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Goliath family E3 ligases regulate the recycling endosome pathway via VAMP3 ubiquitylation

2013; Springer Nature; Volume: 32; Issue: 4 Linguagem: Inglês

10.1038/emboj.2013.1

1460-2075

Yasuo Yamazaki, Christina Schönherr, Gaurav K. Varshney, Murat Dogru, Bengt Hallberg, Ruth H. Palmer,

Endoplasmic Reticulum Stress and Disease

Article25 January 2013free access Goliath family E3 ligases regulate the recycling endosome pathway via VAMP3 ubiquitylation Yasuo Yamazaki Yasuo Yamazaki Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Christina Schönherr Christina Schönherr Department of Molecular Biology, Umeå University, Umeå, SwedenJoint second authors. Search for more papers by this author Gaurav K Varshney Gaurav K Varshney Developmental Genomics Section, Genome Technology Branch, National Human Genome Research Institute, National Institutes of Health, Bethesda, MD, USAJoint second authors. Search for more papers by this author Murat Dogru Murat Dogru Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Bengt Hallberg Bengt Hallberg Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Ruth H Palmer Corresponding Author Ruth H Palmer Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Yasuo Yamazaki Yasuo Yamazaki Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Christina Schönherr Christina Schönherr Department of Molecular Biology, Umeå University, Umeå, SwedenJoint second authors. Search for more papers by this author Gaurav K Varshney Gaurav K Varshney Developmental Genomics Section, Genome Technology Branch, National Human Genome Research Institute, National Institutes of Health, Bethesda, MD, USAJoint second authors. Search for more papers by this author Murat Dogru Murat Dogru Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Bengt Hallberg Bengt Hallberg Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Ruth H Palmer Corresponding Author Ruth H Palmer Department of Molecular Biology, Umeå University, Umeå, Sweden Search for more papers by this author Author Information Yasuo Yamazaki1, Christina Schönherr1, Gaurav K Varshney2, Murat Dogru1, Bengt Hallberg1 and Ruth H Palmer 1 1Department of Molecular Biology, Umeå University, Umeå, Sweden 2Developmental Genomics Section, Genome Technology Branch, National Human Genome Research Institute, National Institutes of Health, Bethesda, MD, USA *Corresponding author. Department of Molecular Biology, Umeå University, Umeå 90187, Sweden. Tel.:+46 90 785 6798; Fax:+46 90 778 007; E-mail: [email protected] The EMBO Journal (2013)32:524-537https://doi.org/10.1038/emboj.2013.1 PDFDownload PDF of article text and main figures. Peer ReviewDownload a summary of the editorial decision process including editorial decision letters, reviewer comments and author responses to feedback. ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinked InMendeleyWechatReddit Figures & Info Diverse cellular processes depend on endocytosis, intracellular vesicle trafficking, sorting and exocytosis, processes regulated post-transcriptionally by modifications such as phosphorylation and ubiquitylation. In addition to sorting to the lysosome, cargo is recycled to the plasma membrane via recycling endosomes. Here, we describe a role of the goliath gene family of protease-associated (PA) domain E3 ligases in regulating recycling endosome trafficking. The two Drosophila members of this family—Goliath and GodzillaCG10277—are located on endosomes, and both ectopic expression and loss-of-function lead to the accumulation of Rab5-positive giant endosomes. Furthermore, the human homologue RNF167 exhibits similar behaviour. We show that the soluble N-ethylmaleimide-sensitive fusion attachment protein receptor (SNARE) protein VAMP3 is a target of these ubiquitin ligases, and that recycling endosome trafficking is abrogated in response to their activity. Furthermore, mutation of the Godzilla ubiquitylation target lysines on VAMP3 abrogates the formation of enlarged endosomes induced by either Godzilla or RNF167. Thus, Goliath ubiquitin ligases play a novel role in regulating recycling endosome trafficking via ubiquitylation of the VAMP3 SNARE protein. Introduction Many important cellular processes