Phosphorylation of Synaptic Vesicle Protein 2A at Thr84 by Casein Kinase 1 Family Kinases Controls the Specific Retrieval of Synaptotagmin-1

Synaptic vesicle protein 2A (SV2A) is a ubiquitous component of synaptic vesicles (SVs). It has roles in both SV trafficking and neurotransmitter release. We demonstrate that Casein kinase 1 family members, including isoforms of Tau–tubulin protein kinases (TTBK1 and TTBK2), phosphorylate human SV2A at two constellations of residues, namely Cluster-1 (Ser42, Ser45, and Ser47) and Cluster-2 (Ser80, Ser81, and Thr84). These residues are also phosphorylated in vivo, and the phosphorylation of Thr84 within Cluster-2 is essential for triggering binding to the C2B domain of human synaptotagmin-1. We show by crystallographic and other analyses that the phosphorylated Thr84 residue binds to a pocket formed by three conserved Lys residues (Lys314, Lys326, and Lys328) on the surface of the synaptotagmin-1 C2B domain. Finally, we observed dysfunctional synaptotagmin-1 retrieval during SV endocytosis by ablating its phospho-dependent interaction with SV2A, knockdown of SV2A, or rescue with a phosphorylation-null Thr84 SV2A mutant in primary cultures of mouse neurons. This study reveals fundamental details of how phosphorylation of Thr84 on SV2A controls its interaction with synaptotagmin-1 and implicates SV2A as a phospho-dependent chaperone required for the specific retrieval of synaptotagmin-1 during SV endocytosis.


Introduction
Synaptic vesicle protein 2 (SV2A, SV2B, and SV2C) isoforms are all integral 12 transmembrane domain synaptic vesicle (SV) proteins. SV2A is the most widely distributed SV2 isoform and is ubiquitously expressed in the CNS, whereas SV2B is brain specific with SV2C the minor isoform (Buckley and Kelly, 1985;Bajjalieh et al., 1994).
SV2A knock-out mice are normal at birth but fail to grow and experience severe seizures before premature death after 3 weeks attributable to multiple neural and endocrine deficits (Crowder et al., 1999), indicating that SV2A plays key roles in postnatal brain function. It has been proposed to function as a positive effector of SV exocytosis, potentially by binding calcium (Mendoza-Torreblanca et al., 2013). All SV2 isoforms possess an N-terminal cytoplasmic domain that interacts with another integral SV protein, synaptotagmin-1 (Syt1; Schivell et al., 1996;Schivell et al., 2005;Lazzell et al., 2004). Synaptotagmin-1 is the key Ca 2ϩ sensor for evoked synchronous neurotransmitter release at the synapse (Brose et al., 1992;Geppert et al., 1994), and thus its efficient incorporation into newly formed SVs during endocytosis is essential to maintain the fidelity of neurotransmission. Disruption of SV2A retrieval during SV endocytosis results in accumulation of synaptotagmin-1 on the plasma membrane of central nerve terminals (Yao et al. 2010), suggesting that SV2A may be required for efficient packaging of this essential calciumsensing protein into SVs.
Relatively little is understood regarding how SV2 isoforms are regulated. Global phosphorylation site mass spectrometry studies have revealed that SV2A is potentially phosphorylated on at least 10 residues within its N-terminal cytoplasmic region (http://www.phosphosite. org/proteinAction.do?idϭ8509&showAllSitesϭtrue). To our knowledge, only one other investigation has analyzed the regulation of SV2A by phosphorylation (Pyle et al., 2000). This study identified an SV-associated kinase that phosphorylated the N-terminal cytoplasmic domain of SV2A. In gel kinase assays and the use of a Casein kinase 1 (CK1) inhibitor (CK1-7) suggested that this kinase was a member of the CK1 group of eukaryotic protein kinases (Pyle et al., 2000). Intriguingly, in vitro phosphorylation of a recombinant N-terminal fragment of SV2A comprising the cytoplasmic domain by CK1 increased its ability to interact with recombinant synaptotagmin-1 approximately threefold (Pyle et al., 2000).
To date, no studies have determined the site(s) phosphorylated by CK1 isoforms within the SV2A N-terminal cytoplasmic domain and how phosphorylation of these residues stimulates recruitment of synaptotagmin-1 and/or influences SV trafficking. In this study, we demonstrate that CK1 and Tau-tubulin protein kinase (TTBK) isoforms efficiently phosphorylate the N-terminal cytoplasmic domain of SV2A within two constellations, namely Cluster-1 (Ser42, Ser45, and Ser47) and Cluster-2 (Ser80, Ser81, and Thr84). We demonstrate that phosphorylation of Thr84 in Cluster-2 is key in triggering binding to synaptotagmin-1. Crystallographic analysis revealed that the phosphorylated Thr84 residue specifically bound to a pocket formed by three conserved Lys residues (Lys314, Lys326, and Lys328) on the surface of the synaptotagmin-1 C2B domain. Finally, we present evidence that phosphorylation of SV2A at Cluster-2 is essential for the efficient retrieval of synaptotagmin-1 during SV endocytosis.

Materials and Methods
Materials. Synaptotagmin-1-pHluorin (Syt1-pHluorin) and synaptophysin-pHluorin constructs were provided by Prof. V. Haucke (WT) or eight Ser/ Thr to A mutants] with GST tag were expressed and purified from HEK293 cells transfected with corresponding constructs [WT, DU number 38880; eight S(T)/A, DU number 44610]. The WT and phosphorylation site(s) mutants full-length SV2A proteins were expressed and purified from HEK293 cells for analyzing the phosphorylation on SV2A in vivo by mass spectrometry. All other reagents were obtained from Sigma-Aldrich. All recombinant proteins, plasmids, and antibodies generated for the present study are available on request and are described in additional detail on our reagents website (https://mrcppureagents. dundee.ac.uk/).
General methods. Recombinant DNA procedures were performed using standard protocols. Mutagenesis was performed using the QuikChange site-directed mutagenesis kit (Stratagene) with KOD polymerase (Novagen). DNA constructs were purified from E. coli DH5␣ using a maxi prep kit (Qiagen) according to the instructions of the manufacturer. Verification of the constructs was performed by the Sequencing Service [Medical Research Council Protein Phosphorylation Unit (MRC-PPU), College of Life Sciences, University of Dundee, Dundee, Scotland, UK; ]. DNA for bacterial protein expression was transformed into E. coli BL21-CodonPlus (DE3)-RIL cells (Stratagene).
