The WD40-repeat Proteins WDR-20 and WDR-48 Bind and Activate the Deubiquitinating Enzyme USP-46 to Promote the Abundance of the Glutamate Receptor GLR-1 in the Ventral Nerve Cord of Caenorhabditis elegans*

Background: USP-46 deubiquitinates the C. elegans glutamate receptor GLR-1. Results: WDR-20 and WDR-48 bind and activate USP-46 in vitro and increase the abundance of GLR-1 in neurons. Conclusion: WD40-repeat proteins stimulate USP-46 activity, resulting in increased GLR-1 stability in neurons and alterations in glutamate-dependent behavior. Significance: WD40-repeat protein regulation of DUB activity is important for glutamate receptor trafficking in vivo. Ubiquitin-mediated endocytosis and degradation of glutamate receptors controls their synaptic abundance and is implicated in modulating synaptic strength. The deubiquitinating enzymes (DUBs) that function in the nervous system are beginning to be defined, but the mechanisms that control DUB activity in vivo are understood poorly. We found previously that the DUB USP-46 deubiquitinates the Caenorhabditis elegans glutamate receptor GLR-1 and prevents its degradation in the lysosome. The WD40-repeat (WDR) proteins WDR20 and WDR48/UAF1 have been shown to bind to USP46 and stimulate its catalytic activity in other systems. Here we identify the C. elegans homologs of these WDR proteins and show that C. elegans WDR-20 and WDR-48 can bind and stimulate USP-46 catalytic activity in vitro. Overexpression of these activator proteins in vivo increases the abundance of GLR-1 in the ventral nerve cord, and this effect is further enhanced by coexpression of USP-46. Biochemical characterization indicates that this increase in GLR-1 abundance correlates with decreased levels of ubiquitin-GLR-1 conjugates, suggesting that WDR-20, WDR-48, and USP-46 function together to deubiquitinate and stabilize GLR-1 in neurons. Overexpression of WDR-20 and WDR-48 results in alterations in locomotion behavior consistent with increased glutamatergic signaling, and this effect is blocked in usp-46 loss-of-function mutants. Conversely, wdr-20 and wdr-48 loss-of-function mutants exhibit changes in locomotion behavior that are consistent with decreased glutamatergic signaling. We propose that WDR-20 and WDR-48 form a complex with USP-46 and stimulate the DUB to deubiquitinate and stabilize GLR-1 in vivo.

Regulation of the abundance of glutamate neurotransmitter receptors (GluRs) 3 at synapses can modulate synaptic strength and is a key molecular mechanism involved in learning and memory (1). Posttranslational modification of GluRs by ubiquitin promotes receptor endocytosis and degradation, providing a mechanism to regulate synaptic GluR levels (2,3). Ubiquitin is covalently attached to and removed from target proteins by a large family of ubiquitin ligases and deubiquitinating enzymes (DUBs), respectively (4). The balance of activity of specific ubiquitin ligases and DUBs controls the localization, function, and stability of target proteins, including neurotransmitter receptors (5)(6)(7)(8).
In Caenorhabditis elegans, the abundance of the AMPA-type GluR, GLR-1, is regulated by ubiquitin (3). Ubiquitin is directly conjugated to GLR-1 and promotes receptor endocytosis and post-endocytic degradation in the lysosome (3,9). Mammalian AMPA receptors are also regulated by ubiquitin (10,11). Several ubiquitin ligases have been identified that regulate invertebrate GluRs (12)(13)(14)(15)(16) and mammalian AMPA receptors (17)(18)(19)(20). DUBs counter the action of ubiquitin ligases by removing ubiquitin from substrates, but the specific DUBs that function at synapses are not well defined. We showed recently that the DUB USP-46 regulates the levels of GLR-1 at synapses in C. elegans. USP-46 promotes the abundance of GLR-1 by deubiquitinating the receptor and preventing its degradation in the lysosome (21).
