Abstract
Background
The conserved Caenorhabditis elegans proteins NID-1/nidogen and PTP-3A/LAR-RPTP function to efficiently localize the presynaptic scaffold protein SYD-2/α-liprin at active zones. Loss of function in these molecules results in defects in the size, morphology and spacing of neuromuscular junctions.
Results
Here we show that the Cav2-like voltage-gated calcium channel (VGCC) proteins, UNC-2 and UNC-36, and the calmodulin kinase II (CaMKII), UNC-43, function to regulate the size and morphology of presynaptic domains in C. elegans. Loss of function in unc-2, unc-36 or unc-43 resulted in slightly larger GABAergic neuromuscular junctions (NMJs), but could suppress the synaptic morphology defects found in nid-1/ nidogen or ptp-3/ LAR mutants. A gain-of-function mutation in unc-43 caused defects similar to those found in nid-1 mutants. Mutations in egl-19, Cav1-like, or cca-1, Cav3-like, α1 subunits, or the second α2/δ subunit, tag-180, did not suppress nid-1, suggesting a specific interaction between unc-2 and the synaptic extracellular matrix (ECM) component nidogen. Using a synaptic vesicle marker in time-lapse microscopy studies, we observed GABAergic motor neurons adding NMJ-like structures during late larval development. The synaptic bouton addition appeared to form in at least two ways: (1) de novo formation, where a cluster of vesicles appeared to coalesce, or (2) when a single punctum became enlarged and then divided to form two discrete fluorescent puncta. In comparison to wild type animals, we found unc-2 mutants exhibited reduced NMJ dynamics, with fewer observed divisions during a similar stage of development.
Conclusions
We identified UNC-2/UNC-36 VGCCs and UNC-43/CaMKII as regulators of C. elegans synaptogenesis. UNC-2 has a modest role in synapse formation, but a broader role in regulating dynamic changes in the size and morphology of synapses that occur during organismal development. During the late 4th larval stage (L4), wild type animals exhibit synaptic morphologies that are similar to those found in animals lacking NID-1/PTP-3 adhesion, as well as those with constitutive activation of UNC-43. Genetic evidence indicates that the VGCCs and the NID-1/PTP-3 adhesion complex provide opposing functions in synaptic development, suggesting that modulation of synaptic adhesion may underlie synapse development in C. elegans.
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Background
Changes in the cell membrane potential can open voltage-gated calcium channels (VGCC) to permit calcium entry. VGCCs are formed by α1, α2/δ, and β subunits and can include a γ subunit [1]. The α1 subunit forms the channel pore, while the auxiliary β and α2/δ subunits affect channel trafficking and physiology [2, 3]. The α2/δ subunits are synthesized as a single polypeptide that undergoes proteolytic cleavage, but remains covalently associated [4–6]. VGCCs have been classified by their pharmacological and electrophysiological properties [1]. Cav2-type channels are localized to the presynaptic active zone, where they function in vesicle exocytosis. Cav1 channels localize more broadly and have been associated with events including gene regulation, local translation and dendritic growth [7].
In addition to synaptic vesicle exocytosis, there have been reports describing a role for VGCCs in regulating presynaptic development. Loss of calcium signaling through the α1 subunit cacophony resulted in reduced neuromuscular junction (NMJ) growth during Drosophila larval development [8]. At the vertebrate NMJ, a role for synaptic calcium channels has been discovered in mediating synaptic stability. The Cav2.1 and Cav2.2 calcium channels were found to bind directly to the extracellular matrix proteins laminin-10 and −11 and this interaction is critical for synaptic maintenance [9]. In the central nervous system, the α2/δ1 protein is a receptor for the extracellular matrix (ECM) protein thrombospondin, and together they act to promote synaptogenesis [10]. These results demonstrate how an interaction between VGCCs and the synaptic ECM can regulate synaptic development and morphology.
Previously, we have shown the synaptic ECM components nidogen (nid-1) and collagen XVIII (cle-1) exhibit distinct roles in the formation of Caenorhabditis elegans NMJs [11]. Mutations in nid-1 cause a disruption in the size, shape and function of these synapses by disrupting the accumulation of the LAR receptor tyrosine phosphatase, PTP-3A, and the intracellular-adaptor protein α-liprin/SYD-2 at active zones [12].
During a screen for nid-1 genetic modifiers we recovered an allele of unc-2, which encodes the single C. elegans Cav2-like α1 subunit [13]. Loss-of-function (LOF) mutations in unc-2 result in presynaptic contacts being slightly enlarged, but also in suppression of the defects caused by the nid-1 mutation. Using time-lapse analysis we show that GABAergic NMJs exhibit dynamic shape changes during the late 4th larval stage (L4), and that new NMJs can be formed by the elongation and division of established presynaptic domains. These dynamic changes were dependent on functional UNC-2. We also find that unc-43, the C. elegans Calmodulin kinase II (CaMKII) homolog, regulates GABAergic synapse formation. LOF in unc-43 suppresses nid-1, while a gain-of-function (GOF) mutation in unc-43 causes nid-1- like defects in NMJ morphology. Our results find a novel interaction between the ECM and VGCCs, where, during synaptic development, they appear to function antagonistically.
Results and discussion
unc-2 regulates the size, shape and morphology of presynaptic domains
We have found that the ECM protein nidogen, nid-1, affects the morphology and function of C. elegans NMJs [11, 12]. We visualized GABAergic NMJs using a SNB-1::GFP (synaptobrevin) chimeric marker, juIs1[14], as an indicator of presynaptic size and placement. In young adult (yAd) wild type (wt) animals GFP-labeled synaptic vesicles cluster in discrete, regularly sized puncta that have a smooth morphology (Figure 1A), with an average area of 0.81 ± 0.01 μm2 (Mean ± S.E.M.). Strong LOF nid-1(cg119) animals have a synapse defective (Syd) phenotype such that fluorescent puncta often exhibit a rough or disorganized appearance and have an apparent area of 1.45 ± 0.08 μm2P <0.05) (Figure 1B).