Plasmid generation. Mouse SV2A was amplified from IMAGE EST6493509 using KOD Hot Start DNA Polymerase (Merck Millipore), cloned into pSC-b (Agilent), and sequenced to completion. This was then ligated into the BglII NotI sites in pCMV mCerulean (mCer) N1 (Anggono et al., 2006). Mutations and shRNA-resistant versions were created using the Quick Change method (Agilent) but using KOD DNA Hot Start polymerase. SV2A-pHluorin was created in a Clontech EGFP-C1 backbone by replacing EGFP with human SV2A using XhoI and AgeI restriction enzymes. The fluorescent pHluorin protein was then inserted between amino acids 197 and 198 at a PclI restriction enzyme site (DU number 42587).
SV2A knockdown was achieved using the published oligonucleotide sequence (GAATTGGCTCAGCAGTATGttcaagagaCATACTGCTGAG CCAATTC) against the rat sequence of SV2A that is identical to the mouse sequence (shRNA1; Dong et al. 2006). Oligonucleotides were ligated into the BglII HindIII sites of pSUPER mCer (Clayton et al., 2010). The SYN1 promoter-driven pHluorin-rSYT1-BGH pA cassette was amplified by adding flanking BglII and SmaI restriction sites and ligated into either vectors pSuper.Neo mCer or pSuper.Neo mCer mSV2A shRNA1 after digestion.
Identification of phosphorylation sites. HEK293 cells were transfected with a construct encoding WT and the indicated mutants of full-length Flag-SV2A. Thirty-six hours after transfection, cells were lysed, and Flag-SV2A was purified by immunoprecipitation and incubated with recombinant WT TTBK2  or kinase inactive (KD) TTBK2[D163A, 1-316] and Mg 2 -[-32 P]ATP for 60 min. Samples were subjected to electrophoresis on a polyacrylamide gel that was stained with colloidal Coomassie blue and autoradiographed. Phosphorylated SV2A was digested with trypsin, and the peptides were separated on a reverse-phase HPLC Vydac C 18 column (catalog #218TP5215; Separations Group) equilibrated in 0.1% (v/v) trifluoroacetic acid, and the column developed with a linear acetonitrile gradient at a flow rate of 0.2 ml/min. Fractions (0.1 ml each) were collected and analyzed for 32 P radioactivity by Cerenkov counting. Phosphopeptides were analyzed by liquid chromatography (LC)-MS/MS using a Thermo U3000 RSLC nano liquid chromatography system (Thermo Fisher Scientific) coupled to a Thermo LTQ-Orbitrap Velos mass spectrometer (Thermo Fisher Scientific). Data files were searched using Mascot (www.matrixscience.com) run on an in-house system against a database containing the appropriate SV2A sequences, with a 10 ppm mass accuracy for precursor ions, a 0.6 Da tolerance for fragment ions, and allowing for Phospho (ST), Phospho (Y), Oxidation (M), and Dioxidation (M) as variable modifications. Individual MS/MS spectra were inspected using Xcalibur 2.2 (Thermo Fisher Scientific), and Proteome Discoverer with phosphoRS 3.1 (Thermo Fisher Scientific) was used to assist with phosphosite assignment. The site of phosphorylation of 32 P-labeled peptides was determined by solid-phase Edman degradation on a Shimadzu PPSQ33A Sequencer of the peptide coupled to Sequelon-AA membrane (Applied Biosystems) as described previously (Campbell and Morrice, 2002). The above LC-MS/MS approach was also used for the analysis of phosphosites on mouse brain SV2A (Table 1) and on WT and mutant SV2A overexpressed in HEK293 cells (Table 2).
Isothermal titration calorimetry. Binding of SV2A peptides to synaptotagmin-1 was assayed by isothermal titration calorimetry (ITC)  Endogenous SV2A was immunoprecipitated from mouse brain extract (8 mg). The immunoprecipitates were electrophoresed on a polyacrylamide gel, and after Colloidal blue staining, bands corresponding to SV2A were excised and digested with trypsin. Phosphorylated peptides were identified by LC-MS/MS analysis. The data analysis was as in Materials and Methods. The sequence of each peptide is shown with possible phosphorylation sites underlined. Also shown are the mass of the peptide, the Mascot score ͓of the peptide identification, in which individual ion scores Ͼ21 indicate identity or extensive homology ( p Ͻ 0.05)͔, and the percentage probability of the phosphosite assignment, as determined by the phosphoRS 3.1 component of the Proteome Discoverer 1.4 software.
using a VP-ITC microcalorimeter (MicroCal). Unphosphorylated or phosphorylated peptides (0.8 mM) of SV2A (residues 76 -90) were titrated into synaptotagmin-1 C2B domain (residues 270 -422, 0.04 mM), and enthalpic changes for each injection (5 l) were recorded while stirring at 300 rpm at a constant temperature of 25°C for 180 s. Injections were performed until a molar peptide/protein ratio of at least 2.5:1 was reached. The integrated binding isotherms for each injection were obtained from the enthalpic changes versus the ratios between peptide concentration and total protein concentration using data analysis software Origin 7.0 (including MicroCal add-on; OriginLab). Single or multiple independent site models were then fitted to the data by nonlinear regression in Origin 7.0 with the MicroCal ITC patch installed. The model with the lowest 2 fit by least-squares analysis was used to obtain the K d apparent. The first injection (2 l) was excluded from the analysis. In all cases, an independent single sites model provided the best fit with an overall stoichiometry of 1 Ϯ 0.3. Protein purification and crystallization of synaptotagmin-1 C2B domain. Recombinant human synaptotagmin-1 C2B domain (residues 270 -422) was overexpressed in E. coli BL21 (DE3; Studier and Moffatt, 1986) with an N-terminal GST tag and TEV-protease cleavage site from construct DU number 44151 (MRC-PPU). Bacterial cells were grown in 50 ml of Luria-Bertani (LB) broth supplemented with 100 mg/ml ampicillin (Amp) at 37°C for 16 h and subsequently used to inoculate 950 ml of LB broth (with Amp) in baffled 2 L flasks. Cultures were grown at 37°C for ϳ5 h with vigorous shaking at 180 rpm until an optical density of ϳ0.6 at 600 nm was reached, and overexpression was subsequently induced with 0.25 mM isopropyl ␤-D-1-thiogalactopyranoside at 19°C for 16 h. Bacterial cells were harvested by centrifugation at 5000 ϫ g and 4°C for 15 min, and the cell pellet was resuspended in 50 mM HEPES, pH7.5, and 250 mM NaCl, supplemented with protease inhibitor cocktail (Calbiochem). Cells were lysed by freeze-thawing at Ϫ80°C, followed by sonication on ice, and the cell extract was cleared from intact cells and debris by centrifugation at 30,000 ϫ g and 4°C for 20 min.