USP-46 and its homologs have been implicated in regulating diverse cellular functions, including endocytosis, cell polarity, signal transduction, chromatin modification, and mitochon-drial biogenesis (22)(23)(24)(25)(26)(27). In some cases, the substrates of the DUB have been identified. For example, USP46 deubiquitinates the phosphatase PHLPP (PH domain and leucine-rich repeat protein phosphatase) to regulate Akt signaling in colon cancer cells (25). The USP46 homolog USP12 negatively regulates Notch levels in Drosophila and mammalian cells by deubiquitinating Notch and promoting its lysosomal degradation (27). USP12 and USP46 also deubiquitinate histones H2A and H2B to regulate development in Xenopus embryos (22). Although the role of USP46 in regulating GluRs has not been examined in the mammalian nervous system, usp46 mutant mice exhibit antidepressive-like behaviors and abnormalities in the GABA signaling system (28,29). However, the mechanism by which USP46 affects the GABA system is not yet known. These studies illustrate that USP46 is involved in a variety of processes in multiple cell types, underscoring the importance of understanding the mechanisms involved in regulating USP46 activity in vivo.
Mammalian USP46 and its close homolog USP12 have very low intrinsic catalytic activity in vitro, indicating that they may be regulated by other factors in vivo (30 -32). Research in systems from yeast to mammals has identified several proteins that interact with USP46 or USP12, including two WD40-repeatcontaining proteins: WDR48 (also known as UAF-1) and WDR20 (22-24, 27, 30, 32, 33). Biochemical isolation of protein complexes shows that the catalytic activity of mammalian USP12 and USP46 can be stimulated by WDR48 (22, 30 -32) and WDR20 (32) in vitro, which suggests that these proteins might be required for normal USP46 function in vivo. In mammalian cells, WDR48 can bind USP12 to promote deubiquitination of non-activated Notch (27). The WDR48 homolog Duf1 binds and stimulates the activity of Ubp9 (USP46) to regulate ATP synthase expression in Saccharomyces cerevisiae (23), and Bun107 (WDR20) and Bun 62 (WDR48) interact with Usp9 in Schizosaccharomyces pombe (24). The conservation of the interaction between the homologs of WDR-20, WDR-48, and USP-46 across phylogeny emphasizes the importance of this complex. However, the physiological relevance of this interaction in vivo remains to be fully defined.
In this study, we identified the C. elegans homologs of WDR20 and WDR48. As with their mammalian counterparts, C. elegans WDR-20 and WDR-48 can bind to and activate USP-46 in vitro. Overexpression of WDR-20 and WDR-48 in neurons increases the abundance and stability of GLR-1 in vivo. Importantly, the effect of the WDR proteins on GLR-1 results in a corresponding change in glutamate-mediated locomotion behavior that is dependent on usp-46. This study identifies a novel physiological role for WDR-20 and WDR-48 in neurons and shows that they can activate USP-46 to control GLR-1 levels in vivo, resulting in changes in glutamate-dependent behavior.
Imaging-Fluorescence imaging of GLR-1::GFP was performed as described previously (21). Briefly, L4 larval-stage animals were immobilized using 30 mg/ml 2,3-butanedione monoxamine (Sigma-Aldrich), and the VNC was imaged in the anterior region of the animals just posterior to the RIG neuronal cell bodies. 1 m (total depth) Z-series stacks were collected using a Carl Zeiss Axioscope M1 microscope with a ϫ100 Plan Apochromat (1.4 numerical aperture) objective equipped with GFP and Cy3.5 filters. Images were collected with an Orca-ER charge coupled device (CCD) camera (Hamamatsu) and MetaMorph (version 7.1) software (Molecular Devices). Maximum intensity projections of Z-series stacks were used for quantitative analyses of fluorescent puncta. Exposure settings and gain were adjusted to fill the 12-bit dynamic range without saturation and were identical for all images taken of each fluorescent marker. Line scans of ventral cord puncta were generated using MetaMorph (version 6.0) and were analyzed with custom-written software (Jeremy Dittman, Weill Cornell Medical College) in Igor Pro (version 5) (Wavemetrics) (3). Arc lamp output was monitored by measuring the intensities of 0.5-m FluoSphere beads (Invitrogen). Puncta intensities for wild-type and mutant animals were normalized to the average bead intensity for the corresponding day before normalizing the wild-type intensities to 1. Puncta density was determined by quantifying the average number of puncta per 10 m of the VNC. GFP reporter strains were imaged as above, except that young adult animals were imaged. Primary neuronal cultures were imaged as above but without 2,3-butanedione. The anti-HA-Alexa Fluor 594 punctum fluorescence intensity relative to the interpunctal neurite fluorescence was analyzed using Igor Pro (version 5) as described above.
