The dynein cofactor NudE is necessary for neuronal morphogenesis

To determine whether the loss of NudE disrupts axon and/or dendrite morphogenesis, we utilized the class IV da neurons in Drosophila as a model. Located just beneath the transparent larval cuticle, the class IV da neurons are easily accessible for live-imaging analysis of neuronal morphology, as well as dynamic events such as microtubule growth and intracellular transport. Similar to the majority of mammalian neurons, the axons and dendrites of class IV neurons are morphologically distinct and emanate from opposite sides of the neuronal cell body. We first compared the morphology of the class IV ddaC neurons in wild-type 3rd instar larvae with ddaC neurons in larvae lacking NudE (nudE^39A/39A and nudE^39A/Df(3L)BSC673; nudE^39A is a protein null allele) (Wainman et al., 2009). Animals that lack NudE survive through late larval stages, making it possible to analyze ddaC neurons in homozygous mutant 3rd instar larvae. To visualize class IV da neuron morphology, we utilized green fluorescent protein (GFP)-tagged CD4 (CD4–GFP) expressed under the control of the pickpocket (ppk) enhancer (ppk-CD4–GFP) (Han et al., 2011). The loss of NudE resulted in a significant decrease in dendrite length and branch number in both the nudE^39A/39A and nudE^39A/Df(3L)BSC673 3rd instar larvae (Fig. 1A–C,G–I). In addition, the dendrites within the distal arbors of nudE⁻ neurons had fewer branches in comparison with control ddaC neurons (Fig. 1G). Neurons lacking NudE also displayed a severe ‘axon splitting’ phenotype. Control axons emerged from the ddaC cell bodies as a single process that extended unbranched into the ventral nerve cord, whereas the axons projected by neurons lacking NudE formed multiple fine branches a short distance from the soma (Fig. 1B,C). Confocal optical sectioning revealed that these fine branches were indeed derived from the axons and were not just dendrite branches that bundled with the axons (data not shown). Some of these ectopic axon branches even grew back past the soma and occasionally invaded the dendritic arbor. Combined, these data reveal that NudE is necessary for normal dendrite growth and arbor patterning, as well as axonal morphogenesis.

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Fig. 1.

Loss of NudE disrupts dendrite and axon morphogenesis. (A–E) Representative images of class IV ddaC neurons illuminated by expression of ppk-CD4–GFP in live intact 3rd instar larvae. Arrowhead indicates axon. Scale bars: 50 µm (left-hand images); 10 µm (right-hand images showing magnified views of axon). (F–I) Quantification of axon branching (F), dendrite patterning (G), dendrite length (H) and dendrite branching (I) phenotypes. For nudE^39A/39A ppk-Gal4 UAS-nudE neurons, dendrite length was significantly different from that of control and nudE^39A/39A neurons (P=0.003 and P=0.0004, respectively); the number of branch points was also significantly different from those of control and nudE^39A/39A neurons (P=0.05 and P=0.002, respectively). Error bars indicate s.d., ***P=0.001–0.0001; n.s., not significant; n=8 neurons for all genotypes except for nudE^39A/39A n=9. The color code for the genotypes is shown at the bottom of the figure.

To confirm that the axon and dendrite phenotypes are due to the loss of NudE, we generated two NudE transgenes – a genomic construct that encompassed the entire coding region of the nudE gene (nudE^{genomic-wild-type}) and a UAS transgene (UAS-nudE^wild-type). nudE^{genomic-wild-type} rescued the lethality associated with loss of NudE, and the adults were morphologically normal, with the exception of slightly disordered anterior wing margin bristles. Dendrite length and branch number were fully rescued by nudE^{genomic-wild-type} (Fig. 1E,G–I). ppk-Gal4, which is expressed in class IV da neurons starting in late stage embryos, was used to express UAS-nudE^wild-type. In animals lacking NudE, ppk-Gal4 UAS-nudE^wild-type only partially rescued the dendrite growth and branching defects (Fig. 1D,G–I). It is possible that ppk-Gal4 UAS-nudE^wild-type failed to fully rescue dendrite arborization in nudE⁻ neurons owing to the timing and/or pattern of ppk-Gal4-mediated expression. However, expression of UAS-nudE^wild-type utilizing other Gal4 lines, including the ubiquitously expressed actin-Gal4 and pan-neuronal elav-Gal4, which drive early expression, also failed to fully rescue the neuronal morphology defects and lethality (data not shown). Based on these results, it is likely that UAS-nudE might express NudE at suboptimal levels. It is also important to note that overexpressing nudE in control animals, using either UAS-nudE or nudE^{genomic-wild-type}, had no effect on viability or neuronal morphology, which indicates that increasing expression of NudE is not disruptive.

