Rab3A Is Involved in Transport of Synaptic Vesicles to the Active Zone in Mouse Brain Nerve Terminals

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Vol. 12, Issue 10, 3095-3102, October 2001

Rab3A Is Involved in Transport of Synaptic Vesicles to the Active Zone in Mouse Brain Nerve Terminals

A.G. Miriam Leenders,^* Fernando H. Lopes da Silva,^* Wim E.J.M. Ghijsen,^* and Matthijs Verhage ^§

^*Graduate School for the Neurosciences, Institute of Neurobiology, University of Amsterdam, 1098 SM The Netherlands, Molecular Neuroscience, R. Magnus Institute, University of Utrecht Medical Center, 3584 CG Utrecht, The Netherlands

Submitted February 2, 2001; Revised May 25, 2001; Accepted July 19, 2001
Monitoring Editor: Suzanne R. Pfeffer

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The rab family of GTP-binding proteins regulates membrane transport between intracellular compartments. The major rab proteinin brain, rab3A, associates with synaptic vesicles. However, rab3Awas shown to regulate the fusion probability of synaptic vesicles,rather than their transport and docking. We tested whether rab3Ahas a transport function by analyzing synaptic vesicle distributionand exocytosis in rab3A null-mutant mice. Rab3A deletion did notaffect the number of vesicles and their distribution in restingnerve terminals. The secretion response upon a single depolarizationwas also unaffected. In normal mice, a depolarization pulse inthe presence of Ca²⁺ induces an accumulation of vesicles close to and docked at theactive zone (recruitment). Rab3A deletion completely abolishedthis activity-dependent recruitment, without affecting the totalnumber of vesicles. Concomitantly, the secretion response in therab3A-deficient terminals recovered slowly and incompletely afterexhaustive stimulation, and the replenishment of docked vesiclesafter exhaustive stimulation was also impaired in the absenceof rab3A. These data indicate that rab3A has a function upstreamof vesicle fusion in the activity-dependent transport of synapticvesicles to and their docking at the activezone.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Synaptic vesicles of the mammalian brain take up fast-acting neurotransmitters, mostly glutamate and $gamma$ -aminobutyric acid (GABA),and release them, upon activation, into a specialized area ofthe presynaptic membrane, the active zone. Subsequently, thesevesicles recycle locally in preparation for a new round of transmitterrelease. Although synaptic vesicle recycling is a highly specializedform of vesicle trafficking, several molecular principles havebeen recognized that appear to be similar to vesicle traffickingin other compartments of neurons, in other cells, and in otherspecies. Different members of protein families, such as the syntaxins,the synaptobrevins/vesicle-associated membrane proteins, and themunc18/s1 proteins, appear to have similar functions in differentsystems (Bennett and Scheller, 1993; Söllner et al., 1993; Jahnand Südhof, 1999). The rab protein family appears to be an exception.Synaptic vesicles contain three isoforms, rab3A is present inmost if not all synapses in the rodent brain, and rab3B and rab3Care present in a subset of synapses (Fischer von Mollard et al.,1994; Jahn and Südhof, 1999). Recent evidence (Geppert et al.,1997) suggests that the function of rab3A may be different fromother rab proteins in othersystems.

Rab proteins are a large family of small GTP-binding proteins. Its members are localized in distinct cellular compartmentsin mammals but also in yeast (Novick and Zerial, 1997; Olkkonenand Stenmark, 1997). Rab proteins are thought to act as a GTP-dependentmolecular switch to improve the fidelity of protein-protein interactionsat the targets of a transport step, i.e., the pairing of solubleN-ethylmaleimide-sensitive factor attachment receptor (SNARE)proteins that drive vesicle fusion (Schimmöller et al., 1998;Gonzalez and Scheller, 1999). Hence, rab proteins generally actas facilitators in transport steps, i.e., upstream of SNARE complexesandfusion.