Detection of GLR-1::GFP by Immunoblot Analysis of Wholeanimal Lysates-Total GLR-1::GFP protein levels were determined by immunoblot analysis of total worm lysates prepared from mixed-stage populations of animals expressing GLR-1::GFP (nuIs24). Lysates were made by resuspending worms in SDS sample buffer, followed by freezing at Ϫ80°C and boiling for 2 min. After electrophoresis and transfer, the upper half of the nitrocellulose membrane was probed with monoclonal anti-GFP antibodies (JL-8, Covance), and the lower half was probed with polyclonal anti-tubulin antibodies (Abcam) for normalization of input levels.
Cell Culture-HEK293T cells (a gift from Grace Gill) were maintained in DMEM with 0.5% Fetal Clone II Serum (HyClone) and penicillin/streptomycin (Invitrogen). Cells were transfected with 0.5-3 g of plasmid DNA using Lipofectamine 2000 according to the directions of the manufacturer. pCMV-GFP was cotransfected along with other plasmids as a control to monitor transfection efficiency.
Immunoprecipitation from Tissue Culture Cells-After 24 h, cells were washed once with PBS and lysed with IP buffer (50 mM Tris (pH7.5), 150 mM NaCl, 0.5% Nonidet P-40). Harvested cells were spun at 14,000 rpm for 10 min at 4°C. Cleared lysate was incubated for 4 -12 h with protein A-and G-Sepharose beads (GE Healthcare) and mouse anti-FLAG antibody (M2, Sigma) in the presence of protease inhibitors (10 g/ml leupeptin, 5 g/ml chymostatin, 3 g/ml elastin, 1 g/ml pepstatin A, and 1 mM PMSF) and 0.01 M DTT. Immunoprecipitated complexes were washed four times with lysis buffer and resuspended in 2ϫ SDS-PAGE buffer. Samples were subjected to SDS-PAGE on 10% acrylamide gels and subsequently transferred to a nitrocellulose membrane. Immunoblots were blocked in Tris-buffered saline with Tween (TBS-T) and 5% milk and probed with the following antibodies: mouse anti-GFP (Covance), rabbit anti-FLAG (Rockland, a gift from Ira Herman), rat anti-HA (Roche, a gift from Ira Herman), mouse anti-Myc (Santa Cruz Biotechnology, a gift from Ira Herman), rabbit anti-FLAG (M2)-HRP-conjugated (Sigma, a gift from Grace Gill).
Ub-VME Reaction-HEK293T cells were transfected as above. FLAG⅐USP-46 complexes were immunoprecipitated with anti-FLAG antibody and resuspended in 30 l Ub-VME reaction buffer (20 mM Tris (pH 8.0), 150 mM NaCl, and 1 mM DTT). Samples were divided into two separate tubes, and 1.5 g of Ub-VME was added to one of them. 1.5 l of reaction buffer was added to the other (control) sample. Samples were incubated at 37°C for 30 min with intermittent, gentle shaking. Reactions were stopped by addition of 5 l of 5ϫ SDS-PAGE sample buffer.
Primary Culture of C. elegans Neurons-Cells were isolated and cultured as described in Ref. 36. Cells were grown for no more than 3 days at 20°C prior to fixation and staining. Cells were washed two times with M9 buffer (phosphate-buffered saline with magnesium sulfate) and then fixed in 3% parafor-maldehyde in PBS for 30 min at room temperature. Incubation for 2 min with 0.2% Triton X-100 in PBS was used to permeabilize the cells. After blocking with 0.2% BSA in PBS for 20 min, cells were incubated with mouse anti-HA, monoclonal 16B12, Alexa Fluor 594 conjugate (Invitrogen, a gift from Lars Dreier) at 1 g/ml in blocking solution for 45 min at room temperature. Cells were washed four times with PBS prior to mounting and imaging.
