bulb-shaped swellings (sw) of various sizes. Black and stippled areas represent more superficial focal planes than light and dark gray areas. Scale bar, 5 µm. B, Electron micrograph of a stalk (st) portion of the calyx of Held that wraps halfway around the MNTB cell body (cb). Regions of close apposition between presynaptic and postsynaptic membrane alternate with regions of wide separation, called the EES (next to asterisks). The end of the stalk contacts a somatic appendage (sa). Boxed region is shown in D. Scale bar, 2 µm. C, Elements of the MAC: mitochondrion (m), mitochondrial plaque (mp, solid arrows), filaments (f), punctum adherens (pa, open arrows), and vesicular chain (vc, dotted arrows). Scale bar, 100 nm. D, Electron micrograph of the boxed outline in B reveals mitochondria surrounding a central core of neurofilaments (nf). Synapses (s) and MACs (M) are interspersed along the stalk and occupy most of the regions of apposition between presynaptic and postsynaptic membranes. Asterisk underlies the extended extracellular space. Scale bar, 250 nm. E, Electron micrograph of a neck (n) that connects two swellings (sw), the latter of which contains synapses (s). Scale bar, 1 µm.

Synaptic junctions are found in the calyceal stalks and swellings. Numerous zones containing synapses alternate along theentire length of the stalks with regions where the presynapticand postsynaptic membranes separate (Fig. 1B, asterisks; boxedarea amplified in D). Synaptic junctions are also formed withsomatic appendages (labeled sa in Fig. 1B) that extend away fromthe cell body along the sides and end of each stalk. Synapticjunctions are rarely found on the side of the stalk that facesaway from the postsynaptic cell body. That side of the stalk isusually apposed to glial processes and myelinated axons. The samearrangement of synapses is found in large and small swellings(data not shown). Necks are not in apposition to the postsynapticsurface, contain neurofilaments, are unmyelinated, and lack synapticjunctions (Fig. 1E).

Regions of apposition of the presynaptic and postsynaptic membranes contain not only synaptic junctions but also specializedorganelle assemblies that we have named the MAC (Fig. 1C) (Spirouet al., 1998). The key elements of this structure are a punctumadherens (pa), thought to attach the membranes of two cells, tetheredvia filaments (f) that extend ~180 nm (179 ± 12.7 nm; n = 26)away from the membrane to a dense plaque called the mitochondrialplaque (mp), which is oriented parallel to the membrane and subjacentto a mitochondrion. The mitochondrial surface is typically flattenedwhere it faces the mitochondrial plaque, and its cristae are orientedperpendicular to its flattened surface. Within the filaments arefound membranous structures that are tubular or vesicular in appearance,called the vesicular chain [vc, after Tolbert and Morest (1982)].MACs are common elements within the calyx, and in many individualultrathin sections are often located adjacent to synapses (Fig.1D). Their apparent proximity to synapses and associations withmembranous, often vesicular structures are suggestive of a rolefor MACs in synapticfunction.

The adjacency of mitochondria-associated adherens complexes and synapses is revealed by serial section electron microscopy

To determine the spatial association between MACs and synapses, serial ultrathin sections (60-70 nm) of the MNTB, where calycesof Held are located, were collected and processed for electronmicroscopy. Representative serial sections from a small swellingare pictured in Figure 2A-E. In A, a MAC (M1) with its mitochondrion(m1), mitochondrial plaque, vesicular chain (vc), filaments, andpunctum adherens is located at the left portion of the swelling.The vesicular chain of MAC-M1 (A-C) is composed of vesicular andtubular membranes. A synapse (B-E, s1) lies adjacent to MAC-M1.The dense projections of s1, thought to represent vesicle-dockingsites, are evident in Figure 2C-E. Mitochondrion m1 forms a secondMAC in the three sections after Figure 2E (data not shown). Theregion of cell membrane containing MAC-M1 and s1 at the left partof the swelling is isolated by a region of wide separation betweenthe presynaptic and postsynaptic membrane from another region,in the middle of the swelling, which contains another MAC (M2)and synapse (s2). These enlarged spaces have been noted in calycesof several species [rat, Lenn and Reese (1966); bat, Nakajima(1971), Petelina (1975); cat, Jean-Baptiste and Morest (1975),Casey and Feldman (1985)] and are called extended extracellularspaces (EESs) (Fig. 2, asterisks). MAC-M2 exhibits a more complexarrangement of vesicular and tubular membrane (Fig. 2B-D) thatmerges with a group of synaptic vesicles, some of which are associatedwith dense projections of s2 (Fig. 2C-E). The middle region ofthe swelling is separated by another EES from a third region ofmembrane apposition at the right of the swelling. This MAC (M3)also partly overlies its adjacent synapse (Fig. 2C-E, s3). Therefore,the spatial relationship between MACs and synapses is complexand is best revealed by mapping the location of MACs and synapseson the presynaptic membrane surface.

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Figure 2. Serial sections indicate that MACs are adjacent to synapses. These serial sections of a swelling in contact with an MNTB cell body (cb) reveal three regions of membrane apposition (left, middle, and right) separated by an EES (asterisks; rightmost EES is only marked in A). Three MACs (M1, A-C; M2, B; M3, C-E) and their associated mitochondria (m1, m2, and m3 in A; m3 labeled again in C) and vesicular chain (vc) are adjacent to synapses (s1, s2, and s3). Large coated vesicles are budding from the side of the terminal facing away from the MNTB cell and postsynaptically from the extended extracellular space (C, D, solid arrows). Bumps in the presynaptic membrane (E, open arrows) at the synapse could indicate vesicle fusion or retrieval sites. A coated vesicle (E, solid arrow) is located adjacent to the presynaptic membrane. Scale bar (shown in E for A-E): 200 nm.