We next set out to determine whether the change in dendrite arborization that resulted from the loss of NudE was due to decreased dynein function. In order to do so, we assayed whether nudE genetically interacts with dynein light intermediate chain (dlic), which encodes an essential subunit of the dynein complex. RNA interference (RNAi)-mediated knockdown of dlic produced a very mild dynein loss-of-function dendrite phenotype, which could be enhanced by the co-expression of dicer2 (dcr) to generate a dendritic arbor that resembled those found in animals with loss of dynein function (Fig. 2A,C) (Satoh et al., 2008; Zheng et al., 2008). The dlic-RNAi dendrite-patterning phenotype was enhanced by the loss of NudE (Fig. 2D), indicating that NudE acts with dynein in order to mediate dendrite growth and branching.

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Fig. 2.

Loss of NudE enhances the dynein loss-of-function dendrite morphogenesis phenotype. (A–D) Representative images of class IV ddaC neurons illuminated by expression of ppk-CD4–GFP in live intact 3rd instar larvae. Dendrite patterning was mildly disrupted in ppk-Gal4 UAS-dlic-RNAi larvae (A). The expression of dcr enhances the dendrite arborization phenotype caused by reducing levels of Dlic (C). Reducing levels of NudE and Dlic at the same time reduces dendrite growth and branching, similar to ppk-Gal4 UAS-dlic-RNAi UAS-dcr (D). Arrowheads indicate axons. Scale bars: 50 µm.

NudE associates with Golgi outposts in dendrites

NudE family members have been previously implicated in axonal transport in mammalian neurons, as well as in fruit fly motor neurons, raising the possibility that the dendrite phenotypes that we observed in nudE⁻ neurons are caused by perturbation of the transport of vesicles and/or organelles in dendrites (Liang et al., 2004; Pandey and Smith, 2011; Segal et al., 2012; Shao et al., 2013; Shim et al., 2008; Shmueli et al., 2010; Valakh et al., 2012; Yamada et al., 2008; Yi et al., 2011; Zhang et al., 2009). In neurons, a subset of Golgi complexes localizes to dendrites in the form of ‘outposts’, and these Golgi outposts have been shown to mediate dendrite arborization and microtubule growth (Horton and Ehlers, 2003; Horton et al., 2005; Ori-McKenney et al., 2012; Ye et al., 2007). Although previous studies have demonstrated that the loss of dynein activity changes the distribution Golgi outposts in ddaC neurons (Zheng et al., 2008), it is still unknown which dynein cofactors participate in the transport of Golgi outposts, and how cofactors affect Golgi outpost dynamics, localization and/or function.

To test the idea that NudE mediates Golgi outpost localization and/or function, we set out to determine whether NudE usually associates with Golgi outposts in dendrites. To do so, we first generated a construct to express a fluorescently-tagged NudE protein (UAS-Cherry–NudE) in neurons and monitored its dynamic localization by using live-cell imaging. When expressed in class IV da neurons, Cherry–NudE localized to both dendrites and axons, and had a punctate appearance typical of vesicle-associated proteins (Fig. 3A,A′). Cherry–NudE particles moved in anterograde and retrograde directions at speeds typical of kinesin- and dynein-mediated transport (0.66±0.39 µm s⁻¹ in axons and 0.48±0.22 µm s⁻¹ in dendrites). Consistent with a role in axonal transport, we observed that Cherry–NudE colocalized with the synaptic vesicle marker synaptobrevin–GFP, as well as with mitochondria-targeted GFP (mito–GFP; data not shown), indicating that NudE participates in the transport of multiple different types of cargo in neurons. Next, we utilized the medial-Golgi marker ManII–GFP, which labels both Golgi and Golgi outposts, in combination with Cherry–NudE (Gal4⁴⁷⁷ UAS-ManII–GFP UAS-Cherry–NudE; Gal4⁴⁷⁷ is expressed in class IV da neurons). Live-imaging analysis revealed that Cherry–NudE and ManII–GFP colocalized in dendrites (Fig. 3B–Bʹʹ). To investigate whether NudE participates in a specific aspect of Golgi outpost localization, we characterized Cherry–NudE and ManII–GFP colocalization. Nearly two-thirds of the Cherry–NudE and ManII–GFP particles that colocalized were stationary (Fig. 3C), suggesting that NudE primes Golgi outposts for transport and/or that they associate with Golgi outposts at the end of runs. We found that the majority of dynamic colocalized Cherry–NudE and ManII–GFP particles traveled in a retrograde direction, indicative of movement towards the microtubule plus end and kinesin-mediated transport (Fig. 3C). Fewer than 5% of the colocalized particles moved in a direction (anterograde) that was consistent with dynein-mediated transport (Fig. 3C). Indeed, only a few anterograde-moving Golgi outposts colocalized with Cherry–NudE, whereas the majority of Golgi outposts that moved in a retrograde direction colocalized with Cherry–NudE. This supports a model in which NudE acts to limit dynein activity during events such as plus-end-directed transport (e.g. when dynein is carried by kinesin to the axon terminal) and/or when dynein is stationary at the beginning and end of runs.