Behavioral Assays-Spontaneous locomotion of young adult hermaphrodites was analyzed as described previously (21,37). Briefly, reversals were defined as a backward movement that brought the tip of the nose farther back than the position of the large pharyngeal bulb at the start of the movement. Individual animals were monitored for 5 min each. For each experiment, all genotypes shown were tested on each assay day.
Quantitative PCR-cDNA was reverse-transcribed from RNA using established protocols. Amplification reactions were run on a Stratagene real-time cycler, MX4000, using SYBR Green (Invitrogen) reaction mixture with Rox as a reference dye. Amplification of usp-46, wdr-20, and wdr-48 was specific, as monitored by agarose gel and melting curves. The relative abundance of each gene product for each genotype was normalized to actin using the ⌬⌬Ct method. All amplifications were performed in triplicate using cDNA from two to three independent RNA isolations.

Identification of C. elegans WDR-20 and WDR-48-We
showed previously that the DUB USP-46 regulates the abundance of the glutamate receptor GLR-1 in the VNC of C. elegans (21). To study how USP-46 activity is regulated in the nervous system, we decided to characterize proteins that were known to interact with USP-46 or its close homolog, USP-12. Two WD40-repeat proteins, WDR20 and WDR48, were of particular interest because mammalian WDR20 and WDR48 can bind to and activate USP-46 and its close homolog, USP12, in vitro (30 -33). We identified homologs of both WDR20 and WDR48 in the C. elegans genome (GenBank TM accession numbers NM_001269255.1 and NM_065530.5, respectively). The C. elegans ORF C08B6.7 is 43% similar and 33% identical to human WDR-20, and the ORF F35G12.4 is 55% similar and 43% identical to human WDR48. C. elegans WDR-20 and WDR-48 are predicted to contain the same number and organization of WD40 repeats as their mammalian counterparts (Fig. 1A). C08B6.7 is also similar to mammalian DMWD (Dystrophia Myotonica, WD repeat containing), another WD40-repeat protein that interacts with USP12/46 (33). However, C08B6.7 is closer in homology to WDR20. Hereafter, we refer to C. elegans C08B6.7 as WDR-20 and We next tested whether C. elegans WDR-20 and WDR-48 could activate the catalytic activity of USP-46 using an in vitro DUB assay. The catalytic activity of a population of USP enzymes can be estimated by incubating the enzyme with HA epitope-tagged ubiquitin-vinyl methyl ester (HA-Ub-VME), a non-catalyzable ubiquitin suicide substrate (39). The active site cysteine of USP family DUBs forms an irreversible covalent bond with HA-Ub-VME, which results in an ϳ9-kDa increase in the apparent molecular mass of the enzyme. We measured the effect of WDR-48 and WDR-20 on USP-46 activity by immunoprecipitating FLAG⅐USP-46 from HEK293T cells expressing FLAG⅐USP-46 alone ( Fig FEBRUARY 7, 2014 • VOLUME 289 • NUMBER 6

WDR-20 and WDR-48 Regulate Glutamate Receptors
His 6 ⅐WDR-20 increased the proportion of catalytically active USP-46 ( Fig. 2A, lane 6). As expected, no increase in FLAG⅐USP-46 molecular weight was observed in the absence of HA-Ub-VME substrate ( Fig. 2A, lanes 1, 3, 5, and 7). The low level of USP-46 activity observed in the absence of the WDR proteins ( Fig. 2A, lane 2) could represent low intrinsic enzyme activity, as reported previously (30,32), or could be attributed to the presence of endogenous human WDR20 and WDR48 in HEK293T cells. To ensure that the change in apparent molecular weight was due to the catalytic activity of USP-46, we repeated the experiment with a catalytically inactive version of USP-46 in which the catalytic cysteine was mutated to alanine (USP-46 (CϾA)). Incubation of FLAG⅐USP-46(CϾA) with HA-Ub-VME did not cause a change in molecular weight either in the absence or presence of the WDR proteins (Fig. 2B). These data show that C. elegans WDR-20 and WDR-48 can form a complex with USP-46 and enhance its catalytic activity, demonstrating that the regulation of USP-46 by these WD40-repeat proteins in vitro is conserved.
