Faculty Bibliography

Synaptic vesicles (SVs) are triggered to fuse with the surface membrane at the presynaptic transmitter release site (TRSs) core by Ca2+ influx through nearby attached CaV2.2 channels [see accompanying paper: Khanna et al. (2007)Eur. J. Neurosci., 26, 547-559] and are then recovered by endocytosis. In this study we test the hypothesis that the TRS core is linked to an endocytosis-related protein complex. This was tested by immunostaining analysis of the chick ciliary ganglion calyx presynaptic terminal and biochemical analysis of synaptosome lysate, using CaV2.2 as a marker for the TRS. We noted that CaV2.2 clusters abut heavy-chain (H)-clathrin patches at the transmitter release face. Quantitative coimmunostaining analysis (ICA/ICQ method) demonstrated a strong covariance of release-face CaV2.2 staining with that for the AP180 and intersectin endocytosis adaptor proteins, and a moderate covariance with H- or light-chain (L)-clathrin and dynamin coat proteins, consistent with a multimolecular complex. This was supported by coprecipitation of these proteins with CaV2.2 from brain synaptosome lysate. Interestingly, the channel neither colocalized nor coprecipitated with the endocytosis cargo-capturing adaptor AP2, even though this protein both colocalized and coprecipitated with H-clathrin. Fractional recovery analysis of the immunoprecipitated CaV2.2 complex by exposure to high NaCl (approximately 1 m) indicated that AP180 and S-intersectin adaptors are tightly bound to CaV2.2 while L-intersectin, H- and L-clathrin and dynamin form a less tightly linked subcomplex. Our results are consistent with two distinct clathrin endocytosis complexes: an AP2-containing, remote, non-TRS complex and a specialised, AP2-lacking, TRS-associated subcomplex linked via a molecular bridge. The most probable role of this subcomplex is to facilitate SV recovery after transmitter release.

CaV2.2 channels play a key role in the gating of transmitter release sites (TRS) at presynaptic terminals. Physiological studies predict that the channels are linked directly to the TRS but the molecular composition of this complex remains poorly understood. We have used a high-affinity anti-CaV2.2 antibody, Ab571, to test a range of proteins known to contribute to TRS function for both an association in situ and a link in vitro. CaV2.2 clusters were isolated intact on immunoprecipitation beads and coprecipitated with a number of these proteins. Quantitative staining covariance analysis (ICA/ICQ method) was applied to the transmitter release face of the giant calyx terminal in the chick ciliary ganglion to test for TRS proteins with staining intensities that covary in situ with CaV2.2, resulting in a covariance sequence of NSF>RIM>spectrin>Munc18>VAMP>alpha-catenin, CASK>SV2>Na+-K+ approximately 0. A high-NaCl dissociation challenge applied to the immunoprecipitated complex, using the fractional recovery (FR) method [Khanna, R., Li, Q. & Stanley, E.F. (2006) PLoS.ONE., 1, e67], was used to test which proteins were most intimately associated with the channel, generating an FR sequence for CaV2.2 of: VAMP>or=actin>tubulin, NSF, Munc18, syntaxin 1>spectrin>CASK, SNAP25>RIM, Na+-K+ pump, v-ATPase, beta-catenin approximately 0. Proteins associated with endocytosis are considered in a companion paper [Khanna et al. (2007)Eur. J. Neurosci., 26, 560-574]. With the exception of VAMP and RIM, the ICQ and FR sequences were consistent, suggesting that proteins that covary the most strongly with CaV2.2 in situ are also the most intimately attached. Our findings suggest that the CaV2.2 cluster is an integral element of a multimolecular vesicle-fusion module that forms the core of a multifunctional TRS.

N type calcium channels (CaV2.2) play a key role in the gating of transmitter release at presynaptic nerve terminals. These channels are generally regarded as parts of a multimolecular complex that can modulate their open probability and ensure their location near the vesicle docking and fusion sites. However, the proteins that comprise this component remain poorly characterized. We have carried out the first open screen of presynaptic CaV2.2 complex members by an antibody-mediated capture of the channel from purified rat brain synaptosome lysate followed by mass spectroscopy. 589 unique peptides resulted in a high confidence match of 104 total proteins and 40 synaptosome proteome proteins. This screen identified several known CaV2.2 interacting proteins including syntaxin 1, VAMP, protein phosphatase 2A, G(O alpha), G beta and spectrin and also a number of novel proteins, including clathrin, adaptin, dynamin, dynein, NSF and actin. The unexpected proteins were classified within a number of functional classes that include exocytosis, endocytosis, cytoplasmic matrix, modulators, chaperones, and cell-signaling molecules and this list was contrasted to previous reports that catalogue the synaptosome proteome. The failure to detect any postsynaptic density proteins suggests that the channel itself does not exhibit stable trans-synaptic attachments. Our results suggest that the channel is anchored to a cytoplasmic matrix related to the previously described particle web.

