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The Journal of Neuroscience, October 1, 2002, 22(19):8438-8446

Structure/Function Analysis of Ca²⁺ Binding to the C₂A Domain of Synaptotagmin 1

Rafael Fernández-Chacón^{1, 4}, Ok-Ho Shin¹, Andreas Königstorfer³, Maria F. Matos¹, Alexander C. Meyer⁴, Jesus Garcia², Stefan H. Gerber¹, Josep Rizo², Thomas C. Südhof¹, and Christian Rosenmund⁴

¹ Center for Basic Neuroscience, Department of Molecular Genetics, and Howard Hughes Medical Institute, and ² Departments of Biochemistry and Pharmacology, The University of Texas Southwestern Medical Center, Dallas, Texas 75390-9111, and ³ Max-Planck-Institut für experimentelle Medizin and ⁴ biophysikalische Chemie, 37070 Göttingen, Germany

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Synaptotagmin 1, a Ca²⁺ sensor for fast synaptic vesicle exocytosis, contains two C₂ domains that form Ca²⁺-dependent complexes with phospholipids. To examine the functional importance of Ca²⁺ binding to the C₂A domain of synaptotagmin 1, we studied two C₂A domain mutations, D232N and D238N, using recombinant proteins and knock-in mice. Both mutations severely decreased intrinsic Ca²⁺ binding and Ca²⁺-dependent phospholipid binding by the isolated C₂A domain. Both mutations, however, did not alter the apparent Ca²⁺ affinity of the double C₂ domain fragment, although both decreased the tightness of the Ca²⁺/phospholipid/double C₂ domain complex. When introduced into the endogenous synaptotagmin 1 gene in mice, the D232N and D238N mutations had no apparent effect on morbidity and mortality and caused no detectable alteration in the Ca²⁺-dependent properties of synaptotagmin 1. Electrophysiological recordings of cultured hippocampal neurons from knock-in mice revealed that neither mutation induced major changes in synaptic transmission. The D232N mutation, however, caused increased synaptic depression during repetitive stimulation, whereas the D238N mutation did not exhibit this phenotype. Our data indicate that Ca²⁺ binding to the C₂A domain of synaptotagmin 1 may be important but not essential, consistent with the finding that the two C₂ domains cooperate and may be partially redundant in Ca²⁺-dependent phospholipid binding. Moreover, although the apparent Ca²⁺ affinity of the synaptotagmin 1/phospholipid complex is critical, the tightness of the Ca²⁺/phospholipid complex is not. Our data also demonstrate that subtle changes in the biochemical properties of synaptotagmin 1 can result in significant alterations in synaptic responses.

Key words: synaptotagmin; neurotransmitter release; exocytosis; C2 domain; Ca²⁺-binding site; synaptic plasticity

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

When an action potential invades a nerve terminal, voltage-gated Ca²⁺ channels open, and Ca²⁺ triggers fast neurotransmitter release with an overall probability of 0.05-1.00 (Hessler et al., 1993; Rosenmund et al., 1993; Xu-Friedman et al., 2001). Because of the steep Ca²⁺ sensitivity of release (Bollmann et al., 2000; Schneggenburger and Neher, 2000), the final step in triggering release requires cooperative interaction of multiple Ca²⁺ ions with its receptor(s). Although several Ca²⁺ sensors are likely involved in neurotransmitter release, the synaptic vesicle protein synaptotagmin 1 probably is the primary sensor for synaptic vesicle exocytosis. This conclusion is based on the fact that synaptotagmin 1 binds multiple Ca²⁺ ions (Ubach et al., 1998; Fernández et al., 2001) and is essential for fast, Ca²⁺-triggered exocytosis in central synapses (Geppert et al., 1994) in a manner whereby its apparent Ca²⁺ affinity dictates the Ca²⁺ responsiveness of release (Fernández-Chacón et al., 2001).

Synaptotagmin 1 is the prototype of a large family of proteins, many of which are probably Ca²⁺ sensors for exocytosis (for review, see Südhof, 2002). All synaptotagmins are composed of an N-terminal transmembrane region, a central linker sequence, and two C-terminal C₂ domains. The two C₂ domains, C₂A and C₂B, bind multiple Ca²⁺ ions and form Ca²⁺-dependent phospholipid complexes (Davletov and Südhof, 1993; Chapman and Jahn, 1994; Ubach et al., 1998; Fernández et al., 2001). In addition, the synaptotagmin C₂ domains bind to several proteins in vitro as a function of Ca²⁺, most prominently the soluble N-ethylmaleimide-sensitive factor attachment protein (SNAP) receptor (SNARE) syntaxin 1 (Chapman et al., 1995; Li et al., 1995; Kee and Scheller, 1996). Because the C₂ domains account for the majority of the synaptotagmin 1 sequence (Perin et al., 1990), synaptotagmin 1 can be considered a membrane-tethered Ca²⁺-binding machine.