usp-46 null mutants exhibit a decreased abundance of GLR-1::GFP in the VNC (21). This effect is dependent on USP-46 catalytic activity because the reduction in GLR-1::GFP can be rescued by expression of wild-type USP-46 but not catalytically inactive USP-46 (USP-46 (CϾA)). We found that overexpression of USP-46 under control of the glr-1 promoter in either an usp-46 mutant or wild-type background does not increase the abundance of GLR-1::GFP in the VNC over wildtype levels (21) (Fig. 3, F and K). Overexpression of the usp-46 transgene was confirmed using quantitative PCR (ϳ9-fold increase versus the wild type). These results suggest that expression of USP-46 is not limiting and that USP-46 activity may be tightly controlled in vivo.
Overexpression of WDR-20 and WDR-48 Affects GLR-1-dependent Locomotion Behavior-Changes in the levels of GLR-1 at the cell surface, and at synapses in particular, might be expected to alter GLR-1 signaling and, consequently, affect GLR-1-dependent locomotion. Because WDR-20 and WDR-48 increase surface levels of GLR-1 in neuronal cultures, we tested whether overexpression of WDR-20 and WDR-48 affected the frequency of spontaneous reversals during locomotion. In C. elegans, spontaneous locomotion is characterized by periods of forward movement interspersed with brief periods of back-  The numbers listed below the images indicate the average normalized ratio of GLR-1::GFP to tubulin control. Experiments were repeated at least twice with independent biological replicates. B, representative immunoprecipitation experiments detecting the relative amounts of ubiquitinated GLR-1::GFP in membranes prepared from mixed-stage populations of animals expressing the GLR-1::GFP transgene (nuIs24). Membranes were prepared from wild-type animals and animals expressing wdr-20, wdr-48, and usp-46 under the control of the glr-1 promoter (pzIs24). Total GLR-1::GFP was first immunoprecipitated using polyclonal anti-GFP antibodies (first IP, lanes 1 and 2) and either directly immunoblotted (IB) with anti-GFP antibodies (lanes 1 and 2) or subjected to a second, sequential immunoprecipitation of ubiquitin-GLR-1 conjugates using polyclonal anti-ubiquitin antibodies (second IP, lanes 3 and 4). Immunoblot analyses were used to detect immunoprecipitated proteins from each IP. Immunoprecipitated GLR-1::GFP from the first IP and ubiquitin-GLR-1::GFP conjugates immunoprecipitated in the second IP were detected with monoclonal anti-GFP antibodies. 120 times more material was loaded for the anti-GFP blot of the second IP than for the anti-GFP blot of the first IP. The numbers listed below the right panel indicate the average normalized ratio of the amount of ubiquitinated GLR-1 (right panel) to the amount of GLR-1::GFP isolated in the first IP (left panel) (Ub-GLR-1-GLR-1) from three independent experiments (p Ͻ 0.05).  FEBRUARY 7, 2014 • VOLUME 289 • NUMBER 6 ward movement (44). The amount of glutamatergic transmission in VNC interneurons controls the frequency of these reversals. For example, animals with reduced glutamatergic signaling, such as those with mutations in the vesicular glutamate transporter eat-4/VGLUT or glr-1, exhibit decreased reversal frequencies compared with wild-type animals (3,44,47). In contrast, mutants with increased glutamatergic signaling have increased reversal frequencies (3,13,16,37,44). We found that overexpression of WDR-20, WDR-48, and USP-46 (Pglr-1::wdr-20/wdr-48/usp-46) increased spontaneous reversal frequencies compared with wild-type animals, which is consistent with increased glutamatergic signaling (Fig. 5I). Conversely, usp-46 (ok2232) mutants have decreased reversal frequencies (Fig. 5J), consistent with previous results (21). Interestingly, overexpression of WDR-20 and WDR-48 (Pglr-1::wdr-20/wdr-48) significantly increased reversal frequencies compared with controls, and this effect was completely blocked in usp-46 null mutants (Pglr-1::wdr-20/wdr-48; usp-46 (ok2232)) (Fig. 5J). These data indicate that overexpression of WDR-20 and WDR-48 proteins affect GLR-1-dependent locomotion behavior in an usp-46-dependent manner.

