Abstract
The signaling mechanisms that allow the conversion of a growth cone into a mature and stable synapse are yet to be completely understood. Ubiquitination plays key regulatory roles in synaptic development and may be involved in this process. Previous studies identified the Drosophila ubiquitin conjugase bendless (ben) to be important for central synapse formation, but the precise role it plays has not been elucidated. Our studies indicate that Ben plays a pivotal role in synaptic growth and maturation. We have determined that an incipient synapse is present with a high penetrance in ben mutants, suggesting that Ben is required for a developmental step after target recognition. We used cell-autonomous rescue experiments to show that Ben has a presynaptic role in synapse growth. We then harnessed the TARGET system to transiently express UAS (upstream activating sequence)–ben in a ben mutant background and identified a well defined critical period for Ben function in establishing a full-grown, mature synaptic terminal. We demonstrate that the protein must be present at a time point before but not during the actual growth process. We also provide phenotypic evidence demonstrating that Ben is not a part of the signal transduction pathway involving the well characterized ubiquitin ligase highwire. We conclude that Bendless functions as a novel developmental switch that permits the transition from axonal growth and incipient synapse formation to synaptic growth and maturation in the CNS.
Introduction
The formation, growth, and stabilization of synapses are crucial phenomena in the establishment of functional neural circuits. An important regulatory mechanism in synapse formation and function is ubiquitination, which refers to the posttranslational modification of a target protein by the addition of one (monoubiquitination) or more (multiubiquitination and polyubiquitination) adducts of the 76 amino acid ubiquitin polypeptide (Murphey and Godenschwege, 2002; DiAntonio and Hicke, 2004; Haas and Broadie, 2008). The transfer of ubiquitin to a substrate takes place through an enzymatic cascade involving a ubiquitin activating enzyme E1, a ubiquitin conjugating enzyme E2, and a ubiquitin ligase E3 (Hershko and Ciechanover, 1998). With regard to regulation of nervous system development, ubiquitin has been implicated in the regulation of axon guidance (Campbell and Holt, 2001), axonal pruning (Watts et al., 2003), synapse development (DiAntonio et al., 2001), neurotransmitter release (Wilson et al., 2002; Aravamudan and Broadie, 2003), number of postsynaptic receptors (Bedford et al., 2001; Buttner et al., 2001; Burbea et al., 2002; Patrick et al., 2003), and components of the postsynaptic density (Ehlers, 2003).
One of the first results that pointed to the ubiquitin system playing a role in the regulation of neuronal connectivity came from the analysis of the Drosophila mutant bendless (ben). ben was identified more than two decades ago in a behavioral screen for defects in the giant fiber system (GFS) (see Fig. 1A,B) that resulted in an altered escape response (Thomas and Wyman, 1982). Cloning of ben led to its identification as an E2 ubiquitin conjugase (Muralidhar and Thomas, 1993; Oh et al., 1994). The mutation was found to particularly affect the synapse between the giant fiber (GF) and the tergotrochanteral motorneuron (TTMn) as the GF axon, after making normal contact with the peripherally synapsing interneuron (PSI), fails to make the lateral “bend,” which represents its large presynaptic terminal on the TTMn (Thomas and Wyman, 1984). Additional phenotypes were also reported in thoracic musculature (Edgecomb et al., 1993) and in the visual system (Muralidhar and Thomas, 1993; Oh et al., 1994).
Previous studies have suggested that Ben plays an important role in axon guidance or target recognition (Muralidhar and Thomas, 1993; Oh et al., 1994). However, the underlying mechanism by which Ben regulates the formation of a mature synapse is yet to be clarified. Our analyses of the ben mutant in the GF system using anatomical studies as well as specific approaches to determine the spatial and temporal aspects of gene function have given us novel evidence indicating that Ben plays an important role in synapse growth. Our studies suggest that Ben functions as an acute developmental switch that allows axonal growth to transition into synaptic growth, allowing for the establishment of a mature synaptic connection. To our knowledge, this is the first time that a component of the ubiquitin system has been shown to play the role of a key permissive factor that allows synaptic growth and maturation to take place, in contrast to, say, the ubiquitin ligase highwire (hiw) which can been characterized to actively regulate the growth process.