Maps indicating the location of MACs and synapses were made in the swelling and stalk compartments of the calyx (Fig. 3A,B).Densities of the presynaptic and postsynaptic membrane, when viewedusing magnification of at least 4000×, could be classified assynapse or punctum adherens regions of MACs. Electron micrographswere scanned into a computer and aligned, and the membrane areasoccupied by synapses and MACs were coded in dark gray and black,respectively. The membrane of the nerve terminal that did notface the postsynaptic cell was not included in the analysis, andthe remaining membrane was unfolded into a flat sheet. The resultingen face maps revealed that MACs and synapses formed clusters thatwere separated by large distances. Inspection of the compositeelectron micrographs revealed that non-MAC or synapse-containingmembrane (coded in light gray) was primarily occupied by the EES.In the en face map of the swelling shown in Figure 3A, the clusterswere composed of MACs forming a core surrounded by synapses, exceptat the periphery of the swelling where synapses were found withoutassociated MACs. Inspection of the composite micrographs revealedthat these were regions along the side of the swellings that facedsomatic appendages of the MNTB cell. An intertwined arrangementof MACs and synapses was also found in stalks (Fig. 3B). Here,MACs were interspersed with synapses and found in regions thatapposed somatic appendages (Fig. 3B, right side).

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Figure 3. The interdigitated spatial relationship of synapses and MACs is revealed in en face views of the flattened presynaptic membrane. Lengths of membrane that contain synapses are coded dark gray, and punctum adherens components of MACs are coded black. Other regions of membrane, primarily composed of extended extracellular space, are coded light gray. Small white circles represent the vesicular chain and mitochondrial plaque components of MACs. A, En face diagram through one swelling portion of a calyx (77 serial sections). B, En face diagram through one stalk portion of a calyx (36 serial sections). C, The shortest distance from the mitochondrial plaque or vesicular chain components of MACs to synapses averaged 202 ± 94.9 nm (arrow). D, The shortest distance from synapses to the nearest MAC often could exceed 500 nm, reflecting a category of synapses that are not located near MACs (as shown in A).

The adjacency of MACs and synapses was quantified by measuring the distance, on the en face diagram, from the vesicular chainor mitochondrial plaque portion of the MAC (Fig. 3A,B, small whitecircles) to the nearest synapse. The mean distance from thesecomponents of the MAC to the edge of the nearest synapse was 202± 94.9 nm, or approximately five synaptic vesicle diameters (Fig.3C). However, the distance from some synapses to the nearest MACcould approach 1 µm (Fig. 3D), consistent with the absence ofMACs in some regions of membrane apposition (Fig. 3A). These distanceswere measured from five series of sections taken from four calycesin two animals, each having a composite thickness of 1.3-4.8 µm.The same spatial relationship between MACs and synapses was alsoevident in another five reconstructions, taken from five calyces(four of which are from a third animal), each having a compositethickness of at least 0.5 µm.

Construction of en face diagrams from serial sections affords the opportunity to estimate the number of synapses and MACsin each calyx of Held. In each en face diagram, individual synapsesand puncta adherentia were outlined, and their surface area wascalculated by summing the lengths measured from the micrographsand then multiplying by the section thickness. The average sizesfor each en face diagram are reported in Table 1. Overall, synapticjunction surface area averaged 70,079 nm² and occupied 11.6% of the presynaptic membrane surface, whereasMACs surface area averaged 54,622 nm² and occupied 5.8% of the presynaptic membrane surface. The postsynapticMNTB cell body is nearly spherical in shape and ~35 µm in diameter.Using published measurements that the calyx covers on average38% of the postsynaptic cell body in cats [our calculation fromSmith et al. (1991, 1998)], we estimate that the calyx of Heldcontains ~2400 synaptic junctions and 1600 MACs. The number ofsynapses is larger than that estimated for large synaptic end-bulbterminals in the ventral cochlear nucleus (Ryugo et al., 1996).


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Table 1. Presynaptic membrane specializations in the calyx of Held

Vesicular and tubular membrane structures in the nerve terminal

Arrangements of membrane within the MAC can take the form of two to four linked vesicular structures or, more commonly, ofcombinations of tubular and vesicular membrane that can extendalong the sides of the mitochondrion away from the cell membrane(Fig. 4F, dotted arrow). The tubular networks are curved and branched,have a twisted appearance, and appear to be fused or in the processof budding round vesicles that are the size of synaptic vesicles(Fig. 4B,E,F, arrowheads). Some membranous structures are non-round,with profiles that are approximately the size of synaptic vesicles(vesicular chain of M1 in Figs. 2A and 4E).

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Figure 4. Coated and noncoated vesicles appear fused with the vesicular chain component of the MAC. A, A mitochondrion forms a MAC (M) adjacent to a synapse (s). The vesicular chain (vc) leads into a branched tubular network adjacent to the mitochondrion, to which coated vesicles (solid arrows) appear fused. A coated vesicle at the synapse (open arrow) appears to be in the process of endocytosis. B, Two mitochondria form side-by-side MACs (M); the edge of a synapse (s) is adjacent to one of the MACs. The vesicular chain forms a tubular or flattened structure to which vesicles appear fused (arrowheads). C, Coated vesicles (solid arrows) are located next to the vesicular chain and just inside the presynaptic membrane. D, A coated pit (open arrow) is located at the end of a membrane invagination, at the edge of the EES (asterisk is within glial process inside the EES), and near a MAC. E, F, Noncoated vesicles (arrowheads) appear fused to the vesicular chain, which appears flattened in E and tubular, bending along the side of the mitochondrion (dotted arrow), in F. A coated vesicle (open arrow) appears to be in the final stage of budding from the presynaptic membrane. Scale bar (shown in F for A-F): 250 nm.