Effects of wdr-20 and wdr-48 Loss-of-function Mutants on GLR-1::GFP and GLR-1-dependent Locomotion Behavior-We
next tested whether the WDR proteins are expressed in the nervous system by analyzing the expression pattern of wdr-20 and wdr-48 transcriptional reporters (i.e. GFP under control of the wdr-20 or wdr-48 promoters, respectively). We found that wdr-20 is expressed in several neurons in the head and tail (Fig.  6B, left panel), including several glr-1-expressing neurons on the basis of overlap with a glr-1 transcriptional reporter (Pglr-1::dsRED) (Fig. 6C), and in VNC processes (data not shown). Although expression of the wdr-48 transcriptional reporter was weak, we were able to detect GFP expression in several head neurons and cells in the tail, including the anal depressor cell (Fig. 6B, right panel). These transcriptional reporters may not encompass the full endogenous expression pattern of the wdr genes; however, these data suggest that both wdr-20 and wdr-48 are expressed in the nervous system.
To determine whether WDR-20 and WDR-48 are required to maintain normal levels of GLR-1::GFP, we analyzed the distribution of GLR-1::GFP in the VNC of wdr-20 (gk547140) and wdr-48 (tm4575) loss-of-function mutants. The wdr-20 (gk547140) allele contains a non-sense mutation (GϾA) that results in a premature stop codon at residue 288 of the WDR-20 protein. The wdr-48 (tm4575) allele deletes 132 amino acids from the WDR-48 coding region, disrupting WD40 repeat domains 5-7, and is predicted to represent a null allele because of the introduction of a premature stop codon downstream of the deletion (Fig. 6A). We found that wdr-20 mutant animals exhibited a 25% decrease in GLR-1::GFP punctum fluorescence intensity in the VNC (Fig. 6, E and G). This effect could be rescued by expression of wild-type wdr-20 cDNA in interneurons under control of the glr-1 promoter (Fig. 6, F and G, Rescue). These data indicate that wdr-20 functions in interneurons to maintain normal GLR-1::GFP levels in the VNC. In contrast, we observed no change in GLR-1::GFP punctum fluorescence intensity in the VNC of wdr-48 (tm4575) mutants compared with wild-type controls (Fig. 6, H, I, and K). Similarly, we found no alteration in GLR-1::GFP punctum intensity in another independent wdr-48 mutant, wdr-48 (gk173034) (Fig. 6, J and  K). The wdr-48 (gk173034) allele contains a missense mutation (GϾA) at a putative splice donor site of the first intron (Fig.  6A), creating alternative splice variants that ultimately result in premature stop codons (data not shown). The genetic lesions described above were verified through amplification and sequencing of cDNA and/or genomic DNA. These results show that wdr-20, but not wdr-48, is required for maintaining total levels of GLR-1::GFP in the VNC, suggesting that the WDR proteins regulate GLR-1 via distinct mechanisms.
Because GLR-1::GFP fluorescence intensity in the VNC likely represents both surface and internal pools of the receptor, and because our data indicate that overexpression of WDR-20 and WDR-48 increases surface levels of GLR-1 (Fig. 5G) and the rate of spontaneous reversals (I and J), we tested the effects of wdr-20 and wdr-48 loss-of-function mutation on locomotion behavior. Interestingly, we found that both wdr-20 and wdr-48 mutant animals exhibited decreased reversal frequencies, consistent with decreased glutamatergic signaling. In addition, the magnitude of this decrease was similar to that observed in usp-46 mutant animals (Fig. 6L). These data demonstrate that both wdr-20 and wdr-48 are required for normal GLR-1-dependent locomotion behavior. These data also suggests that, although wdr-48 mutants do not exhibit decreased total GLR-1::GFP levels in the VNC, these mutants likely have reduced surface levels or function of GLR-1 at the synapse. Our data suggest a model whereby WDR-20 and WDR-48 act together to regulate USP-46 activity, which, in turn, controls GLR-1 levels at the synapse.