Materials and Methods
Drosophila stocks.
All stocks were grown on standard medium at either 22°C or 25°C unless otherwise indicated. The following fly stocks were used: ben1, hereafter referred to as ben (Thomas and Wyman, 1984), ben deficiency (Bloomington stock 968, Df(1)HA92/FM7c), upstream activating sequence (UAS)–ben (second chromosome), ben; UAS–ben, UAS–green fluorescent protein (GFP)–ben (second chromosome), fat facets (faf) EP(3)0381 (Rorth et al., 1998), hiwND8(Wan et al., 2000), and UAS–bskDN (Weber et al., 2000). Three P[GAL]4 drivers that express in the GF system were used: the A307 driver has strong presynaptic expression in the GF along with weaker expression in postsynaptic targets (Allen et al., 1998), c17 drives expression in the GF but not in its postsynaptic targets (Godenschwege et al., 2002), and ShakB–Gal4 drives expression only postsynaptically (Jacobs et al., 2000).
Generation of UAS–GFP–ben transgenic line.
ben cDNA was cloned into the eGFPC1 vector with KpnI and SalI. The GFP–ben fragment was excised with NheI and SpeI and subcloned into the pUASt vector cut with XbaI. Construct fidelity was verified by sequencing (Davis Sequencing, Davis, CA), and embryos were transformed at the Transgenic Drosophila Fly Core (Massachusetts General Hospital, Boston, MA).
Electrophysiology.
Sharp electrode intracellular recordings from the TTM muscles were obtained from intact adult flies in a method similar to that described previously (Tanouye and Wyman, 1980). The physiological assay was modified and data were analyzed as described previously (Godenschwege et al., 2002).
Dye injections, imaging, and analysis.
For anatomical analysis, the dissected CNS was mounted dorsal side up on a poly-lysine-coated slide. The preparation was immersed in saline and viewed with a 40× water immersion lens. The axons of the GFs are identified in the connective using differential interference contrast optics. A glass electrode (20–80 MΩ) containing 1% aqueous Lucifer yellow and backfilled with 3 m LiCl was used to impale the GF in the connective. The dye was injected into the GF by the passage of 3–5 nA of hyperpolarizing current using a Getting 5A Amplifier (Getting Instruments). Images in Figures 2 and 6 were obtained by taking maximum projections of Z-stack images taken using an advanced SPOT camera and MetaVue software. Deconvolution was performed on images using Autovisulize and Autoblur software version 9.3 (Autoquant). For UAS–GFP–ben localization in Figure 5, the image in A was taken using a coolSNAP HQ2 camera on a Nikon Eclipse FN1 microscope with 10× objective using NIS elements. Image was deconvolved with AutoquantX2 software (Media Cybernetics). Images in B–D were taken on a Nikon Eclipse C1si confocal system with a 40× objective on a 90i microscope.
Ultrastructure.
The adult CNS was dissected from ben flies that were electrophysiologically tested and wild-type (wt) controls. The CNS underwent prefixation in 2.5% glutaraldehyde for 24 h and was osmicated (1% osmium tetroxide) for 1 h. Subsequent to dehydration, the CNS was embedded in Epon–Araldite. Ultrathin serial sections (50–60 nm) were taken and counterstained with 1% aqueous uranyl acetate and lead citrate. The sections were examined with a Jeol 100s electron microscope. The GF–TTMn synaptic region was photographed, and the negatives were scanned using a high-resolution flatbed scanner.
Temporal expression of UAS–ben using the TARGET system.
The TARGET system (McGuire et al., 2003) was used to temporally express UAS–ben in a ben mutant background. We crossed ben; UAS–ben flies to A307/Cyo; tub–Gal80ts/TM6. The cross was set up at the permissive temperature (we found 22°C sufficient for the tub–Gal80 to suppress A307 and restrict UAS–ben expression). Pupal day 0 (P0) pupae of ben/Y; A307/UAS–ben; tub–Gal80ts/+ were collected, and UAS–ben expression was induced for 24 h [∼16% of pupal development (PD)] by temperature shifts to 30°C at P0, P0 plus 6 h, P0 plus 12 h, P0 plus 18 h, P0 plus 24 h, P0 plus 48 h, P0 plus 72 h, P0 plus 96 h, and P0 plus 120 h. The TTM response was determined after eclosion in 2- to 3-d-old adults and compared with control specimens: ben/Y; A307/UAS–ben; TM6/+.
