Integration of cellular ubiquitin and membrane traffic systems: focus on deubiquitylases

The cell is comprised of integrated multilevel protein networks or systems. The ubiquitin, protein homeostasis and membrane trafficking systems are highly integrated. Here, we look at the influence of reversible ubiquitylation on membrane trafficking and organelle dynamics. We review the regulation of endocytic sorting, selective autophagy and the secretory pathway by ubiquitin signals, with a particular focus on detailing the contribution of deubiquitylating enzymes.

The cell is comprised of integrated multilevel protein networks or systems. The ubiquitin, protein homeostasis and membrane trafficking systems are highly integrated. Here, we look at the influence of reversible ubiquitylation on membrane trafficking and organelle dynamics. We review the regulation of endocytic sorting, selective autophagy and the secretory pathway by ubiquitin signals, with a particular focus on detailing the contribution of deubiquitylating enzymes.

Introduction
The complement of expressed proteins provides the building blocks for an integrated set of systems that combine to orchestrate overall cell behaviour. The ubiquitin system constitutes > 1.5% of cellular protein.
It overlaps with, not only the proteostasis system but also with the cell signalling system, by generating a complex signalling code on 1000's of substrate proteins [1][2][3]. The spectrum of ubiquitylated proteins in a cell is determined by the net activity of ubiquitin conjugation cascades (involving E1s, E2s and E3s), which principally attach ubiquitin molecules to lysine residues, balanced by the opposing action of the deubiquitylating enzymes (DUBs), which hydrolyse this isopeptide bond. The seven internal lysines of ubiquitin allow for the formation of topologically distinct ubiquitin isopeptide chain types. These, together with a minor fraction of linear ubiquitin chains and a large fraction of mono-ubiquitylation sites may be recognised by multiple types of reader proteins that contain ubiquitin-binding domains that effectively translate the ubiquitin code [4,5]. Some E2s, DUBs and readers display exquisite selectivity for particular ubiquitin chain linkage types, while others show little discrimination. The length of an ubiquitin chain is also an important parameter that can determine avidity for lower affinity binders. The cell membrane traffic system controls protein turnover through endocytosis and autophagy, but more fundamentally maintains compartmental organisation in the face of large-scale membrane flux. Here, we will discuss the integration of the ubiquitin and membrane trafficking systems. Subcellular compartmentalisation results from the differential trafficking patterns of membrane components. From the point of view of ubiquitin-conjugating and deubiquitylating enzymes, it provides a means to confer specificity by restricting the palette of available substrates. Thus, understanding of the ubiquitin system may require localisation data for all components. To date, systematic subcellular localisation has been reported for the majority of DUBs and for the fraction of RING E3 ligases possessing a trans-membrane domain [6][7][8][9]. In this review, we will explore the impact of reversible ubiquitylation on membrane trafficking and organelle dynamics.

Ubiquitin as a sorting signal
The distribution of membrane proteins is largely governed through a balance of active sorting and retention signals, which governs their inclusion into vesicular or tubular transport intermediates [10]. For the most part their flow is constitutive, determined by intrinsic sequence-mediated signals (e.g. KDEL for ER retention, NPXY for endocytosis of LDL receptor). Cells also reconfigure the subcellular distribution of proteins in response to prevailing conditions. In many cases, ligand occupancy of receptors is coupled to their redistribution, which is accomplished through the generation of sorting signals by post-translational modification. Although ubiquitylation can serve as a supplementary plasma membrane internalisation signal, for numerous receptors its most critical function resides at the sorting endosome. Here, it promotes receptor incorporation into intralumenal vesicles (ILVs) of the multivesicular body (MVB) which commits cargo for lysosomal degradation [11].
Early work in the 1990s identified ubiquitylation of a number of plasma membrane proteins but its significance for membrane trafficking only became clear from pioneering studies in yeast [12][13][14]. Shortly thereafter, studies of Caenorhabditis elegans vulval development led to the identification of SLI-1, a homologue of the ubiquitin E3-ligase c-Cbl, as a negative regulator of signalling downstream of the LET-23 receptor tyrosine kinase (RTK) [15]. Extension of these results to human cells quickly followed, with the observation that epidermal growth factor receptor (EGFR) recruits c-Cbl to endosomes leading to EGFR ubiquitylation and receptor down-regulation through lysosomal sorting [16]. Mass spectrometry studies suggest that epidermal growth factor receptor (EGFR) is ubiquitylated at multiple sites, with Lys63-linked chains highly represented and necessary for sorting [17,18]. A prominent role for Lys63-linked ubiquitin chains in the endosomal pathway is also evident in yeast [19]. c-Cblmediated ubiquitylation was established as a widely used sorting signal that promotes lysosomal sorting of multiple activated RTKs (e.