DISCUSSION
Ubiquitin has emerged as a critical regulator of synapse development and function (48 -50). Although the specific DUBs that function in the nervous system are beginning to be described (8,51), the mechanisms that regulate DUB activity in vivo are understood poorly. A large scale proteomics study revealed that 36% of mammalian DUBs interact with WD40repeat proteins (33). In particular, the WD40-repeat proteins WDR-20 and WDR-48/UAF-1 can interact with and stimulate the catalytic activity of USP12 and USP46 in vitro (30,32,33). In this study, we identified C. elegans homologs of WDR20 and WDR48. We showed that WDR-20 and WDR-48 can form a complex with USP-46 in heterologous cells and activate its catalytic activity in vitro (Figs. 1 and 2). Overexpression of WDR-20 and WDR-48 in neurons results in increased abundance of GLR-1 in the VNC, and this effect was further enhanced by coexpression of USP-46 but not by catalytically inactive USP-46 (CϾA) (Fig. 3). Coexpression of WDR-20, WDR-48, and USP-46 results in an increase in total GLR-1 protein and a corresponding decrease in the levels of ubiquitin-GLR-1 conjugates (Fig. 4), suggesting that the WDR proteins stimulate USP-46 to deubiquitinate and stabilize GLR-1. In addition, overexpression of WDR-20 and WDR-48 increases the levels of GLR-1 on the cell surface in an usp-46-dependent  FEBRUARY 7, 2014 • VOLUME 289 • NUMBER 6 manner (Fig. 5G). Importantly, overexpression of WDR-20 and WDR-48 affects GLR-1-dependent locomotion behavior in a manner that is consistent with increased glutamatergic signaling, and this effect is blocked by usp-46 mutation (Fig. 5J). Conversely, wdr-20 and wdr-48 loss-of-function mutants have decreased spontaneous locomotion reversals, which is similar to usp-46 null mutants and consistent with decreased glutamatergic signaling (Fig. 6L) (21). Together, our results show that the WD40-repeat proteins WDR-20 and WDR-48 function together with USP-46 to promote the stability and synaptic abundance of GLR-1 in vivo.

WDR-20 and WDR-48 Regulate Glutamate Receptors
Although we found that the effect of overexpressing WDR-20 and WDR-48 on surface expression of GLR-1::GFP and on locomotion behavior was completely dependent on usp-46 (Fig. 5, G, H, and J), their effect on GLR-1::GFP levels in the VNC was only partially dependent on usp-46 (A-E). These data suggest that the WDR proteins likely act through USP-46 to regulate functional GLR-1 levels at the synaptic surface. In support of this idea, we found that, similar to usp-46 mutants, wdr-20 and wdr-48 loss-of-function mutants exhibit defects in locomotion behavior consistent with decreased glutamatergic signaling (Fig. 6L). In addition, although wdr-20 and usp-46 loss-of-function mutants have decreased levels of GLR-1::GFP in the VNC, wdr-48 loss-of-function mutants did not affect the abundance of GLR-1::GFP (Fig. 6, H-K). These data suggest that, although WDR-20 and WDR-48 may have differential effects on GLR-1 trafficking, both WDR-20 and WDR-48 regulate GLR-1 at the synaptic surface to impact locomotion behavior.