Results
A residual synaptic connection is present in ben mutants
We examined the ben phenotype by performing electrophysiological recordings from the TTM and found 88% of the responses to be mutant. A wild-type response from the muscle is defined as one with a response latency below 1 ms and which follows 100% at 100 Hz stimulation. In accordance with previous studies, we found ben specimens to exhibit long, variable latencies and not follow 1:1 at high-frequency stimulation (Fig. 1B). To ascertain the penetrance of the mutant phenotype, we further crossed ben to a deficiency that spanned the entire ben gene and physiologically assayed offspring that were transheterozygous for ben and the deficiency. The physiology of the resultant transheterozygotes was 93% mutant (Table 1), which is not significantly different from the physiology of homozygous ben specimens as determined by a Fisher's exact test (two-tailed p value = 1.000).
For our anatomical analysis, we dissected the CNS out of the same ben specimens that had been physiologically tested and dye injected the GFs with Lucifer yellow, an anionic fluorescent dye that is small enough to pass through gap junctional contacts. In wild-type specimens, Lucifer yellow passes through the GF terminal into the TTMn 90–95% of the time depending on duration of the fill and the health of the specimen (Fig. 2A). We found transynaptic fills from the truncated GF terminal to the TTMn in 55% (n = 22) of ben specimens (Fig. 2B). This indicated that there was a direct functional connection containing gap junctions between the GF and its target motor neuron. Because the ben mutation is an ethyl methane sulfonate-induced point mutant, it was possible that this synaptic contact pertains to a residual function of the mutant protein rather than being indicative of a null phenotype. To address this issue, we also performed Lucifer yellow dye injections in specimens that were transheterozygous for ben and the deficiency. We still saw transynaptic fills from the GF to the TTMn with a similar penetrance of 54% (n = 16). To ensure that this residual synaptic connection seen in ben mutants was not just a case of delayed synaptogenesis or an initial stage of synaptic degeneration, we also analyzed ben mutants that were aged at 25°C for 2 weeks. Even in this case, the truncated GF terminal remained dye coupled with the TTMn.
Because the GF–TTMn synapse is a mixed electrical–chemical synapse (Blagburn et al., 1999; Allen and Murphey, 2007), we also wanted to determine whether components of the chemical synapse might be present in the terminals of ben mutants. We determined the localization of two synaptic vesicle markers, synaptotagmin and synaptobrevin, in the ben mutant by expressing GFP-tagged constructs in the GFS. An example of synaptotagmin–GFP localization in a wild-type and a ben specimen is seen in Figure 2, C and D, respectively. We could see fluorescent puncta of both proteins accumulate at the tips of the truncated terminal, suggesting the presence of synaptic vesicles (n = 18). We furthered this observation by performing ultrastructural analyses on the ben mutant and comparing the synaptic phenotype with what is seen in a wild-type specimen (Fig. 3A,B). We traced the GF to the synaptic region in three ben specimens and were able to isolate sections that show T-bars indicative of presynaptic release sites as well as close juxtaposition of the presynaptic and postsynaptic membrane with a single layer of vesicles indicative of gap junctional contact as described previously (Blagburn et al., 1999; Godenschwege et al., 2006) (Fig. 3C–F). The ultrastructural results are dramatic, and although the truncated GF tapers down to a much smaller axonal diameter, the essential synaptic features are still seen in the reduced contact region with the TTMn. These results suggest that an incipient chemical and gap junctional synapse is formed in a ben mutant background. Hence, Bendless does not seem to be required for nascent synapse formation but rather plays a role in synaptic growth and maturation.