C₂ domains are composed of stable eight-stranded -sandwiches with flexible loops emerging from the top and bottom (Sutton et al., 1995). Ca²⁺ binds exclusively to the top loops at sites that are formed by residues that are widely separated in the primary sequence and often coordinate multiple Ca²⁺ ions. As a result, C₂ domains bind Ca²⁺ ions in a cluster with a low intrinsic Ca²⁺ affinity (Ubach et al., 1998; Fernández et al., 2001). This affinity increases dramatically in the presence of phospholipid membranes that potentiate the apparent Ca²⁺ affinity of C₂ domains up to 1000-fold (Zhang et al., 1998). Mutations in the top loops of C₂ domains differentially alter their intrinsic and apparent Ca²⁺ affinities. For example, a point mutation in the C₂A domain of synaptotagmin 1, R233Q, increases its intrinsic Ca²⁺ affinity but decreases its apparent Ca²⁺ affinity (Fernández-Chacón et al., 2001). When introduced into the endogenous mouse synaptotagmin 1 gene by homologous recombination, this mutation decreased by approximately twofold the apparent Ca²⁺ affinity of the double C₂ domain fragment of native synaptotagmin 1 for phospholipids but not for SNARE complexes. Because the R233Q mutation lowered the Ca²⁺ sensitivity of neurotransmitter release twofold in the mutant mice, these results suggested that the Ca²⁺-dependent synaptotagmin/phospholipid complex is the driving force behind the Ca²⁺ triggering of neurotransmitter release (Fernández-Chacón et al., 2001). However, it is unclear why synaptotagmins contain two independently folded C₂-domains with similar Ca²⁺-dependent properties. In the present study, we have tested the effects of mutations in the Ca²⁺-binding sites of the C₂A domain of synaptotagmin 1 using a combination of biophysical, biochemical, genetic, and electrophysiological approaches.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Nuclear magnetic resonance spectroscopy measurements of intrinsic Ca²⁺ binding by wild-type and mutant C₂A domains. ¹H-¹⁵N heteronuclear single quantum coherence (HSQC) spectra were acquired with 1 hr total acquisition time at 25°C in a Varian INOVA500 nuclear magnetic resonance (NMR) spectrometer (spectral widths = 7600 and 1163 Hz in the ¹H and ¹⁵N dimensions, respectively) using uniformly ¹⁵N-labeled C₂A domains (Zhang et al., 1994). The Ca²⁺ titrations were recorded at 150-160 µM protein concentrations with successive additions of 0, 0.05, 0.1, 0.15, 0.2, 0.25, 0.3, 0.375, 0.45, 0.525, 0.6, 0.675, 0.75, 1, 1.2, 2, 5, 10, 20, 30, and 40 mM Ca²⁺. The Ca²⁺ affinities of the different sites were calculated by curve-fitting the Ca²⁺ dependence of selected chemical shifts to standard protein-ligand equilibrium equations using Sigma Plot (Fernández-Chacón et al., 2001).

Ca²⁺-dependent phospholipid binding studies of wild-type (WT) and mutant recombinant C₂A domains were performed with two assays. (1) Glutathione S-transferase (GST)-pulldown assays using ³H-labeled liposomes containing 30% phosphatidyl serine(PS)/70% phosphatidyl choline (PC) and immobilized GST-fusion proteins were performed essentially as described (Fernández-Chacón et al., 2001; Gerber et al., 2001). Data obtained with identical amounts of recombinant proteins, liposomes, and glutathione beads were evaluated in terms of both Ca²⁺ affinity and amount of binding (see Fig. 2A,B). Results from multiple experiments are summarized in Table 2. (2) Liposome centrifugation assays using soluble C₂ domain GST-fusion proteins eluted from glutathione columns after purification and heavy liposomes were performed essentially as described by Sugita et al. (2002). Briefly, dried lipids (PS/PC = 25:75, w/w) were suspended in HEPES buffer (50 mM HEPES, 100 mM NaCl, 4 mM EGTA, pH 6.8) containing 0.5 M sucrose, vortexed, and sonicated. Heavy liposomes were isolated by centrifugation (100,000 × g for 30 min) after adding 4 vol of HEPES buffer without sucrose. The heavy liposomes were then washed with HEPES buffer, precipitated by centrifugation (13,000 rpm for 10 min), and resuspended in HEPES buffer. Recombinant GST-synaptotagmin 1 C₂ domains (6 µg protein) were incubated with 100 µg of liposomes with various concentrations of free Ca²⁺ clamped with Ca²⁺/EGTA buffers and centrifuged (13,000 rpm for 10 min). The pellets were washed with the corresponding Ca²⁺/EGTA buffer, treated with chloroform/methanol (1:2, v/v), and centrifuged again (13,000 rpm for 15 min). The protein precipitate was then analyzed by SDS-PAGE and Coomassie Blue staining.

Ca²⁺-dependent phospholipid and syntaxin binding by native synaptotagmins was examined essentially as described (Fernández-Chacón et al., 2001), and bound proteins were analyzed by SDS-PAGE and immunoblotting.

Generation of knock-in mutant mice by homologous recombination. Mice carrying the D232N or the D238N point mutations in the endogenous synaptotagmin 1 gene were generated essentially as described previously for the R233Q and the K236Q knock-in mutants (Fernández-Chacón et al., 2001). Mice were genotyped by PCR as described (Fernández-Chacón et al., 2001), and PCR fragments were digested with specific restriction enzymes to detect diagnostic restriction sites that were inserted in conjunction with the point mutations (BstBI for D232N and EcoRI for D238N). As in our previous study on the R233Q and K236Q mutants, all analyses were performed on the offspring of matings between compound heterozygotes carrying one allele of the D232N or D238N knock-in, and a second allele of the control knock-in that includes the same neomycin gene in the intron but lacks the mutation in an exon. This procedure ensured that all analysis was performed on precisely matched controls.