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Fig. 3.

NudE colocalizes with Golgi outposts in dendrites and prevents them from entering axons. (A,A′) Representative image of a ddaC neuron co-expressing CD4–GFP (A) and Cherry–NudE (A′). Arrowhead indicates axon. Inset in A′ shows a magnified view of an axon, arrows indicate several Cherry–NudE particles. (B) Representative kymograph showing the motility of Cherry–NudE (B, red channel in B″) and the Golgi marker ManII–GFP (B′, green channel in B″) in dendrites. Cell body is to the left. (C) Quantification of Cherry–NudE and ManII–GFP movement and colocalization in dendrites (the distances that Cherry–NudE and ManII–GFP particles travel in the anterograde or retrograde direction are similar, data not shown). (D,E) Representative images (D) and quantification (E) of Golgi outposts in the axons of control (ppk-Gal4 UAS-ManII–GFP, left panel in D) and nudE^39A/39A (right panel in D) neurons. Arrowheads indicate Golgi outposts. Error bars indicate s.d., **P=0.01–0.001, n=19 control axons, n=15 nudE^39A/39A axons. Scale bars: 50 µm (A); 10 µm (D, inset of A′); 5 µm (x axis of B″); 30 s (y axis of B″).

We also characterized how the loss of nudE disrupted the localization of Golgi outposts. More specifically, we sought to determine whether Golgi outposts mislocalize to axons in neurons that lack NudE, as previously reported for neurons with reduced dynein activity (Zheng et al., 2008). In nudE^39A/39A neurons, the number of Golgi outposts that were present in axons increased significantly (Fig. 3D,E), consistent with the model that NudE is required for the dendrite-enriched localization of Golgi outposts.

NudE modulates microtubule dynamics and is necessary for the uniform plus-end-distal polarity of axonal microtubules

Dendrite morphology is highly dependent on the microtubule cytoskeleton, raising the possibility that the dendrite arborization phenotypes resulting from the loss of NudE are also be associated with an underlying defect in the microtubule cytoskeleton. Microtubules have a plus- and minus-end, and growth occurs predominantly at the microtubule plus end. In the axons of da neurons, all microtubules are oriented with their plus ends positioned distal to the cell body, similar to mammalian neurons, whereas in dendrites, the majority of microtubule plus ends are located proximally (Rolls et al., 2007). To monitor microtubule growth dynamics and to determine the orientation of microtubules in axons and dendrites, we utilized EB1–GFP, which is a fusion of the microtubule-plus-end-binding protein EB1 with GFP (Rolls et al., 2007). EB1 associates with growing microtubule plus ends and dissociates a short distance from the plus-end tip; this behavior gives EB1–GFP a comet-like appearance in live-cell imaging experiments and enables us to simultaneously analyze both microtubule growth and microtubule orientation.