To better understand how nidogen affects NMJs, we conducted a screen for genetic modifiers of the nid-1 phenotype (see Methods). We recovered ju493, which appeared to largely suppress the synaptic vesicle accumulation defects present in nid-1(cg119) animals (Figure 1C). By themselves, the ju493 animals were uncoordinated (Unc), and also displayed synaptic morphology defects (Figure 1D). We mapped the allele to the left arm of linkage group X, and found ju493 failed to complement unc-2(e55), a strong LOF allele [13]. By PCR amplification and sequence analysis, we found that ju493 animals had a large deletion within the unc- 2 coding region, suggesting that it is likely a strong LOF allele (Figure 1K). unc-2 is one of three C. elegans genes encoding VGCC α1 subunits. We tested LOF alleles in the other two VGCC, egl-19 and cca-1, and did not observe any suppression of nid-1 defects [See Additional file 1: Figure S1], indicating the observed effect is specific to unc-2.
We further characterized the effect of unc-2 LOF using the e55 allele, which causes a premature stop codon in exon 9 (Figure 1K). Presynaptic domains of unc-2(e55) mutants had smooth and oval-shaped SNB-1::GFP puncta, but the area of the puncta was significantly increased over wt by approximately 20% (1.04 ± 0.07 μm2, P <0.05) (Figure 1E) in yAd animals. We also found that the total number of presynaptic clusters was slightly reduced in unc-2(e55) mutants (wt 25.6 ± 0.2 puncta/100 μm versus unc-2 22.8 ± 0.7 puncta/100 μm (P <0.05)). Like ju493, the e55 mutation suppressed vesicle-accumulation defects found in nid-1(cg119) (Figure 1F). Puncta formed in nid-1;unc-2 double mutants had an average area of 1.15 ± 0.10 μm2 (P <0.05 versus nid-1 or wt; P >0.05 versus unc-2), and appeared morphologically similar to wt.
To more quantitatively assess the NMJ morphology, we calculated the circularity of the SNB-1::GFP fluorescent puncta (Figure 1J) (see Methods). Wild type SNB-1::GFP puncta are ovoid, and have an average circularity of 0.70 ± 0.01. By comparison, in unc-2(e55) the puncta varied slightly, but significantly, from wt (0.66 ± 0.03, P <0.05), while in nid-1 mutants, the puncta were more elongated and less circular (0.60 ± 0.01, P <0.05). The nid-1;unc-2 double mutants were like wt (0.74 ± 0.02, P <0.05 versus nid-1 or unc-2; P >0.05 versus wt), indicating that the elongated morphology in nid-1 was ameliorated by removing unc-2 function.
UNC-2 is the single Cav2-like VGCC α1 subunit present in C. elegans, and is localized to the presynaptic active zone [15]. At synapses UNC-2 regulates calcium ion entry that facilitates synaptic vesicle exocytosis [16]. It is the reduced neural transmission from motor neurons to muscles that likely results in the reduced locomotor activity and the Unc phenotype. To address that the suppression of the nid-1 presynaptic defects was not the result of reduced exocytosis and/or locomotor activity, we tested a LOF mutation in unc-13, which plays essential roles in synaptic transmission and also regulates the sub-synaptic accumulation of synaptic vesicles [16, 17]. unc-13(s69) null mutants are also Unc, but have a more severe loss of locomotor activity than unc-2. In unc-13(s69) yAd animals, puncta were slightly, but not significantly, enlarged (0.95 ± 0.07 μm2, P >0.05 versus wt) (Figure 1G), and there was a significant reduction in the number of puncta formed (18.7 ± 1.5/100 μm (P <0.05 versus wt). In nid-1(cg119);unc-13(s69) double mutants, presynaptic domains were nid-1 like, elongated and disorganized (1.29 ± 0.10 μm2, P >0.05 versus nid-1 and P <0.05 versus unc-13) (Figure 1H). This result suggests that the suppression of nid-1 by unc-2 is unlikely to be the result of impaired exocytosis or reduced locomotion.
We identified unc-2 as a regulator of presynaptic development because it largely suppressed the morphological defects present in nid-1 LOF animals. Cav2-like channels are known to affect synaptic development [8, 9], including by linking synapses to the ECM [18, 19]. In Drosophila mutations in cacophony, a Cav2 α1 voltage-gated calcium channel subunit, result in fewer NMJs being formed, although loss of syntaxin or synaptobrevin showed normal synapses, arguing the loss of the calcium channel had an effect on synapses distinct from its role in exocytosis [8]. We find that although unc-13 mutants have fewer presynaptic domains, this effect was insufficient to suppress the morphological defects caused by the loss of nid-1. It has also been shown that GABA, the neurotransmitter used by the neurons examined here, is not required for NMJ formation [20, 21]. From these results we conclude that UNC-2 regulates presynaptic development in C. elegans independently from neurotransmission, and the phenotype caused by the loss of NID-1 at synapses requires functional UNC-2.
Presynaptic domains exhibit developmentally dynamic morphologies
C. elegans development consists of four larval stages, ultimately leading to an approximately 5 to 10-fold increase in organism length. Since no new GABAergic motor neurons are added after the first larval stage, axons of these neurons, to accommodate the increase in body size, must grow and add synapses accordingly. Since all previous observations were made in yAd animals, we examined synaptic puncta of wt animals in the early, mid and late L4 stages, using the maturation of the vulva as a guide for the developmental stage [22]. In the early L4 stage, SNB-1::GFP puncta in GABAergic neurons appeared of normal size (0.79 ± 0.05 μm2) (Figure 2A). The average area of the puncta noticeably increased starting during the mid-L4 stage (0.87 ± 0.08 μm2) and through the late-L4 stage (1.27 ± 0.08 μm2), and the puncta shapes were frequently found to be elongated, often with a disorganized perimeter (Figure 2B, C). Elongated, disorganized puncta were infrequently observed in yAd stage animals (0.81 ± 0.01 μm2) (Figure 2D), indicating that in wt, presynaptic domains have developmentally dynamic morphologies.
unc-2 mutants displayed fewer presynaptic domains than wt animals (Figure 1). We wondered if this was an effect of the failure to establish synaptic domains during development or the deterioration of existing connections. We found that the puncta in early (0.90 ± 0.05 μm2) and mid L4 (0.79 ± 0.04 μm2) were evenly sized and regularly shaped (Figure 2E, F). However, in late L4 unc-2(e55) animals, enlarged puncta were observed, although to a lesser degree than wt (1.07 ± 0.06 μm2), but did not appear disorganized. Similarly sized puncta were observed in young unc-2 adults (1.04 ± 0.07 μm2) (Figure 2H).