Rab3A and rab3C are associated with synaptic vesicles in their GTP-bound form and dissociate from the vesicle upon GTP hydrolysisor depolarization of the nerve terminal (Fischer von Mollard etal., 1994). After GDP-GTP exchange, rab3A can associate with synapticvesicles again. Rab3 isoforms interact with different generalrab-binding proteins and with at least two specific effector proteins,rabphilin-3A (Li et al., 1994; Shirataki et al., 1994) and Rim(Wang et al., 1997). Rab3A null-mutant mice (Geppert et al., 1994)and rab3 null-mutant worms (Nonet et al., 1997) are viable andhave mild phenotypes, suggesting nonessential functions of rab3.Caenorhabditis elegans rab3 null mutants have fewer synaptic vesicles,especially near the active zone, but more at ectopic sites, suggestingthat synaptic vesicle transport in the nerve terminal is impairedin the absence of rab3 (Nonet et al., 1997). In contrast, thesynapse morphology appeared to be normal in rab3A knockout mice(Geppert et al., 1994). Instead, rab3A was proposed to act asa negative regulator of vesicle fusion. Hence, it was concludedthat rab3, unlike other rab proteins and rab3 in C. elegans, actsdownstream of vesicle transport and vesicle docking at the activezone (Geppert et al., 1997). However, in a review of these findings,it has been suggested that this action is probably not the onlyfunction of rab3A (Bean and Scheller, 1997).

Here, we show that in nerve terminals isolated from mouse brain, rab3A also has a classical transport role in the traffickingof synaptic vesicles to their target. Stimulation of the terminalsby chemical depolarization evokes a redistribution of synapticvesicles such that more vesicles get close to and docked at theactive zone (Leenders et al., 1999). This evoked vesicle recruitmentis abolished in nerve terminals isolated from rab3A knockout mice.Concomitantly, recovery of the secretion capacity and replenishmentof docked vesicles after exhaustive stimulation were impairedin the mutants. In contrast, synaptic vesicle recruitment andneurotransmitter release induced by hyperosmotic sucrose werenot affected in rab3A-deficient nerveterminals.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Rab3A Knockout Mice

Rab3A-deficient mice have been described previously (Geppert et al., 1994). All experiments were performed with null-mutantand wild-type littermates from heterozygous matings by experimenterswho were unaware of thegenotype.

Synaptosomal Preparation

Synaptosomes were prepared from whole forebrain of 4-5-mo-old mice by Percoll (Amersham Pharmacia Biotech AB, Uppsala, Sweden)density gradient centrifugation as described (Dunkley et al.,1988). The synaptosomal fractions in the 10-15% and the 15-23%Percoll interfaces were pooled and washed twice in artificialcerebrospinal fluid (aCSF) that contained 132 mM NaCl, 3 mM KCl,2 mM MgSO₄, 1.2 mM NaH₂PO₄, 10 mM HEPES, and 10 mM D-glucose +2 mM CaCl₂. Synaptosomes were kept on ice in aCSF + 2 mM CaCl₂at a protein concentration of 2 mg/ml until use in the assay within4 h after isolation. Protein concentration was determined accordingto Bradford (1976) with bovine serum albumin as astandard.

Release Assay

K⁺ Stimulations. To determine fast transmitter release, synaptosomes (40 µg of protein) were pelleted and resuspended in 20 µl of aCSF supplementedwith 50 µM EGTA, preincubated at 37°C for 5 min, and depolarizedfor 100 ms by use of a rapid mixing device (Leenders et al., 1999).In short, this mixing device consists of two syringes controlledby pneumatic dispensers. Syringe 1 (37°C) from this mixer devicereleases a small aliquot (100 µl) of high-K⁺ medium (see below) to the synaptosomes and after a delay of 100ms, controlled by a digital timer, stop medium (250 µl, see below)is added from syringe 2 (0-4°C) to terminate the depolarization.Depolarization medium: aCSF containing 50 mM KCl (which iso-osmoticallyreplaced NaCl) in the presence of 2 mM CaCl₂ (for total release)or 50 µM EGTA (for the Ca²⁺-independent release); stop medium: aCSF containing 0.8 mM EGTA.For the predepolarization protocol synaptosomes (2 mg/ml) in aCSFwith 2 mM CaCl₂ were preincubated at 37°C for 2 min and eitherdepolarized, by increasing K⁺ to 30 mM, or kept in control medium. After 3 min depolarizationsynaptosomes were pelleted and resuspended in aCSF with 2 mM CaCl₂and incubated at 37°C for 10-30 min. Thereafter, synaptosomeswere resuspended in aCSF + 50 µM EGTA before 100-msdepolarization.