GST-tagged protein was purified by affinity chromatography in a 16/20 XK column (GE Healthcare) packed with 10 ml of glutathione Sepharose 4B (GE Healthcare) in 50 mM HEPES, pH 7.5, and 250 mM NaCl, and bound protein was eluted with 40 mM reduced glutathione, 50 mM HEPES, pH 7.5, and 250 mM NaCl. Purified protein was cleaved with TEV protease (DU6811; MRC-PPU) in 50 mM HEPES, pH 7.5, 250 mM NaCl, and 40 mM reduced glutathione on ice overnight and subsequently desalted and eluted into 50 mM HEPES, pH 7.5, using a HiPrep 26/10 desalting column (GE Healthcare). Cleaved protein was further purified by ion exchange chromatography using a 16/20 XK column packed with 10 ml of Source 15S matrix (GE Healthcare), which was equilibrated in 50 mM HEPES, pH 7.5, and bound protein was eluted in a linear concentration gradient from 0 to 50% in five column volumes of 50 mM HEPES, pH 7.5, and 1 M NaCl. Fractions containing cleaved synaptotagmin-1 C2B domain fragment were finally purified by size exclusion chromatography in a HiLoad 16/600 Superdex 200 PG column (GE Healthcare) in 50 mM HEPES, pH 7.5, and 50 mM NaCl. Protein purity and quality was monitored by SDS-PAGE, followed by staining with Coomassie Brilliant Blue, and protein concentration was estimated with a NanoDrop photospectrometer (Thermo Fisher Scientific) using the theoretical extinction coefficient and molecular mass of the protein sequence using the PROTPARAM web server (Gasteiger et al., 2005).
Purified human synaptotagmin-1 C2B domain (residues 270 -422) was crystallized with the synthetic peptide of SV2A (residues 76 -90), which was phosphorylated at Thr84. Commercially available crystallization screens were used to find preliminary conditions for protein crystallization, and a Mosquito Crystal liquid handling robot (TTP Labtech) was used to spot 0.2 l of protein/peptide solutions (molar ratio of 1:3) and 0.2 l of reservoir solution into 96-well MRC plates (Hampton Research). Initial protein crystals were obtained by sitting drop vapor diffusion at 291 K in Index HT, Crystal Screen HT, and PEG/Ion HT crystallization screens (Hampton Research) and were subsequently manually optimized. Final crystallization using hanging-drop vapor diffusion at 291 K was set up by co-crystallizing 0.5 mM synaptotagmin-1 C2B with 1.4 mM SV2A peptide [EGGASSDA(pT)EGHDED], which was com-bined with reservoir solution consisting of 0.1 M HEPES, pH 7.5, 18% polyethylene glycol (PEG) 3350, and 50 mM CaCl 2 in a 1:1 ratio.
x-Ray data collection and structure determination and refinement crystals were soaked in 25% glycerol, 20% PEG 3350, 100 mM, and 50 mM CaCl 2 for 5 min and flash frozen in liquid nitrogen. Diffraction data was obtained at 100 K using a Rigaku MicroMax-007 rotating anode x-ray generator (1.54 A(Angstrom)) coupled to a Saturn 944 CCD detector and processed using the XDS program package (Evans, 2006). Diffraction images of two reflection sets from one crystal were scaled and merged using Aimless version 0.2.17, and Laue groups were determined with Pointless version 1.8.17 (Evans and Murshudov, 2013) within the CCP4 program suite (Kabsch, 2010). The crystals were packed in the monoclinic space group P1211 and crystallized to 1.87 Å resolution, which was cut to 1.95 Å to obtain Ͼ90% completeness for the outer shell.
The synaptotagmin-1 C2B domain structure was solved using PHENIX Phaser version 2.5.5 (McCoy et al., 2007) by molecular replacement with Protein Data Bank (PDB) entry 1TJX (Cheng et al., 2004) as input template. The model was refined by iterative operations using PHENIX Refine version 1.8.3 (Adams et al., 2010) in combination with manual model building in COOT (Emsley and Cowtan, 2004). Residues 81-90 of the SV2A peptide and solvent molecules were added manually to the model according to electron-and difference-density maps. A difference map of the Apo protein of Syt1 was created in Phenix Refine after initial refinements without the SV2A peptide chain included in the model. Illustrations were prepared with PyMol (http://www.pymol.org/), and electrostatics representations were calculated using the APBS plugin (Baker et al., 2001).
For fluorescence polarization assays, 0-20 M protein of synaptotagmin-1 C2B domain (residues 270 -422) was titrated into 0.1 M FlAsH-labeled peptide in 30 l of 50 mM HEPES-NaOH, pH 7.5, and 50 mM NaCl in black 384-well assay plates (Corning). Fluorescence polarization was monitored at 485 nm excitation and 520 nm emission using a Pherastar FS plate reader (BMG Labtech) and plotted against synaptotagmin-1 C2B concentration. A nonlinear one-site binding model with Hill slope was fitted to the data points using analysis software Prism 6 (GraphPad Software).
Hippocampal neuronal cultures. Dissociated primary hippocampal enriched neuronal cultures were prepared from both male and female E17.5 C56BL/6J mouse embryos by trituration of isolated hippocampi to obtain a single-cell suspension, which was plated at a density of 5 ϫ 10 5 cells per coverslip on poly-D-lysine and laminin-coated 25 mm coverslips. Cultures were maintained in Neurobasal media supplemented with B-27, 0.5 mM L-glutamine, and 1% v/v penicillin/streptomycin. After 72 h, cultures were further supplemented with 1 M cytosine ␤-Darabinofuranoside to inhibit glial proliferation. Cells were transfected after 7-8 d in culture with Lipofectamine 2000 as described previously (Gordon et al., 2011). In all experiments, two constructs were coexpressed; either Syt1-pHluorin or synaptophysin-pHluorin was cotransfected with either mCer empty vector or mCer-pSUPER shRNA vectors. In addition, mCer-SV2A was coexpressed with a pSUPER shRNA vector, which expressed Syt1-pHluorin. Neurons were imaged after 13-16 d in culture.
Immunolabeling. Immunolabeling of transfected cultured hippocampal neurons was performed as described previously (Gordon et al., 2011). Syt1-pHluorin expression was visualized at 480 nm, whereas SV2A expression was visualized at 550 nm. Identically sized regions of interest were placed over transfected Syt1-pHluorin puncta and nontransfected puncta in the same field of view, along with background regions. The level of SV2A expression was calculated by subtracting background autofluorescence before rationing transfected/nontransfected SV2A expression levels.