such as cell migration (Marin et al, 2010) and neurotransmitter release depend on intracellular vesicle trafficking, sorting and exocytosis (Sudhof and Rothman, 2009). While endocytosis provides a switching-off mechanism for cellular signalling by removing activated receptors from the cell surface, more recent studies suggest signalling from endocytosed receptors is still active and may even be amplified in the endocytic pathway (von Zastrow and Sorkin, 2007; Mazot et al, 2011). Endocytic vesicles are can be roughly divided into early endosomes, late endosomes and recycling endosomes (Platta and Stenmark, 2011) and trafficking is regulated post-transcriptionally by modifications such as phosphorylation and ubiquitylation (Piper and Lehner, 2011; Haglund and Dikic, 2012). In addition to sorting to the lysosome, an estimated two thirds of internalized receptors are recycled back to the plasma membrane via recycling endosomes from early endosome (Steinman et al, 1983; Schmid et al, 1988; Mayor et al, 1993). Generally, vesicles are transported along actin filaments or microtubules prior to docking and fusion with an acceptor membrane. The latter step is largely regulated by soluble N-ethylmaleimide-sensitive fusion attachment protein receptors (SNAREs) (Proux-Gillardeaux et al, 2005; Tayeb et al, 2005; Veale et al, 2010; Zylbersztejn and Galli, 2011). SNARE proteins are characterized by a conserved stretch of 60–70 amino acids known as the SNARE motif, and most have a carboxyl-terminal transmembrane domain connected by a short linker sequence (Jahn and Scheller, 2006). SNAREs form a complex with two other specific partner SNAREs, leading to specific regulation of membrane fusion. When appropriate sets of SNAREs combined, they form a stable complex consisting of coiled-coil four-helix bundle. While this complex formation is known to be sufficient to drive membrane fusion in vitro, post-transcriptional modifications such as phosphorylation and palmitoylation have also shown to regulate the function and localization of SNAREs (Snyder et al, 2006). A large number of SNARE mammalian proteins have been characterized, including the endosomal SNARE VAMP3/Cellubrevin, which is implicated in recycling of membrane receptors from endosome to the plasma membrane (McMahon et al, 1993; Galli et al, 1994). In Drosophila, two VAMP3/Cellubrevin homologous SNAREs are encoded in the genome; n-Syb is neuronally specific and associated primarily with synaptic vesicles (DiAntonio et al, 1993), while the closely related Syb/dVAMP is more generally expressed (Chin et al, 1993; DiAntonio et al, 1993). These two proteins appear to be functionally interchangeable not only with one another, but also with mammalian VAMP3/cellubrevin (Bhattacharya et al, 2002). Many studies have established the importance of ubiquitylation in controlling receptor endocytosis and endosomal sorting, and a number of molecular mechanisms and components regulating these processes have been described (Piper and Lehner, 2011; Haglund and Dikic, 2012). Ubiquitylation is considered to be an important signal in regulation of intracellular traficking, offering advantages such as the ability to regulate the modification by removal deubiquitinating enzymes, and the creation of binding sites for ubiquitin binding domain containing proteins. An estimated 300 human genes encode RING domain proteins in keeping with the already comprehensive repertoire of tasks that are undertaken by this class of proteins in the cell (Li et al, 2008). The Drosophila melanogaster Goliath PA domain E3 ligase has been described as expressed in the mesoderm (Bouchard and Cote, 1993), although further analysis of Goliath function in the fruitfly has not been reported. In fact, in Drosophila the goliath gene family comprises two members—goliath and godzillaCG10277. Xenopus GREUL1 (Goliath-related E3 ubiquitin ligase1) has been reported to function in the development of the anterior ectoderm (Borchers et al, 2002). The mouse orthologue G1RP (G1-related protein) was isolated from 32Dcl3 myeloblastic cells and has shown to be induced in apoptosis in response to IL-3 depletion (Baker and Reddy, 2000). Although a human homologue of Goliath, h-Goliath, has