Sucrose Stimulations. Synaptosomes (2 mg/ml) in aCSF with 2 mM CaCl₂ were preincubated at 37°C for 2 min. Synaptosomes where then stimulated with0.5 M sucrose in aCSF either with 2 mM CaCl₂ or 50 µM EGTA. After15 s, stimulation was stopped by addition of aCSF medium withan NaCl concentration that restored the iso-osmolarity of themedium.

HPLC Analysis of Released Transmitters. Synaptosomal suspension (150 µl) was centrifugated through 75 µl of 50:50% (vol/vol) mixture of silicone oil (Dow Corning550, Mavan, Alphen aan den Rijn, Netherlands) and dinonylphtalatefor 2 min in a Sigma table centrifuge at 15,000 × g. From thesupernatant a 90-µl aliquot was pipetted onto 10 µl ice-cold trichloroaceticacid (10%)/homoserine (5 µM). Amino acid levels (glutamate andGABA) were determined by reversed phase high-performance liquidchromatography (Verhage et al., 1989).

Electron Microscopical Analysis

Synaptosomes (40 µg/20 µl) were stimulated as described above for release assay and fixed by rapid addition of ice-cold 2%paraformaldehyde and 2.5% glutaraldehyde. Synaptosomes were embeddedin Epon, and ultrathin coupes (80 nm) were stained with uranylacetate and lead citrate and examined in a Philips 201 electronmicroscope, essentially as described previously (Breukel et al.,1997). For each experimental condition, 25 sections with a clearlyvisible active zone were selected for analysis of synaptic vesicledistribution. The minimal distance between the active zone andthe center of each synaptic vesicle was determined for all vesicles,vesicles were collected in 50-nm bins and the percentage of vesiclesper bin was plotted against the distance to the active zone. Synapticvesicles within 25 nm from the active zone were counted as morphologicallydockedvesicles.

Statistical Analysis

The data were analyzed by paired or unpaired Student's t test, except for difference in distribution of the synaptic vesicles,which was tested by one-way analysis of variance with repeatedmeasures. The rejection of the null hypothesis was accepted assignificant if p < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Vesicle Distribution Is Normal in Resting Nerve Terminals from rab3A Null Mutants

To identify a potential role of rab3A in synaptic vesicle transport, we analyzed the distribution of synaptic vesicles andtheir neurotransmitter release in nerve terminals isolated fromrab3A null mutant mice and their wild-type littermates. Electronmicroscopy revealed no differences between the synaptosomal preparationsfrom the two groups (Figure 1, A and B). Morphometric analysisindicated that the diameter of the terminals, the active zonelength, and the total amount of synaptic vesicles per terminalwere similar in the two groups (Figure 1, C-E). The distributionof synaptic vesicles in the terminals was analyzed by measuringthe shortest distance between the active zone and the center ofeach vesicle and collecting these distances in bins of 50 nm (approximatelythe synaptic vesicle diameter). In resting nerve terminals, thesynaptic vesicle distribution was not different between the twogroups (Figure 1F).

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Figure 1. Ultrastructure and morphometric analysis of mouse brain nerve terminals from control and rab3A null-mutant littermates. Typical electron micrographs of synaptosomal preparations from wild-type (A) and rab3A-deficient (B) littermates. Micrographs were selected when the active zone with attached (part of the) postsynaptic density was present in the section and used for morphometric analysis of synaptic vesicle distribution and docking by an observer unaware of the genotype. Bar, 0.2 µm. Average diameter of the nerve terminals (C), active zone length (D), and total number of synaptic vesicles (E) were not different in resting nerve terminals of wild-type and rab3A mutants (n = 4 for both groups). Also, the intrasynaptic distribution of synaptic vesicles relative to the active zone was not different (F; see MATERIALS AND METHODS for details). The average diameter of the nerve terminals was determined by measuring from the active zone membrane the largest distance across the section.