Fluorescent imaging of pHluorin trafficking. Hippocampal cultures were mounted in a Warner imaging chamber with embedded parallel platinum wires (RC-21BRFS) and placed on the stage of Zeiss Axio Observer D1 epifluorescence microscope. Neurons transfected with mCer vectors were visualized with a Zeiss Plan Apochromat 40ϫ oilimmersion objective (numerical aperture 1.3) at 430 nm excitation, whereas pHluorin reporters were visualized at 500 nm (both using a dichroic filter Ͼ525 nm and long-pass emission filter Ͼ535 nm). Cultures were stimulated with a train of 300 action potentials delivered at 10 Hz (100 mA, 1 ms pulse width). Cultures were subjected to continuous perfusion at room temperature (23°C) with imaging buffer (136 mM NaCl, 2.5 mM KCl, 2 mM CaCl 2 , 1.3 mM MgCl 2 , 10 mM glucose, and 10 mM HEPES, pH 7.4, supplemented with 10 M 6-cyano-7-nitroquinoxaline-2,3-dione and 50 M DL-2-amino-5-phosphonopentanoic acid). After stimulation, cultures were then challenged with alkaline imaging buffer (50 mM NH 4 Cl substituted for 50 mM NaCl) to reveal total pHluorin fluorescence. Fluorescent images were captured at 4 s intervals using a Hamamatsu Orca-ER digital camera and processed offline using NIH Image J 1.43 software. Regions of interest of identical size were placed over nerve terminals, and the total fluorescence intensity was monitored over time.
Only regions that responded to action potential stimulation were selected for analysis. All statistical analyses were performed using Microsoft Excel and Prism software (GraphPad Software). The pHluorin fluorescence change was calculated as ⌬F/F 0 .
Surface fraction of Syt1-pHluorin. Estimation of surface Syt1-pHluorin was performed by perfusing acidic imaging buffer (substituting 20 mM MES for HEPES, pH 5.5) over cultures for 30 s (to quench surface Syt1-pHluorin), followed by a 1 min perfusion with imaging buffer, pH 7.4. Cultures were then subjected to alkaline imaging buffer for 30 s to reveal total Syt1-pHluorin. The surface fraction of Syt1-pHluorin as a percentage of total was estimated using the following equation: (neutral fluorescence Ϫ acidic fluorescence/alkali fluorescence Ϫ acidic fluorescence) ϫ 100.
Statistical analysis. In all cases, n refers to the number of independent experiments performed. All statistical analyses were performed using Prism software (GraphPad Software), and all data were tested by Student's t test with the exception of pHluorin time course experiments (two-way ANOVA) and Syt1-pHluorin surface expression during SV2A knockdown (one-way ANOVA).
To map the phosphorylation sites on SV2A, we used fulllength SV2A isolated from a HEK293 cell overexpression system, using TTBK2[1-316] that our in vitro studies suggested was the most efficient CK1 family kinase at phosphorylating SV2A in vitro. Consistent with data shown in Figure 1, we found that WT but not a kinase-inactive fragment of TTBK2 phosphorylated full-length SV2A ( Fig. 2A). TTBK2[1-316] 32 P-phosphorylated full-length SV2A was digested with trypsin, and the resultant tryptic peptides were analyzed by chromatography on a C 18 column (Fig. 2B). The major 32 P-labeled phosphopeptides were subjected to mass spectrometry and solid-phase Edman sequencing to identify the phosphorylation sites. This analysis resulted in the identification of 8 phosphorylation sites (Ser42, Ser45, Ser47, Ser62, Ser80, Ser81, Thr84 and Ser127; Fig. 2C). These phosphorylation sites are all located within the N-terminal 160 residue cytoplasmic domain of SV2A (Fig. 2D). Sequence alignment indicates that the evolutionary conserved CK1 phosphorylation sites on SV2A lie within two constellations that we have termed here Cluster-1 (Ser42, Ser45, and Ser47) and Cluster-2 (Ser80, Ser81, and Thr84). The nonconserved Ser62 and Ser127 residues lie outside these clusters (Fig. 2E). Mutation of all eight phosphorylation sites on the full-length SV2A abolished phosphorylation by TTBK2[1-316] ( Fig. 2A). We were also able to monitor phosphorylation of SV2A by TTBK2[1-316] using phosphospecific antibodies that we generated that recognize SV2A after phosphorylation of either Cluster-1 or Cluster-2 residues ( Fig. 2A). This revealed that full-length SV2A isolated from HEK293 cells was detectably phosphorylated at Cluster-2 but not Cluster-1. After incubation with WT but not kinase-inactive TTBK2[1-316], phosphorylation of Cluster-1 sites became detectable and phosphorylation of Cluster-2 sites markedly increased.
We also compared the ability of TTBK and CK1 isoforms to phosphorylate mutants of SV2A[1-160] in which Cluster-1 (Ser42, Ser45, and Ser47) and/or Cluster-2 (Ser80, Ser81, and Thr84) residues are mutated to Ala to ablate phosphorylation. These studies revealed that all CK1 family kinases tested phosphorylated SV2A[1-160] at both Cluster-1 and Cluster-2 residues to differing extents, because phosphorylation of SV2A [1-160] was significantly suppressed after mutation of either Cluster-1 or Cluster-2 (Fig. 1). Moreover, mutation of both Cluster-1 and Cluster-2 residues virtually abolished phosphorylation of SV2A by this group of kinases, indicating that these sites do indeed comprise the major phosphorylation sites by the CK1 family. We were also able to monitor phosphorylation of SV2A by CK1 and TTBK isoforms that phosphorylated SV2A to the highest stoichiometry by using phosphospecific antibodies that we generated that recognize SV2A after phosphorylation of either Cluster-1 or Cluster-2 residues (Fig. 1).

Phosphorylation of SV2A at Ser80/Ser81 and Thr84 in vivo
We next analyzed the phosphorylation of SV2A in vivo. Endogenous SV2A immunoprecipitated from mouse brain was resolved in SDS-PAGE (data not shown) from which two major bands corresponding to SV2A were excised and subjected to mass spectrometry analysis (one band migrated beyond 150 kDa maker, whereas the other was between the 75 and 100 kDa markers).
Peptides matching mouse SV2A sequence were identified from both excised bands, indicating these two distinguishable bands from SDS-PAGE correspond to SV2A. The significant mass difference between the product ions from modified and unmodified peptides (data not shown) allowed us to identify the phosphorylated peptides from SV2A (Table 1). Other than Ser393, all of the identified phosphorylation sites (Table 1) accumulated in the N-terminal cytoplasmic region (residue 1-169) of SV2A, predominantly in the Cluster-2 phosphorylation sites (Fig. 1).