In neurons lacking NudE, the frequency of EB1–GFP comets increased significantly in both axons and dendrites (Fig. 4A,B), indicating that NudE has a crucial role in regulating microtubule growth and dynamics. These data suggest that the dendrite growth and branching defects in nudE⁻ neurons might be due, in part, to an imbalance in microtubule growth and stability. Next, we investigated whether the loss of NudE affects the orientation of microtubules, similar to the loss of dynein function (Zheng et al., 2008). Our experiments using EB1–GFP revealed that the orientation of dendritic microtubules was not affected by the loss of NudE. In the dendrites of control neurons, as well as neurons lacking NudE, EB1–GFP comets traveled predominantly towards the cell body (Fig. 4A,C). However, the loss of NudE did affect the orientation of axonal microtubules. In the axons of control ddaC neurons, all EB1–GFP comets traveled away from the cell body, indicating that the microtubules were oriented with plus ends distal (Fig. 4A,C). By contrast, in the axons of ddaC neurons lacking NudE, EB1–GFP comets traveled both away from and towards the cell body, indicating that microtubule polarity was mixed (Fig. 4A,C). This is consistent with previous studies that have reported that the loss of dynein activity disrupts the organization of axonal microtubules (Baas and Mozgova, 2012; Zheng et al., 2008). To assess microtubule polarity, we also utilized Nod–GFP, a chimeric protein that translocates to the minus ends of microtubules (Andersen et al., 2005; Clark et al., 1997). When expressed in control and nudE⁻ ddaC neurons, Nod–GFP localized predominantly to dendrites, consistent with the minus-end distal organization of dendritic microtubules (data not shown). In contrast to controls, Nod–GFP mislocalized to the axons of a significant number of nudE^39A/39A neurons. These results suggest that NudE specifically regulates the polarity of axonal, but not dendritic, microtubules and that NudE has a role in modulating microtubule dynamics in both compartments.

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Fig. 4.

Loss of NudE affects microtubule growth and the polarity of axonal but not dendritic microtubules. (A) Kymographs generated from representative movies of EB1–GFP comets present in the axons (top) and dendrites (bottom) of neurons in live intact 3rd instar larvae. ppk-EB1–GFP control (left) and nudE^39A/39A (right) neurons are shown. The cell body is to the left in all kymographs. Scale bars: 5 µm (x axis); 30 s (y axis). (B) Quantification of EB1–GFP comet frequency in axons (top) and dendrites (bottom). Comet frequency reflects the number of growing microtubules (control axons, n=13 neurons, which includes a total of 58 comets; nudE^39A/39A axons, n=11 neurons, which includes a total of 156 comets; control dendrites, n=24 dendrite segments in nine neurons, which includes a total of 247 comets; nudE^39A/39A dendrites, n=32 dendrite segments in eight neurons, which includes a total of 540 comets). Boxes represent first and third quartiles (median indicated by line) and whiskers indicate minimum and maximum values. (C) Quantification of the direction that EB1–GFP comets traveled, which reflects the polarity of microtubules in axons (top) and dendrites (bottom) (control axons, n=11 axons with 135 comets; control dendrites, n=12 dendrites with 323 comets; nudE^39A/39A axons, n=9 axons with 115 comets; nudE^39A/39A dendrites, n=8 dendrites with 540 comets). Error bars indicate s.d., **P=0.01–0.001, ***P=0.001–0.0001, ****P<0.0001; n.s., not significant.

Reducing γ-tubulin activity does not rescue the axonal microtubule polarity defect in nudE⁻ neurons

Our data revealed that neurons lacking nudE contain microtubules of mixed polarity, as well as ectopic Golgi outposts. The mislocalized Golgi outposts might serve as sites of ectopic microtubule nucleation in axons, resulting in microtubules that have their plus ends positioned proximally. Microtubules are nucleated at Golgi outposts and somatic Golgi by the microtubule nucleator γ-tubulin (Chabin-Brion et al., 2001; Efimov et al., 2007; Ori-McKenney et al., 2012; Rivero et al., 2009). We reasoned that if the Golgi outposts present in the axons of nudE⁻ neurons serve as ectopic sites for microtubule nucleation, knocking down γ-tubulin should restore the microtubules to a uniform plus-end-distal array. Knocking down γ-tubulin can also be used to test whether changes in γ-tubulin localization and/or activity in axons are generally responsible for the appearance of plus-end-proximal microtubules, irrespective of whether microtubules are nucleated at the ectopic axonal Golgi outposts. For example, it is also possible that NudE normally functions to exclude γ-tubulin from axons. Thus, these experiments were designed to resolve whether γ-tubulin-mediated nucleation is responsible for the change in axonal microtubule polarity that occurs in the absence of NudE.