Bendless has a cell-autonomous presynaptic function
We generated UAS–ben transgenic flies and conducted a series of rescue experiments to determine a spatial role for Bendless in the GFS. By driving UAS–ben expression in a ben mutant background under the control of A307, which is a strong driver that expresses in the GF and its postsynaptic target, we were able to completely rescue the Bendless phenotype physiologically and anatomically (100% wt; n = 22) (Table 1 and data not shown). Using the weaker presynaptic driver c17, we were still able to get a significant rescue (83% wt; n = 24) (Table 1), which improves with double the dosage of the UAS–ben transcript (91% wt; n = 32) (Table 1). In contrast, expression with the postsynaptic driver ShakB–Gal4 was unable to rescue the mutant phenotype (13% wt; n = 24) (Table 1). Our results confirm the previous observation that Bendless does indeed have a presynaptic role in synapse function (Oh et al., 1994) and additionally proves that it functions cell autonomously in the GFS.
Our anatomical studies led us to hypothesize that Bendless was involved in synaptic growth and maturation. Interestingly, driving expression of UAS–ben with A307 in a wild-type background did not disrupt the synapse physiologically (100% wt; n = 24) (Table 1) or cause anatomical changes (data not shown). The absence of a gain-of-function phenotype, like an overgrown terminal, for Ben overexpression suggests that Bendless is not an effector molecule that is sufficient to induce synaptic growth on its own. We also expressed UAS–ben in a ben mutant background with the presynaptic c42.2 driver, which turns on expression in the latter half of PD when the giant fiber would be undergoing additional growth after having made its synapse in wild-type specimens. We did not see any significant rescue of the ben phenotype under these conditions (20% wt; n = 13) (Table 1). This was intriguing and contrary to what might have been expected; Ben function was not required during the actual growth of the GF presynaptic terminal.
Critical period for bendless before synaptic growth
Because the expression of UAS–ben during later stages of PD by using the c42.2 driver did not rescue the ben mutant phenotype, we proceeded to determine more precisely the time point when protein function was necessary to make a normal synapse. Previous anatomical studies have delineated the various developmental stages of the GFS (Phelan et al., 1996; Allen et al., 1998) (Fig. 4A) and have also identified critical periods for synapse formation (Murphey et al., 2003). We used the TARGET system (McGuire et al., 2004a,b) to regulate UAS–ben expression during different stages of GF development. Briefly, in the TARGET system, a temperature-sensitive variant of Gal80 (Gal80ts) is cloned behind a tubulin promoter and regulates Gal4 expression in a temperature-dependent manner. At a permissive temperature (22°C), Gal80ts binds Gal4 and inhibits gene expression, whereas at a nonpermissive temperature (30°C), the Gal80ts protein misfolds and does not bind Gal4 and gene expression is allowed to turn on.
In a ben mutant background, we turned on UAS–ben expression under the control of Gal80ts and the A307 driver by giving 24 h temperature shifts to nonpermissive temperature (30°C) at a late larval stage (L3) and various stages of PD (Fig. 4B). The timeline of GF development that corresponds to these stages is indicated in the schematic (Fig. 4A,B). Although the duration of the temperature shift is indicated (Fig. 4B, red lines), it should be noted that transgene presence is likely to be seen with an ∼3 h delay and can persist for up to ∼12 h after the temperature shift as detailed in the original study (McGuire et al., 2004a). Comparing these results with internal controls, we found the period of maximum rescue to be when UAS–ben expression is turned on in the first 24 h of PD (80% wt; n = 132) (Fig. 4B). The rescue ability decreases significantly for temperature shifts after P0 plus 12 h (62% wt; n = 34), and no rescue was seen after P0 plus 48 h (11% wt; n = 54). The time interval at which Ben is required to obtain any rescue of the mutant phenotype is indicated by the yellow highlight. We also performed temperature shifts of 48 h duration starting at P0, P0 plus 24 h, P0 plus 48 h, P0 plus 72 h, P0 plus 96 h, and P0 plus 120 h and still found a significant reduction in the rescue potential after P0 plus 24 h (data not shown). Hence, the critical period of UAS–ben expression is the first 24 h of PD, a time interval earlier than the occurrence of synaptic growth (Fig. 4, green highlight). This is rather interesting because the Ben protein is required for synaptic growth but need not be present during the growth event itself.