CK1 isoforms are known to preferentially phosphorylate a Ser/Thr residue in a protein that is "primed" by previous phos-phorylation at the Ϫ3 position (corresponding to Ser81 relative to Thr84 in SV2A; Flotow et al., 1990). In addition, a Ϫ4 position acidic or phosphorylated residue (corresponding to Ser80 relative to Thr84 in SV2A) has also been reported to facilitate phosphorylation (Meggio et al., 1991). Therefore, it is possible that phosphorylation of Ser80/Ser81 might prime phosphorylation of Thr84. To test this possibility in vivo, we overexpressed WT or Ser/Thr to Ala mutant SV2A in HEK293 cells and assessed their phosphorylation state. As shown in Table 2, similar to what was observed in mouse brain extract, WT SV2A was phosphorylated at the Cluster-2 sites (Ser81, Ser82, and Thr84; Table 2), vali-  -160] or indicated SV2A mutants in which either Cluster-1 (Ser42, Ser45, and Ser47; termed C1 Mutant) and/or Cluster-2 (Ser80, Ser81, and Thr84; termed C2 Mutant) phosphorylation sites were mutated to Ala to prevent phosphorylation. Reactions were left to proceed for 30 min at 30°C, subjected to electrophoresis on a polyacrylamide gel, stained with colloidal Coomassie blue, and autoradiographed. The Coomassie blue-stained SV2A[1-160] band was excised, and 32 P incorporation was assessed by Cerenkov counting. Relative phosphorylation of WT SV2A[1-160] by CK1 family kinases is indicated in the table. Reactions were also subjected to immunoblot analysis with the indicated phospho-specific antibodies that recognize phosphorylated Cluster-1 or Cluster-2 sites. All data are representative of at least two independent experiments. dating the utility of this overexpression system for studying SV2A phosphorylation in vivo. More importantly, no phosphorylated peptide covering Thr84 was identified in the absence of phosphorylation on either Ser80 or Ser81, whereas absence of phosphorylation of Thr84 had no significant effect on the phosphorylation of Ser80 and Ser81. Mutation of Ser80 and Ser81 to Ala also prevented phosphorylation of Thr84.
Cluster-2 phosphorylation promotes the ability of SV2A to bind synaptotagmin-1 To explore whether CK1-mediated phosphorylation of SV2A directly controlled its association with other protein(s), we generated biotinylated peptides that encompassed either the dephosphorylated or triply phosphorylated Cluster-1 (Ser42, Ser45, and Ser47) or Cluster-2 (Ser80, Ser81, and Thr84) residues of SV2A. These were conjugated to streptavidin-Sepharose and used in affinity purification studies to identify protein(s) that associated with the phosphorylated but not dephosphorylated peptides in mouse brain extract. Mass spectrometry analysis revealed that the major hit that associated with the phosphorylated peptide to a much greater extent than the dephosphorylated Cluster-2 peptide are the highly related synaptotagmin-1 and synaptotagmin-2 proteins. As mentioned in the Introduction, synaptotagmin-1 interacts with SV2A through its N-terminal domain (Schivell et al., 1996(Schivell et al., , 2005Lazzell et al., 2004;Fig. 3A). Immunoblot analysis confirmed that synaptotagmin-1 interacted with the Cluster-2 phosphorylated peptide but not with the dephosphorylated peptide (Fig. 3B). No clear-cut specific interactors to the Cluster-1 peptide were identified in parallel experiments (data not shown).
To obtain additional evidence that the interaction between SV2A and synaptotagmin-1 was promoted by phosphorylation, we immunoprecipitated SV2A from mouse brain and treated the immunoprecipitates in the presence or absence of lambda phosphatase. This revealed that treatment with lambda phosphatase lowered the level of synaptotagmin-1 associated with immunoprecipitated SV2A, and this effect was blocked by the addition of EDTA, which inhibits lambda phosphatase catalytic activity (Fig. 3C).

Phosphorylated Cluster-2 SV2A peptide interacts with synaptotagmin-1 C2B domain
Human synaptotagmin-1 is a 422 residue protein possessing a transmembrane membrane region at the N terminus (residues 58 -80) that anchors it to SV membranes, which is followed by two Ca 2ϩ -binding C2 domains termed C2A (residues 157-245) and C2B (residues 287-382). Synaptotagmin-1 operates as the key Ca 2ϩ sensor in SV trafficking and neurotransmitter release at the synapse (Brose et al., 1992;Geppert et al., 1994). To establish which region of synaptotagmin-1 interacts with the phosphorylated Cluster-2 peptide, we expressed fragments of synaptotagmin-1 and tested their ability to interact with biotinylated phosphorylated Cluster-2 peptide. This revealed that a fragment encompassing isolated C2B domain interacted robustly with the phosphorylated Cluster-2 peptide under conditions in which fragments lacking the C2B domain failed to bind (Fig. 3D).
We next performed isothermal calorimetric-binding analysis to assess the interaction of the isolated synaptotagmin-1 C2B domain (residues 270 -422) with different combinations of Cluster-2 phosphorylated residues (Ser80, Ser81, and Thr84; Fig.  4). This revealed that the key phosphorylation site mediating binding between the SV2A C2B domain and synaptotagmin-1 was Thr84. The Cluster-2 peptide phosphorylated only at Thr84 interacted with synaptotagmin-1 C2B domain with high affinity (K d of ϳ300 nM), whereas all peptides phosphorylated at Ser80 and/or Ser81, but not Thr84, failed to bind to the synaptotagmin-1 C2B domain. SV2A peptides phosphorylated at Thr84 as well as Ser80 and/or Ser81 also interacted with the C2B domain of synaptotagmin-1, but the binding affinities were lower than with the peptide phosphorylated at Thr84 alone (Fig. 4). In addition, phosphorylation at Ser81 together with phosphorylated Thr84 seems to decrease the enthalpic nature of the interaction, and this may indicate a destabilizing effect on binding of the phosphorylation at Ser81. This destabilizing effect was also reflected in an increased binding entropy of peptides phosphorylated at pSer81 ϩ pThr84 and pSer80 ϩ pSer81 ϩ pThr84, which was estimated at ϳ20 cal ⅐ mol Ϫ1 ⅐ K Ϫ1 . We also calculated the dissociation constant of the interactions, and the peptide phosphorylated at pSer81 ϩ pThr84 had a higher K d of ϳ900 nM than the peptide phosphorylated at pSer80 ϩ pThr84. However, it should be noted that the increased dependency on entropy in the interaction between synaptotagmin-1 and peptides containing phosphorylated Ser81 increased the signal-to-noise ratio and hence error in the calculated K d . Thus, phosphorylation of SV2A on Thr84 is both necessary and sufficient for its interaction with the C2B domain of synaptotagmin.