The presynaptic N type Ca channel (CaV2.2) is associated with the transmitter release site apparatus and plays a critical role in the gating of transmitter release. It has been suggested that a distinct CaV2.2 long C terminal splice variant is targeted to the nerve terminal and is anchored at the release face by calcium/calmodulin-dependent serine protein kinase (CASK) and Munc-18-interacting protein (MINT), two modular adaptor proteins. We used the isolated chick ciliary ganglion calyx terminal together with two new antibodies (L4569, L4570) selective for CaV2.2 long C terminal splice variant to test these hypotheses. CaV2.2 long C terminal splice variant was present at the presynaptic transmitter release sites, as identified by Rab3a-interacting molecule (RIM) co-staining and quantitative immunocytochemistry. CASK was also present at the terminal both in conjunction with, and independent of its binding partner, MINT. Immunoprecipitation of CaV2.2 long C terminal splice variant from brain lysate coprecipitated CASK, confirming that these two proteins can form a complex. However, CASK was not colocalized either with CaV2.2 long C terminal splice variant or the transmitter release site marker RIM at the calyx terminal release face. Neither was MINT colocalized with CaV2.2 long C terminal splice variant. Our results show that native CaV2.2 long C terminal splice variant is targeted to the transmitter release sites at an intact presynaptic terminal. However, the lack of enrichment of CASK at the release site combined with the failure of this protein or its partner MINT to colocalize with CaV2.2 argues against the idea that these modular adaptor proteins anchor CaV2.2 at presynaptic nerve terminals.

Fast neurotransmitter release at presynaptic terminals occurs at specialized transmitter release sites where docked secretory vesicles are triggered to fuse with the membrane by the influx of Ca2+ ions that enter through local N type (CaV2.2) calcium channels. Thus, neurosecretion involves two key processes: the docking of vesicles at the transmitter release site, a process that involves the scaffold protein RIM (Rab3A interacting molecule) and its binding partner Munc-13, and the subsequent gating of vesicle fusion by activation of the Ca2+ channels. It is not known, however, whether the vesicle fusion complex with its attached Ca2+ channels and the vesicle docking complex are parts of a single multifunctional entity. The Ca2+ channel itself and RIM were used as markers for these two elements to address this question. We carried out immunostaining at the giant calyx-type synapse of the chick ciliary ganglion to localize the proteins at a native, undisturbed presynaptic nerve terminal. Quantitative immunostaining (intensity correlation analysis/intensity correlation quotient method) was used to test the relationship between these two proteins at the nerve terminal transmitter release face. The staining intensities for CaV2.2 and RIM covary strongly, consistent with the expectation that they are both components of the transmitter release sites. We then used immunoprecipitation to test if these proteins are also parts of a common molecular complex. However, precipitation of CaV2.2 failed to capture either RIM or Munc-13, a RIM binding partner. These findings indicate that although the vesicle fusion and the vesicle docking mechanisms coexist at the transmitter release face they are not parts of a common stable complex.

BACKGROUND:The integral synaptic vesicle protein and putative calcium sensor, synaptotagmin 1 (STG), has also been implicated in synaptic vesicle (SV) recovery. However, proteins with which STG interacts during SV endocytosis remain poorly understood. We have isolated an STG-associated endocytic complex (SAE) from presynaptic nerve terminals and have used a novel fractional recovery (FR) assay based on electrostatic dissociation to identify SAE components and map the complex structure. The location of SAE in the presynaptic terminal was determined by high-resolution quantitative immunocytochemistry at the chick ciliary ganglion giant calyx-type synapse. METHODOLOGY/PRINCIPLE FINDINGS/RESULTS:The first step in FR analysis was to immunoprecipitate (IP) the complex with an antibody against one protein component (the IP-protein). The immobilized complex was then exposed to a high salt (1150 mM) stress-test that caused shedding of co-immunoprecipitated proteins (co-IP-proteins). A Fractional Recovery ratio (FR: recovery after high salt/recovery with control salt as assayed by Western blot) was calculated for each co-IP-protein. These FR values reflect complex structure since an easily dissociated protein, with a low FR value, cannot be intermediary between the IP-protein and a salt-resistant protein. The structure of the complex was mapped and a blueprint generated with a pair of FR analyses generated using two different IP-proteins. The blueprint of SAE contains an AP180/X/STG/stonin 2/intersectin/epsin core (X is unknown and epsin is hypothesized), and an AP2 adaptor, H-/L-clathrin coat and dynamin scission protein perimeter. Quantitative immunocytochemistry (ICA/ICQ method) at an isolated calyx-type presynaptic terminal indicates that this complex is associated with STG at the presynaptic transmitter release face but not with STG on intracellular synaptic vesicles. CONCLUSIONS/SIGNIFICANCE/CONCLUSIONS:We hypothesize that the SAE serves as a recognition site and also as a seed complex for clathrin-mediated synaptic vesicle recovery. The combination of FR analysis with quantitative immunocytochemistry provides a novel and effective strategy for the identification and characterization of biologically-relevant multi-molecular complexes.