Because GLR-1::GFP fluorescence in the VNC represents both surface and internal pools of receptors, our data suggest that WDR-20 and WDR-48 may regulate internal pools of GLR-1 via an usp-46-independent mechanism. The WDR proteins may interact directly with GLR-1 to regulate receptor trafficking. Alternatively, WDR-20 and WDR-48 may activate another DUB to control GLR-1. Indeed, several other studies indicate that WDR-20 and WDR-48 or their homologs can function together with other DUBs. For example, mammalian WDR48/UAF-1 can bind and stimulate USP1 activity (30,33,52), and yeast Bun107/WDR20 and Bun62/WDR48 both interact with Ubp15, the S. pombe homolog of mammalian USP7 (24). Thus, USP-46 may function together with other DUBs downstream of WDR-20 and WDR-48 to control GLR-1 levels. Consistent with this idea, USP-46 and its homologs have been shown to function together with other DUBs in several systems. USP-46 functions together with USP-47 and MATH-33/USP7 to regulate cell polarity in the C. elegans embryo (26), and the USP46 homolog Ubp9 functions redundantly with several other DUBs to regulate endocytosis and cell polarity in S. pombe (24) and mitochondrial function in S. cerevisiae (23). Further genetic and biochemical analysis will be required to identify the usp-46-independent mechanisms by which the WDR proteins regulate GLR-1.
Our data are consistent with other in vitro studies showing that both WDR20 and WDR-48/UAF1 are required for maximal activation of mammalian USP12 and USP46 (32). A recent study on ubiquitin chain specificity of DUBs showed that WDR48-USP46 complexes have a preference for cleaving lysine 6-and lysine 11-linked ubiquitin chains (31). It will be interesting in the future to test whether different combinations of activator proteins may also alter the ubiquitin chain specificity of USP46. It is possible that WDR20 may not only fully activate the catalytic activity of the DUB but may also determine its ubiquitin chain specificity. Regarding subcellular localization, we showed previously that USP-46 partially colocalizes with the endosomal marker RAB5 in the cell body and VNC (21). In yeast, the WDR proteins Bun107 and Bun62 can regulate the subcellular localization of Ubp9p (24), and it is possible that WDR-20 and WDR-48 regulate the subcellular localization of USP-46 in neurons. However, we found that mCherry-tagged WDR-20 and WDR-48 (under control of the glr-1 promoter) were predominantly diffuse throughout the cell body and VNC (data not shown). Because the WDR proteins can bind and activate USP-46 to regulate GLR-1 levels in the VNC, our localization data suggest that the WDR proteins may either transiently localize and activate USP-46, or, perhaps, even low levels of WDR proteins at the synapse are sufficient to activate the DUB. Alternatively, the mCherry-tagged WDR proteins may not accurately reflect the subcellular distribution of the endogenous proteins. Although other physiological targets for WDR20 have not yet been identified, activation of USP46 or USP12 by WDR48 toward specific substrates has been described in Xenopus laevis, S. cerevisiae, and mammalian cell culture (22,23,27). In light of the conservation of WDR-20 between species, it is likely that future studies in diverse systems and cell types will uncover additional targets for WDR20 in conjunction with WDR48.
Concluding Remarks-Regulation of AMPA receptor levels at the synapse is an important mechanism for controlling synaptic strength, and much research has focused on understanding the proteins involved in regulating endo-and exocytosis of GluRs at the synapse. After endocytosis, AMPA receptors can be targeted to the lysosome for degradation or recycled back to the synaptic cell surface in an activity-dependent manner (53,54). However, the mechanisms that control this critical sorting decision are understood poorly. We showed previously that USP-46 deubiquitinates GLR-1 and prevents its degradation in the lysosome (21). Here we identify WDR-20 and WDR-48 as regulators of USP-46 activity and show that expression of both WDR proteins in neurons increases the abundance of GLR-1 in vivo. Our data suggest that controlling the expression levels of WDR-20 and WDR-48 may provide a mechanism to regulate USP-46 DUB activity and, consequently GLR-1 stability and function at synapses. Future studies will be focused on identifying upstream signals, such as changes in synaptic activity, that might regulate WDR-20 or WDR-48 expression and/or localization. Furthermore, WDR protein regulation of USP46 and GluRs may be conserved in the mammalian nervous system because the mammalian homologs of WDR-20, WDR-48, and USP-46 have highly overlapping patterns of expression in the mouse brain, including regions such as the hippocampus that are involved in learning and memory (Allen Brain Atlas). Because 36% of mammalian DUBs can interact with WD40repeat family proteins (33), understanding how WDR-20 and WDR-48 regulate USP-46 may be informative for understand-ing the regulatory mechanisms that control a large number of other DUBs.