Bendless localization is cytoplasmic and nuclear
Ubiquitination is known to regulate synaptic function at both a protein level, by directly affecting signaling such as locally at the synapse, and a gene level, through the control of transcription factors (Murphey and Godenschwege, 2002; DiAntonio and Hicke, 2004). Hence, components of the ubiquitin system have been found to be expressed in both the nucleus and the cytosol. Sequence analysis points to Bendless being a cytoplasmic protein attributable to the lack of characterized nuclear localization motifs. To further characterize Bendless, we proceeded to determine its intracellular distribution. We generated a transgenic line containing UAS–ben with an N-terminal GFP fusion tag (UAS–GFP–ben). To verify that the GFP tag did not disrupt protein function, we expressed the construct under the control of the A307 driver in a ben mutant background and found that it was able to effect a robust rescue of the mutant phenotype (93% wt; n = 16) (Table 1). Given the functional rescue, we studied Ben protein localization by expressing UAS–GFP–ben in a wild-type background. We found that GFP–Ben is uniformly cytosolic throughout the entire neuron, inclusive of the GF axons, dendrites, and synaptic region (Fig. 5A,D). In addition to its ubiquitous cytosolic localization, we also find strong nuclear accumulation of GFP–Ben in cell bodies of the GF (Fig. 5B). Nuclear localization of GFP–Ben was seen in all subsets of neurons in which A307 Gal4 drives expression; an example of the dorsal longitudinal motorneuron (DLMn) cell body is seen in Figure 5C. These data highlight an important aspect of regulation whereby a molecule can have a precise temporal role affecting one particular synaptic connection despite having a ubiquitous spatial distribution.
Bendless is in a distinct signaling pathway from Highwire
In the established ubiquitination pathway, ubiquitin is transferred from an activating enzyme to a conjugating enzyme and finally onto a target substrate via a ubiquitin ligase that confers substrate specificity (Hershko and Ciechanover, 1998). Ben is a conjugating enzyme, and a possible candidate to be the downstream ligase for Ben in Drosophila is the ubiquitin ligase highwire. Hiw has been well characterized for regulating synaptic morphology at the Drosophila larval neuromuscular junction (NMJ) (Wan et al., 2000; DiAntonio et al., 2001; Wu et al., 2005, 2007; Collins et al., 2006). hiw mutants exhibit a dramatic increase in the number of synaptic branches and boutons along with an increase in synaptic span. NMJ synaptic development was found to be dependent on a balance of positive and negative regulators of ubiquitination. This balance is exemplified by the fact that hiw interacts with the deubiquitinating protease faf, and overexpression of Faf results in a phenotype similar to hiw mutants (DiAntonio et al., 2001).
We wanted to determine whether ben and hiw acted through the same signaling cascade in establishing a central synapse by analyzing the mutants for phenotypic similarities. If Ben were the upstream conjugase partner of the ligase Hiw, then it follows that loss of Ben function should phenocopy loss of Hiw. We characterized the GFS, both physiologically and anatomically, in specimens carrying the hiwND8 loss-of-function allele. Loss of hiw function did affect the GF–TTMn synapse physiologically as well as anatomically. Anatomically, we found ectopic axonal branches off the presynaptic terminal extending outside the target region in many specimens, but we did not find truncated GF terminals as seen in ben specimens (n = 30) (Table 2, Fig. 6B). Interestingly, we ascertained a similar anatomical result of axonal overgrowth with the overexpression of Faf in the GFS as well (n = 16) (Table 2), indicating that both loss-of-function hiw and gain-of-function Faf have similar effects on growth at a central synapse. Clearly, the ben mutant phenotype is distinctly different from the hiw and Faf phenotypes, with the former exhibiting synaptic undergrowth and the latter two exhibiting synaptic overgrowth.