Evoked Vesicle Recruitment Is Abolished in rab3A Null Mutants

A short episode of depolarization (0.1-15 s) evokes a redistribution of synaptic vesicles in isolated rat brain nerve terminalssuch that more vesicles accumulate close to and docked at theactive zone, whereas less vesicles remain at distant sites (Leenderset al., 1999). Because the total amount of synaptic vesicles doesnot change after depolarization, their redistribution within theterminal reflects a net transport toward the active zone. Thisredistribution is referred to as depolarization-evoked vesiclerecruitment. In nerve terminals isolated from wild-type mice,we observed similar depolarization-evoked vesicle recruitmentas in rat nerve terminals after 100-ms depolarization in the presenceof Ca²⁺ (Figure 2A). However, this depolarization-evoked vesicle recruitmentwas completely abolished in nerve terminals isolated from rab3Amutant littermates. Depolarization did not change the distributionof synaptic vesicles in these terminals (Figure 2B). The totalamount of vesicles per synaptic section was similar in wild-typeand rab3A mutant mice and did not change after stimulation (Figure2C).

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Figure 2. Redistribution of synaptic vesicles induced by 100-ms depolarization in nerve terminals from wild-type and rab3A-deficient littermates. Distribution of synaptic vesicles relative to the active zone in wild-type (A) and rab3A-deficient synaptosomal sections (B) with (filled symbols) and without (open symbols) 100-ms depolarization. Morphometric analysis as in Figure 1F. The total amount of synaptic vesicles (C) and the number of vesicles morphologically docked at the active zone (D) were calculated separately. For each condition (stimulated and unstimulated) 25 sections were analyzed per animal and 4 animals of each genotype. Data are means ± SEM *p < 0.05.

An important aspect of depolarization-evoked vesicle recruitment is an increased number of synaptic vesicles morphologicallydocked at the active zone. In wild-type terminals, the numberof docked vesicles increased >50% after 100-ms depolarization(2.1 ± 0.1-3.3 ± 0.3 vesicles/section; n = 4, p < 0.05; Figure2D). This increase in docked vesicles was also absent in rab3A-deficientterminals. Instead, the number of docked vesicles tended to decreasein the mutant nerve terminals after 100-ms depolarization (Figure2D, not significant, p = 0.12). The reduction in docked vesiclesin the absence of rab3A is based on quantifications in randomsections of isolated nerve terminals. Serial reconstructions ofnerve terminals (Verhage et al., 1991; Schikorski and Stevens,1997) indicated that the absolute reduction per synapse is approximatelyfivevesicles.

Recovery of Secretion Capacity after Exhaustive Stimulation Is Impaired in rab3A Null Mutants

The loss of depolarization-evoked synaptic vesicle recruitment in rab3A null mutants may compromise their ability to restorethe secretion capacity after exhaustive stimulation. To test this,nerve terminals isolated from wild-type and rab3A null mutantlittermates were first stimulated exhaustively to deplete releasablevesicles (McMahon and Nicholls, 1991; Verhage et al., 1991). Synaptosomeswere then repolarized to allow the replenishment of their secretioncapacity. This replenishment was tested by measuring neurotransmitterrelease upon a brief depolarization (100 ms). In control experiments,the first, exhaustive depolarization wasomitted.