Coated vesicles in the nerve terminal, presumably recaptured from the presynaptic membrane, are the same size as synapticvesicles and can be found in proximity to and fused to tubularnetworks associated with MACs (Figs. 2E, 4A,C, solid arrows).Coated vesicles appear to emerge from synaptic zones or adjacentareas of presynaptic membrane (Fig. 4A,F, open arrows). Synapticzones also contain structures that could represent vesicle fusionsites or the early stages of vesicle reuptake (Fig. 2E, open arrowsat s2). The EES appears to be a common site of membrane recycling(Figs. 2C, 4D, open arrows), as originally observed using scanning(freeze-fracture) and transmission electron microscopy (Heuserand Reese, 1973; Gulley et al., 1978). All areas of the presynapticnerve terminal membrane seem capable of endocytotic events, sowe measured the prevalence of coated pits, presumably representingendocytosing vesicles, in different regions of the presynapticmembrane. Most coated pits were found immediately adjacent tothe synapse (27%) or at the edge of the EES (42%). Large endocytoticcoated pits and vesicles are often located post-synaptic to theEES or associated with membrane that faces away from the MNTBcell and are probably not involved in synaptic vesicle recycling(Fig. 2C, solid arrows). On the basis of the presence of MAC andsynapse-containing regions of membrane apposition, flanked byEES and endocytotic profiles, we propose that the calyx is composedof numerous activity modules, each with a self-contained systemof vesiclerecycling.

Are there subpopulations of mitochondria in the calyx of Held?

Mitochondria that form MACs have structural specializations in the precise orientation of their cristae and flattened edgewhere they abut the mitochondrial plaque. The branched and curvingappearance of mitochondria in individual electron micrographs(Fig. 2, m3) was suggestive that MAC-forming mitochondria weremore complex structurally than other mitochondria in the nerveterminal. To investigate this hypothesis, mitochondria were reconstructedacross serial sections, and their complexity was determined bycounting the number of tips, or ends, of processes. For example,the electron micrograph in Figure 5A reveals what appear to befour presynaptic mitochondria. In the next two sections in theseries (Fig. 5B,C), three of the profiles (labeled m in Fig. 5A)merge into a single mitochondrion. Three-dimensional reconstructionof this mitochondrion (Fig. 5D,E) reveals the three limbs seenin the serial sections (labeled m). The mitochondrion has fourtips and forms two MACs (punctum adherens, green; mitochondrialplaque, orange) that are adjacent to synapses (red). The analysisof geometric complexity revealed distinct populations of mitochondriain the calyx. Most mitochondria did not form MACs and had twoends and were therefore vermiform in shape, although they mayhave a bend or curve along their length (Table 2). Mitochondriathat formed MACs had a greater tendency to be complex (p < 0.001;Fisher's Exact Test), could form MACs along more than one process,and often had a process that extended away from the membrane intothe core of the stalk or swelling (Fig. 2, m3; Fig. 5F,G, toplimb of mitochondrion). Location of a mitochondrion within 200nm of the presynaptic membrane, in a region of presynaptic andpostsynaptic membrane apposition, was a strong predictor thatit formed a MAC.

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Figure 5. Mitochondria can form more than one MAC and have complex geometry. A-C, Three limbs of a single, MAC-forming mitochondrion (m). One MAC (M) and its adjacent synapse (s) are pictured. Asterisks indicate EES. Scale bar, 250 nm. D, E, Orthogonal views of a three-dimensional reconstruction of the complex mitochondrion pictured in A-C. The mitochondrion (blue), mitochondrial plaques (orange bars), puncta adherentia (green), and synapses (red) are depicted. F, G, Three-dimensional reconstruction of a second complex mitochondrion (end and side views) with its associated MAC and synaptic structures. The two long limbs of this mitochondrion extend >1 µm in length.


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Table 2. Structural complexity of mitochondria

Structural correlates of vesicle release probability

The multitude of synapses in a single calyx and the requirement for the calyx to transmit high rates of activity to the MNTBcell may dictate that not all synapses release a vesicle witheach invading action potential. MAC-associated synapses may havegreater capacity to sustain vesicle release during the later stagesof a spike train. The number of synaptic vesicles that are inposition to be released is thought to be the structural equivalentof the readily releasable pool (von Gersdorff et al., 1996; Schikorskiand Stevens, 1997). We counted in serial sections the number ofsynaptic vesicles that were docked in calyceal synapses to determinewhether MAC-associated synapses have a greater number of dockedvesicles. Synaptic vesicles were classified as docked if therewas no resolvable distance between their membrane and the presynapticmembrane or dense projections of the synaptic junction (Fig. 6A).There was no difference in the mean number of docked synapticvesicles in MAC-associated synapses (2.6 ± 1.71) from those synapticjunctions positioned farther (>500 nm) from the MAC (2.6 ± 1.5),and therefore their distributions are combined (Fig. 6B). Thelow-calcium transcardial rinse that we used may have stopped vesiclefusion before fixation, but perhaps permitted reloading of vesicledocking sites in both MAC-associated and MAC-independent synapses.Using the estimate that each action potential evokes release of0.2 of the readily releasable synaptic vesicle pool (Schneggenburgeret al., 1999), we suggest that synapses having three or more dockedvesicles are most likely to release a quantum of neurotransmitterupon depolarization (Fig. 6B, rightmost portion of distribution).Multiplying our distribution of the docked vesicles per synapseby our estimate of the number of synaptic junctions in the calyx,we calculate that the calyx contains 6200 readily releasable synapticvesicles. Although the number of docked vesicles per synapse isa factor of 5-7 lower in the calyx than in hippocampal boutons(Harris and Sultan, 1995; Schikorski and Stevens, 1997), the greatmajority of hippocampal boutons contain only one active site.The large number of synapses in the calyx terminal may provideenough of a safety net that limits the rate at which individualsynapses need to refill their docking sites, especially if thereleased fraction of vesicles declines during a spike train. Investigationof the effects of stimulus history on vesicle priming will requiredevelopment of an in vitro preparation with appropriate ultrastructurepreservation that permits counting of docked vesicles.