Ubiquitin and receptor internalisation
Ubiquitylation is one of several potential internalisation signals following receptor activation that allows coupling to adaptor proteins for both clathrin-dependent and independent internalisation pathways [25]. In the case of EGFR, a ubiquitindependent nonclathrin pathway can be favoured under conditions of full receptor activation [26]. A recent siRNA screen identified up to 15 DUBs influencing EGFR receptor turnover. Prominent positive regulators include USP6 and USP9X [27] (Fig. 1). Of these, USP6 showed the most pronounced plasma membrane localisation in a systematic survey of GFP-DUB localisation [9]. In a separate whole-genome siRNA screen, USP6 was found to activate Wnt signalling by deubiquitylating Frizzled receptors and increasing their plasma membrane expression [28].
A number of accessory proteins associated with receptor internalisation have ubiquitin-binding domains, but are themselves mono-ubiquitylated in an EGF-dependent manner (EPS15, EPS15R and Epsin) [29]. USP9X depletion retards EGFR internalisation at low doses of EGF, when only the clathrin-dependent pathway is operative, and little if any receptor is ubiquitylated. Savio and colleagues suggest that the relevant USP9X substrate is in fact the monoubiquitylated protein EPS15, but the mechanistic details of how this might influence internalisation are currently unclear [27]. Studies in yeast suggest that deubiquitylation of the EPS15 homologue, Ede1 by Ubp2 and Ubp7, influences the rate of clathrin-coated vesicle formation [30]. In addition to its role in governing receptor internalisation, USP9X also plays a positive role in directing lysosomal trafficking from the sorting endosome [27]. However, it does not directly influence the ubiquitylation status of the receptor itself, once again suggesting an indirect mechanism. Candidate substrates include the E3 ligase ITCH that associates with endosomes [31], or in fact an endosomal fraction of EPS15, which is ubiquitylated by the SPOPL/Cullin-3 ubiquitin ligase [32]. One further siRNA screen across the DUB family identified Cezanne as a negative regulator of EGFR down-regulation [33].