been described as expressed in normal and pathological haematopoietic cells, its function remains unknown (Guais et al, 2006). Most functional information comes from studies of mammalian GRAIL/RNF128, which plays a role in immune tolerance (Mueller, 2004). In this work, we describe the goliath gene family of PA domain E3 ligases as key regulators of the recycling endosome pathway. We show that the two Drosophila members of this family—Goliath and GodzillaCG10277—exhibit an endosomal location, and that both gain- and loss-of-function lead to the accumulation of Rab5-positive giant endosomes, implying a regulatory role in endosomal processes. Furthermore, expression of RNF167, a human member of the Goliath E3-ligase family, exhibits similar behaviour. Here, we identify the SNARE protein, VAMP3, as a prominent ubiquitylation target of these ubiquitin ligases. In agreement with VAMP3 being a target for Goliath family ubiquitin ligases, we show that recycling endosome trafficking is abrogated in response to their activity. Furthermore, loss of VAMP3 reverses both the Godzilla and RNF167 induced Rab5-positive giant endosome phenotype. In conclusion, our data suggest a novel function for the Goliath ubiquitin ligases in regulating recycling endosome trafficking via ubiquitylation of the VAMP3 SNARE protein. Results Goliath and Godzilla encode endosomally localized PA-TM-RING domain ubiquitin ligases. In Drosophila melanogaster, the goliath gene family comprises two members—goliath and godzillaCG10277. Goliath is expressed in muscles (Artero et al, 2003), while the related godzilla exhibits a more general expression pattern. Together, they encode a family of ubiquitin ligases in the fly that exhibit a distinct domain architecture: a signal peptide (a.a. 1–25), a PA domain (a.a. 98–207 Goliath; a.a. 53–155 Godzilla) (Mahon and Bateman, 2000), a transmembrane domain (a.a. 235–257 Goliath; a.a. 173–195 Godzilla) and a RING domain (a.a. 303–343 Goliath; a.a. 235–276 Godzilla) (Deshaies and Joazeiro, 2009; Figure 1A). The unusual presence of a transmembrane domain (a.a. 235–257 Goliath; a.a. 173–195 Godzilla) suggests that Goliath and Godzilla are membrane bound proteins. The PA domain is a highly conserved motif found in members of the protease superfamily and displays 32.3% identity between Goliath and Godzilla (Mahon and Bateman, 2000). Goliath also contains a C3H2C3-type RING domain, which is well-conserved among homologues (Figure 1B). The RING family of E3 ligases is the largest E3-ligase family, containing C3H2C3 or C3HC4 RING domains (Deshaies and Joazeiro, 2009). This domain contains four pairs of metal binding residues with a characteristic linear sequence of Cys-X2-Cys-X9-39-Cys-X1-3His-X2-3Cys/HisX2-Cys-X4-48-Cys-X2-Cys, where X can be any amino acid although there are distinct preferences for particular types of amino acid at a particular position (Lovering et al, 1993). The RING domain of Godzilla is 51% identical to that of Goliath suggesting an important and conserved functional role. This consensus is conserved across species in the larger Goliath family (Figure 1B). In contrast to two members in Drosophila, there are nine predicted homologues in humans (Figure 1C), including GRAIL/RNF128, which plays a role in immune tolerance (Mueller, 2004). Figure 1.Goliath and Godzilla encode endosomally localized PA-TM-RING E3 ligases. (A) Schematic domain structure of Drosophila Goliath and Godzilla. SP, signal peptide; PA, protease-associated domain; TM, transmembrane, and RING domain. (B) Sequence alignment of related RING domains. RNF167, RNF128 (also known as GRAIL) and RNF130 (also known as hGoliath) are human sequences. The RING domain (blue) contains six conserved Cys (C1–C6) and two His (H1 and H2) residues, which coordinate Zn2+ and are important for ligase activity. *For ligase-dead mutants, two His residues were substituted to Arg, corresponding to His323 and His326 in Goliath and His255 and His258 in Godzilla. (C) Phylogenic relationship of PA-TM-RING E3-ligase genes. (D) Subcellular localization of Goliath and Godzilla. Goliath-C-GFP (green, left) or Godzilla-C-GFP (green, right) transfected HEK293 cells were co-stained with cell organelle markers (red). EEA1, early