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Figure 6. Synapses vary in the number of docked vesicles. A, Two synaptic vesicles (arrows) are docked at the presynaptic membrane, alongside hypothesized docking structures called dense projections (dp). B, Distribution of the number of docked vesicles found in individual synapses. Mean number of docked vesicles is 2.53 ± 1.61; n = 56.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Our fundamental finding is that the MAC is intertwined with synapses and is found in the prototypical fast, glutamatergicnerve terminal, the calyx of Held. Because of its proximity tosynapses and the component organelles from which it is constructed,we hypothesize that the MAC plays a central role in high rate,temporally precise neurotransmission that is a hallmark of thecalyx terminal (Guinan and Li, 1990). The presence of coated,presumably endocytosing, vesicles adjacent to fusion sites andin locations encircling MAC/synapse clusters suggests that thecalyx is composed of multiple activity zones, each being an enginefor releasing and recharging its vesicle store. Increasingly,evidence points to a central role for mitochondria in regulatingexocytosis on a fast time scale (Kaftan et al., 2000) (see below).The MAC is the most highly ordered structural arrangement of whichwe are aware, linking mitochondria to synaptic junctions, andit may play an integral role in synaptic transmission in thecalyx.

Auditory brainstem circuits

The presence of MACs in end-bulbs and modified end-bulbs of Held in the cochlear nucleus (Cant and Morest, 1979; Tolbert andMorest, 1982), in large collateral terminals of calyceal axonsin the superior olive (Spirou et al., 1998), and in calyces ofHeld implies their importance in neural circuits that subservethe early stages of sound localization (Fig. 7A). MAC-containingend-bulbs activate spherical bushy cells (Cant and Morest, 1979),which excite binaural cells of the medial superior olive (MSO)bilaterally and lateral superior olive ipsilaterally. MAC-containingmodified end-bulbs activate globular bushy cells (Tolbert andMorest, 1982), which in turn excite ipsilateral cells of the lateralnucleus of the trapezoid body (LNTB) via MAC-containing modifiedend-bulbs (Spirou et al., 1998) and contralateral cells of theMNTB via calyces (now shown to also contain MACs). LNTB cellsprovide inhibitory input to the MSO (our unpublished data), andMNTB cells inhibit cells of the MSO and LSO (Moore and Caspary,1983; Smith, 1995). Therefore, MAC-containing terminals driveboth excitatory and inhibitory inputs to binaural comparator neurons.

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Figure 7. Auditory brainstem circuitry. A, Auditory nerve (AN) fibers end in large, MAC-containing nerve terminals (*) onto spherical (SBC) and globular (GBC) bushy cells of the cochlear nucleus. GBCs project ipsilaterally, via MAC-containing modified end-bulbs (*), to cells of the posteroventral lateral nucleus of the trapezoid body (pvLNTB) and contralaterally, via MAC-containing calyces (*), to cells of the medial nucleus of the trapezoid body (MNTB). Cells of the medial superior olive (MSO) and lateral superior olive (LSO) compare bilateral excitatory (from spherical bushy cells) and inhibitory (from LNTB and MNTB cells) inputs to assign a location to a sound source in space. B, Hypothesized functions of the MAC [M; composed of a mitochondrial plaque (mp), vesicular chain (vc), filaments (f), punctum adherens (pa), and a mitochondrion]. MNTB postsynaptic cell is at bottom; EES, extended extracellular space. Hypotheses: #1, The vesicular chain is a reservoir for newly formed synaptic vesicles. #2, The close proximity of mitochondria to the presynaptic membrane allows for calcium buffering at synapses. #3, Calcium (Ca) is shuttled through the mitochondrion to other active zones of the terminal. #4, Orientation of cristae facilitates calcium diffusion. #5, Mitochondria support neurosecretion by manufacture of glutamate (Glut) neurotransmitter and refilling synaptic vesicles. #6, Stabilization of the presynaptic membrane during high rates of activity is achieved by the punctum adherens. #7, Puncta adherentia determine tonotopic innervation of the MNTB during development.