Cell culture and electrophysiology. Microislands of astrocyte feeder cells were prepared 4-5 d before hippocampal neurons were plated. Briefly, islands of substrate (0.1 gm/l poly-D-lysine; 1 gm/l rat tail collagen in 1 mM acetic acid) were applied to round glass coverslips using a stamp containing regularly spaced squares (200 × 200 µm). Type 1 astrocytes (5000/cm²) were preplated in DMEM containing 10% fetal calf serum. Once astrocytes reached confluency, 5-fluoro-2'deoxyuridine (10 µM) was added to inhibit further proliferation. Newborn animals were decapitated according to the rules of the state and animal welfare committee. Brains were cleaned of meninges and vascular tissue, and then the hippocampi were removed in physiological salt solution. The tissue was enzymatically dissociated in papain (2 U/ml) in DMEM for 60 min at 37°C. Before plating the dissociated hippocampal neurons at a density of 500/cm², the medium of the astrocyte feeder cells was replaced with serum-free medium (Neurobasal medium A supplemented with B27, Glutamax, and Pen/strep; Invitrogen). Neurons were allowed to mature for 14-21 d before they were used for experiments, and only islands containing single neurons were examined. Patch pipette solutions contained (in mM): 135 K-Gluconate, 10 HEPES, 1 EGTA, 4.6 MgCl₂, 4 Na-ATP, 15 creatine phosphate, 50 U/ml phosphocreatine kinase (300 mOsm, pH 7.3). The extracellular saline solution contained (in mM): 140 NaCl, 2.4 KCl, 10 HEPES, 10 glucose, 4 CaCl₂, and 4 MgCl₂ unless noted otherwise (305 mOsm, pH 7.3). All chemicals, except for MK-801 (Tocris, Bristol, UK), were purchased from Sigma. All solutions were applied using a fast flow system at room temperature (Pyott and Rosenmund, 2002).

Electrophysiology and statistics. Cells were whole-cell voltage clamped at 70 mV with either an Axopatch 200B amplifier (Axon Instruments) under control of the Clampex 8.0 (Axon Instruments) program or an EPC9 patch-clamp amplifier (HEKA Elektronik, Lambrecht, Germany). Currents were low-pass filtered at 1 or 5 kHz and stored at either 10 or 20 kHz. The series resistance was compensated to 70-90%. Only cells with series resistances below 10 M were analyzed. Statistical significance was tested using unpaired, nonparametric Wilcoxon tests. All values are presented as the mean ± SEM.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

D232N and D238N mutations severely impair Ca²⁺ binding to the C₂A domain of synaptotagmin 1

The three Ca²⁺-binding sites of the synaptotagmin 1 C₂A domain are formed by six amino acid side chains, five aspartate residues and one serine residue, located on two separate loops that extend from the top of the domain (Ubach et al., 1998). Intrinsic Ca²⁺ binding by the C₂A domain is of low affinity (>20 mM for the third Ca²⁺ ion) and lacks cooperativity (Table 1). To perturb Ca²⁺ binding to the C₂A domain without affecting its structure, we introduced point mutations into the C₂A domain Ca²⁺ binding sites. These mutations, D232N and D238N, target key aspartate residues that coordinate multiple Ca²⁺ ions (Ubach et al., 1998) but are nevertheless conservative, and they preserve the overall structure of the domain (Shao et al., 1998; Contreras et al., 1999). We then analyzed purified recombinant wild-type and mutant C₂A domains by NMR spectroscopy, using HSQC spectra in the presence of increasing Ca²⁺ concentrations to monitor Ca²⁺ binding to the C₂A domains. Our data revealed that the mutations severely altered the Ca²⁺-binding properties of the C₂A domain (Fig. 1) (data not shown). Both mutations caused a large decrease in the intrinsic Ca²⁺ affinities of the second and third Ca²⁺-binding sites, and the D238N but not the D232N mutation also reduced the intrinsic affinity of the first Ca²⁺-binding site (Table 1).

View this table: [in this window] [in a new window]   Table 1.   Intrinsic Ca2+-binding affinities of wild-type and mutant C2A domains

View larger version (48K): [in this window] [in a new window]   Figure 1.   Intrinsic Ca2+ binding to the wild-type (WT) and the D232N and D238N mutant C2A domains of synaptotagmin 1 monitored by NMR spectroscopy. Ca2+ titrations were examined by 1H-15N HSQC spectra acquired with 150-165 µM of purified recombinant C2A domains. Panels illustrate the Ca2+-dependent shifts of selected cross-peaks corresponding to the D172 (top panels) and D230 (bottom panels) NH groups in all three C2A domains. The cross-peaks from these NH groups are shown in red, and other cross-peaks are shown in black. Numbers next to the resonances indicate the Ca2+ concentration (in millimolar) for that particular position of the cross-peak. Note the typical triphasic movement of the cross-peaks in the wild-type C2A domain, with the corresponding Ca2+-binding sites (Ca1, Ca2, and Ca3) indicated next to each phase. In the mutants, only biphasic movements with a different Ca2+ dependence are detectable. For quantitation of the various Ca2+-binding parameters, see Table 1.

To determine the effect of the mutations on Ca²⁺-dependent phospholipid binding by the isolated C₂A domain, we used two methods: pulldowns of radiolabeled liposomes with immobilized GST-fusion proteins of the C₂A domains (Fig. 2) and a liposome centrifugation assay (Fig. 3). The two assays gave fundamentally the same results. In the isolated C₂A domain, both mutations severely depressed Ca²⁺-dependent phospholipid binding. Consistent with the decrease in intrinsic Ca²⁺ binding by the mutant domains (Table 1), phospholipid binding was more impaired by the D238N than the D232N mutation (Table 2). Curiously, the small amount of remaining Ca²⁺-dependent phospholipid binding in the D232N mutant exhibited a higher apparent Ca²⁺ affinity than that of the wild-type C₂A domain or of the D238N mutant C₂A domain (Fig. 2, Table 2). Viewed together, these data demonstrate that in the isolated C₂A domain, the D232N and D238N mutations severely impair Ca²⁺ binding and Ca²⁺-dependent phospholipid binding.