To further confirm the distinct roles played by Ben and Hiw at a central synapse, we also looked at components of the hiw downstream signaling pathway. The downstream pathway of Drosophila hiw includes the mitogen-activated protein kinase kinase kinase wallenda (wnd), the Jun kinase (JNK) basket (bsk), and the D-fos transcription factor. At the NMJ, the inhibition of JNK signaling by the expression of a UAS–bskDN construct was found to suppress the hiw phenotype (Collins et al., 2006). We expressed UAS–bskDN in a ben mutant background and did not find the ben phenotype to be suppressed (Table 1). Overall, our experiments strongly suggest that Ben and Hiw function in distinct pathways to regulate central synapse growth. A detailed description of the hiw phenotype, additional analysis of its function, and subsequent characterization of its downstream signaling cascade at a central synapse will be performed in a separate study.
Discussion
Bendless and Highwire
The results from this study have given us new insights into how ubiquitin system components establish functional synaptic connections. The temporal analysis of Bendless has been critical in illustrating its role as a developmental “switch” in converting a growth cone into a mature synapse. As mentioned previously, the ben mutation is the result of a single amino acid change in the conserved catalytic core of the conjugase domain of the protein. This highlights the fact that the conjugase activity of the protein is necessary for the observed synaptic phenotype. Analysis of synaptic growth in Drosophila has primarily been done at the peripheral synapse of the NMJ (Laviolette et al., 2005; Goold and Davis, 2007; Fulga and Van Vactor, 2008; Liebl et al., 2008; Schwenkert et al., 2008; Seabrooke and Stewart, 2008). Components of the ubiquitin system, such as the ubiquitin ligase hiw, the deubiquitinating protease faf, and the synapse-associated E3 ligase PDZRN3, are known to play important roles in the growth and function of the fly NMJ (DiAntonio et al., 2001; McCabe et al., 2004; Wu et al., 2005; Collins et al., 2006; Lu et al., 2007). Significant studies have been performed with particular regard to the conserved family of hiw ubiquitin ligases. In Drosophila, hiw functions as a negative regulator of synapse development as mutants exhibit dramatic synaptic overgrowth at the larval NMJ (Wan et al., 2000). In Caenorhabditis elegans, loss of function of the hiw homolog rpm-1 results in multiple phenotypes at the NMJ as well as in the CNS (Schaefer et al., 2000; Zhen et al., 2000). At the NMJ, some NMJs exhibit enlarged presynaptic terminals containing multiple active zones, whereas others contain underdeveloped or absent presynaptic terminals (Zhen et al., 2000). In the worm mechanosensory circuit, the sensory neurons were found to retract synaptic branches, extend ectopic axons, and fail to accumulate synaptic vesicles, whereas some of the motor neurons exhibited phenotypes such as altered synaptic organization, branching, and overgrowth (Schaefer et al., 2000). Downstream signaling components have been isolated for both hiw and rpm-1 in Drosophila and C. elegans, respectively, and a number of conserved elements have been identified (Schaefer et al., 2000; Nakata et al., 2005; Collins et al., 2006; Grill et al., 2007; Abrams et al., 2008; Li et al., 2008). Mutations in homologs of hiw in zebrafish and mice are also known to cause a variety of synaptic disruptions (Burgess et al., 2004; D'Souza et al., 2005).
Ben and Hiw play distinct roles in synapse growth. In our study, we have been able to analyze the novel roles played by these ubiquitin system components at the GFS central synapse. We have shown that ben and hiw loss of function result in very different phenotypes, with ben specimens exhibiting synaptic undergrowth and hiw specimens exhibiting synaptic overgrowth. We also show that Ben function does not involve JNK, a well characterized downstream signaling partner identified for Hiw in Drosophila. It is also interesting to compare and contrast the role Hiw plays at a peripheral synapse with the role Ben plays at a central synapse. hiw mutants exhibit a presynaptic overgrowth phenotype at the NMJ, whereas ben mutants exhibit a reduction in presynaptic growth in the CNS. Also, Hiw does not localize to the nucleus and was found to regulate synaptic growth throughout development, whereas Ben has nuclear as well as cytosolic localization and only functions in a critical time period. Finally, Hiw activity is associated with the bone morphogenetic protein (BMP) retrograde signaling pathway that is known to be dependent on the retrograde motor (McCabe et al., 2004). We found no evidence that Bendless function is dependent on the retrograde motor (our unpublished data). All these data underline the fact that there are distinct targets for the ubiquitination cascades involving Ben and Hiw.