MACs are also present in rat calyces of Held (our unpublished data) [also see Casey and Feldman (1985), their Figs. 5, 8,19, 20, 22, although the presence of MACs was not noted by theseauthors], but their prominence and association with synapses hasnot been determined. MACs have been described in terminals ofsome olivo-cochlear fibers that project from cells of the superiorolive onto cell bodies of spiral ganglion neurons [monkeys: Kimuraet al. (1987; humans: Rask-Andersen et al. (2000)]. It is notknown whether these olivo-cochlear neurons generate high ratesof temporally synchronous activity, in common with other MAC-containingauditory system neurons. The only other report of MACs of whichwe are aware is by Gray (1963) in his original description ofthis structure in the spinal cord. The cell type giving rise tonerve terminals containing MACs was not determined, nor have wefound subsequent descriptions of this structure in more recentstudies of the spinal cord. Structures bearing similarity to MACs,called filamentous contacts, have been described in thalamic relaynuclei (Colonnier and Guillery, 1964; Lieberman and Spacek, 1997).However, filamentous contacts are segregated from most synapsesin the terminal. They do exhibit a vesicular chain-like membrane(called agranular reticulum) located between mitochondria andthe presynaptic punctum adherens. The mitochondrial cristae areless strictly oriented than in the MAC and occasionally filamentsextend from the reticular membrane to the punctum adherens, butthere is no mitochondrial plaque. Filamentous contacts featurea similar network of punctum adherens, filaments, and reticulumin the postsynaptic cell, incorporate tight junctions, and arealso found at dendrodendritic and somasomatic junctions. Theymost likely play roles in intercellular communication that aredistinct fromMACs.

Vesicle recycling and the readily releasable pool

The vesicular chain component of MACs and synapses points to roles in vesicle membrane recycling. Generally two modes of vesiclerecycling are thought to occur at nerve terminals: full fusionof vesicles with the presynaptic membrane followed by clathrin-mediatedendocytosis (Heuser and Reese, 1973) and partial fusion of vesiclemembrane followed by rapid, clathrin-independent disassociationfrom the presynaptic membrane (also known as "kiss-and-run") (Ceccarelliet al., 1973; for review, see von Gersdorff and Matthews, 1999).Clathrin-coated endocytotic vesicles may fuse with endosomal intermediatesthat bud new synaptic vesicles, but recent evidence indicatesthat fusion with endosomes may not be part of the life cycle ofthe vesicle (Murthy and Stevens, 1998), even in the case of clathrin-coatedvesicles (Takei et al., 1996). Coated vesicles are a common featurein calyx terminals and bud from synaptic zones, but more frequentlyfrom edges of the EES that form a border around MAC-synapse clusters.Coated vesicles are frequently located near and sometimes appearfused with the vesicular chain component of the MAC, so recyclingthrough endosomal intermediates may support replenishment of vesiclestores in the calyx of Held. Therefore in the calyx the distinctionbetween recycling and reserve (to sustain high activity rates)vesicle pools may be blurred (Kuromi and Kidokoro, 1999). Kiss-and-runmay also be at play in calyx terminals but cannot be resolvedwith certainty using electronmicroscopy.

The calyx, like many other central synapses, exhibits frequency-dependent synaptic depression that is caused mainly by depletionof the readily releasable pool of synaptic vesicles (Borst etal., 1995; von Gersdorff and Matthews, 1997; Wang and Kaczmarek,1998). In rats, the readily releasable pool size in the calyxwas estimated to be 700 vesicles (Schneggenburger et al., 1999).Using docked vesicles as a morphological indicator, we estimatethat 6200 vesicles constitute the readily releasable pool in calyces,which may reflect the larger size of calyces in cats than inrats.

Hypothesized functions of the MAC

The conglomerate elements of the MAC result in a structure that, because of its uniqueness, is somewhat enigmatic in nature.In this section we offer several hypotheses (schematized in Fig.7B) about the function of several MAC components and characteristicsas a framework for investigating MAC functions in large auditorysystem nerveterminals.

Vesicular chain
Recovery from synaptic depression of postsynaptic current amplitude is more rapid at high rates of stimulation at calycealand hippocampal synapses (Stevens and Wesseling, 1998; Wang andKaczmarek, 1998). Despite the reduced amplitude of postsynapticcurrents, postsynaptic action potentials are reliably generatedin brain slices at stimulus rates exceeding 500 Hz (Wu and Kelly,1993). We hypothesize (Fig. 7B, #1) that vesicular chain membraneprovides a reservoir for rapid formation of new vesicles underconditions of sustained, high rates ofactivity.

Mitochondrion, mitochondrial plaque, and filaments: a system to regulate calcium levels
In the calyx, multiple calcium channels open to induce the release of single quanta, so the calcium load on the terminal canbe very high (Borst and Sakmann, 1999a). Accumulating evidenceindicates that mitochondria in nerve terminals, especially thosenearest the synapse, increase their calcium conductance and sequestercalcium during a train of impulses (David et al., 1998; Jonaset al., 1999; Pivovarova et al., 1999; Zenisek and Matthews, 2000).Activity-dependent changes in presynaptic calcium concentrationcan reach 5-10 µM at 200 nm from the synapse (Neher, 1998) andare likely detected by the mitochondrial component of the MAC,tethered at about that distance. Indeed, immediately after tetanicpulse trains, recovery from depression in the calyx is independentof membrane calcium currents (Forsythe et al., 1998) and may becaused in part by calcium re-release from MAC components. We hypothesize(Fig. 7B, #2) that the mitochondrial (and perhaps vesicular chain)components of the MAC are positioned precisely by the mitochondrialplaque and filaments to cooperate with other calcium-bufferingentities in the terminal. Proper calcium buffering will affectfacilitation or depression of vesicle release during successiveaction potentials (Forsythe et al., 1998; Bellingham and Walmsley,1999; Borst and Sakmann, 1999b; Wu and Borst, 1999).