To assess the frequency of enlarged puncta relative to the total number of presynaptic domains observed, we binned individual puncta measured into categories, based on measured area (Figure 3). During the late L4 stage, approximately 35% of the puncta in wt animals appeared enlarged, with an area greater than 1.4 μm2 (approximately nid-1-like), compared to yAds, where less than 15% of puncta fit into that category. The increased number of enlarged puncta came at the expense of normal-sized puncta, suggesting a natural size change occurs during this period. By comparison, there was no change in the proportion of the population (26%) of puncta that measured larger than 1.4 μm2 in unc-2(e55) when we compared late L4s to yAds (Figure 3).
To investigate more precisely the dynamic changes in synapse morphology during the late-L4 stage, we performed time-lapse confocal microscopy on live, non-anesthetized animals (see methods). In wt animals, we saw the following dynamic behaviors: SNB-1::GFP puncta forming de novo, puncta that disappeared, puncta that changed shape by increasing and decreasing in size, and at a low frequency, an existing punctum divided such that two puncta were generated (Figure 4A-C). Overall, per segment of the nerve cord examined (approximately 150 to 200 μm), a net increase of 1 puncta/hour in wt animals was observed.
By contrast in unc-2(e55) animals we found little evidence of dynamic shape changes. Puncta still formed de novo, and puncta did enlarge, but rarely did those enlarged puncta shrink or divide (Figure 4D-F) as was seen in wt. Overall, per segment of the nerve cord examined unc-2 mutants displayed a net loss of approximately 3 NMJ puncta/hour under our time-lapse protocol. It is not clear whether these were budding events that initiated and failed, or were delayed. The decreased number of puncta seen by GFP imaging may be due to a failure in unc-2 animals to add and/or maintain synapses during development. Alternatively, our observations are also consistent with a significant delay in synaptic development, although not a total failure of synaptic addition. Due to the presence of de novo appearance of SNB-1::GFP puncta in unc-2(e55) mutants during the time-lapse imaging, we infer the observed synaptic dynamics likely relies on UNC-2 function after, not during, initial NMJ formation. Further, preliminary analyses indicate that synapses formed in the L3 stage of unc-2 animals can also be enlarged, indicate the function of UNC-2 is not confined to the L4 developmental stage.
unc-36 genetically interacts with unc-2 to regulate neuromuscular junction morphology
Mutations in unc-36, one of two VGCC α2/δ subunit genes in the C. elegans genome, often phenocopy unc-2[15, 23, 24], so we tested if unc-36 was required for normal synaptic morphology. Similar to unc-2, unc-36(e251) caused an increase in SNB-1::GFP area in yAd animals (1.10 ± 0.07 μm2) (P <0.05) (Figure 5A). A slight, but not significant, decrease in puncta number (23.1 ± 1.5) (P >0.05) was also observed. unc-36(e251);nid-1(cg119) double mutants appeared like unc-36 synapses alone, with an apparent area of 1.11 ± 0.07 μm2 (P <0.05 compared to nid-1(cg119) and P >0.05 versus unc-36(e251)) (Figure 5B). Double mutants of unc-2 and unc-36 had puncta that resembled each of the single mutants (1.08 ± 0.05 μm2, P >0.05 versus unc-2 or unc-36 alone) (Figure 5C). unc-2(e55);unc-36(e251);nid-1(cg119) triple mutants displayed no significant differences from either of the double mutant combinations (1.15 ± 0.06 μm2, P >0.05 versus unc-2;nid-1 or unc-36;nid-1) (Figure 5D). unc-36 was also able to suppress ptp-3A defects (1.50 ± 0.09 μm2 (P <0.05) versus unc-36(e251);ptp-3A(tm352) = 0.80 ± 0.10 μm2 (P <0.05) (Figure 5E,F). From these data, we concluded unc-2 and unc-36 likely function in a linear genetic pathway to interact with ptp-3A and nid-1 in synapse development.
We also tested the second C. elegans α2/δ subunit-encoding gene, T24F1.6/tag-180[25]. A LOF allele, ok779, exhibited a minor effect on SNB-1::GFP area (0.73 ± 0.03 μm2 (P <0.05)) [see Additional file 1: Figure S1], and number (28.8 puncta/100 μm (P >0.05)) in yAd animals. tag-180(ok779);nid-1(cg119) double mutants were more like nid-1(cg119) than the ok779 (1.65 ± 0.12 μm2, P <0.05 versus nid-1 alone), indicating the suppression of nid-1 defects is specific to unc-36. Double mutants of ok779 with unc-2 (1.02 μm2, P >0.05 versus unc-2 alone) or unc-36 (1.14 μm2, P >0.05 versus unc-36 alone) similarly showed no significant change from the unc-2 or unc-36 single mutants.
Next we addressed whether the role of unc-36 is cell autonomous. We were able to rescue the Unc (not shown) and Syd (Figure 5G) defects in yAd unc-36(e251) animals by reintroducing a wild type copy of UNC-36 under the control of the endogenous promoter (N = 4 lines) (puncta area - 0.84 ± 0.03, P <0.05 versus unc-36(e251)). The unc-36 promoter is broadly active in the animal, including the muscles and nervous system [15, 25, 26]. To determine whether unc-36 could be functioning cell autonomously, we specifically expressed UNC-36 in the GABAergic motor neurons in unc-36(e251);juIs1 animals. As expected, the locomotor defects were not rescued, but the size of the presynaptic puncta in these animals was significantly reduced relative to unc-36(e251) yAd animals lacking the transgene (0.69 ± 0.05, P <0.05 versus unc-36(e251)) (Figure 5H) (N = 1 line), indicating that unc-36 is capable of cell autonomously affecting the GABAergic NMJs.