Bendless is required for synaptic growth and maturation
Functional neuronal circuits are established through a series of events: neurite outgrowth, axon guidance, target recognition, synapse formation, and synaptic growth and maturation. When the bendless mutant was originally characterized, Ben was thought to play an important role in either axon guidance or target recognition (Muralidhar and Thomas, 1993; Oh et al., 1994). Our analysis of the ben mutant clearly shows that Ben has an important role in synaptic growth. A number of specimens exhibit dye coupling between the GF and the motorneuron dendrite demonstrating that an incipient synapse is still formed (Fig. 2B) and that the mutant phenotype arises from a failure of this immature connection to grow into a mature synapse. In addition, we also shown that both gap junctional and chemical components are present at ben mutant terminals with synaptic vesicle marker localization as well as ultrastructural analyses (Figs. 2D, 3C–F).
The current view of synapse formation is that a nascent synapse can be rapidly assembled from material present in a growth cone in prepackaged vesicles and packets (Roos and Kelly, 2000; Ziv and Garner, 2004). After this primary rapid assembly of a nascent synapse, a secondary slower growth and maturation process takes place to result in a stable mature synapse. An insightful study on the Drosophila kinesin immaculate connections (imac) has shown it to be a permissive regulator of presynaptic maturation at the larval NMJ (Pack-Chung et al., 2007). Imac was found to be involved in the anterograde transport of synaptic vesicle precursors to the tip of the growth cone, an initial stage of synaptogenesis. In ben specimens, synaptic vesicles are still transported all the way down to the tip of the truncated terminal as evidenced by the localization of GFP-tagged synaptotagmin and synaptobrevin (Fig. 2D). Our data strongly suggest that the ben mutant phenotype is resultant at a point after synaptic vesicular transport. Hence, we conclude that the bendless terminal is an incipient synapse that fails to grow and mature and that Ben is a permissive regulator whose function is required for the initiation of a secondary process in presynaptic growth.
Bendless as a developmental switch
It is counterintuitive that, although Bendless is required for synaptic growth and maturation, our data show that it is not required during the growth process. This highlights the important role Ben plays as a developmental switch. Transient expression of UAS–ben before the growth of the presynaptic terminal was sufficient to rescue the ben phenotype anatomically and physiologically, but expression during the growth period had no effect (Fig. 4). This suggests that Bendless is not involved in the actual growth process but rather has to be present in advance to alter signaling and initiate changes that allow growth to take place. Here it is essential to differentiate between axonal and synaptic growth, because it has been determined previously that axonal growth is unaffected in ben mutants (Muralidhar and Thomas, 1993). Hence, Ben function is required to permit axonal growth to switch to synaptic growth.
The molecules in the signaling pathway of this novel mechanism remain to be further investigated. In conclusion, tight spatial and temporal control of synaptic connectivity in the nervous system is undoubtedly crucial to normal function. Determining how exactly Bendless regulates the formation of a mature synapse will give us future novel insights into this phenomenon.
Footnotes
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This work was supported by National Institutes of Health (NIH) Grant R01-NS044609 (R.K.M.). T.A.G. was supported by NIH Grant R01 HD050725-01A1. We thank J. B. Thomas for kindly providing us with the bendless cDNA and the L. M. Schwartz laboratory, particularly Jeffery Kane and Chul Kim for molecular help and resources. We also thank P. Carrucio and X. Shan-Crofts for technical assistance in conducting the temperature shift experiments. For various fly stocks, we are grateful to the A. DiAntonio and C. Collins laboratories as well as the Bloomington Stock Center.
- Correspondence should be addressed to Dr. Rodney K. Murphey, Department of Biological Sciences, Sanson Science Building, Florida Atlantic University, Boca Raton, FL 33431. rmurphey{at}fau.edu