Structure of Cluster-2 phosphorylated peptide bound to synaptotagmin-1 C2B domain
To probe the mechanism by which phosphorylated SV2A binds to synaptotagmin-1, we crystallized the Thr84 phosphorylated Cluster-2 peptide (residues 76 -90) with the C2B domain (residues 270 -422) of synaptotagmin-1 (PDB entry 4v11; for crystallographic statistics, see Table 3). This revealed that the C2B domain adopted the same overall topology as the previously described nuclear magnetic resonance (NMR;Fernandez et al., 2001) and x-ray crystallography (Cheng et al., 2004;Honigmann et al., 2013) structures, composed of two layers of antiparallel ␤ sheets, along with two short ␣ helices (Fig. 5A). Electron density of the Thr84 phosphorylated Cluster-2 peptide from residues 81-90 was clearly resolved, interacting with a positively charged surface region of synaptotagmin-1 that has been referred to as the "polybasic region" (Fernandez et al., 2001; Fig. 5B). The phosphorylated Thr84 residue formed hydrogen bonds with three highly conserved surface-exposed Lys residues on the synaptotagmin-1 C2B domain (Lys314, Lys326, and Lys328; Fig.  5C). These Lys residues are distributed on two anti-parallel ␤ sheets and form a specific binding pocket that precisely accommodates the phosphorylated Thr84 residue (Fig. 5C). The importance of these residues is emphasized by the finding that 4 (Figure legend continued.) subjected to immunoblot analysis with the indicated phosphospecific antibodies that recognize phosphorylated Cluster-1 or Cluster-2 sites. It should be noted that a low level of unidentified kinase(s) copurifies with Flag-SV2A from HEK293 cells, which phosphorylates it to a low level in the absence of TTBK2. B, Full-length Flag-SV2A was incubated with WT TTBK2  in the presence of Mg 2ϩ -[␥-32 P]ATP for 60 min as in A. Phosphorylated SV2A was digested with trypsin, and peptides were separated by reverse-phase HPLC on a C 18 column. The peaks containing the 32 P-labeled phosphopeptides are marked as in the subdivisions of C. C, Summary of the mass spectrometry and solid-phase Edman sequencing data obtained after analysis of the peak fractions. The deduced amino acid sequence of each peptide is shown, and the deduced 32 P-labeled site is indicated in red. Note that, as SV2A was isolated from HEK293 cells, certain peptides are pre-phosphorylated by endogenous kinase(s). D, Domain structure of SV2A with the position of eight residues phosphorylated by TTBK2 indicated. All numbering refers to the human sequence. E, Sequence alignment of the residues of SV2A that encompass the TTBK2 phosphorylation sites from the indicated species. Residues highlighted indicated in red comprise the phosphorylation sites. Phosphorylation of SV2A at Cluster-2 promotes the interaction with synaptotagmin-1. Biotinylated dephosphorylated or triply phosphorylated (Ser80, Ser81, and Thr84) peptides that encompassed the Cluster-2 region of SV2A were conjugated to streptavidin-Sepharose and incubated in mouse brain extract. Peptide-streptavidin-Sepharose conjugates were washed, electrophoresed, and analyzed by mass spectrometry (A) or immunoblot analysis with the indicated antibody (B). In A, proteins that were not present in the control biotin sample are listed. We also excluded three proteins (40S protein S19, 40S ribosomal protein S7, and elongation factor 1-␣ 1) that are known frequent contaminants of mass spectrometry experiments (Mellacheruvu et al., 2013). MW, Molecular weight; SN, supernatant; PD, pull-down. C, Endogenous SV2A was immunoprecipitated from mouse brain extract, and the immunoprecipitates were treated in the presence (ϩ) or absence (Ϫ) of lambda phosphatase and/or EDTA that inhibits the activity of lambda phosphatase. The immunoprecipitates were washed and subjected to immunoblot analysis with the indicated antibodies. IP, Immunoprecipitated; IB, immunoblot. D, Schematic representation of the domain architecture of human synaptotagmin-1. To establish which region of synaptotagmin-1 interacts with the phosphorylated Cluster-2 peptide, we expressed in E. coli the indicated fragments of synaptotagmin-1. These proteins were incubated with biotinylated dephosphorylated or triply phosphorylated peptides used in A conjugated to streptavidin-Sepharose. The peptidestreptavidin-Sepharose conjugates were washed, electrophoresed, and subjected to immunoblot analysis with an anti-GST antibody. Similar results were obtained in at least two separate experiments for all data shown in this figure. individual mutations of Lys314, Lys326, or Lys328 inhibited binding of the Cluster-2 Thr84 phosphorylated peptide to the synaptotagmin-1 C2B domain at least sixfold, with mutation of Lys328 having the largest effect (Fig. 5D). Mutation of Lys326 and Lys328 together reduced binding of the SV2A peptide with phosphorylated Thr84 to levels similar to the nonphosphorylated peptide binding to WT synaptotagmin-1 (Fig. 5D).
Initially, we also crystallized the triply phosphorylated Ser80, Ser81, and Thr84 Cluster-2 peptide (residues 76 -90) with the C2B domain (residues 270 -421) of synaptotagmin-1 because this peptide represented the phosphorylation status seen in the previous mass spectrometry experiments. Similarly, as seen with the peptide only phosphorylated at Thr84, electron density of residues 82-90 was clearly resolved. However, no density was observed for the Ser80 and Ser81 phosphorylated residues, also indicating that these residues may be disordered in this structure (data not shown).

Phosphorylation of SV2A at Cluster-2 does not affect its trafficking
We next addressed whether Cluster-2 phosphorylation of SV2A has a direct effect on its trafficking during action potentialevoked SV recycling. We generated an SV2A-pHluorin fusion protein by inserting the pH-sensitive GFP pHluorin into the in-travesicular loop between the first and second transmembrane domains. This manipulation has no detrimental effect on evoked SV recycling (Kwon and Chapman, 2011). At neutral pH, the GFP pHluorin moiety is highly fluorescent, but its fluorescence is quenched in an acidic environment. Therefore, SV2A-pHluorin has little or no fluorescence when inside SVs (which have a pH of ϳ5.5). The fusion of SV2A-pHluorin-expressing SVs can be viewed as an increase in fluorescence and retrieval of SV2A-pHluorin from the plasma membrane as a subsequent decrease (because SV endocytosis is the rate-limiting step rather than SV acidification; Sankaranarayanan and Ryan, 2000).
Both WT (SV2AWT-pHluorin) and a triple mutant with all Cluster-2 sites mutated to alanine (SV2AP-null-pHluorin) were distributed in a punctate manner when expressed in neuronal culture, indicating their localization to nerve terminals (Fig. 6A). When transfected neurons were challenged with a train of 300 action potentials (10 Hz), we observed no significant alteration in the extent of the SV2AP-null-pHluorin response compared with SV2AWT-pHluorin [maximal evoked ⌬F, reflective of mobilization of the recycling SV pool normalized to the total SV pool (revealed by alkaline buffer), SV2AWT-pHluorin, 0.39 Ϯ 0.05; SV2AP-null-pHluorin, 0.43 Ϯ 0.04; n ϭ 4 for each; p ϭ 0.52, Student's t test]. This indicates that SV exocytosis was unlikely to be affected by expression of this reporter. There was also no Figure 4. Phosphorylation of Thr84 of SV2A is critical in promoting the interaction with synaptotagmin-1. Quantitative ITC-binding assay to assess the interaction of the isolated synaptotagmin-1 C2B domain (residues 270 -422) with a peptide encompassing the Cluster-2 region of SV2A (residues 76 -90) in which combinations of Ser80, Ser81, and Thr84 were phosphorylated as indicated. SV2A peptides (0.8 mM), with phosphorylated residues as indicated on top of each panel, were titrated into purified synaptotagmin-1 C2B domain (0.04 mM) at 25°C using a VP-ITC microcaloriter (MicroCal). The titration thermogram representing enthalpic heat release in microcalories per second is shown at the top, and the integrated binding isotherms are shown at the bottom of each panel. When applicable, the best-fit curve, reaction stoichiometry (N), and dissociation constant (K d ) were calculated. Similar results were obtained in at least two separate experiments for all data shown in this figure.
significant difference in the loss of fluorescence after action potential stimulation (Fig. 6B), indicating that Cluster-2 phosphorylation has no direct effect on SV2A retrieval during SV endocytosis.