Mitochondrial geometry and cristae: an intracellular conduit for calcium movement
Mitochondria most likely participate with endosomal structures, such as endoplasmic reticulum, in an elaborate calcium-bufferingnetwork that can shuttle calcium signals through the cytoplasmwithin organelles (Babcock et al., 1997; Rizzuto et al., 1998).We hypothesize (Fig. 7B, #3) that the complex geometry of manyMAC-associated mitochondria, perhaps together with the vesicularchain, may subserve this function, shuttling calcium from oneactivity module across the EES to another activity module andthereby affecting release probability at synapses several micrometersaway. Furthermore, we propose (Fig. 7B, #4) that the cristae ofMAC-associated mitochondria are oriented perpendicular to themembrane to facilitate diffusion away from the synaptic regionto other ends of the mitochondrion. Cristae of neuronal mitochondriacan form lamellar, rather than tubular, structures (Perkins etal., 1997) that should have high capacity for calciumdiffusion.

Mitochondrial biochemistry: possible source of energy and neurotransmitter
Tethering mitochondria near synaptic structures may link the upregulation of Krebs' cycle enzymatic activity by calcium toincreased ATP production (Denton and McCormack, 1980) to supportsynaptic mechanisms activated by neural activity. Also, mitochondriacan manufacture glutamate from $alpha$ -ketoglutarate, which in pancreashas a direct effect on insulin secretion (Maechler and Wollheim,1999). We hypothesize (Fig. 7B, #5) that MAC-associated mitochondriamay manufacture glutamate for use as a neurotransmitter, whichis then used to refill recycled synaptic vesicles (Maycox et al.,1988).

Punctum adherens: synaptic stabilization and development
We have hypothesized previously (Fig. 7B, #6) that the punctum adherens component of the MAC provides needed stability tothe calyx-MNTB neuron contact to sustain high rates of neuralactivity and high-capacity membrane recycling (Spirou et al.,1998). The punctum adherens component of the MAC may play an additionalrole during early formation of the synapse. The cadherin proteinfamily may be sufficiently diverse (Kohmura et al., 1998; Brose,1999; Serafini, 1999) to underlie the tonotopic pattern by whichcalyceal growth cones innervate the appropriate MNTB cells topreserve this fundamental organizing principle of auditory neuralcircuits (Fig. 7B, #7). A similar role in forming retinotopicconnections was proposed for filamentous contacts (Colonnier andGuillery, 1964). The development of suitable experimental preparationsand probes will form the basis for investigating these and otherhypotheses about functions of this atypical organelleassembly.

  FOOTNOTES

Received Aug. 2, 2000; revised Oct. 6, 2000; accepted Oct. 9, 2000.