To determine whether γ-tubulin-mediated nucleation contributes to the axonal microtubule-polarity defects in nudE⁻ neurons, we used the hypomorphic alleles γTub23C^A15-2 and γTub23C^A14-9 in combination, which allows the animals to survive to larval stages (we refer to this genetic combination hereafter as ‘γ-tubulin knockdown’). In the axons of γ-tubulin knockdown neurons, virtually all the EB1–GFP comets traveled in an anterograde direction, similar to that in control neurons (Fig. 5A,C). This indicates that decreasing the levels of γ-tubulin does not affect axonal microtubule polarity. Next, we knocked down γ-tubulin in animals that lacked NudE. Reducing γ-tubulin in nudE⁻ neurons did not change the number of retrograde EB1–GFP axonal comets in axons compared with that in nudE⁻ neurons (Fig. 5B,C). Thus, decreased γ-tubulin activity does not affect the number of retrograde EB1–GFP comets in the axons of neurons that lack NudE.

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Fig. 5.

γ-tubulin-mediated microtubule nucleation is not responsible for the change in axonal microtubule polarity that is caused by the loss of NudE. (A,B) The polarity of axonal microtubules was determined using EB1–GFP, the comet trajectories of which are plotted in kymographs. The cell body is to the left in all kymographs. Scale bars: 5 µm (x axis); 30 s (y axis). (C) Quantification of the direction that EB1–GFP comets traveled in axons. γTub23C^A14-9/A15-2, n=16 axons with 156 comets. γTub23C^A15-2/A14-9; nudE^39A/39A, n=12 axons with 193 comets. The percentage of comets traveling anterograde and retrograde in the axons of nudE^39A/39A and γTub23C^A15-2/A14-9; nudE^39A/39A neurons was significantly different from control (****P<0.0001 for both genotypes). n.s., not significant.

The NudE C-terminus is not required for dendrite branching

Next, we sought to determine whether we could identify which domains of NudE are crucial for its activity in dendrite growth and branching. Members of the NudE family of proteins comprise an N-terminal coiled-coil domain and an unstructured, poorly conserved C-terminus. Sites in both the N- and C-terminus of NudE and NudEL have been shown to bind to different subunits of the dynein complex, and conserved residues in the coiled-coil domain have been shown to recruit another important dynein cofactor, Lis1 (Liang et al., 2004; Sasaki et al., 2000; Stehman et al., 2007; Wang and Zheng, 2011; Zyłkiewicz et al., 2011). The NudE and NudEL C-terminal domains also mediate several protein interactions and are targets of post-translational modifications, including phosphorylation (Bradshaw et al., 2013). The unphosphorylated C-terminal domain has been proposed to inhibit NudE and NudEL activity by folding back to interact with the N-terminus (Soares et al., 2012; Zyłkiewicz et al., 2011). Yet, how the C-terminal domain affects the activity of NudE-family members in cells is still poorly understood – some reports suggest that the C-terminal domain is essential (Mori et al., 2007; Stehman et al., 2007), whereas other reports indicate that it is dispensable (Wang and Zheng, 2011; Zyłkiewicz et al., 2011).

To determine whether the C-terminal domain of Drosophila NudE regulates and/or is necessary for its activity in neurons, we generated a construct in order to express a truncated NudE protein that lacked the entire C-terminal domain (UAS-nudE^ΔC). As described above, expressing a wild-type NudE protein under the control of ppk-Gal4 (ppk-Gal4 UAS-nudE^wild type) only partially rescued the NudE loss-of-function phenotypes (Fig. 1D,G–I). This result suggested that we could utilize the Gal4-UAS system to identify both loss- and gain-of-function mutations in NudE. We reasoned that loss-of-function mutations in NudE would result in a weaker rescue phenotype than the wild-type protein, whereas gain-of-function mutations should fully rescue nudE⁻ neurons. The expression of NudE^ΔC in class IV da neurons (ppk-Gal4 UAS-nudE^ΔC) fully rescued dendrite arborization defects in nudE^39A/39A larvae, suggesting that removing the C-terminal domain increased this aspect of NudE activity (Fig. 6A,C,D). To further probe the role of the NudE C-terminal domain in neuronal morphogenesis and microtubule organization, we also generated a genomic nudE construct that lacked the C-terminal domain (nudE^genomic-ΔC). Consistent with the experiments using the UAS-nudE^ΔC transgene, nudE^genomic-ΔC fully rescued the dendrite arborization defects in neurons that lacked NudE (Fig. 6B–D). These data are consistent with the model that the C-terminal domain of NudE has an inhibitory effect on the activity of the full-length NudE protein. However, these results also surprisingly reveal that the C-terminal domain, which is entirely removed in these experiments, is dispensable for dendrite growth and branching. Thus, these data indicate that during dendrite morphogenesis, the NudE C-terminal domain might act as an ‘activity switch’ but is otherwise redundant or unnecessary for dendrite growth and branching.