Ablation of SV2A binding accelerates synaptotagmin-1 retrieval during SV endocytosis
We next examined whether Cluster-2 phosphorylation controlled the trafficking of its phospho-dependent interaction partner synaptotagmin-1. To achieve this, we examined the trafficking of an Syt1-pHluorin reporter (Diril et al., 2006) Kononenko et al., 2013). However, we observed a significant acceleration in activity-dependent Syt1[K326A/K328A]-pHluorin retrieval when compared with Syt1WT-pHluorin (Fig. 6D). This acceleration was not attributable to escape of Syt1[K326A/ K328A]-pHluorin from the immediate vicinity of the nerve terminal, because identical kinetics were observed when a larger axonal area was sampled out with nerve terminals (data not shown).
Genomic deletion of the monomeric adaptor for synaptotagmin, stonin 2, accelerates both Syt1WT-pHluorin retrieval and SV endocytosis (Kononenko et al., 2013). Thus, ablation of the SV2A-synaptotagmin-1 interaction may also have a global effect on SV endocytosis. To test this, we determined the effect of SV2A knockdown on a distinct SV cargo, synaptophysin, because this SV protein is absent from SV2A protein complexes (Schivell et al., 1996). Knockdown of SV2A had no effect on either the peak fluorescent response (maximal evoked ⌬F, empty shRNA vector, 0.36 Ϯ 0.04; SV2A shRNA1, 0.32 Ϯ 0.04; n ϭ 7 empty, n ϭ 5 shRNA1; p ϭ 0.43, Student's t test) or the retrieval kinetics of synaptophysin-pHluorin (Fig. 7E). Thus, SV2A phosphorylation is specifically required for synaptotagmin-1 retrieval and not SV endocytosis in general.

CK1 isoforms phosphorylate SV2A at highly conserved sites
We demonstrate in vitro that four CK1 and two TTBK isoforms phosphorylated the cytoplasmic N-terminal domain of SV2A  at two regions termed Cluster-1 (Ser42, Ser45, and Ser47) and Cluster-2 (Ser80, Ser81, and Thr84; Figs. 1, 2). Both clusters are highly conserved (Fig. 2E), indicating that the phosphorylation of these residues may play critical roles. In agreement, the key residue Thr84 is conserved in both SV2B and SV2C, as is Ser81. Because phosphorylation of substrates by CK1 kinases is facilitated by an acidic residue or priming phosphorylation at the Ϫ3 position (Flotow et al., 1990;Meggio et al., 1991), phosphorylation of Ser81 primes for phosphorylation of Thr84. Consistent with this, mutation of Ser80 and Ser81 prevented phosphorylation of Thr84 in SV2A overexpressed in HEK293 cells (Table 2). When we crystallized the C2B domain of synaptotagmin-1 with the Cluster-2 Ser80, Ser81, and Thr84 triply phosphorylated peptide, we observed no electron density for the phosphorylated Ser80 and Ser81, indicating that these residues may not be interacting specifically with the C2B domain. Consistent with this, the triply phosphorylated peptide did not interact with the synaptotagmin-1 C2B domain with higher affinity than the singly Thr84 phosphorylated peptide (Fig. 4). Therefore, it is likely that the principal role of Ser80 and Ser81 is to prime Thr84 for phosphorylation by CK1 family kinase(s) rather than to mediate interaction with synaptotagmin-1.
Which CK1 family member(s) phosphorylate SV2A at Cluster-1 and Cluster-2 sites in vivo? To address this question, systematic analysis of SV2A phosphorylation in CK1 isoform knockdown or knock-out systems may be required. This analysis may be complicated by the redundancy of multiple CK1 isoforms phosphorylating SV2A, as suggested by our in vitro experimentation (Fig. 1). None of the widely used pan CK1 inhibitors described to date (D4476, CKI-7, and IC261) are sufficiently potent (in vitro IC 50 values Ͼ1 M), or selective (see http://www.kinasescreen.mrc.ac.uk/kinase-inhibitors), to be used to determine which CK1 isoforms regulate SV2A phosphorylation in vivo. Although certain CK1 family kinases tested, such as TTBK1, TTBK2[1-316], and CK1␦, phosphorylated SV2A more efficiently in vitro than other family members (CK1␣1 and CK␥1), it is not possible to rule out that this was a result of the recombinant kinases possessing low intrinsic activity because of their expression in E. coli and/or lack of factors required to promote phosphorylation of SV2A by CK1 kinase(s). The finding that phosphorylation of Ser80 and Ser81 promotes phosphorylation of Thr84 in vivo (Tables 1, 2) is consistent with CK1 family kinase(s) known to require a Ϫ3/Ϫ4 phosphorylation priming mechanism. Figure 5. Crystal structure of Thr84 phosphorylated Cluster-2 peptide bound to synaptotagmin-1 C2B domain. A, A ribbon diagram of the synaptotagmin-1 C2B domain (residues 270 -422) bound to a peptide encompassing the Cluster-2 region of SV2A (residues 81-90) that is phosphorylated at Thr84 (PDB entry 4v11). The synaptotagmin-1 C2B domain is shown with ␤ strands colored in cyan, helices in magenta, and loops in gray. The backbone of the SV2A peptide, binding at the polybasic region, is colored in yellow. The side chains of residues of the polybasic region interacting with the SV2A peptide are shown as stick models. The two Ca 2ϩ ions, binding between loops 1 and 3, are shown as green spheres. B, Electrostatic surface representation of synaptotagmin-1 with the bound SV2A peptide. The negatively charged phosphate group of the SV2A peptide is binding to the positively charged surface area at the polybasic region of synaptotagmin-1. Negative charge (acidic) is shown in red and positive charge (basic) in blue. The electrostatic map is contoured from Ϫ5 to 5 kTe. C, Stereo-image and close-up analysis of the pocket on the C2B domain that interacts with Thr84 phosphorylated residue. The three highly conserved surface-exposed Lys residues on synaptotagmin-1 (Lys314, Lys326, and Lys328) interact with Thr84 of SV2A, and distances between the -amino groups of the lysine residues and the phosphate group of phosphorylated Thr84 are shown in angstroms. These Lys residues are distributed on anti-parallel ␤ sheets 3 and 4, and their side chains form a specific binding pocket that precisely accommodates the phosphorylated Thr84 residue. The 2mFo-dFc map, before manual building of the peptide model and refinement, is shown as gray mesh and was contoured at 1 within 2 Å of the SV2A peptide. D, Fluorescence polarization analysis of WT and indicated Lys substitution mutants (K314A, K326A, K328A, and K326A/K328A) of synaptotagmin-1 C2B domain and peptide encompassing Cluster-2 region of SV2A (residues 76 -90), which was either phosphorylated at Thr84 or unphosphorylated as a negative control. Data points and error bars represent mean Ϯ SD (n ϭ 3), and similar results were obtained in at least two separate experiments for all data shown in this figure.