This work was supported by National Science Foundation Grant IBN 9728933. We thank Albert Berrebi for expertise in PEP-19immunocytochemistry, Brian Pope and Marcia Feinberg for technicalassistance, and Erika Hartweig for training in the collectionof serial sections. We thank members of the Sensory NeuroscienceResearch Center, William Wonderlin, and Philip Smith for criticalreview of this manuscript, Peter Mathers for insightful discussionsof data, and George Augustine for reading an earlier version ofthispaper.
Correspondence should be addressed to Dr. George A. Spirou, Box 9200, Department of Otolaryngology, West Virginia UniversitySchool of Medicine, Morgantown, WV 26506-9200. E-mail: gspirou{at}wvu.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Babcock DF, Herrington J, Goodwin PC, Park YB, Hille B (1997) Mitochondrial participation in the intracellular Ca²⁺ network. J Cell Biol 136:833-844[Abstract/Free Full Text].
Bellingham MC, Walmsley B (1999) A novel presynaptic inhibitory mechanism underlies paired pulse depression at a fast central synapse. Neuron 23:159-170[ISI][Medline].
Berrebi AS, Mugnaini E (1991) Distribution and targets of the cartwheel cell axon in the dorsal cochlear nucleus of the guinea pig. Anat Embryol 183:427-454[Medline].
Berrebi AS, Spirou GA (1998) PEP-19 immunoreactivity in the cochlear nucleus and superior olive of the cat. Neuroscience 83:535-554[ISI][Medline].
Borst JG, Sakmann B (1999a) Depletion of calcium in the synaptic cleft of a calyx-type synapse in the rat brainstem. J Physiol (Lond) 521:123-133[Abstract/Free Full Text].
Borst JG, Sakmann B (1999b) Effect of changes in action potential shape on calcium currents and transmitter release in a calyx-type synapse of the rat auditory brainstem. Philos Trans R Soc Lond B Biol Sci 354:347-355[ISI][Medline].
Borst JG, Helmchen F, Sakmann B (1995) Pre- and postsynaptic whole-cell recordings in the medial nucleus of the trapezoid body of the rat. J Physiol (Lond) 489:825-840[Abstract/Free Full Text].
Brose N (1999) Synaptic cell adhesion proteins and synaptogenesis in the mammalian central nervous system. Naturwissenschaften 86:516-524[ISI][Medline].
Cant NB, Morest DK (1979) The bushy cells in the anteroventral cochlear nucleus of the cat. A study with the electron microscope. Neuroscience 4:1925-1945[ISI][Medline].
Casey MA, Feldman ML (1985) Aging in the rat medial nucleus of the trapezoid body. II. Electron microscopy. J Comp Neurol 232:401-413[ISI][Medline].
Ceccarelli B, Hurlbut WP, Mauro A (1973) Turnover of transmitter and synaptic vesicles at the frog neuromuscular junction. J Cell Biol 57:499-524[Abstract/Free Full Text].
Colonnier M, Guillery RW (1964) Synaptic organization in the lateral geniculate nucleus of the monkey. Z Zellforsch Mikrosk Anat 62:333-355.
David G, Barrett JN, Barrett EF (1998) Evidence that mitochondria buffer physiological Ca²⁺ loads in lizard motor nerve terminals. J Physiol (Lond) 509:59-65[Abstract/Free Full Text].
Denton RM, McCormack JG (1980) The role of calcium in the regulation of mitochondrial metabolism. Biochem Soc Trans 8:266-268[Medline].
Fekete DM, Rouiller EM, Liberman MC, Ryugo DK (1984) The central projections of intracellularly labeled auditory nerve fibers in cats. J Comp Neurol 229:432-450[ISI][Medline].
Forsythe ID, Tsujimoto T, Barnes-Davies M, Cuttle MF, Takahashi T (1998) Inactivation of presynaptic calcium current contributes to synaptic depression at a fast central synapse. Neuron 20:797-807[ISI][Medline].
Gray EG (1963) Electron microscopy of presynaptic organelles of the spinal cord. J Anat Lond 97:101-106.
Guinan Jr JJ, Li RY (1990) Signal processing in brainstem auditory neurons which receive giant endings (calyces of Held) in the medial nucleus of the trapezoid body of the cat. Hear Res 49:321-334[ISI][Medline].
Gulley RL, Landis DMD, Reese TS (1978) Internal organization of membranes at end bulbs of Held in the anteroventral cochlear nucleus. J Comp Neurol 180:707-741[ISI][Medline].
Harris KM, Sultan P (1995) Variation in the number, location and size of synaptic vesicles provides an anatomical basis for the nonuniform probability of release at hippocampal CA1 synapses. Neuropharmacology 34:1387-1395[ISI][Medline].
Held H (1893) Die centrale Gehorleitung. Archiv für Anatomie und Physiologie. Anat Abt 201-248.
Heuser JE, Reese TS (1973) Evidence for recycling of synaptic vesicle membrane during transmitter release at the frog neuromuscular junction. J Cell Biol 57:315-344[Abstract/Free Full Text].
Jean-Baptiste M, Morest DK (1975) Transneuronal changes of synaptic endings and nuclear chromatin in the trapezoid body following cochlear ablations in cats. J Comp Neurol 162:111-134.
Jonas EA, Buchanan J, Kaczmarek LK (1999) Prolonged activation of mitochondrial conductances during synaptic transmission. Science 286:1347-1350[Abstract/Free Full Text].
Joris PX, Carney LH, Smith PH, Yin TC (1994a) Enhancement of neural synchronization in the anteroventral cochlear nucleus. I. Responses to tones at the characteristic frequency. J Neurophysiol 71:1022-1036[Abstract/Free Full Text].
Joris PX, Smith PH, Yin TC (1994b) Enhancement of neural synchronization in the anteroventral cochlear nucleus. II. Responses in the tuning curve tail. J Neurophysiol 71:1037-1051[Abstract/Free Full Text].
Kaftan EJ, Xu T, Abercrombie RF, Hille B (2000) Mitochondria shape hormonally-induced cytoplasmic calcium oscillations and modulate exocytosis. J Biol Chem 275:25465-25470[Abstract/Free Full Text].
Kimura RS, Bongiorno CL, Iverson NA (1987) Synapses and ephapses in the spiral ganglion. Acta Otolaryngol [Suppl] 438:1-18[Medline].
Kohmura N, Senzaki K, Hamada S, Kai N, Yasuda R, Watanabe M, Ishii H, Yasuda M, Mishina M, Yagi T (1998) Diversity revealed by a novel family of cadherins expressed in neurons at a synaptic complex. Neuron 20:1137-1151[ISI][Medline].
Kuromi H, Kidokoro Y (1999) The optically determined size of exo/endo cycling vesicle pool correlates with the quantal content at the neuromuscular junction of Drosophila larvae. J Neurosci 19:1557-1565[Abstract/Free Full Text].