endosome; LC3B, autophagosome; LysoTracker, lysosome; MitoTracker, mitochondria. Goliath-C-GFP and Godzilla-C-GFP-induced enlarged vesicle-like structures colocalize with EEA1 (arrowheads), and partially with LC3B (arrowheads); indicating that Goliath and Godzilla localize on an enlarged endosome membranes, but not on lysosomes or mitochondria. Bar 10 μm. The results shown here are typical images from at least four independent experiments. (E) Endogenous Drosophila protein is localized on endosomes in vivo. Endosomes were enlarged by expression of constitutively active Rab5 (Rab5Q88LYFP) in the Drosophila wing disc with MS1096-Gal4. Endogenous Godzilla is accumulated on the resultant enlarged Rab5-positive endosomes. The results shown here are typical images from at least four independent experiments. Download figure Download PowerPoint Drosophila goliath null mutants, in which all five coding exons were deleted, are viable and fertile. Given the restricted expression of goliath in embryonic muscles (Artero et al, 2003) we subsequently generated mutants in the locus of the more generally expressed related family member godzillaCG10277 (Supplementary Figure S1). Mutants in this locus—ΔgodzillaCG10277—are larval lethal. In an initial attempt to clarify the mechanism of function of the Goliath family ligases, we examined their subcellular localization. A significant amount of Godzilla clearly colocalizes with endosomal markers, such as EEA1, upon overexpression (Figure 1D; Supplementary Figure S2). While less extensive than that observed with Godzilla, overlap with EEA1 is also observed with the related Goliath (Figures 1D and 2A). In general, we noted that expression of Godzilla results in a stronger enlarged endosome phenotype than Goliath. This was also reflected in the more obvious loss of Mannose-6-Phosphate Receptor staining in cells expressing Godzilla, suggesting that Godzilla expression may lead to perturbations in the endosomal maturation process (Figure 2A). In agreement with these results, endogenous Godzilla protein in Drosophila tissues displays a vesicle localization overlapping with endosomes (Supplementary Figure S1E–G). To confirm the presence of endogenous Godzilla protein in the endosomal compartment, we expressed activated Rab5—Rab5Q88LYFP (Stenmark et al, 1994) to produce enlarged endosomes in a number of tissues. Expression of activated Rab5–Rab5Q88LYFP in the wing disc leads to the accumulation of endogenous Godzilla protein on the resulting enlarged endosomes (Figure 1E). Taken together, these data suggest that Goliath family ubiquitin ligases function in endosomal trafficking processes. Figure 2.Goliath and Godzilla ligase activity leads to the accumulation of Rab5-positive giant endosomes. (A) Goliath C-GFP, Godzilla-C-GFP or pCGFP was transfected into HEK293 cells, and stained with antibodies detecting early and late endosome marker proteins (EEA1 and M6PR, respectively). Expression of either Goliath or Godzilla resulted in significantly enlarged endosomes (>3 μm in diameter) as compared with control (∼0.4 μm). Dotted box shows an expanded view of each panel. (B) Rab5 colocalizes on giant vesicles induced by expression of Goliath and Godzilla. HEK293 cells were transfected with Goliath-C-GFP or Godzilla-C-GFP together with pEGFP-DsRed-Rab5. Dotted box shows an expanded view of each panel. (C) Overexpression of Godzilla leads to the formation of giant endosomes in Drosophila. GFP-tagged Godzilla was expressed with the MS1096-Gal4 wing driver. Early endosomes were visualized by anti-Rab5 (upper panel) or by co-expression of mCherry::2xFYVE, an early endosome biomarker (lower panel). Godzilla::GFP (green) is localized on specific microdomains of enlarged mCherry::2xFYVE-positive endosomes. Membrane targeted GFP (GFPCAAX) was used as control. Enlarged endosomes are seen in Godzilla-overexpressing tissue (arrowheads). Bar 10 μm. The results shown here are typical images from at least four independent experiments. Download figure Download PowerPoint Goliath and Godzilla ubiquitin ligase activity induces the formation of giant endosomes In both Drosophila wing disc expression and vertebrate cell culture experiments, we noticed that the