Regulation of endosomal sorting by DUBs
Endosomal sorting is accomplished through capture of ubiquitylated cargo at the endosome membrane by components of the Endosomal Sorting Complex Required for Transport (ESCRT) machinery [34,35]. This machinery promotes lumenal budding of cargo containing ILVs from the limiting membrane [36] and terminates growth factor receptor signalling by sequestration from the cytosol. It is classically divided into four subcomplexes, ESCRTs 0, I, II and III. Two DUBs, USP8 (also known as UBPY) and AMSH (STAMBP) are integrated within this complex protein network. The ESCRT-0 complex, comprising HRS (HGS) and STAM, presents the first point of engagement of ubiquitylated receptors through multiple ubiquitin-binding domains [34]. Both DUBs engage with ESCRT-0 by competing for a shared binding site on STAM. They also both contain N-terminal MIT domains, which bind to overlapping spectra of multiple ESCRT-III proteins [37][38][39]. USP8 and AMSH belong to different subfamilies of DUBs; ubiquitin-specific proteases and the metalloprotease JAMM family, respectively. AMSH has exquisite specificity for Lys63linked ubiquitin chains, while USP8 is nonselective [40][41][42][43][44]. In vitro, both are activated through association with STAM, which binds to ubiquitin and decreases the Km [41,45,46]. As ubiquitin is a reversible post-translational modification, a simple model posits that receptor fate at the endosome will be governed by competing ubiquitinconjugating and deubiquitylating activities [47]. The Lys63 linkage-specific DUB, AMSH, conforms to this model [41]. Its depletion leads to enhanced degradation kinetics of acutely activated EGFR and its ligand [27,33,40,48]. Fusion of AMSH to the C-terminus of EGFR blocks receptor degradation [18]. AMSH is also recruited to GAP junction plaque sites and negatively regulates the turnover of the GAP junction protein Connexin 43 [49]. Note that the exquisite selectivity of AMSH for Lys63-linkages will only allow for editing of ubiquitin chains, and that it cannot remove the proximal ubiquitin directly attached to receptors. Mutations in AMSH lead to Microcephaly Capillary Malformation Syndrome (MIC-CAP) [50]. These generally cluster in its MIT domain, but a catalytically inactivating mutation (T313I) has also been characterised [51].
USP2 has also been shown to localise to endosomes and negatively regulate EGFR down-regulation [52]. This enzyme will cleave all ubiquitin linkage types including the proximal ubiquitin. Loss of either protein provided a similar impact on EGFR degradation in the family-wide DUB screen of Savio et al.
[27]. USP2 not only interacts with and stabilises the sterol-regulated E3-ligase IDOL but also rescues LDLR from lysosomal degradation, recalling the example of USP7 described in detail below [53]. This principle of negative regulation of lysosomal sorting has been extended to many ubiquitylated receptors and channels and to other DUB family members. Examples include, the stabilisation of cystic fibrosis transmembrane conductance regulator (CFTR) by USP10 [54] and glutamate receptors in both nematode and mammalian model systems by USP46 [55,56].
The effects of USP8 depletion are profound and widespread, leading to a major disruption of endosomal organisation. In distinction to AMSH, USP8 depletion predominantly impairs RTK degradation, but in addition blocks the retromer-dependent retrieval of the cation-independent mannose 6-phosphate receptor (ciM6PR) to the Golgi apparatus and the plasma membrane recycling of the VEGFR2, Frizzled (Fz) and Smoothened (Smo) [27,45,57-61]. One major consequence of USP8 depletion is the loss of both ESCRT-0 components, HRS and STAM, which are turned over in a proteasome-dependent manner [45,62,63]. Despite binding to the same site on STAM and being expressed at similar levels [5], AMSH cannot compensate for USP8 loss owing to its restricted ubiquitin chain specificity [64]. In addition, USP8 governs the global flux of cellular ubiquitin; its depletion drains the nucleus of ubiquitin by accumulation on endosomes [45,60]. Note that the pleiotropic effects of USP8 make the observed phenotypes very sensitive to the efficiency of depletion in siRNA experiments, as explicitly addressed by Mizuno et al. [65]. Certain scenarios, for example, suboptimal depletion or particular cell types, reveal negative regulation of lysosomal trafficking by USP8 [66,67] (Fig. 1). Overexpression of USP8 also leads to enhanced recycling of the epithelial Na + channel [68]. Activating mutations in USP8 have been linked to Cushing's Disease, which is caused by corticotroph adenomas of the pituitary [69,70]. One suggestion is that this may reflect increased levels of EGFR through enhanced recycling to the plasma membrane.
The effect of USP8 on the retromer pathway may be linked to its control of HRS stability. HRS has been suggested to interact with the core retromer components SNX1 and VPS35 and to influence this pathway [71]. The retromer-dependent pathway requires the participation of F-actin which is recruited by the WASH complex. Activity of WASH is positively regulated by ubiquitylation, mediated by an E3 ligase have reported that USP7 incorporates into this complex through interactions with both components and localises to endosomes ( Fig. 1) in addition to the nucleus where it has previously established roles [73]. USP7 has opposing activities in the context of the retromer pathway; it stabilises the WASH E3-ligase TRIM27 by opposing its auto-ubiquitylation, but it also deubiquitylates WASH itself. It is proposed that USP7 is used to buffer WASH ubiquitylation to maintain optimal endosomal activity and F-actin levels.
Interestingly heterozygous deletion or mutation of USP7 leads to mental impairments that resemble Schaaf-Yang syndrome which is associated with MAGE-L2 mutations [73].
There is an emerging appreciation that distinct organelles can influence each other at sites of direct contact. For example, the ER-localised phosphatase, PTP1B, can dephosphorylate the EGF receptor on endosomes [74]. The closely related DUBs, USP20 and USP33, deubiquitylate activated b-adrenergic receptors as well as the adaptor/signalling protein b-arrestin (in the case of USP33), to favour recycling from endosomes, despite largely being associated with the secretory pathway [75][76][77]. In a further intriguing model, the ER restricted E3-ligase RNF26 is proposed to bind to and ubiquitylate SQSTM1/p62. This then links to ubiquitin-binding adaptors (e.g. EPS15, TOL-LIP) on endosomal vesicles to tether them on the ER and confine them to perinuclear regions (Fig. 2) [78]. It is unclear how this relates to an existing model suggesting that SQSTM1 links cargo to the (-) end directed microtubule motor protein, dynein, that drives inward movement of endosomes [79]. USP15, which has also been identified as a binding partner of RNF26, reverses this capture by deubiquitylating SQSTM1, thereby increasing endosome mobility and global distribution [78].