Lenn NJ, Reese TS (1966) The fine structure of nerve endings in the nucleus of the trapezoid body and the ventral cochlear nucleus. Am J Anat 118:375-389[ISI][Medline].
Lieberman AR, Spacek J (1997) Filamentous contacts: the ultrastructure and three-dimensional organization of specialized non-synaptic interneuronal appositions in thalamic relay nuclei. Cell Tissue Res 288:43-57[ISI][Medline].
Maechler P, Wollheim CB (1999) Mitochondrial glutamate acts as a messenger in glucose-induced insulin exocytosis. Nature 402:685-689[Medline].
Maycox PR, Deckwerth T, Hell JW, Jahn R (1988) Glutamate uptake by brain synaptic vesicles. Energy dependence of transport and functional reconstitution in proteoliposomes. J Biol Chem 263:15423-15428[Abstract/Free Full Text].
Moore MJ, Caspary DM (1983) Strychnine blocks binaural inhibition in lateral superior olivary neurons. J Neurosci 3:237-242[Abstract].
Morest DK (1968) The collateral system of the medial nucleus of the trapezoid body of the cat, its neuronal architecture and relation to the olivo-cochlear bundle. Brain Res 9:288-311[Medline].
Murthy VN, Stevens CF (1998) Synaptic vesicles retain their identity through the endocytic cycle. Nature 392:497-501[Medline].
Nakajima Y (1971) Fine structure of the medial nucleus of the trapezoid body of the bat with special reference to two types of synaptic endings. J Cell Biol 50:121-134[Abstract/Free Full Text].
Neher E (1998) Vesicle pools and Ca²⁺ microdomains: new tools for understanding their roles in neurotransmitter release. Neuron 20:389-399[ISI][Medline].
Perkins G, Renken C, Martone ME, Young SJ, Ellisman M, Frey T (1997) Electron tomography of neuronal mitochondria: three-dimensional structure and organization of cristae and membrane contacts. J Struct Biol 119:260-272[ISI][Medline].
Petelina EV (1975) Ultrastructure of synapses in the nucleus of the trapezoid body of the bat. Arkh Anat Gistol Embriol 68:14-18[Medline].
Pivovarova NB, Hongpaisan J, Andrews SB, Friel DD (1999) Depolarization-induced mitochondrial Ca accumulation in sympathetic neurons: spatial and temporal characteristics. J Neurosci 19:6372-6384[Abstract/Free Full Text].
Rask-Andersen H, Tylstedt S, Kinnefors A, Illing R (2000) Synapses on human spiral ganglion cells: a transmission electron microscopy and immunohistochemical study. Hear Res 141:1-11[ISI][Medline].
Rizzuto R, Pinton P, Carrington W, Fay FS, Fogarty KE, Lifshitz LM, Tuft RA, Pozzan T (1998) Close contacts with the endoplasmic reticulum as determinants of mitochondrial Ca²⁺ responses. Science 280:1763-1766[Abstract/Free Full Text].
Ryugo DK, Wu MM, Pongstaporn T (1996) Activity-related features of synapse morphology: a study of endbulbs of Held. J Comp Neurol 365:141-158[ISI][Medline].
Schikorski T, Stevens CF (1997) Quantitative ultrastructural analysis of hippocampal excitatory synapses. J Neurosci 17:5858-5867[Abstract/Free Full Text].
Schneggenburger R, Meyer AC, Neher E (1999) Released fraction and total size of a pool of immediately available transmitter quanta at a calyx synapse. Neuron 23:399-409[ISI][Medline].
Serafini T (1999) Finding a partner in a crowd: neuronal diversity and synaptogenesis. Cell 98:133-136[ISI][Medline].
Smith PH (1995) Structural and functional differences distinguish principal from nonprincipal cells in the guinea pig MSO slice. J Neurophysiol 73:1653-1667[Abstract/Free Full Text].
Smith PH, Joris PX, Carney LH, Yin TC (1991) Projections of physiologically characterized globular bushy cell axons from the cochlear nucleus of the cat. J Comp Neurol 304:387-407[ISI][Medline].
Smith PH, Joris PX, Yin TC (1998) Anatomy and physiology of principal cells of the medial nucleus of the trapezoid body (MNTB) of the cat. J Neurophysiol 79:3127-3142[Abstract/Free Full Text].
Spirou GA, Berrebi AS (1996) Organization of ventrolateral periolivary cells of the cat superior olive as revealed by PEP-19 immunocytochemistry and Nissl stain. J Comp Neurol 368:100-120[ISI][Medline].
Spirou GA, Brownell WE, Zidanic M (1990) Recordings from cat trapezoid body and HRP labeling of globular bushy cell axons. J Neurophysiol 63:1169-1190[Abstract/Free Full Text].
Spirou GA, Rowland KC, Berrebi AS (1998) Ultrastructure of neurons and large synaptic terminals in the lateral nucleus of the trapezoid body of the cat. J Comp Neurol 398:257-272[ISI][Medline].
Sternberger LA (1979) In: Immunocytochemistry, Ed 2. New York: Wiley.
Stevens CF, Wesseling JF (1998) Activity-dependent modulation of the rate at which synaptic vesicles become available to undergo exocytosis. Neuron 21:415-424[ISI][Medline].
Takei K, Mundigl O, Daniell L, De Camilli P (1996) The synaptic vesicle cycle: a single vesicle budding step involving clathrin and dynamin. J Cell Biol 133:1237-1250[Abstract/Free Full Text].
Tolbert LP, Morest DK (1982) The neuronal architecture of the anteroventral cochlear nucleus of the cat in the region of the cochlear nerve root: electron microscopy. Neuroscience 7:3053-3067[ISI][Medline].
von Gersdorff H, Matthews G (1997) Depletion and replenishment of vesicle pools at a ribbon-type synaptic terminal. J Neurosci 17:1919-1927[Abstract/Free Full Text].
von Gersdorff H, Matthews G (1999) Electrophysiology of synaptic vesicle cycling. Annu Rev Physiol 61:725-752[ISI][Medline].
von Gersdorff H, Vardi E, Matthews G, Sterling P (1996) Evidence that vesicles on the synaptic ribbon of retinal bipolar neurons can be rapidly released. Neuron 16:1221-1227[ISI][Medline].
Wang LY, Kaczmarek LK (1998) High-frequency firing helps replenish the readily releasable pool of synaptic vesicles. Nature 394:384-388[Medline].
Wu LG, Borst JG (1999) The reduced release probability of releasable vesicles during recovery from short-term synaptic depression. Neuron 23:821-832[ISI][Medline].
Wu SH, Kelly JB (1993) Response of neurons in the lateral superior olive and medial nucleus of the trapezoid body to repetitive stimulation: intracellular and extracellular recordings from mouse brain slice. Hear Res 68:189-201[ISI][Medline].
Zenisek D, Matthews G (2000) The role of mitochondria in presynaptic calcium handling at a ribbon synapse. Neuron 25:229-237[ISI][Medline].

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