endosomes were abnormally large upon Godzilla expression (>3 μm, up to 15 μm, Figure 2; quantified in Figure 3C). This is not due to the addition of the carboxy-terminal GFP since HA-tagged versions of both Godzilla and Goliath display similar localization and activity as their GFP-tagged counterparts (Supplementary Figure S3). Consistently, we noted that Godzilla was significantly more potent in the production of dramatically enlarged endosomes than Goliath. These enlarged endosomes were Rab5 and mCherry-FYVE positive in their nature (Figure 2B and C; Supplementary Figure S4), leading us to hypothesize that Godzilla/Goliath might play an important role in endosomal maturation perhaps via ubiquitylation of a key component of the endosomal machinery. In keeping with an important role for ubiquitin ligase activity, we were able to show that mutation of key His residues in the RING finger domain, corresponding to His323 and His326 in Goliath and His255 and His258 in Godzilla (Figure 1B; Su et al, 2009), abrogated the ability of either Godzilla or Goliath to generate large endosomes (Figure 3). Figure 3.Goliath- or Godzilla-induced endosomal enlargement is dependent on their ubiquitin ligase activity. (A, B) HEK293 cells were transfected with Goliath-C-GFP, ligase-dead Goliath-C-GFP (A), Godzilla-C-GFP, or ligase-dead Godzilla-C-GFP (B), and stained for EEA1 and ubiquitylated proteins (FK2). Strong ubiquitylation was observed on enlarged endosomes upon expression of ligase-active forms of Goliath and Godzilla, but not ligase-dead forms. Lower panels show an expanded view of dotted boxed area of upper image. Bar 10 μm. (C) Quantification of induction of enlarged endosomes by Goliath and Godzilla. The number of transfection-positive (GFP-positive) HEK293 cells containing giant endosomes was quantified. Results are given as means±s.d. of four independent experiments. Download figure Download PowerPoint Godzilla function is required in vivo for integrity of endosome trafficking In light of these results, we examined the effect of loss of function of these proteins on endosomes. To test this, we examined endosome accumulation in third instar larvae wing discs lacking Godzilla. RNAi knockdown of Godzilla resulted in a significant decrease in endogenous Godzilla protein (Supplementary Figure S1), and an accompanying robust accumulation of Rab5-positive endosomes (Figure 4A). This robust phenotype was also observed in ΔgodzillaCG10277 mutant animals, where there is a dramatic buildup of Rab5-positive endosomes in third instar larva prior to lethality (Figure 4B and C). Importantly, this endosomal phenotype is rescued by Godzilla genomic rescue (Supplementary Figure S5). Figure 4.Loss of Godzilla function leads to a robust accumulation of Rab5 endosomes. (A) RNAi-mediated knockdown of Godzilla driven by MS1096-Gal4 induces the formation of Rab5-positive giant endosomes in the Drosophila wing disc. Control is MS1096-Gal4-driven UAS-GFPCAAX. Rab5 (red) and GFP (green) are shown. Left panels are lower magnification overview of wing discs. Right panels are close-up view of the centre of wing pouch. Enlarged Rab5-positive endosomes are observed with godzilla RNAi but not in control. (B) Godzilla mutant animals exhibit enlarged Rab5-positive endosomes. Wing discs of late third instar larvae were visualized with antibodies towards Rab5 (red) as well as phalloidin to visualize F-actin (green). Dotted box shows an expanded view of each panel. Rab5-positive endosomes are enlarged and accumulated in godzilla mutant wing discs, but not in control (w1118). Bar 10 μm. (C) Rab5 endosomes accumulate to high levels in godzilla mutant wing discs. Both images were taken at identical exposure times. The results shown here are typical images from at least four independent experiments. Download figure Download PowerPoint Identification of VAMP3 as a target of Godzilla ubiquitin ligase activity Taken together, our data strongly suggest that Godzilla and Goliath play an important role in endosomal processing, leading to perturbation of signalling processes in vivo. We rationalized that a key substrate for their ubiquitylation activity may be a component of the endosomal trafficking machinery, which may be