On exhaustive stimulation, the total amount of Ca²⁺-dependent release of the major, endogenous neurotransmitters in brain, glutamate,and GABA was similar in wild-type and rab3A-deficient nerve terminals(Figure 3A). A single test pulse of 100-ms depolarization alsoled to a comparable Ca²⁺-dependent release in the two groups (Figure 3B), although GABArelease during 100-ms depolarization was slightly higher in rab3A-deficientterminals (0.22 ± 0.02 nmol/mg of protein in wild types versus0.27 ± 0.04 nmol/mg of protein in rab3A null mutants, n = 11,p < 0.05). The Ca²⁺-independent component of release was also similar between thetwo groups (glutamate: 2.6 ± 0.4 in controls vs. 2.5 ± 0.4 inmutants; GABA: 0.8 ± 0.1 in controls vs. 0.8 ± 0.1 in mutants).These similar release responses upon short or long stimulationare consistent with the similar distribution of synaptic vesiclesobserved in resting nerve terminals from the two groups (Figure1).

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Figure 3. Neurotransmitter release during single depolarizations and after exhaustive predepolarization in nerve terminals from wild-type and rab3A-deficient littermates. Isolated nerve terminals from wild-type and rab3A-deficient mice were depolarized for 3 min (A) or for 100 ms (B) with or without prior depolarization (3 min), and the release of endogenous glutamate and GABA was measured. In each protocol (outlined on the left) the Ca²⁺-dependent (exocytotic) release of endogenous transmitters was calculated by subtracting the Ca²⁺-independent release (40 mM K⁺ + 50 µM EGTA) from the total release (40 mM K⁺ + 2 mM Ca²⁺). No differences were observed in the total content of the terminals (glutamate: 45.1 ± 1.4 in controls vs. 46.6 ± 1.6 in mutants; GABA: 37.1 ± 2.7 in controls vs. 37.6 ± 2.6 in mutants) and in the Ca²⁺-independent component of release (glutamate: 2.6 ± 0.4 in controls vs. 2.5 ± 0.4 in mutants; GABA: 0.8 ± 0.1 in controls vs. 0.8 ± 0.1 in mutants). Data represent means ± SEM of 6-11 independent experiments. *p < 0.05.

After exhaustive depolarization, intracellular vesicle transport in wild-type mice had completely replenished the releasablepool within a 10-min recovery phase (Figure 3B). However, in rab3A-deficientterminals the replenishment was not complete, and neurotransmitterrelease was decreased by ~50% after 10-min recovery (Figure 3B,p < 0.05). Only after 30-min recovery, the response of rab3A-deficientnerve terminals approached control levels (i.e., the responseto a 100-ms depolarization without preceding exhaustive depolarization,Figure 3B). This indicates that the vesicle pool can be largelyreplenished in the absence of rab3A, but only with a considerabledelay (>30 min, more than threefold slower than in wild-type terminals).Even after 30 min the recovery tended to be lower in the absenceof rab3A (not significant, p < 0.08 for glutamate and p < 0.18forGABA).

Replenishment of Docked Vesicles after Exhaustive Stimulation Is Impaired in rab3A Null Mutants

To investigate morphological correlates of the impaired replenishment in the rab3A mutants, we analyzed vesicle distributionin isolated nerve terminals at the ultrastructural level withthe use of the same stimulation protocol. Nerve terminals weremixed with fixative instead of depolarization buffer at the startof the second stimulus (Figure 3). Subsequent morphometric analysisshowed that in wild-type terminals the number of docked vesicleswas comparable with unstimulated nerve terminals. However, inrab3A-deficient terminals the pool of docked synaptic vesicleswas decreased compared with unstimulated rab3A-deficient terminals(Figure 4A, n = 4, p < 0.05). The total number of vesicles wasnot altered in any of the conditions and in both groups (Figure4B), indicating that the reduced number of docked vesicles inthe rab3A mutants reflects an impaired transport of vesicles totheir release site. Hence, both morphometric analysis at the ultrastructurallevel and biochemical analysis of neurotransmitter release indicatedthat the recovery of vesicular release after exhaustive stimulationwas compromised upon deletion of rab3A expression.