View larger version (20K): [in this window] [in a new window]   Figure 2.   Apparent Ca2+-binding affinities of the wild-type (WT) and mutant C2A domains of synaptotagmin 1 measured by Ca2+-dependent GST pulldowns of radiolabeled liposomes. A, Ca2+ titrations of phospholipid binding with equal amounts of recombinant C2A domains (25 µg protein) and radiolabeled liposomes. Note that both mutations (D232N and D238N) inactivate >80% of Ca2+-dependent phospholipid binding, but that the remaining binding is still Ca2+ dependent. B, Same data as in B but normalized for maximal binding to illustrate the shift in apparent Ca2+ affinities of the D232N mutant. Note that because of the low signal-to-noise, in particular for the D238N mutant C2A domain, which exhibits almost no Ca2+-dependent phospholipid binding, the curve fits are rather inaccurate in single experiments as shown here but can be averaged from multiple experiments as summarized in Table 2.

View larger version (97K): [in this window] [in a new window]   Figure 3.   Apparent Ca2+ affinities of wild-type and mutant single and double C2 domain fragments from synaptotagmin 1 measured by Ca2+-dependent binding to liposomes. The isolated wild-type and D232N and D238N mutant C2A domain, the wild-type C2B domain, and the wild-type and mutant double C2 domain fragments were analyzed. Liposomes composed of 25% PS/75% PC were incubated with the indicated C2 domains (present as soluble purified GST-fusion proteins) at the Ca2+ concentrations shown on top (clamped with Ca2+/EGTA buffers) and centrifuged, and bound proteins were analyzed by SDS-PAGE and Coomassie blue staining. Data shown are from a single representative experiment repeated multiple times.

View this table: [in this window] [in a new window]   Table 2.   Apparent Ca2+-binding affinities of wild-type and mutant C2A domains measured as Ca2+/phospholipid complexes

Generation of knock-in mice carrying D232N or D238N mutations

To test the functional consequences of the D232N and D238N mutations in vivo, we generated mice that carried these mutations separately (Fig. 4A). These mice were obtained by the same approach used to make knock-in mice with the R233Q and K236Q mutations (Fernández-Chacón et al., 2001) and analyzed similarly by breeding to control mice. These control mice had gone through the same genetic manipulations as the mutant mice and also contained a neomycin resistance gene in an intron but lacked a mutation. The D232N and D238N mutant mice exhibited no outward abnormality. They bred normally and displayed no noticeable morbidity or premature mortality and no obvious behavioral defects. In both types of mutant mice, the apparent levels of synaptotagmin 1 and other proteins (vasolin-containing protein, Syntaxin 1A/B, Synapsins 1A, 1B, 2A, and 2B, SNAP-25, synaptobrevin 2, Munc18-1, synaptophysin 1, Rab3A, rabphilin, and synaptotagmin 7) were evaluated by immunoblotting with detection by enhanced chemiluminescence (Fig. 4B) (data not shown). No major changes in protein levels were detected.

View larger version (14K): [in this window] [in a new window]   Figure 4.   Strategy for generating knock-in mice with D232N and D238N mutations in the synaptotagmin 1 C2A domain. A, Design of knock-in vectors for homologous recombination. Similar to previous experiments (Fernández-Chacón et al., 2001), a genomic clone containing a single exon from the murine synaptotagmin 1 gene (top) was used to generate targeting vectors in which D232N or D238N mutations were introduced into the exon (middle), with two copies of the thymidine kinase (TK) gene for negative selection and a neomycin resistance cassette (neo) for positive selection. The mutant exons were then introduced into the endogenous synaptotagmin 1 gene by homologous recombination, which also introduces the neomycin resistance gene cassette into the intron (bottom). Numbered arrows identify oligonucleotides (1872 and 1873) used for genotyping. The position of the outside probe for detection of homologous recombination by Southern blotting is indicated on the right. The location of selected restriction sites are shown (H, HindIII; B, BglII; E, EcoRI; N, NheI; C, ClaI; P, PstI), and the scale is given on the right. The mutant mice produced by homologous recombination were then crossed with control mice obtained in a previous study (Fernández-Chacón et al., 2001) in which the neomycin gene was introduced into the intron without any mutations in the coding region, and all analyses were performed on littermate offspring from matings between double heterozygous mice carrying one mutant allele (either D232N or D238N) and one control allele with the neomycin cassette but without a mutation. B, Immunoblots of total brain homogenates (30 µg of protein) from wild-type (+/+), heterozygous (+/), and homozygous (/) littermates stained with monoclonal antibodies specific for synaptotagmin 1 and rab3a.

Enhanced short-term depression in synaptotagmin 1 D232N mutant mice

To test the effects of the D232N and D238N mutations on synaptotagmin 1 function, we cultured hippocampal neurons from newborn knock-in mice and performed electrophysiological recordings in neurons that had formed autapses. In all experiments, neurons from mutant and wild-type littermates were cultured and analyzed simultaneously to control for culture-dependent variabilities in synaptic responses. EPSCs in response to action potentials induced at low frequency by brief somatic depolarizations (0 mV, 1-2 msec) appeared similarly robust for all mice tested (data not shown), consistent with a fundamentally normal release apparatus in the mutant mice. We next measured the short-term plasticity properties of wild-type and synaptotagmin 1 mutants by evoking trains of action potentials at 10 Hz (50 stimuli) and 50 Hz (5 stimuli). Although the D238N mutation had no major effect on the time course of EPSCs at both frequencies, the D232N mutation produced significantly faster depression of EPSC amplitudes at both frequencies (Fig. 5). This effect is opposite to that caused by the neighboring R233Q mutation that resulted in strong facilitation under the same conditions (Fernández-Chacón et al., 2001).