α2/δ subunits have been implicated in synapse formation and development [10, 27, 28]. In the vertebrate central nervous system (CNS), thrombospondin (TSP) molecules act as ligands for α2/δ1. Overexpression of α2/δ1 results in increased synaptogenesis, while interfering with the TSP-α2/δ1 interaction inhibited synaptogenesis. The C-terminal region of TSP, that contains EGF repeats, binds directly to the von Willebrand factor-A domain (VWF-A) present in the α2 portion of the α2/δ1 protein [10]. Since NID-1 contains EGF repeats and localizes near NMJs [11, 29], and UNC-36 has a VWF-A domain, it is possible that NID-1 might physically interact with UNC-36. However, at GABAergic NMJs, the loss of nid-1 causes morphological defects that are suppressed by removing unc-36. Also, LOF in unc-36 has a very modest reduction in synapses formed. Thus, it seems unlikely that NID-1 acts as a ligand for UNC-36 to promote synapse addition.
There is evidence from Drosophila that α2/δ subunits can have effects on synaptic development independent from the α1 subunits [28]. However, our data suggest unc-36 and unc-2 are acting in the same genetic pathway. Work from the Bargmann lab has demonstrated that UNC-36, along with the calcium channel chaperone CALF-1, is required for the localization of UNC-2 to the synaptic plasma membrane [15]. Thus, a simple explanation for the synaptic patterning defects would be a failure to direct UNC-2 to the synaptic plasma membrane in unc-36(e251) mutants. In this model, we would assume that UNC-2 is the key player required to drive changes in synaptic development, although we cannot rule out UNC-36 may have additional functions at NMJs.
unc-36 function is required during the 4th larval stage period for synaptic development
Next, to address the temporal requirement of VGCC, we used the α2/δ-antagonist gabapentin [30] to acutely inhibit VGCC function specifically during the L4 stage of development. In cultured vertebrate neurons gabapentin inhibits the trafficking of α2/δ subunits from the endoplasmic reticulum to the plasma membrane [31]. Wild type early L4 animals were exposed to gabapentin (100 μM) for 24 hours. When imaged as yAds, these animals had a significant increase in SNB-1::GFP area (1.00 ± 0.06 μm2, P <0.05 versus vehicle alone - 0.83 ± 0.06) (Figure 5I). This suggests that gabapentin is phenocopying unc-36 LOF, although since presynaptic domains in double mutants of unc-36 with tag-180 resembled those found in unc-36 alone, we cannot rule out that gabapentin was broadly affecting α2/δ function.
Gabapentin treatment of nid-1(cg119) mutant L4 animals, resulted in a significant decrease in the SNB-1::GFP area (0.96 ± 0.05 μm2, P <0.05 versus nid-1 alone), indicating that acute gabapentin treatment of nid-1(cg119) animals during the L4 stage was able to, at least partially, suppress presynaptic defects (Figure 5J). We conclude from our analysis that the synaptic patterning that occurs in late L4 animals requires intact α2/δ function during that period, rather than being fixed in an earlier developmental event. nid-1 mutants have defective presynaptic morphologies prior to L4, and these appear to be ameliorated by LOF in unc-2. Thus, we do not rule out a function for VGCCs prior to L4, and this result would suggest that synaptic morphologies are broadly dynamic during L4 development.
CaMKII regulates synaptic morphology
To identify molecules that might utilize changes in local calcium concentrations to shape presynaptic domains, we undertook a candidate-molecule approach. The first gene we examined was unc-43/CaMKII. CaMKII has been extensively linked to both pre- and postsynaptic development in multiple organisms (for review see [32, 33]). UNC-43 has been shown to work downstream of unc- 2, and UNC-43 localization is dependent on UNC-2. CaMKII proteins have been shown to affect synapse development in multiple systems, including C. elegans where UNC-43 functions in the synaptic development of the glutamatergic neurons [34–36]. Because the complete loss of unc-43 is embryonic lethal, we used a hypomorphic LOF allele, e408. e408 yAd animals have slightly enlarged SNB-1::GFP (Figure 6A) (1.03 ± 0.08 μm2, P <0.05 versus wt). Thus, reduced UNC-43 function has a similar manifestation at synapses as the loss of UNC-2 and UNC-36.
Like LOF in unc-2 or unc-36, the unc-43(e408) LOF suppressed defects present in nid-1 (Figure 6B) (1.06 ± 0.07 μm2, P <0.05 versus nid-1) and ptp-3A yAds (ptp-3A(ok244) (1.03 ± 0.12 μm2, P <0.05 versus ptp-3A(ok244) (1.42 ± 0.09 μm2)). In contrast, unc-43(n498) GOF [37], bearing a constitutively activating mutation, E108K, in the active site core [35], SNB-1::GFP puncta were elongated and disorganized in yAds (1.26 ± 0.11 μm2, P <0.05 versus wt) (Figure 6C), and similar to nid-1 (P >0.05 versus nid-1).
We next examined whether unc-43 was functioning cell autonomously by expressing an mCherry-tagged unc-43 cDNA, under the control of the unc-25 promoter, in the unc-43(e408);juIs1 animals. Replacing UNC-43D (Wormbase: CE28054) specifically in the GABAergic neurons rescued the defects in e408, (0.83 ± 0.05 μm2, (N = 6 lines) P >0.05 versus wt and P <0.05 versus e408). The RFP::UNC-43 chimera was localized throughout the cytoplasm, including being present at synapses, as evidenced by co-localization with the SNB-1::GFP (Figure 6D-G). The localization of UNC-43 suggests it could be directly functioning at NMJs to locally affect morphology.
Conclusions
VGCCs contribute to synaptic development in Caenorhabditis elegans
Here we show that mutations in the single Cav2, unc-2, result in changes to the number, size and shape of presynaptic domains that form during development. The overall reduction in the number of synapses formed in unc-2 mutants is modest, suggesting that the primary role of VGCCs is not to promote de novo synapse addition. Rather, UNC-2 function is most evident in the maintenance of presynaptic domain morphology, as unc-2 mutants display areas that are enlarged relative to wild type.
The function of unc-2 in regulating presynaptic morphology is also observed when the synaptically associated adhesion molecules NID-1 or PTP-3A are absent. Removing UNC-2 from nid-1 or ptp-3 loss-of-function backgrounds ameliorates the mislocalization of presynaptic proteins and synaptic overgrowth in those mutants. This indicates that the morphological changes associated with the loss of NID-1-mediated adhesion require functional UNC-2, but independent of synaptic vesicle exocytosis.