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Figure 4. Total number of synaptic vesicles and the number of morphologically docked vesicles in nerve terminals from wild-type and rab3A-deficient littermates after a 3-min depolarization and 10-min recovery. Number of docked synaptic vesicles (A) and total number of synaptic vesicles (B) per section were analyzed in terminals fixated before (

) and after ( $black-square$ ) 3-min depolarization and 10-min recovery (see Figure 3). Data represent means + SEM of four independent experiments. *p < 0.05.

Hypertonic Sucrose Application Does not Reveal a Transport Phenotype in rab3A Null Mutants

Application of hyperosmotic sucrose solutions is an artificial stimulus widely used to analyze the size and the replenishmentof the releasable synaptic vesicle pool, especially in electrophysiologicalanalyses of hippocampal autapses (Stevens and Tsujimoto, 1995;Rosenmund and Stevens, 1996). We confirmed that also in the nerveterminal preparation, hyperosmotic sucrose induced vesicular releasefrom the same vesicle pool as membrane depolarization, althoughin a Ca²⁺-independent manner (our unpublished results; Lonart et al., 1998).We applied hypertonic (0.5 M) sucrose solutions for 15 s (Geppertet al., 1997). This yielded approximately six- to sevenfold moreglutamate and GABA release than the Ca²⁺-dependent component after 100-ms depolarization (Figure 5). Theamounts released by either stimulus did not differ in the presenceor absence of rab3A (Figure 5). Concomitantly, paired applicationsof hyperosmotic sucrose solutions separated by a 10-min periodof recovery revealed no differences in vesicle replenishment betweenmutant and control nerve terminals, but the second sucrose applicationwas less effective for both groups (Figure 5A). Finally, 100-msdepolarization after sucrose stimulation and 10-min recovery alsorevealed no differences in vesicle replenishment between controland rab3A-deficient nerve terminals (Figure 5B).

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Figure 5. Neurotransmitter release after application of hyperosmotic sucrose solutions and chemical depolarization to nerve terminals from wild-type and rab3A-deficient littermates. Isolated nerve terminals from wild-type and rab3A-deficient mice were stimulated either once or twice with 0.5 M sucrose for 15 s (A) or with 100-ms chemical depolarization with or without previous sucrose stimulation (B) and the release of endogenous glutamate and GABA was measured. The stimulation protocols are outlined on the left. (A) Total release is plotted. (B) Ca²⁺-dependent (exocytotic) release of endogenous transmitters was calculated by subtracting the Ca²⁺-independent release (40 mM K⁺ + 50 µM EGTA) from the total release (40 mM K⁺ + 2 mM Ca²⁺). Data represent means ± SEM of five independent experiments.

Application of 0.5 M sucrose for 15 s to wild-type nerve terminals produced an increase in the amount of synaptic vesicleswithin 150 nm from the active zone (Figure 6A; p < 0.05, n = 6)and a decrease in the amount of synaptic vesicles at 200-1000-nmdistance from the active zone (our unpublished results). Thisredistribution was similar to the redistribution observed after0.1 (Figure 2A) or 15-s chemical depolarization (Figure 6B). Unlikedepolarization, redistribution of synaptic vesicles after hyperosmoticsucrose application was also observed in the absence of Ca²⁺ (our unpublished results). Furthermore, unlike depolarization,0.5 M sucrose also induced redistribution in rab3A-deficient terminalsas in wild types (Figure 6, A and B; p < 0.05, n = 6). Hence,whereas a defect in evoked vesicle recruitment was evident inrab3A null mutants upon membrane depolarization in the presenceof Ca²⁺, no defects were observed with the use of hyperosmotic sucrose.