regulated by this family of ligases. Indeed, expression of constitutively active Rab5 or knockdown of Rab7 has also been documented as generating large endosomes (Stenmark et al, 1994; Poteryaev et al, 2010), suggesting that Godzilla/Goliath may regulate Rab5 activity by some unknown mechanism. With this hypothesis in mind we set out to test a number of candidates, with focus on regulators of Rab5 and Rab7 activity. Those molecules tested included: Rab5, Rab7 (Chavrier et al, 1990), the Rab5-specific guanine nucleotide exchange factor (GEF) Rabex5 (Valsdottir et al, 2001; Penengo et al, 2006) and the Rab GDP dissociation inhibitor RabGDI (Ullrich et al, 1994; Poteryaev et al, 2010). In spite of convincing evidence that expression of either Godzilla or Goliath resulted in a high level of ubiquitylation, as measured by anti-FK2 staining (Figure 3), we were unable to identify a cellular target by this candidate approach. In order to proceed, we carried out a proteomics-based analysis (UbiSCAN), employing anti-GG antibodies to identify conserved cellular targets of Drosophila Godzilla (Xu et al, 2010). This analysis enables the identification, not only of substrate molecules, but also identification of those lysines targeted for ubiquitylation within the substrate. This approach led to the identification of the SNARE protein VAMP3, which is known to be involved in vesicle fusion and trafficking (McMahon et al, 1993) as a substrate for this family of ubiquitin ligases (Figure 5; Supplementary Figure S6; Supplementary Table S1). VAMP3 was heavily ubiquitylated at Lys 66, Lys 68 and Lys 77 in samples containing active Godzilla, but not in Godzilla ligase-dead control lysates. Human VAMP3/Cellubrevin and the Drosophila orthologues Synaptobrevin (Syb, also called dVAMP) and neuronal-Synaptobrevin (n-Syb) show significant identity of 71 and 64%, respectively, and importantly these ubiquitylated Lys residues (Lys 66, 68 and 77) in VAMP3 are completely conserved in the Drosophila homologues (Figure 5B). Figure 5.VAMP3, an endosomal SNARE protein, is ubiquitinated by Godzilla. (A) Schematic of identification of ubiquitiylated proteins by anti-GlyGly antibody purification (Xu et al, 2010). Cell extracts containing ubiquitylated proteins were digested by trypsin, resulting in generation of di-glycine conjugated peptides on the ε-amine group of lysine. Peptides were immuno-purified by anti-GlyGly antibody then subjected to nLC-MS/MS analysis. (B) Sequence alignment of VAMP3 and its Drosophila homologue, Synaptobrevin (Syb, dVAMP) and neuronal-Synaptobrevin (n-Syb). Identically conserved residues are highlighted in grey and the transmembrane domain and linker region are marked. Three ubiquitinated lysine residues (Lys66, Lys68 and Lys77) identified in VAMP3 are shown in red. These ubiquitinated lysine residues are completely conserved between human and Drosophila VAMP3 homologues. (C) Localization of VAMP3 on Godzilla-induced giant endosomes. Wild-type or ligase-dead Godzilla expressing HEK293 cells were stained with anti-VAMP3 antibody (red). (D) Rab11-mediated recycling is disrupted in wild-type Godzilla expressing cells, but not in ligase dead. (E) VAMP3 knockdown rescues the formation of giant endosomes induced by Godzilla, quantified in (F). Quantified results are given as mean±s.d. for four independent experiments. Bar 10 μm. (G) Formation of Rab5-positive giant endosomes in godzilla loss-of-function wing discs is suppressed upon knockdown of the Drosophila VAMP3 homologue Synaptobrevin (Syb). Upper panel: late third instar larvae wing disc expressing UAS-godzilla RNAi driven by MS1096-Gal4; bottom panel: MS1096-Gal4 driving both UAS-godzilla RNAi and UAS-syb RNAi wing disc. Wing discs were visualized with Rab5 (red) and phalloidin to visualize F-actin (green). Dotted box shows an expanded view. (H) Formation of FYVE-positive giant endosomes in Godzilla-overexpressing wing discs is suppressed upon knockdown of Syb. Giant endosomes observed upon Godzilla overexpression (upper panel, arrowheads) are suppressed in a Syb knockdown background (bottom panel). Download figure Download PowerPoint In order to confirm whether VAMP3 is a potential target of Godzilla, we investigated VAMP3 