Regulation of adhesion and growth at synapses
Synapses are dynamic structures that can be added or removed, or change shape to accommodate functional changes in neural networks and/or organismal growth. In Drosophila, transient changes in adhesion have been shown directly to permit switching between synaptic stability and synaptic growth [38–43]. Molecularly, both Fas2 and discs large (DLG) appear to be important for synaptic stability. Down regulation of Fas2-mediated adhesion by activation of CaMKII has been shown to specifically induce synaptic growth [40, 42, 43].
DLAR, the Drosophila PTP-3 homolog, has also been shown to complex with different ligands to switch between synaptic stability and synaptic growth [39]. In vertebrates, cell adhesion molecules like laminins and nidogens are required for NMJ maintenance. In cultured vertebrate neurons, regulation of liprin-α, via CaMKII, has been shown to regulate LAR to affect dendritic spine stability at excitatory synapses [40]. Overall, these findings suggest that changes in synaptic morphology that occur normally in development require modulation of the synaptic adhesion that maintains synaptic structure.
Using time-lapse analysis we find that, in C. elegans, during a specific developmental window, presynaptic domains in wild type animals can be morphologically similar to those found in nid-1/ptp-3A mutant adults. Further, we observed that a nid-1-like elongated punctum could divide to form multiple new puncta. These dynamics, both elongation and division, were dependent on unc-2. Based on our results and data from other systems, a simple model is that nidogen-LAR adhesion maintains NMJ structure, and that developmental changes in synaptic morphology require transient inhibition of nidogen-LAR adhesion, and that this occurs via a pathway that includes UNC-2, UNC-36 and UNC-43.
Cooperative versus antagonistic interactions between the extracellular matrix and voltage-gated calcium channels in synaptic maintenance
Previous work has shown that the ECM and the VGCCs work cooperatively to stimulate synapse development [9, 10, 19]. For example, the synaptically associated laminin β2 subunit can directly bind to an extracellular loop in the VGCC α1 polypeptide. In cultured neurons, this interaction induces the clustering of synaptic vesicles at the binding site. However, neither the genetic ablation of either Cav2.1 or laminin β2, nor disrupting the binding of these proteins in vivo results in a total failure in synapse formation [9]. Rather, a defect in synaptic growth and/or maintenance was observed in those animals. Similarly, NMJs in mice lacking nidogen-2 do form normally, but fail to develop, beginning to fragment around three weeks after birth, suggesting a role in synaptic maintenance for nidogen-2 as well [44], although no interaction has been described between nidogen and VGCCs in vertebrates.
We have found that nidogen is required for synaptic maintenance, which suggests a conservation of function for this ECM molecule. However, we also see that the defects observed in nid-1 mutants require functional UNC-2 VGCCs. Thus, in contrast to the apparent cooperative interaction observed in vertebrates, our study suggests perhaps an antagonistic interaction between VGCCs and ECMs in C. elegans. It is possible that our findings reflect a difference in the growth of vertebrate NMJs that form at axon terminals and C. elegans NMJs that form en passant.
It is worth noting that we also find that presynaptic domains in unc-2 mutants are slightly enlarged in comparison to wild type animals. This may seem contradictory in that the loss of unc-2 also limits synapses from elongating during specific periods of development or when nid-1 is absent. A simple way of thinking about this is that in the absence of UNC-2, NMJs are too stable, unable to respond to signals that instruct them to enlarge or shrink. This would be a novel finding for this class of VGCCs: that they function as key regulators of dynamic changes in synaptic morphology. Going forward our goal will be to identify how UNC-2 can regulate these seemingly distinct functions at NMJs.
Methods
Caenorhabditis elegans strains
All C. elegans strains were maintained at 20 to 22.5°C as described [45]. The following alleles were used in this report: N2 (var. Bristol), nid-1(cg119), unc-2(ju493), unc-2(e55), unc-36(e251), tag-180(ok779), egl-19(n582), cca-1(ad1650), ptp-3A(tm352), ptp-3A(tm352); ptp-3A(ok244), ptp-3(mu256), unc-43(n498), unc-43(e408), nid-1(cg119)rpm-1(ju44), unc-13(s69), tra-2(q276)/mnC1. The following integrated strain was used: juIs1 [Punc-25::SNB-1::GFP]. Transgenic animals were generated by germ line transformation as described [46]. To conduct the ju493/e55 non-complementation, tra-2(q276);juIs1/+;ju493/+ XX males were crossed to unc-2(e55) hermaphrodites. Cross progeny were identified by presence of GFP (juIs1), non-complementation was determined by presence of UncGfp animals.
Genetic modifier screen
nid-1(cg119)rpm-1(ju44);juIs1 animals were mutagenized using 50mM ethane methyl sulfonate (EMS). F2 animals were scored for a hypercontracted uncoordinated phenotype that is observed in syd-2;rpm-1 double mutants. Individual HypUnc animals were allowed to self-fertilize to insure transmission of the phenotype. The animals were outcrossed to either nid-1(cg119) or rpm-1(ju44) single mutant backgrounds to determine the effect of new mutations.