Mapping of the synaptotagmin-1-SV2A interaction site
The N terminus of SV2A interacts with synaptotagmin-1 (Schivell et al., 1996(Schivell et al., , 2005, and this interaction is enhanced by CK1 phosphorylation in vitro (Pyle et al., 2000). Our data establish that CK1 phosphorylation of Thr84 promotes the interaction of SV2A with the C2B domain of synaptotagmin-1 (Fig. 4). Crystallographic analysis reveals that the phosphorylated Thr84 residue interacts with a specific pocket on the surface of the synaptotagmin-1 C2B domain (Fig. 5). This lies within the "polybasic region" (Fernandez et al., 2001). This pocket is formed from three surface-exposed Lys residues (Lys314, Lys326, and Lys328) that make hydrogen bonds with the phosphate moiety of the phosphorylated Thr84 residue (Fig. 5). These Lys residues are conserved in all species of synaptotagmin-1 we have analyzed and in 13 of the 17 synaptotagmin isoforms present in humans, suggesting that these will all possess the ability to interact with CK1phosphorylated SV2 isoforms. The Lys residues equivalent to Lys326 and Lys328 are absent in the C2A domain of synaptotagmin-1, likely accounting for its failure to bind the Cluster-2 Thr84 phosphorylated peptide.
The regions surrounding the phosphorylated Thr84 binding pocket on the synaptotagmin-1 C2B domain bind to other components, including phosphoinositides (Schiavo et al., 1996), adaptor protein 2 (AP-2; Zhang et al., 1994), calcium channels (Leveque et al., 1992), other synaptotagmins (Chapman et al., 1996), and target-soluble N-ethylmaleimidesensitive factor attachment protein receptor (t-SNARE) dimers (Bhalla et al., 2006). NMR analysis (Joung et al., 2012) revealed that inositol hexaphosphate IP6 binds to a pocket that lies adjacent to that for the phosphorylated Thr84 binding pocket. The phosphate groups on IP6 form key interactions with Lys328, Thr330, and Lys332 residues in human synaptotagmin-1. Inspection of the structure of the C2B domain does not rule out the possibility that the C2B domain could bind simultaneously to the phosphorylated Cluster-2 SV2A peptide and IP6/phosphoinositide, with Lys328 functioning as a pivotal residue capable of interacting with both phosphorylated Thr84 and an inositol phosphate group. Phosphoinositide binding has been proposed to control the interaction of the C2B domain with the t-SNARE dimer (Rickman et al., 2004). Thus, Lys328 may act as a molecular switch, binding either phosphorylated SV2A for its retrieval or IP6 for t-SNARE-specific interactions. Other studies have suggested that the Lys327 and Lys328 residues (corresponding residues in human SYT1) control C2B dimerization and regulate interactions with both AP-2 and voltage-gated calcium channels (Chapman et al., 1998;Grass et al., 2004). Therefore, more work is required to study the interplay between the interaction of synaptotagmin-1 with CK1-phosphorylated SV2A and other binding components.
Phosphorylation of SV2A controls synaptotagmin-1 retrieval during SV endocytosis We found that removal of the phosphorylation-dependent SV2A interaction by either mutagenesis of the C2B domain, shRNA knockdown of SV2A, or mutagenesis of T84 on SV2A all result in increased retrieval kinetics of Syt1-pHluorin. This was surprising, because disruption of endocytic sorting mechanisms by either knockdown of adaptor protein complexes or monomeric adaptors (Kim and Ryan, 2009;Willox and Royle, 2012;Kononenko et al., 2014) or mutagenesis of key endocytosis motifs (Voglmaier et al., 2006;Yao et al., 2010;Koo et al., 2011;Foss et al., 2013) usually result in retarded SV cargo retrieval. This acceleration was not attributable to defective retention of Syt1-pHluorin in nerve terminals, because retrieval kinetics were identical when axonal regions were analyzed. Interestingly, accelerated Syt1-pHluorin retrieval was also observed in neurons derived from stonin 2 knock-out mice (Kononenko et al., 2013). Stonin 2 is a synaptotagmin-specific adaptor molecule, and knock-out neurons displayed both accumulation of Syt1-pHluorin at the plasma membrane and enhanced SV endocytosis kinetics. We also observed increased plasma membrane accumulation of Syt1-pHluorin on perturbation of SV2A interactions, but we see Figure 6. Inhibition of SV2A binding accelerates Syt1-pHluorin retrieval during SV endocytosis. A, Hippocampal neurons were transfected with either WT or phospho-null (P-null) SV2A-pHluorin. Grayscale images show that SV2A-pHluorin was correctly targeted to nerve terminals. Scale bar, 1 m. B, Neurons transfected with either WT (blue) or P-null (red) SV2A-pHluorin were stimulated with a train of 300 action potentials (10 Hz). Graph displays the mean ⌬F/F 0 time course for SV2A-pHluorin Ϯ SEM normalized to the peak of stimulation (n ϭ 5 WT, n ϭ 4 P-null). C, Neurons were transfected with either WT or K326/328A Syt1-pHluorin. Grayscale images show that Syt1-pHluorin was correctly targeted to nerve terminals. Scale bar, 1 m. Surface expression of either Syt1WT-pHluorin or Syt1[K326/328A]-pHluorin displayed as a percentage of total pHluorin Ϯ SEM (**p ϭ 0.004). D, Neurons transfected with either WT (blue) or K326/328A (red) Syt1-pHluorin were stimulated with a train of 300 action potentials (10 Hz). Graph displays the mean ⌬F/F 0 time course for Syt1-pHluorin Ϯ SEM normalized to the peak of stimulation (significantly different between time points 128 -140 s; p Ͻ 0.05; n ϭ 8 for both WT and K326/328A). In both B and D, the bar indicates period of stimulation.
where (on SVs and/or plasma membrane) and when (before, during, or after action potential stimulation) SV2A is phosphorylated by a CK1 family kinase.