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Fig. 6.

The NudE N-terminus is sufficient for normal dendrite arborization. (A,B) Representative images of class IV ddaC neurons illuminated through expression of ppk-CD4–GFP in live intact 3rd instar larvae. Arrowhead indicates axons. Scale bars: 50 µm. (C,D) Dendrite arborization was quantified using Sholl analysis (C) and by measuring dendrite length (D). Error bars indicate s.d., **P=0.01–0.001, ***P=0.001–0.0001; n.s., not significant; n=8 neurons for all genotypes, except n=9 for nudE^39A/39A.

Overexpression of Lis1 rescues dendrite arborization defects in nudE⁻ neurons

One key molecular function that has been proposed for the NudE family of proteins is the promotion of an interaction between dynein and Lis1 (McKenney et al., 2010; Shu et al., 2004). Although Lis1 can directly interact with dynein, these reports show that NudE tethers Lis1 to dynein, prolonging the interaction between cofactor and motor (McKenney et al., 2010). Recent biochemical studies using purified proteins have shown that Lis1 directly regulates several properties of the dynein motor – such as the amount of force that the motor produces – that are likely to be crucial for its function in cells (Huang et al., 2012; McKenney et al., 2010). However, it is not known whether a principal function of NudE in neurons is to mediate and/or enhance an association between Lis1 and dynein during neuronal morphogenesis. Several groups have shown that increasing Lis1 concentrations can compensate, at least partially, for the loss of NudE or NudEL in different cell types and in cell extracts (Efimov, 2003; Li et al., 2005; Shu et al., 2004; Wang and Zheng, 2011; Zyłkiewicz et al., 2011). Based on these findings, we sought to determine whether increasing Lis1 levels in neurons rescues the dendrite arborization defects that manifest in nudE⁻ class IV da neurons. To overexpress Lis1, we utilized ppk-Gal4 in combination with UAS-Lis1 and then quantified the effects of Lis1 overexpression in both control and nudE⁻ neurons. First, increasing Lis1 levels in control ddaC neurons did not affect dendrite length, dendrite branch number or dendrite branch position, indicating that elevated Lis1 levels does not interfere with normal dendritogenesis (Fig. 7B,F). As described above, loss of NudE significantly reduced dendrite arbor size and resulted in an increased number of proximal branches. Increasing the amount of Lis1 in neurons that lacked NudE rescued these dendrite morphogenesis defects, resulting in neurons with normal dendrite length, branch number and branch distribution (Fig. 7C,E,F). These results raise the possibility that the dendrite arborization defects caused by the loss of NudE might be largely due to a decrease in Lis1 activity, which in turn results in less active dynein. As previously reported (Zheng et al., 2008), we also found that loss of Lis1 resulted in a severe dendrite morphogenesis defect that resembled the loss of dynein function (data not shown). To further probe the relationship between NudE and Lis1 in dendritogenesis, we generated a mutant genomic nudE construct that was designed to disrupt the interaction between these two proteins (nudE^{genomic-E113A,R124A}). We mutated two amino acids (E113A and E124A) in the N-terminal domain of NudE that have been previously shown to diminish the interaction between NudE and Lis1 (Derewenda et al., 2007; Wang and Zheng, 2011; Zyłkiewicz et al., 2011). In contrast to nudE^{genomic-wild-type}, nudE^{genomic-E113A,R130A} only partially rescued the dendrite arborization defects in nudE^39A/39A animals, indicating that an interaction with Lis1 is necessary for NudE to mediate normal dendrite growth and branching (Fig. 3D–F). In summary, these results are consistent with a model in which NudE interacts with Lis1 and dynein to promote dendrite morphogenesis.

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Fig. 7.

Overexpressing Lis1 rescues abnormal dendrite arborization that is caused by the loss of NudE. (A–D) Representative images of ddaC neurons illuminated through expression of ppk-CD4–GFP in live intact 3rd instar larvae. Arrowheads indicate axons. Scale bars: 50 µm. (E,F) Dendrite arborization was quantified using Sholl analysis (E) and by measuring dendrite length (F). Error bars indicate s.d., ***P=0.001–0.0001, n.s., not significant; n=8 neurons for all genotypes, except n=9 for nudE^39A/39A.