Image analysis
Synapse morphology of D type neurons was visualized by juIs1 [Punc-25 SNB-1::GFP]. All images were collected on either a Zeiss Pascal confocal microscope or an Olympus FV1000 confocal microscope equipped with Fluoview software (Olympus America Inc., Center Valley, PA USA). Images were acquired using multi-track parameters when necessary (unc-36 and unc-43 rescue), with either a 63X or 60X Plan-apochromat objective, respectively. Animals were anesthetized using 0.5% phenoxy-propanol (TCI America, Portland, OR U.S.A.) in M9 and mounted on 2% agarose pads. Measurements of SNB-1::GFP were as described with minor modifications [11]. All images were collected using the exact same microscope settings. Briefly, confocal images were projected into a single plane using the maximum projection and exported as a tiff file with a scale bar. Using ImageJ the files were converted to a binary image using the threshold command, so that the binary image resembled the RGB image. A region of interest was drawn around the relevant region of the nerve cords. The following measurement options were selected: Area, Center of Mass, Circularity, Perimeter, Fit Ellipse, and Limit to Threshold. Scaling was set by measuring the scale bar. The “Analyze Particle” command was used with a minimum of four pixels and no maximum size. The following options were selected: Outline Particles, Ignore Particles Touching Edge, Include Interior Holes and Reset Counter. The resulting measurements were exported to Microsoft Excel and GraphPad Prism for statistical analysis. Comparisons of single mutants to the wild type were tested by Students two-tailed t-test, while double and triple mutant combinations were compared within the group using a Kruskal-Wallis test with a Dunn’s Multiple Comparison post hoc test. Circularity is a measure of how close to a perfect circle an object is, where 0 is a line and 1 is a perfect circle. The test relates the area of the observed object to the area of a circle with the same radius:
UNC-36 rescue
To rescue the unc-36(e251) defect we generated a PCR product including the putative promoter and endogenous 3′UTR using the following primers (unc-36promF1: 5′-ccacgtacatagaattcggaatc-3′ and unc-36 3′UTR R1: 5′- caaggcagttggaaagtcgac-3′). The PCR product was TOPO cloned into pCRXLII (Life Technologies, Grand Island, NY USA) to generate pBA234. pBA234 was injected at 10 ng/μl into unc-36(e251);juIs1 animals along with pPD118.33 (Pmyo-2::gfp) as a co-injection marker, plus pBA186 (Punc-25::mCherry) to mark the GABAergic motor neurons containing the transgene.
Cell-specific rescue
A genomic fragment covering the unc-36 coding region was amplified using the following primers (unc-36promF1: 5′-ccacgtacatagaattcggaatc-3′ and unc-36 3′UTR R1: 5′- caaggcagttggaaagtcgac-3′). The PCR product was T/A cloned into the pCR8/GW/TOPO vector (Life Technologies), and then was recombined using L/R clonase (Life Technologies) into pBA153, creating pEVL404 (Punc-25::unc-36). pEVL404 was injected into unc-36(e251);juIs1 animals at 10 ng/μl along with pPD118.33 (Pmyo-2::gfp) as a co-injection marker. For unc-43, we isolated a full-length cDNA for UNC-43D isoform by RT-PCR from wild type RNA isolated by Trizol using the following primers (unc-43cDNA F1: 5′-atgatgaacgcaagcacca-3′ and unc-43cDNA R1: 5′- ctagaattcagatactgttgtatttgttg-3′). Using the InFusion (Clontech Laboratories, Inc., Mountain View, CA USA) enzyme this product was recombined into pEVL387 (Punc-25::mCherry::unc-43 3′UTR) to generate pEVL400 (Punc-25::mCherry::unc-43E::unc-43 3′UTR). The pEVL400 plasmid was injected into unc-43(e408);juIs1 at 5 ng/μl. Any additional information about sequences or cloning procedures is available upon request.
Time-lapse analysis
L4 animals were immobilized on 10% agarose pads in the presence of 5% (w/v) polystyrene beads (Bangs Laboratory, Fishers, IN USA). Animals were imaged at 5-minute intervals for 1 hour. Animals that died during the acquisition process (as determined by a rapid and dramatic increase in intestinal autofluorescence) were excluded from the analysis. Images were then exported to ImageJ. Z-stacks were produced for each time point, and then times 0 and 60 minutes were thresholded, converted to masks and overlaid as false colored, green and red respectively. This allowed simple determination of spots that were added or removed, grew or shrank or divided during the analysis period. The total number of puncta added/lost during the hour session was determined by comparing initial time and final time points for the appearance or disappearance of puncta.
Pharmacology
Gabapentin (Sigma Aldrich, St. Louis, MO USA) was resuspended in DMSO at 100 mM, and then diluted in 1:10 in PBS and added to standard NGM plates seeded with OP50 E. coli to achieve the final desired concentration. Using plates with an increasing dose of gabapentin, we found that animals reared throughout development on NGM plates containing 100 μM gabapentin phenotypically resembled unc-36, appearing thin, with poor movement (data not shown), thus we used this concentration for our experiments. Plates were permitted to dry overnight and then 20 L4 animals of each genotype were placed on the media. Animals were imaged 24 hours later (as young adults).
Abbreviations
- CaMKII:
-
calmodulin kinase II
- CNS:
-
central nervous system
- ECM:
-
extracellular matrix
- GABA:
-
γ-amino butyric acid
- GOF:
-
gain of function
- LOF:
-
loss of function
- L4:
-
4th larval stage
- NMJ:
-
neuromuscular junction
- S.E.M.:
-
standard error of the mean
- Syd:
-
synapse defective
- Unc:
-
uncoordinated movement
- VGCC:
-
voltage-gated calcium channel
- wt:
-
wild type.
References
Catterall WA, Perez-Reyes E, Snutch TP, Striessnig J: International Union of Pharmacology. XLVIII. Nomenclature and structure-function relationships of voltage-gated calcium channels. Pharmacol Rev. 2005, 57: 411-425. 10.1124/pr.57.4.5.
Dalton S, Takahashi SX, Miriyala J, Colecraft HM: A single CaVbeta can reconstitute both trafficking and macroscopic conductance of voltage-dependent calcium channels. J Physiol. 2005, 567: 757-769. 10.1113/jphysiol.2005.093195.
Opatowsky Y, Chen CC, Campbell KP, Hirsch JA: Structural analysis of the voltage-dependent calcium channel beta subunit functional core and its complex with the alpha 1 interaction domain. Neuron. 2004, 42: 387-399. 10.1016/S0896-6273(04)00250-8.
De Jongh KS, Warner C, Catterall WA: Subunits of purified calcium channels. Alpha 2 and delta are encoded by the same gene. J Biol Chem. 1990, 265: 14738-14741.
Andrade A, Sandoval A, Oviedo N, De Waard M, Elias D, Felix R: Proteolytic cleavage of the voltage-gated Ca2+ channel alpha2delta subunit: structural and functional features. Eur J Neurosci. 2007, 25: 1705-1710. 10.1111/j.1460-9568.2007.05454.x.
Felix R: Voltage-dependent Ca2+ channel alpha2delta auxiliary subunit: structure, function and regulation. Receptors Channels. 1999, 6: 351-362.