Ca(2+) influx through N-type Ca(2+) channels (CaV2.2) is known to be critical for transmitter release at many synapses. These channels are known to be localized to transmitter release sites, but their anchoring mechanism remains unknown. Recent studies have demonstrated that presynaptic organization is subject to interactions with the postsynaptic cell or the intervening extracellular matrix. We used a previously described high-affinity antibody against the N-type Ca(2+) channels, Ab571, to localize Ca(2+) channel clusters at the release face of an isolated giant calyx-type synapse to test whether the maintenance of these clusters requires an intact extracellular matrix or contact with the postsynaptic cell. Because the number of Ca(2+) channel clusters was unchanged after extracellular matrix dispersal or nerve terminal isolation, we conclude that presynaptic transmitter release face Ca(2+) clusters can be maintained independently of extracellular influences. Our results suggest that a presynaptic molecular scaffold is responsible for the maintenance of release site Ca(2+) channel clusters.

BACKGROUND:CACNA1A encodes CaV2.1, the pore-forming subunit of P/Q-type voltage-gated calcium channel complexes. Mutations in CACNA1A cause a wide range of neurologic disturbances variably associated with cerebellar degeneration. Functional studies to date focus on electrophysiologic defects that do not adequately explain the phenotypic findings. OBJECTIVE:To investigate whether some missense mutations might interfere with protein folding and trafficking, eventually leading to protein aggregation and neuronal injury. METHODS:The authors studied the functional consequences of two pore missense mutations, C287Y and G293R, in two families with EA2, one newly discovered and the other previously reported. Both mutations caused episodic and interictal ataxia. The biophysical properties of mutant and wild type calcium channels were examined by whole-cell patch-clamp recordings in transfected COS-7 cells. The plasma membrane targeting was visualized by confocal fluorescence imaging on CaV2.1 tagged with green fluorescent protein. RESULTS:The mutant channels exhibited a marked reduction in current expression and deficiencies in plasma membrane targeting. CONCLUSIONS:In addition to altered channel function, the deficiency in protein misfolding and trafficking associated with the C287Y and G293R mutants may contribute to the slowly progressive cerebellar ataxia.

In Shaker K(+) channels, formation of an electrostatic interaction between two charged residues, D316 and K374 in transmembrane segments S3 and S4, respectively, is a key step in voltage sensor biogenesis. Mutations D316K and K374E disrupt formation of the voltage sensor and lead to endoplasmic reticulum retention. We have now investigated the fates of these misfolded proteins. Both are significantly less stable than the wild-type protein. D316K is degraded by cytoplasmic proteasomes, whereas K374E is degraded by a lactacystin-insensitive, non-proteasomal pathway. Our results suggest that the D316K and K374E proteins are misfolded in recognizably different ways, an observation with implications for voltage sensor biogenesis.

We recently showed that an unglycosylated form of the Shaker potassium channel protein is retained in the endoplasmic reticulum (ER) and degraded by proteasomes in mammalian cells despite apparently normal folding and assembly. These results suggest that channel proteins with a native structure can be substrates for ER-associated degradation. We have now tested this hypothesis using the wild-type Shaker protein. Wild-type Shaker is degraded by cytoplasmic proteasomes when it is trapped in the ER and prevented from interacting with calnexin. Neither condition alone is sufficient to destabilize the protein. Proteasomal degradation of the wild-type protein is abolished when ER mannosidase I trimming of the core glycan is inhibited. Our results indicate that transient interaction with calnexin provides long-term protection from ER-associated degradation.