localization in Godzilla-transfected HEK293 cells. VAMP3 is known to localize on both early and recycling endosomes and is involved in endocytic recycling (McMahon et al, 1993; Galli et al, 1994). In both control and ligase-dead Godzilla-transfected cells, VAMP3 displays a similar intracellular distribution, partially overlapping with ligase-dead Godzilla; suggesting an early and recycling endosome distribution (Figure 5C). In contrast, in cells expressing wild-type Godzilla VAMP3 is found on enlarged endosomes, where it colocalizes with Godzilla (Figure 5C). The Godzilla induced endosomal phenotype peturbs trafficking of both Rab5- and Rab11-positive endosomes and requires VAMP3 As VAMP3 has been shown to play a role in recycling endosome trafficking (Galli et al, 1994; Hong, 2005), we considered the hypothesis that Godzilla may regulate recycling endosome trafficking. In order to test this, we analysed transfected cells for the presence of Rab11-positive recycling endosomes (Ullrich et al, 1994). While cells transfected with ligase-dead Godzilla stain positive for Rab11 recycling endosomes compared with mock-transfected cells, we were unable to detect the presence of Rab11 recycling endosomes in the presence of wild-type ligase active Godzilla (Figure 5D). Interestingly, while the normal pattern of pericentriolar and dispersed Rab11-positive recycling endosomes was not seen, some residual Rab11 staining could still be observed in the vicinity of the Godzilla containing enlarged endosomes, suggesting an inability of Rab11 containing vesicles to be generated (Figure 5D, upper panel). In keeping with this, overexpression of Godzilla in the Drosophila with MS1096-Gal4 also results in a loss of Rab11-positive vesicles in the wing disc (Supplementary Figure S7). To further investigate the significance of VAMP3 as a Godzilla target in the Godzilla-induced giant endosome phenotype, we transfected HEK293 cells either with scrambled control siRNA or with two independently employed siRNAs targeting VAMP3 (Supplementary Figure S8). Indeed, reduction of endogenous VAMP3 expression levels resulted in decreased levels of Rab11 recycling endosomes, while no impact on the presence or vesicle size of EEA1 early endosomes was seen (Supplementary Figure S8). Next, we investigated whether knockdown of VAMP3 was able to block the large endosome phenotype mediated by Godzilla overexpression (Figure 5E and F). Prior to transfection with wild-type Godzilla, endogenous VAMP3 expression levels were reduced by siRNAs targeting VAMP3. A strong reduction in the enlarged endosome phenotype was observed; leading us to conclude that loss of VAMP3 significantly blocks the Godzilla mediated enlarged endosome phenotype. These results suggest that ubiquitylation does not result in a simple inhibition of VAMP3 function, such as inhibition of SNARE complex formation or complex assembly, but that the ubiquitylation of VAMP3 may work as a molecular switch for the recycling endosome pathway. We then examined the effect of loss of Godzilla function in vivo returning to the Drosophila wing disc. Drosophila has two VAMP3 homologues, the neuronal n-Syb and a more generally expressed Syb (Chin et al, 1993; DiAntonio et al, 1993). Knockdown of Drosophila Syb reverses the godzilla mutant phenotype, resulting in a loss of giant Rab5 endosomes in godzilla mutant wing discs (Figure 5G). Furthermore, Drosophila Syb knockdown blocks the formation of FYVE-positive giant endosomes observed upon Godzilla overexpression in the Drosophila wing disc (Figure 5H). Together, these data provide convincing evidence that VAMP3/Syb is a relevant functional target of the Godzilla ligase in vivo in the fruitfly as well as in mammalian cells. The related mammalian RNF167 PA-TM-RING domain ubiquitin ligase induces formation of giant endosomes We then asked whether a role in endosomal trafficking may be conserved among the human members of the Goliath family. Consistent with this we found that expression of human RNF167 also led to the accumulation of giant endosomes that were positive for EEA1, FK2 and VAMP3, with a concomitant loss of Rab11-positive recycling endosomes (Figure 6A and B). Moreover, as with the Godzilla induced gia