View larger version (29K): [in this window] [in a new window]   Figure 5.   Effect of the D232N and D238N mutations on short-term synaptic plasticity analyzed in cultured hippocampal neurons. A, Average synaptic currents (EPSCs) recorded from "microisland" cultures in response to 10 Hz stimulation. EPSCs are normalized to the first response; top traces show a comparison of D232N mutant neurons with wild-type (WT) neurons, and bottom traces show a comparison of D238N mutant neurons with wild-type neurons. Stimulus artifacts are blanked. B, Plot of the average EPSC amplitudes normalized to the first response recorded during 10 Hz stimulation. The comparison of D232N mutant with wild-type responses is shown on the left, and the comparison of D238N mutant with wild-type responses is shown on the right. C and D are same as A and B but with 50 Hz stimulation.

In the R233Q mutant mice, the change in short-term plasticity was paralleled by a reduction in the basal Ca²⁺-triggered response, a right shift in the apparent Ca²⁺ sensitivity of evoked responses, and a decrease in the vesicular and synaptic release probabilities (Fernández-Chacón et al., 2001). We therefore tested whether the D232N mutation caused an increased release probability, because accelerated EPSC depression during trains of action potentials is indicative for this change in release efficacy. Release efficacy can be calculated by quantifying evoked responses and the size of the readily releasable pool (RRP) in the same cell. The average absolute EPSC amplitudes recorded from neurons from mutant and wild-type littermates were similar in all comparisons (D232N 3.6 ± 0.5 nA, n = 48 vs WT 3.7 ± 0.7 nA, n = 39; D238N 3.6 ± 0.6 nA, n = 41 vs WT 3.4 ± 0.8 nA, n = 31) (Fig. 6). The size of the readily releasable vesicle pool can be quantified by integration of the transient inward current component of the response induced by a 4 sec application of 500 mOsm hypertonic sucrose solution applied to the entire cell (Rosenmund and Stevens, 1996). Similar to the absolute EPSC amplitudes, no significant changes were observed between mutants and wild-type controls in the readily releasable pool (D232N 598 ± 86 pC, n = 44 vs WT 551 ± 105 pC, n = 36) and D238N (D238N 655 ± 102 pC, n = 41 vs WT 857 ± 181 pC, n = 30).

View larger version (28K): [in this window] [in a new window]   Figure 6.   Analysis of the vesicle pools, release probabilities, and Ca2+ sensitivities in D232N and D238N mutant neurons in comparison with wild-type (WT) neurons. A, Quantitative analysis of evoked responses and the sizes of the readily releasable vesicle pools of excitatory neurons of D232N and D238N excitatory neurons. Mean amplitudes and pool sizes were normalized to the mean values from the littermate wild-type neurons. B, The vesicular release probability was then calculated as the percentage of action potential evoked vesicles compared with the readily releasable pool. Data shown are means ± SEMs from the number of cells shown in parentheses in the bars. C, Evaluation of synaptic release probability from D232N and wild-type neurons. The rate of use-dependent block of NMDA-EPSCs in the presence of the irreversible open channel blocker MK-801 (5 µM) was not different between D232N and wild-type neurons, indicating that release probability was unchanged by the mutation. D, Ca2+ dependence of evoked release. EPSCs were evoked in 12 mM external Ca2+ and 1 mM Mg2+. Presynaptic Ca2+ influx was varied by adding various concentrations of Cd2+ (3-100 µM) to the external medium (n = 7-35 per concentration). Solid lines are best fits to a logistic hill function to determine the IC50 value for Cd2+.

Accordingly, because neither evoked response nor RRP was different between mutants and wild type, we expect that the probability of an individual fusion competent vesicle to exocytose after arrival of an action potential, the vesicular release probability (P_vr), is also unchanged. This probability can be reliably determined when both the charge of the synaptic responses and the charge of the RRP are recorded in the same neuron and can be computed by simply dividing EPSC charge by readily releasable pool charge. Indeed, we found that the average P_r was unchanged and was ~6% for all groups tested (Fig. 6) and similar to other previously reported values for wild-type cells (Rosenmund and Stevens, 1996; Fernández-Chacón et al., 2001).

In the R233Q mutant mice, the reduced vesicular release probability was accompanied by a reduced synaptic release probability and a reduced apparent Ca²⁺ sensitivity of triggered release. A detailed analysis of the synaptic release probability and apparent Ca²⁺ sensitivity in the D232N mutant mice did not reveal any significant changes compared with wild types (Fig. 6C,D). Synaptic release probability can be reliably determined by the degree of NMDA-EPSC depression during synaptic stimulation in the presence of the use-dependent NMDA channel blocker MK-801 (Rosenmund et al., 1993). The stimulus-dependent decrease of the NMDA-EPSC amplitude was not significantly changed in the D232N mutant neurons compared with wild-type cells (Fig. 6C). The apparent sensitivity of Ca²⁺-triggered release was tested by systematically blocking Ca²⁺ channel with Cd²⁺. We added different concentrations of Cd²⁺ (3-100 µM) to the external solution with constant concentrations of other external divalent cations (12 mM Ca²⁺, 1 mM Mg²⁺). In this routine, only the amount of Ca²⁺ influx is altered without changing axonal excitability. The inhibition of EPSC amplitude as a function of [Cd²⁺]₀ was very similar in D232N mutants and wild types, with IC₅₀ values for Cd²⁺ of 25 and 27 µM, respectively (Fig. 6D).