Ubiquitylation, a key mediator of selective autophagy
Early studies of autophagy emphasised its role as an adaptive response to amino acid deprivation, through the indiscriminate breakdown of cytosolic components. It is now clear that many modes of selective autophagy exist and that in most, but not all cases, accumulation of ubiquitin provides the means to recruit adaptor proteins, which bridge to LC3/GABARAP-coated phagophore membranes [80]. It seems likely that multiple widely distributed ubiquitin-binding sites on the target body will favour coupling to autophagosomes rather than proteasomes using the co-operativity between multiple weak binding interactions of adaptors for both ubiquitin and LC3. In most cases it would seem that a relatively delocalised coating with ubiquitin is more critical than ubiquitylation of specific protein substrates. DUBs may act to limit this distress signal or alternatively act to stabilise core components of the autophagy pathway. For example, USP9X and USP10 have been proposed to regulate the stability of VPS34 complex components [81,82]. Autophagosomes then fuse with lysosomes to generate autolysosomes. Autophagic flux is therefore reliant on appropriate organisation of the endo-lysosomal system. Several studies have highlighted a role for USP8 in various aspects of autophagy, mirroring its complex contribution to endosomal functions (see above). A screen in the Drosophila larval fat body for DUBs influencing autophagy identified USP12 and USP8 as regulators of autophagic flux. In larval fat body cells depleted of USP8, autophagic degradation is blocked, presumably owing to the associated lysosomal defects. In contrast, when the authors turned to HeLa cells they found that depletion of USP8 increased the number of intracellular punctae decorated with the autophagic marker GFP-LC3, with a proportionate increase in the autophagic flux [83]. The accumulation of a-synuclein (SNCA) in neuronal inclusions known as Lewy bodies is a hallmark of Parkinson's Disease (PD). Recent data suggest that USP8 may negatively regulate degradation of a-synuclein by removal of Lys63 ubiquitin chains. At this point it is not clear if this represents a deflection from the autophagic pathway or from capture of soluble protein into MVBs. Most strikingly a rough eye phenotype in Drosophila, induced by a-synuclein expression can be reversed by USP8 depletion [84].

Mitophagy
Defective mitochondria can depolarise and accumulate the damage sensor PTEN-induced putative kinase 1 (PINK1) on their surface [85]. This enables recruitment of the E3-ligase Parkin to the surface of mitochondria. Loss of function mutations in PINK1 and Parkin lead to PD. Full activation of Parkin requires both its own phosphorylation by PINK1 and phosphorylation of ubiquitin on Ser65 (pUb). PINK1generated pUb acts as a Parkin receptor on mitochondria and elicits a conformational change which is stabilised by PINK1-dependent phosphorylation of an internal Ubl domain [86][87][88] (Fig. 3). This leads to clearance of mitochondria via the autophagy pathway utilising specific adaptor proteins, optineurin and NDP52 [85,[89][90][91].
USP30 is the major mitochondrial DUB, facing the cytosol and anchored to the outer membrane through a trans-membrane sequence [92]. It is optimally placed to reverse the Parkin-dependent ubiquitylation of multiple mitochondrial surface proteins and thereby limit mitophagy [93,94]. Mitochondrial damage stimulates Parkin to generate Lys6, Lys11 and Lys63-linked polyubiquitin chains, while USP30 preferentially disassembles the Lys6 and Lys11-linked multimers. However, USP30 is less active towards pUB chains [95][96][97][98]. One model consistent with this observation envisages that by suppressing basal ubiquitylation at mitochondria, USP30 may effectively limit PINK1 ubiquitinsubstrate availability and the generation of pUb 'Parkin-receptor sites', thus primarily influencing the initiation phase of mitophagy [86].
USP30 overexpression impairs Parkin recruitment to depolarised mitochondria and blocks mitophagy [85,99]. Conversely, its depletion enhances mitophagic flux in cultured neurons and epithelial cells [85,99]. In PINK1/Parkin defective, or paraquat-treated fly models of PD, depletion of USP30 can restore motor function and dopamine levels [85]. Reversal of Parkin ubiquitylation at mitochondria primarily reflects the specific localisation of USP30, since targeting other USP family members to mitochondria can fulfil the same function and directing USP30 to peroxisomes protects them from pexophagy [97].
Similar attributes have been suggested for USP15, which is more widely distributed throughout the cytoplasm and associated with diverse cellular functions. Overexpression of USP15 reduced ubiquitin accumulation on mitochondria, while depletion rescued mitophagy defects in PD patient-derived fibroblasts. Concomitant depletion of a proposed Drosophila USP15 orthologue mitigated the effects of Parkin knock-down by siRNA [100]. It is presently unclear, how direct the effect of USP15 may be. Cornelissen et al. first focused on USP15 after identifying it as coimmunoprecipitating with His6-FLAG-tagged Parkin, but other extensive Parkin interactome studies have not found a similar interaction [100][101][102]. A short form of USP35 (s-USP35) has also been localised to mitochondria and is suggested to regulate mitophagy [99]. However, note that this form of the enzyme lacks a catalytic domain. USP8 is proposed to have a nonendosomal function in controlling Parkin autoubiquitylation with predominantly Lys6-linked chains. By virtue of this activity, Parkin recruitment to acutely depolarised mitochondria is accelerated and mitophagy proceeds more efficiently [103].