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Figure 6. Redistribution of synaptic vesicles after application of hyperosmotic sucrose solutions and chemical depolarization to nerve terminals from wild-type and rab3A-deficient littermates. Distribution of synaptic vesicles in synaptosomal sections was analyzed as in Figure 1F with (filled symbols) and without (open symbols) stimulation, i.e., application of 0.5 M sucrose for 15 s (A) or 40 mM K⁺ in presence of 2 mM Ca²⁺ (B). Vesicle distribution after hyperosmotic sucrose stimulation was significantly different from control (*p < 0.05) for both wild-type and rab3A-deficient terminals. Vesicle distribution after 15-s depolarization was significantly different from control in wild-type (*p < 0.05) but not in rab3A-deficient terminals. Data are means ± SEM of six independent experiments.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We have analyzed the role of rab3A in synaptic vesicle trafficking in nerve terminals isolated from mouse brain. Deletionof rab3A expression did not affect the number of synaptic vesiclesor their distribution in resting nerve terminals, but depolarization-evokedrecruitment of these vesicles was completely abolished in rab3Anull mutant mice. Concomitantly, the recovery of the secretioncapacity and the replenishment of docked vesicles after exhaustivestimulation were reduced by 50% in the mutants. Application ofhypertonic sucrose did not reveal this transport phenotype ofthe rab3A nullmutants.

Electrophysiological analysis of synaptic transmission in hippocampal neurons in culture showed that rab3A deletion alteredthe synaptic efficacy and suggested that rab3A limits vesiclefusion, i.e., may act as a negative regulator, downstream of vesicledocking at its target (Geppert et al., 1997). Hence, rab3A, unlikeother rab proteins, appeared to act downstream of SNARE complexformation, the protein complexes that drive vesicle fusion (Jahnand Hanson, 1998). We have uncovered a separate function of rab3A,upstream of SNARE complex formation between vesicle and targetmembrane, exploiting the fact that populations of isolated nerveterminals can be stimulated synchronously and repeatedly. Subsequentmorphometric and functional assays allowed a direct analysis ofsynaptic vesicle (re)distribution and their exocytosis, and revealedthe role of rab3A in vesicletransport.

This transport role of rab3A is a rate-limiting function. The total number of synaptic vesicles and their distribution wasunaltered in resting nerve terminals, but when their transportcapacity was challenged by maximal activation of exocytosis, thetransport role of rab3A was uncovered in two ways. First, thedepolarization-evoked vesicle recruitment to the active zone didnot occur at all in the absence of rab3A, notably without majoreffects on neurotransmitter release at this point. This suggeststhat rab3A deletion affects the transport of synaptic vesiclesthat do not (yet) take part in transmitter release. The slightincrease in GABA release may be interpreted as an effect on releaseprobability and points in the same direction as previous observationsin hippocampal autapses (Geppert et al., 1997). Second, the relevanceof the impaired vesicle recruitment in the absence of rab3A wasrevealed during repeated stimulation: A second depolarizationshowed that the capacity to secrete transmitters as well as vesicledocking at the active zone was compromised by rab3A deletion.At this point, the reduction in the number of docked vesiclesoccurred in parallel with a reduction in neurotransmitter release.This indicates that the reduced vesicle pool at the active zoneresulted from the reduced recruitment of vesicles and not froma faster vesicle depletion due to enhanced release. Hence, inisolated nerve terminals, rab3A deletion did not have major effectson the ongoing exocytosis of predocked vesicles even during maximalactivation, but primarily affects the replenishment of vesiclesfor a new round of secretion. Even very long depolarizations didnot reveal differences in transmitter release between mutantsand controls. Such a role of rab3A is universal, because it wasevident in the mixed population of isolated nerve terminals, i.e.,from all forebrain areas and representing all transmitter systemsin the brain. Apparently, other rab3 isoforms cannot compensatefor this function, although some isoforms are expressed at lowlevels in several areas of the brain (Geppert et al., 1994; Liet al., 1994; Jahn and Südhof, 1999). Potentially, a more drastictransport phenotype will be obtained upon deletion of the otherthree rab3 genes, similar to the clear phenotype in resting nerveterminals of C. elegans rab3 mutants (Nonet et al., 1997).