Effects of the D232N and D238N mutations on the double C₂ domain fragment

The relatively mild phenotype caused by the D232N mutation and the absence of a phenotype in the D238N mice were initially surprising considering the severe effects of these mutations on intrinsic Ca²⁺ binding and on Ca²⁺-dependent phospholipid binding to the isolated C₂A domain. To test whether the native synaptotagmin 1 proteins expressed in the knock-in mice also exhibit a severe impairment on phospholipid binding, we obtained native soluble C₂A/C₂B domain fragments by limited trypsin digestion of brain membranes from the mice and analyzed their ability to bind to phospholipids (Fig. 7A). Because synaptotagmin 1 also binds to the SNARE protein syntaxin 1 in a Ca²⁺-dependent manner, we also tested the solubilized C₂A/C₂B domain fragments for syntaxin 1 binding (Fig. 7B). No changes in either phospholipid or syntaxin 1 binding were detected, as far as was discernable with the relatively limited assays available. Thus, in contrast to the isolated C₂A domain, the D232N and D238N mutations do not cause a major impairment of the Ca²⁺-binding properties of the double C₂ domain fragment as opposed to the R233Q mutation, which affected both the isolated C₂A domain and the double C₂ domain fragment (Fernández-Chacón et al., 2001).

View larger version (80K): [in this window] [in a new window]   Figure 7.   The D232N and D238N mutations do not cause a significant change in Ca2+-dependent phosphopholipid and syntaxin binding by native synaptotagmin 1. A, Soluble C2A/C2B domain fragments of native synaptotagmin 1 were obtained from wild-type and mutant littermate mice by partial trypsin digestion of brain membranes followed by centrifugation. The soluble C2A/C2B domain fragment released into the supernatant was used for binding experiments with liposomes at the indicated free Ca2+ concentrations. Input and bound proteins were then analyzed by immunoblotting using a monoclonal synaptotagmin 1 antibody. The two mutations were analyzed in independent experiments with their littermate wild-type controls, resulting in separate wild-type controls for each mutant. Numbers on the left indicate positions of size markers. B, GST-pulldown experiments of the soluble C2A/C2B domain fragment of synaptotagmin 1 isolated as described above. Proteins were bound to GST and GST-syntaxin (residues 180-264) at the indicated concentrations of free Ca2+ as described in A, and bound proteins were visualized by immunoblotting.

The different effects of the D232N and D238N mutations on the Ca²⁺-dependent phospholipid binding properties of the isolated C₂A domain and the native C₂A/C₂B domain fragments obtained from the knock-in mice suggest that there is functional cooperation between the two C₂ domains of synaptotagmin 1. Although initially this explanation seemed unlikely because the C₂B domain was believed to be unable to bind phospholipids in a Ca²⁺-dependent manner (Schiavo et al., 1996; Bai et al., 2000), during the course of this study we found that the isolated C₂B domain indeed exhibits Ca²⁺-dependent phospholipid binding when properly purified (Fernández et al., 2001). In addition, partial redundancy between the C₂A and C₂B domain in phospholipid binding to the double C₂ domain region has been described recently (Earles et al., 2001), although these results should be interpreted with caution because the isolated C₂B domain did not bind phospholipids in the assay used in this study. To further understand the interplay between the synaptotagmin 1 C₂ domains in phospholipid binding, we used recombinant proteins spanning the double C₂ domain region. Similar to the C₂B domain, the double C₂ domain fragment has a tendency to bind bacterial contaminants that are difficult to remove on GST-affinity resins (Ubach et al., 2001). Therefore we purified the recombinant proteins in solution and used a liposome centrifugation assay rather than GST pulldowns. The wild-type double C₂ domain fragment displayed a significantly higher apparent Ca²⁺ affinity in the presence of phospholipids (~3 µM Ca²⁺) than each isolated C₂ domain (~10 µM Ca²⁺) (Fig. 3), confirming that the two C₂ domains cooperate in lipid binding. In addition, the D232N and D238N mutations had no significant effect on the apparent Ca²⁺ affinity or the amount of phospholipid binding to the recombinant double C₂ domain fragment at physiological ionic strength (Fig. 3), as observed for the native proteins isolated from the knock-in mice (Fig. 7). To explore whether the mutations caused a change in the strength of phospholipid binding, we performed centrifugation assays at different salt concentrations. NaCl had a marked effect on Ca²⁺-dependent phospholipid binding to the wild-type double C₂ domain fragment (Fig. 8), showing that the mutations have an effect on the tightness of binding.