Catterall WA: Structure and regulation of voltage-gated Ca2+ channels. Annu Rev Cell Dev Biol. 2000, 16: 521-555. 10.1146/annurev.cellbio.16.1.521.
Rieckhof GE, Yoshihara M, Guan Z, Littleton JT: Presynaptic N-type calcium channels regulate synaptic growth. J Biol Chem. 2003, 1: 1-
Nishimune H, Sanes JR, Carlson SS: A synaptic laminin-calcium channel interaction organizes active zones in motor nerve terminals. Nature. 2004, 432: 580-587. 10.1038/nature03112.
Eroglu C, Allen NJ, Susman MW, O’Rourke NA, Park CY, Ozkan E, Chakraborty C, Mulinyawe SB, Annis DS, Huberman AD, Green EM, Lawler J, Dolmetsch R, Garcia KC, Smith SJ, Luo ZD, Rosenthal A, Mosher DF, Barres BA: Gabapentin receptor alpha2delta-1 is a neuronal thrombospondin receptor responsible for excitatory CNS synaptogenesis. Cell. 2009, 139: 380-392. 10.1016/j.cell.2009.09.025.
Ackley BD, Kang SH, Crew JR, Suh C, Jin Y, Kramer JM: The basement membrane components nidogen and type XVIII collagen regulate organization of neuromuscular junctions in Caenorhabditis elegans. J Neurosci. 2003, 23: 3577-3587.
Ackley BD, Harrington RJ, Hudson ML, Williams L, Kenyon CJ, Chisholm AD, Jin Y: The two isoforms of the Caenorhabditis elegans leukocyte-common antigen related receptor tyrosine phosphatase PTP-3 function independently in axon guidance and synapse formation. J Neurosci. 2005, 25: 7517-7528. 10.1523/JNEUROSCI.2010-05.2005.
Schafer WR, Kenyon CJ: A calcium-channel homologue required for adaptation to dopamine and serotonin in Caenorhabditis elegans. Nature. 1995, 375: 73-78. 10.1038/375073a0.
Hallam SJ, Jin Y: lin-14 regulates the timing of synaptic remodelling in Caenorhabditis elegans. Nature. 1998, 395: 78-82. 10.1038/25757.
Saheki Y, Bargmann CI: Presynaptic CaV2 calcium channel traffic requires CALF-1 and the alpha(2)delta subunit UNC-36. Nat Neurosci. 2009, 12: 1257-1265. 10.1038/nn.2383.
Richmond JE, Weimer RM, Jorgensen EM: An open form of syntaxin bypasses the requirement for UNC-13 in vesicle priming. Nature. 2001, 412: 338-341. 10.1038/35085583.
Weimer RM, Gracheva EO, Meyrignac O, Miller KG, Richmond JE, Bessereau JL: UNC-13 and UNC-10/rim localize synaptic vesicles to specific membrane domains. J Neurosci. 2006, 26: 8040-8047. 10.1523/JNEUROSCI.2350-06.2006.
Carlson SS, Valdez G, Sanes JR: Presynaptic calcium channels and alpha3-integrins are complexed with synaptic cleft laminins, cytoskeletal elements and active zone components. J Neurochem. 2010, 115: 654-666. 10.1111/j.1471-4159.2010.06965.x.
Chen J, Billings SE, Nishimune H: Calcium channels link the muscle-derived synapse organizer laminin beta2 to Bassoon and CAST/Erc2 to organize presynaptic active zones. J Neurosci. 2011, 31: 512-525. 10.1523/JNEUROSCI.3771-10.2011.
Gally C, Bessereau JL: GABA is dispensable for the formation of junctional GABA receptor clusters in Caenorhabditis elegans. J Neurosci. 2003, 23: 2591-2599.
Jin Y, Jorgensen E, Hartwieg E, Horvitz HR: The Caenorhabditis elegans gene unc-25 encodes glutamic acid decarboxylase and is required for synaptic transmission but not synaptic development. J Neurosci. 1999, 19: 539-548.
Lints R, Hall DH: Reproductive system, egglaying apparatus. In WormAtlas. 2009, 10.3908/wormatlas.1.24.
Schafer WR, Sanchez BM, Kenyon CJ: Genes affecting sensitivity to serotonin in Caenorhabditis elegans. Genetics. 1996, 143: 1219-1230.
Frokjaer-Jensen C, Kindt KS, Kerr RA, Suzuki H, Melnik-Martinez K, Gerstbreih B, Driscol M, Schafer WR: Effects of voltage-gated calcium channel subunit genes on calcium influx in cultured C. elegans mechanosensory neurons. J Neurobiol. 2006, 66: 1125-1139. 10.1002/neu.20261.
Laine V, Frokjaer-Jensen C, Couchoux H, Jospin M: The alpha1 subunit EGL-19, the alpha2/delta subunit UNC-36, and the beta subunit CCB-1 underlie voltage-dependent calcium currents in Caenorhabditis elegans striated muscle. J Biol Chem. 2011, 286: 36180-36187. 10.1074/jbc.M111.256149.
Hunt-Newbury R, Viveiros R, Johnsen R, Mah A, Anastas D, Fang L, Halfnight E, Lee D, Lin J, Lorch A, McKay S, Okada HM, Pan J, Schulz AK, Tu D, Wong K, Zhao Z, Alexeyenko A, Burglin T, Sonnhammer E, Schnabel R, Jones SJ, Marra MA, Baillie DL, Moerman DG: High-throughput in vivo analysis of gene expression in Caenorhabditis elegans. PLoS Biol. 2007, 5: e237-10.1371/journal.pbio.0050237.
Dickman DK, Kurshan PT, Schwarz TL: Mutations in a Drosophila alpha2delta voltage-gated calcium channel subunit reveal a crucial synaptic function. J Neurosci. 2008, 28: 31-38. 10.1523/JNEUROSCI.4498-07.2008.
Kurshan PT, Oztan A, Schwarz TL: Presynaptic alpha2delta-3 is required for synaptic morphogenesis independent of its Ca2 + −channel functions. Nat Neurosci. 2009, 12: 1415-1423. 10.1038/nn.2417.
Kang SH, Kramer JM: Nidogen is nonessential and not required for normal type IV collagen localization in caenorhabditis elegans. Mol Biol Cell. 2000, 11: 3911-3923.