Our data do not exclude a separate role of rab3A as a negative regulator of release probability. The reported short-term enhancementin paired pulse facilitation after rab3A deletion (Geppert etal., 1997) applies to a small subset of vesicles released upona pair of single action potentials. Hence, a change in the releaseof this small number of vesicles will not be detected in our morphologicaland functional analyses of the total synaptic vesicle pool. Becauseat least two specific rab3 effectors have been characterized (Shiratakiet al., 1994; Wang et al., 1997) and additional effectors maybe relevant, it is conceivable that rab3A exerts multiple functionsat distinct steps in the synaptic vesicle cycle (Gonzalez andScheller, 1999).

Apparently, a normal vesicle distribution can be maintained during low activity also in the absence of rab3A. Consequently,synaptosomal preparations from rab3A mutants and controls havesimilar vesicle numbers and distribution. And after exhaustivestimulation, an extended recovery time will finally restore anormal vesicle distribution also in the absence of rab3A. Sucha facilitatory role is in line with the proposed function forother members of the rab family, i.e., as timer devices that controlprotein-protein interactions (Aridor and Balch, 1996). In yeast,however, several rab proteins appear to have essential functions(Novick and Zerial, 1997). Nevertheless, the enhanced rundownof responsiveness in CA1 neurons of the hippocampus at 14 Hz,which was previously observed in the rab3A null mutants (Geppertet al., 1994), and the loss of long-term potentiation in the CA3area but not of regular transmission of these mutants (Castilloet al., 1997) can all be explained by this facilitatory role ofrab3A in vesicle transport. Such a role is also compatible withthe altered vesicle distribution in the viable rab3 mutant ofC. elegans (Nonet et al., 1997), and the effects of mutant rabproteins and introduction of rab antibodies (Olkkonen and Stenmark,1997).

Application of hypertonic sucrose solutions is an established, Ca²⁺-independent method to probe the releasable pool of synaptic vesiclesand paired sucrose applications have been used to monitor therefilling rate of this pool (Stevens and Tsujimoto, 1995; Rosenmundand Stevens, 1996). Although rab3A deletion had a clear effecton depolarization-evoked vesicle recruitment, no effects wereobserved during single or paired sucrose applications. This isin agreement with the unaltered responses to single or pairedsucrose applications in cultured hippocampal neurons from rab3Aknockout mice (Geppert et al., 1997). Apparently, the transportrole of rab3A that we have characterized here is specific forthe depolarization-induced, Ca²⁺-dependent recruitment. Application of hyperosmotic solutionsproduced similar release and vesicle recruitment in the presenceor absence of rab3A and the response to hyperosmotic sucrose inthe mutants was similar to depolarization-evoked recruitment innormal terminals. Hence, hyperosmotic shock appears to bypassthe natural rab3A-regulated vesicle transport. It is conceivablethat the transport role of rab3A relates specifically to Ca²⁺-dependent mechanisms of vesicle recruitment, especially becausetwo of its downstream effectors are Ca²⁺-binding proteins, i.e., rabphilin3A and Rim (Shirataki et al.,1994; Wang et al., 1997) and Ca²⁺ influx have a facilitatory effect on vesicle recruitment (Stevensand Wesseling, 1998; Wang and Kaczmarek, 1998). The reduced expressionof rabphillin-3A in rab3A knockout mice (Geppert et al. 1994)would be in agreement with a regulatory role of the former proteinin vesicle recruitment. However, no phenotype has been observedin rabphillin-3A knockout animals (Schluter et al., 1999).

	ACKNOWLEDGMENTS

We are grateful to Greet Scholten and Elly Besselsen for excellent technical assistance; to Michel Ory for the software toanalyze vesicle distribution; to Anita Vermeer and Robbert Zalmfor breeding, genotyping, and coding the mice; and to Drs. Y.Goda, T.C. Südhof, and R.F. Toonen for critically reading themanuscript. A.G.M.L. is supported by grant 903-42-016 of the NetherlandsOrganization of ScientificResearch.

	FOOTNOTES

Present address: Department of Neurogenomics, Free University Amsterdam, de Boelelaan 1087, 1081 HV Amsterdam, TheNetherlands.

^§ Corresponding author. E-mail address: m.verhage{at}med.uu.nl or ghijsen{at}bio.uva.nl.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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