View larger version (58K): [in this window] [in a new window]   Figure 8.   Salt sensitivity of the Ca2+-dependent complex of the wild-type and mutant double C2 domain fragment from synaptotagmin 1. The double C2 domain fragments were bound to liposomes in the presence of 50 µM Ca2+ and the indicated concentrations of NaCl. Double C2 domain proteins attached to the liposomes after centrifugation were analyzed by SDS-PAGE and Coomassie staining. Note especially that the D238N mutation destabilized the Ca2+-dependent phospholipid complex.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In the present study we have probed the functional importance of Ca²⁺ binding to the C₂A domain of synaptotagmin 1. Two point mutations in the Ca²⁺ ligands of the C₂A domain, D232N and D238N, severely affected intrinsic Ca²⁺ binding and Ca²⁺-dependent phospholipid binding to the isolated C₂A domain. Interestingly, these mutations had little effect on the Ca²⁺-dependent phospholipid binding properties of the double C₂ domain region of synaptotagmin 1 and did not cause major changes in synaptic transmission when introduced into knock-in mice by homologous recombination. D238N mutant mice exhibited no synaptic phenotype, whereas D232N mutant mice displayed only a small but significant increase in synaptic depression. These data show that C₂ domain mutations like the D232N or D238N substitutions, which alter only the Ca²⁺-dependent properties of an isolated C₂A domain but not of the double C₂ domain fragment, do not have a major effect on the overall function of synaptotagmin 1. In contrast, C₂ domain mutations like the R233Q substitution, which decreases the apparent Ca²⁺ affinity of both the isolated C₂A domain and the double C₂ domain fragment, result in a major corresponding change in the function of synaptotagmin 1 (Fernández-Chacón et al., 2001). Together these results suggest that the two C₂ domains of synaptotagmin 1 function as a single cooperative unit whose overall Ca²⁺-binding properties, and not the Ca²⁺-binding properties of its isolated constituents, determine Ca²⁺-triggered neurotransmitter release.

Together with previous studies, our data lead to a model of how the synaptotagmin 1 C₂ domains form Ca²⁺-dependent phospholipid complexes that emphasizes both the interplay between different types of forces and the cooperation between the two C₂ domains (Fig. 9). This model is based on three fundamental observations. First, both C₂ domains individually engage in ternary complexes with phospholipids and Ca²⁺ (Davletov and Südhof, 1993; Chapman and Jahn, 1994; Fernández et al., 2001). Second, intrinsic Ca²⁺ binding to the C₂ domains is noncooperative and exhibits a low Ca²⁺ affinity but becomes cooperative and assumes a high Ca²⁺ affinity when C₂ domain/phospholipid complexes are formed (Zhang et al., 1998; Fernández-Chacón et al., 2001). Third, the C₂ domain/phospholipid/Ca²⁺ complex involves direct interactions of positively charged and hydrophobic residues of the C₂ domain with the phospholipid bilayer that can be as critical for the complex as the bound Ca²⁺ ions (Chapman and Davis, 1998; Zhang et al., 1998; Fernández-Chacón et al., 2001; Gerber et al., 2002). Thus at least three forces attach each C₂ domain to the phospholipid bilayer: the positive charges of the Ca²⁺ ions, positively charged amino acids (in particular R233 and K366), and hydrophobic residues that insert into the bilayer (in particular M173, F234, V304, and I367).

View larger version (41K): [in this window] [in a new window]   Figure 9.   Model of the Ca2+-dependent binding of synaptotagmin 1 C2 domains to phospholipid membranes. The two C2 domains of synaptotagmin 1 (which account for two-thirds of the total sequence) engage in similar but parallel interactions with phospholipid membranes that are fueled by three forces: positive charges supplied by bound Ca2+ ions that are sandwiched between negatively charged phospholipid head groups and C2 domain aspartate residues; positive charges supplied by arginine and lysine residues such as R233 and K366 at the top of the domain; and hydrophobic residues that insert at least partially into the bilayer, such as M173, F234, V305, and I367. In the absence of Ca2+, repulsion by the negatively charged aspartate residues on top of the C2 domains and the negatively charged phospholipid head groups prevents the positively charged and hydrophobic residues at the top of the domain to engage in interactions. Thus in addition to forming a bridge between the phospholipid head groups and the top loops of the C2 domains, Ca2+ ions also neutralize repulsive negative charges. The double C2 domains exhibit an approximately threefold higher apparent Ca2+ affinity than the individual isolated C2 domains when the two independent C2 domains become linked physically.

In agreement with this model, our data show that the Ca²⁺-dependent complex of the double C₂ domain fragment with phospholipids is sensitive to increases in ionic strength (Fig. 8), exhibits an increased apparent Ca²⁺ affinity compared with the individual C₂ domains (Fig. 3), and is less susceptible than the individual C₂ domains to mutations in Ca²⁺-binding sites (Figs. 3, 4). Thus, limited Ca²⁺ binding is sufficient to "switch on" the double C₂ domain fragment and to trigger complete membrane translocation of the entire fragment. Although the disruption of some C₂A domain Ca²⁺-binding sites by the D232N and D238N mutations yields a Ca²⁺/phospholipid complex with the double C₂ domain fragment that is less tight and more sensitive to ionic strength (Fig. 8), the complex is still sufficiently strong to persist at physiological salt concentrations. We have observed previously that the R233Q mutation decreases significantly the apparent Ca²⁺ affinity of both the single C₂A domain and the double C₂ domain region (Fernández-Chacón et al., 2001), whereas our current data show that the D232N and D238N mutations lead to a decrease only in the C₂A domain but not in the double C₂ domain. The differential impact of these mutations can be attributed to differences in the energetic contributions to phospholipid binding by the R233 side chain versus the second and third Ca²⁺-binding sites of the C₂A domain. Such differential contributions to overall binding energies are typical in protein-protein interactions where only a subset of the contacts in the interface, called "hot spots," usually accounts for most of the energy of binding (Cunningham and Wells, 1993). A possible alternative explanation for the synergistic effect revealed by the D232N and D238N mutations on the double C₂ domain fragment is that new Ca²⁺-binding sites are created in the double C₂ domain fragment that are not present in the individual C₂ domains and are formed by direct interactions between the C₂ domains (Garcia et al., 2000). This explanation was evoked previously to explain unexpected properties of the double C₂ domain fragment compared with the single C₂ domains, leading to the suggestion of "cryptic" Ca²⁺-binding sites in the C₂B domain (Bai et al., 2002). However, there is nothing cryptic about the Ca²⁺-binding sites of the C₂B domain because the isolated C₂B domain is a fully functional Ca²⁺-binding and Ca²⁺-dependent phospholipid binding domain (Fernández et al., 2001). Furthermore, direct NMR studies of the double C₂ domain fragment indicate that the two C₂ domains do not interact with each other at Ca²⁺ concentrations between 0 and 20 mM in the absence of ternary components (J. Rizo, unpublished observation). Viewed together, it thus seems likely that the properties of the double C₂ domain fragment can be explained entirely by the model shown in Figure 9.

