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Synaptic transmission is a fundamental process that involves the transfer of information from a presynaptic neuron to a target cell through the release of neurotransmitters. The SV cycle is a complex series of events that enables the recycling of SVs, allowing for the sustained release of neurotransmitters. This process is mediated by a variety of proteins and enzymes, and its regulation is critical for maintaining proper synaptic function. Despite extensive research efforts, many aspects of the SV cycle and the underlying synaptic proteins remain poorly understood, highlighting the need for continued investigation into this important process. During this work, multiple aspects of synaptic transmission were studied by performing
behavioural, pharmacological, optogenetic, electrophysiological and ultrastructural assays on Caenorhabditis elegans. First, the role of two proteins (ERP-1 and RIMB-1) were analysed in the synaptic vesicle cycle. Second, a new optogenetic tool, the pOpsicle assay was described, which enables the direct visualization of synaptic vesicle (SV) release.
Activity-dependent bulk endocytosis (ADBE) enables the endocytosis of SV membrane and proteins in a fast manner during intense stimulation, resulting in bulk endosomes (also so-called large vesicles, LVs). Recycling proteins can be characterized by its site of action, whether they act at the plasma membrane (participating at the LV formation), or at the LV membrane (participating at the SV formation). ERP-1 (the C. elegans ortholog of Endophilin B) was recently identified as a possible SV recycling factor, its contribution to synaptic transmission has not been analysed before. During this project the function and possible cooperation of three proteins, ERP-1, UNC-57 (the C. elegans ortholog of Endophilin A) and CHC-1 (the C. elegans ortholog clathrin heavy chain) were studied, with a special emphasis of the site of action. It has been confirmed that these proteins participate together in synaptic vesicle recycling. Endophilins (ERP-1 and UNC-57) act both at the PM and the LV level, but while UNC-57 has been identified as the main player, ERP-1 rather has a minor role and acts as a back-up protein. CHC-1 functions the LV level in the first place, but it can compensate for the loss of UNC-57 and acts as a back-up protein at the PM.
RIM-binding protein is an evolutionarily conserved active zone protein, which interacts directly with RIM and N, P/Q, as well as L-type Ca2+ channels. RIM-BP and RIM have redundant functions in different model organisms including C. elegans, however, while the loss of UNC-10 (the C. elegans ortholog of RIM) led to drastic behavioural defects, the loss of RIMB-1 (the C. elegans ortholog of RIM-BP) led only to mild phenotypes. During this work the synaptic function of RIMB-1 and its interaction with UNC-10 and UNC-2 (C. elegans ortholog of the CaV2 1 subunit) were extensively investigated. It has been shown that RIMB-1 contributes to the precise localization of VGCCs in cooperation with UNC-10. Furthermore, it has been demonstrated, that RIMB-1 plays different roles in cholinergic and GABAergic neurons, thus it contributes to maintain a proper excitation/inhibition balance.
There are numerous available assays, which enable the indirect analysis of synaptic transmission, however, a tool, that enables the direct visualization of SV release, is highly desired. pOpsicle is a method which combines the optogenetic stimulation of cholinergic neurons with real-time visualization of SV release. A pH-sensitive fluorescence protein, pHuji, was inserted into the second intravesicular loop of the synaptic vesicle membrane protein, synaptogyrin (SNG-1). The fluorescence of pHuji is quenched inside the vesicles, but once they are released, the pH increases and pHuji can be detected. pOpsicle enables not only the direct visualization of SV exo-, and endocytosis events, but also the identification of putative SV recycling proteins.
The centerpiece of all neuronal processes is the synaptic transmission. It consists of a complex series of events. Two key elements are the binding of synaptic vesicles (SV) to the presynaptic membrane and the subsequent fusion of the two membranes. SV are neurotransmitter-filled membranous spheres with many integral and peripheral proteins. The synaptic SNARE complex consists of three interacting proteins, which energize and regulate the fusion of the SV membrane with the presynaptic membrane. Both processes are closely orchestrated to ensure a specific release of neurotransmitter. Already many experiments have been performed, such as genetic screens and proteome analysis of SV, to determine the functions of the various proteins involved. Nevertheless, the functions of the identified proteins are still not fully elucidated. The aim of this thesis was initially applying a tandem affinity purification (TAP) of SV to identify unknown interaction partner of SV and to determine their role. This was supposed to be performed in the model organism Caenorhabditis elegans (C. elegans). The underlying mechanisms are conserved throughout the phylogentic tree and identified interaction partners will help to understand the processes in the mammalian brain. Although there is no neuron-rich tissue in C. elegans as in other model organisms, the diverse genetic methods allows a rapid creation of modified organisms and a prompt determination of the function of identified proteins. The integral SV protein synaptogyrin has been fused to a TAP-tag. The TAP-tag consists of a ProteinA, a TEV protease cleavage site and a calmodulin binding peptide (CBP). Both affinity purification steps are performed sequentially and allow a highly specific native purification of proteins and their interaction partners. Due to technical difficulties the purification strategy was modified several times during the course of this thesis and then finally abandoned for a more promising project, the SNARE complex purification. In conclusion, one of the reasons was the necessary lack of detergent.
The amended aim of this thesis has been the TAP of solubilized SNARE complex to identify unknown interaction partner and to determine their role. In order to increase the specificity of the purification, in terms of formed complexes, the two SNARE subunits, synaptobrevin (SNB-1 in C. elegans) and syntaxin (UNC-64 in C. elegans), were separately fused to the different affinity tags. As the modifications of the proteins could impair their function and lead to false interaction partners, their functionality was tested. For this purpose, the corresponding fusion constructs were expressed in strains with mutated snb¬1 and unc-64. Non-functional synaptic proteins display an altered course of paralysis in an aldicarb assay. The fusion proteins which were expressed in their respective mutant strains displayed a near to wild-type (WT) behavior in contrast to the naive mutant strains. Multiple TAP demonstrated SNB-1 signals in Western blot analysis and complex sets of proteins in the final elution step in a silver staining of SDS-PAGEs. These samples were sent with negative control (WT purification) for MS analysis to various cooperation partners. 119 proteins were identified which appeared only in data sets with SNARE proteins and not in WT samples. If proteins were detected in ≥ 2 SNARE positive MS analysis and had known neural functions or homologies to neuronal proteins in other species, they were selected for further analysis. These candidates were knocked down by RNAi and tested for synaptic function in a following aldicarb assay. The treatment with their specific RNAi resulted for mca-3 in a strong resistance, while frm-2, snap-29, ekl-6, klb-8, mdh-2, pfk-2, piki-1 and vamp-8 resulted in hypersensitivity. The most responsive genes frm-2, snap-29 and mca-3 were examined, whether they displayed a co-localization together with synaptobrevin in promoter fusion constructs or functional fusion constructs. In fluorescence microscopy images only MCA-3::YFP demonstrated neuronal expression.
In order to substantiate the synaptic nature and functionality of the MCA-3::YFP a swimming assay was performed. Here, fusion construct expressing strains, which contained mutated mca-3, were compared with untreated mutant strains and WT strains according to their behavior. In this swimming assay a partial restoration of WT behavior was shown in the MCA-3::YFP expressing mutant strains. Based on these data, we discovered with MCA 3 a new interaction partner of the SNARE complex. MCA-3 is a plasma membrane Ca2+-ATPase and was initially seen only in their role in the endocytosis. Its new putative role is the reduction of Ca2+ concentration at the bound SNARE complex. Since an interaction of syntaxin with Ca2+ channels has been demonstrated, it would be comprehensible to reduce the local concentration of Ca2+ to a minimum by tethering Ca2+ transporters to the SNARE complex.