Davies A, Hendrich J, Van Minh AT, Wratten J, Douglas L, Dolphin AC: Functional biology of the alpha(2)delta subunits of voltage-gated calcium channels. Trends Pharmacol Sci. 2007, 28: 220-228. 10.1016/j.tips.2007.03.005.
Tran-Van-Minh A, Dolphin AC: The alpha2delta ligand gabapentin inhibits the Rab11-dependent recycling of the calcium channel subunit alpha2delta-2. J Neurosci. 2010, 30: 12856-12867. 10.1523/JNEUROSCI.2700-10.2010.
Colbran RJ, Brown AM: Calcium/calmodulin-dependent protein kinase II and synaptic plasticity. Curr Opin Neurobiol. 2004, 14: 318-327. 10.1016/j.conb.2004.05.008.
Lisman J, Yasuda R, Raghavachari S: Mechanisms of CaMKII action in long-term potentiation. Nat Rev Neurosci. 2012, 13: 169-182.
Tam T, Mathews E, Snutch TP, Schafer WR: Voltage-gated calcium channels direct neuronal migration in Caenorhabditis elegans. Dev Biol. 2000, 226: 104-117. 10.1006/dbio.2000.9854.
Umemura T, Rapp P, Rongo C: The role of regulatory domain interactions in UNC-43 CaMKII localization and trafficking. J Cell Sci. 2005, 118: 3327-3338. 10.1242/jcs.02457.
Reiner DJ, Newton EM, Tian H, Thomas JH: Diverse behavioural defects caused by mutations in Caenorhabditis elegans unc-43 CaM kinase II. Nature. 1999, 402: 199-203. 10.1038/46072.
Park EC, Horvitz HR: Mutations with dominant effects on the behavior and morphology of the nematode Caenorhabditis elegans. Genetics. 1986, 113: 821-852.
Woo J, Kwon SK, Choi S, Kim S, Lee JR, Dunah AW, Sheng M, Kim E: Trans-synaptic adhesion between NGL-3 and LAR regulates the formation of excitatory synapses. Nat Neurosci. 2009, 12: 428-437. 10.1038/nn.2279.
Johnson KG, Tenney AP, Ghose A, Duckworth AM, Higashi ME, Parfitt K, Marcu O, Heslip TR, Marsh JL, Schwarz TL, Flanagan JG, Van Vactor D: The HSPGs Syndecan and Dallylike bind the receptor phosphatase LAR and exert distinct effects on synaptic development. Neuron. 2006, 49: 517-531. 10.1016/j.neuron.2006.01.026.
Hoogenraad CC, Feliu-Mojer MI, Spangler SA, Milstein AD, Dunah AW, Hung AY, Sheng M: Liprinalpha1 degradation by calcium/calmodulin-dependent protein kinase II regulates LAR receptor tyrosine phosphatase distribution and dendrite development. Dev Cell. 2007, 12: 587-602. 10.1016/j.devcel.2007.02.006.
Zito K, Parnas D, Fetter RD, Isacoff EY, Goodman CS: Watching a synapse grow: noninvasive confocal imaging of synaptic growth in Drosophila. Neuron. 1999, 22: 719-729. 10.1016/S0896-6273(00)80731-X.
Beumer K, Matthies HJ, Bradshaw A, Broadie K: Integrins regulate DLG/FAS2 via a CaM kinase II-dependent pathway to mediate synapse elaboration and stabilization during postembryonic development. Development. 2002, 129: 3381-3391.
Koh YH, Popova E, Thomas U, Griffith LC, Budnik V: Regulation of DLG localization at synapses by CaMKII-dependent phosphorylation. Cell. 1999, 98: 353-363. 10.1016/S0092-8674(00)81964-9.
Fox MA, Ho MS, Smyth N, Sanes JR: A synaptic nidogen: developmental regulation and role of nidogen-2 at the neuromuscular junction. Neural Dev. 2008, 3: 24-10.1186/1749-8104-3-24.
Brenner S: The genetics of Caenorhabditis elegans. Genetics. 1974, 77: 71-94.
Mello CC, Kramer JM, Stinchcomb D, Ambros V: Efficient gene transfer in C.elegans: extrachromosomal maintenance and integration of transforming sequences. Embo J. 1991, 10: 3959-3970.
Acknowledgements
BDA was supported in part by a postdoctoral fellowship from the Muscular Dystrophy Association, P20 RR016475 from the INBRE Program of the NCRR and RC1 GM091086 from the NIH. YJ is an investigator of, HHMI. Support was provided by NIH NS035546 to YJ.
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Authors’ contributions
RCC and BDA carried out the molecular, genetic and cell biological studies and collected and analyzed the data. YJ and BDA designed and conducted the genetic screen to isolate ju493. BDA drafted the manuscript. All authors have read and approved the final manuscript.
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Additional file 1: Figure 1: Specificity of interaction between unc-2/unc-36 and nid-1. (A) The egl-19 LOF allele, n582, animals had normal appearing SNB-1::GFP puncta. (B) In egl-19(n582); nid-1(cg119) the puncta appear enlarged and disorganized. (C) A deletion in the Cav3-like channel, cca-1, had no obvious effect on SNB-1:GFP morphology. (D) Removing cca-1 from nid-1 mutants did not suppress the morphological changes, as puncta were observed to be elongated and disorganized. (E) Loss of the second α 2/δ subunit, tag-180, had only a modest effect on SNB-1::GFP puncta, but did not suppress the defects found in nid-1 mutants (F). (G) A plot of the puncta area measured by genotype as mean (circle) with the 5 to 95% confidence interval (whiskers). All animals in these micrographs are young adults (1 to 2 days post larval stage 4 (L4)). (EPS 7 MB)
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Caylor, R.C., Jin, Y. & Ackley, B.D. The Caenorhabditis elegans voltage-gated calcium channel subunits UNC-2 and UNC-36 and the calcium-dependent kinase UNC-43/CaMKII regulate neuromuscular junction morphology. Neural Dev 8, 10 (2013). https://doi.org/10.1186/1749-8104-8-10
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DOI: https://doi.org/10.1186/1749-8104-8-10