Our previous observation on the R233Q knock-in mice showed that a decrease in the apparent Ca²⁺ affinity of the double C₂ domain leads to a decrease in release probability. Now we have observed that the D232N and D238N mutations do not alter the phospholipid binding of the double C₂ domain and that these mutations do not have a major effect on neurotransmitter release in vivo. The observation that the D232N and D238N mutations in the knock-in mice did not cause a large change in synaptotagmin function shows that the biochemical cooperation of the synaptotagmin C₂ domains in phospholipid binding translates into functional cooperation in vivo. We did observe, however, a significant enhancement in synaptic depression after repetitive stimulation in the D232N knock-in mice. Because analysis of cultured hippocampal neurons is sensitive to artifacts caused by differences in the genetic background of mice and drifts in culture conditions, we analyzed the synaptic properties of the mutant neurons under tightly controlled conditions. All analyses were performed simultaneously for mutant and control neurons obtained from littermates, with the control consisting of mice derived by homologous recombination with a neomycin gene cassette in an intron, but without a mutation in the synaptotagmin 1 gene. The best internal but somewhat involuntary control for the specificity of the D232N mutant phenotype, however, was provided by the D238N mutant mice, which did not exhibit such phenotype. In contrast to our previous study examining the impact of the R233Q mutation, we were unable to link the significant change in short-term plasticity for the D232N mutant (Fig. 5) to any significant changes in vesicular or synaptic release probability or to a shift in the apparent Ca²⁺ sensitivity of neurotransmitter release. Either the change is too small to be detectable by these methods, or perhaps more likely, the synaptic depression is not caused directly by a change in release probability or Ca²⁺ sensitivity of release.

We were also unable to find a defined correlation between the phenotype of the D232N mice and the Ca²⁺-dependent phospholipid or syntaxin 1-binding properties of the double C₂ domain region of synaptotagmin 1. The slight increase in the apparent Ca²⁺ affinity of the residual phospholipid binding to the isolated D232N C₂A domain mutant (Fig. 2) could potentially underlie this phenotype. However, we could not detect such an increase in the context of the double C₂ domain fragment within the limits of the centrifugation assay used. In any case, neurotransmitter release is an exquisitely regulated process, and it is thus not surprising if subtle biochemical changes in the Ca²⁺ sensor, which may be difficult to detect with assays performed in vitro with limited components, translate into more significant changes in the properties of neurotransmitter release. Moreover, the lack of a correlation of short-term plasticity with release probabilities or Ca²⁺ sensitivity of release, and the differential effects of the D232N mutation and D238N mutations in phospholipid binding and synaptic physiology, support the notion that the function of the C₂A domain in triggering Ca²⁺-dependent neurotransmitter release is complex. Therefore, additional yet unidentified molecular targets may be important for regulating Ca²⁺-triggered release, although the Ca²⁺-dependent interaction of synaptotagmin 1 with syntaxin 1 appeared unchanged. Future experiments will have to address the relative merits of these possibilities.

Note added in proof. Similar results were recently obtained in Drosophila with a single DN mutant, although the biochemical consequences of the mutation were not studied with assays that detect phospholipid binding to the C₂B domain (Robinson et al., 2002).

	FOOTNOTES

Received April 22, 2002; revised July 3, 2002; accepted July 3, 2002.

This study was supported by Grant NS40944 from the National Institutes of Health to J.R., Grant Ro1296/5-1 from the Deutsche Forschungsgemeinschaft to C.R., and postdoctoral fellowships from the Spanish Ministry of Education and the Fulbright Commission to R.F.C. and the Deutsche Forschungsgemeinschaft to S.H.G, and a fellowship from the Boehringer Ingelheim Fonds to A.C.M. We thank Ina Herfort, Izabella Leznicki, and Andrea Roth for excellent technical assistance, Nicole Hamlin (University of Texas Southwestern Medical Center, Dallas, TX) and Dr. Hermann Riedesel, Jürgen Krause, and Stefan Röcklin (Max-Planck-Institut für experimentelle Medizin, Göttingen) for outstanding help with mouse husbandry, and Dr. E. Neher and Dr. R. Jahn for advice.

Correspondence should be addressed to Dr. Christian Rosenmund, Department Membranbiophysik, Max-Planck-Institut für biophysikalische Chemie, Am Fassberg, D-37070 Göttingen, Germany. E-mail: crosenm{at}gwdg.de.

R. Fernández-Chacón's present address: Departamento Fisiología Médica y Biofísica, Universidad de Sevilla, Avenida Sánchez-Pizjuán 4, 41009 Sevilla, Spain.

S. Gerber's present address: Universitaet Heidelberg, 69115 Heidelberg, Germany.

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