Endo-lysosomal damage response (ELDR)
Endosomal compartments may get damaged by endogenous factors including ROS and neurotoxic aggregates, in the course of pathogen entry and experimentally, through the application of various transfection reagents [104]. This leads to ubiquitylation and recruitment of the autophagic machinery via specific adaptor molecules such as Atg16L1 [105]. Papadopoulos et al. described a role for the AAA-ATPase p97 in the efficient clearance of damaged endosomal compartments by selective autophagy, following the application of a lysosomotropic agent. Three p97-interacting proteins, UBXD1, PLAA and the DUB YOD1/ OTUD2, were also required for the clearance of damaged lysosomes. A positive requirement for a DUB in autophagic clearance is unexpected. They suggest that a subset of Lys63 ubiquitin chain-decorated endosomes also accumulate Lys48-linked chains which need to be removed by YOD1 to allow envelopment by LC3 containing phagophores [106]. In vitro, YOD1 discriminates between these chain types, although Lys 27, 29 and 33 chains are preferred substrates [44].

Ubiquitin and the secretory pathway
The major function of ubiquitin, heretofore associated with the secretory pathway is mediation of the ER-associated degradation (ERAD) pathway, which has been extensively reviewed elsewhere [107]. A role of nonspecified DUB activity has been proposed in sharpening the discrimination of triaged ERAD substrates, much as previously described for both endosomal-and proteasome-associated DUBs [108]. In preceding studies the ER-localised USP19 was shown to rescue the ERAD substrates cystic fibrosis transmembrane conductance regulator (CFTR)DF508 and T-cell receptor-a (TCRa) from proteasomal degradation [109]. Several DUBs associate with the retro-translocation-driving ATPase p97 (e.g. YOD1, ATXN3, USP13), some of which can positively regulate the ERAD pathway [7,[110][111][112].
Some DUBs show clear association with organelles of the secretory pathway, yet distinct roles in membrane trafficking have not been reported. One exception is the isoform of USP19, which contains a transmembrane anchor that exclusively targets it to the ER [9,109]. Recent work has associated it with an unconventional secretion pathway that becomes important under conditions of proteasome depletion or disfunction (Misfolding Associated Protein Secretion, MAPS). The catalytic domain of USP19 is proposed to capture misfolded protein (including a-synuclein) at the surface of the ER and facilitate their transfer into vesicular structures that contain late endosomal markers (e.g. rab9), but are distinct from exosome carriers. This property of USP19 requires both ER localisation and catalytic activity. The resultant carrier vesicles then secrete proteins after fusion with the plasma membrane [113]. A further "chaperone like" activity of USP19 has also recently been proposed. Folding of the Wnt signalling coreceptor LRP6 is promoted by ubiquitylation of a specific cytosol facing lysine which promotes its retention in the ER. Exit from the ER of folded protein is then enabled by USP19-mediated deubiquitylation [114] (Fig. 2).
Other functions of ubiquitin associated with vesicle trafficking and compartmental identity are beginning to emerge. Properly folded secretory proteins are packaged into COPII vesicles for transport from the ER to the cis-Golgi. Early studies in yeast suggested that a complex of Bre5 and the DUB Ubp3 regulate this process, possibly by sustaining the levels of the COPII coat component Sec23p [115]. Some secreted proteins such as collagen and fibronectin are too large to be included in a standard size vesicle, presenting a longstanding conundrum to the field [116]. Jin et al. have shown that mono-ubiquitylation of the COPII component Sec31p permits expansion of vesicle size and increased secretion of collagen. The relevant E3 ligase has been identified as a cullin-RING ubiquitin ligase (CRL) complex incorporating the BTB protein KLHL12 as a recognition module in conjuction with two penta-EF-hand calcium-binding proteins PEF1 and ALG2 which couple a transient rise in Ca 2+ to a more sustained ubiquitin signal on Sec31p [117,118]. Secretion of another large protein fibronectin is controlled by the cytosolic CRL incorporating von-Hippel Lindau (VHL) adaptor subunit [119].
The related DUBs, USP20 and USP33, are also present on the ER. They have both been linked to the maintenance of activity of the ER associated type 2 iodothyronine deiodinase that activates thyroxine [120]. Both also interact with VHL but only USP20 appears to influence its stability [121]. USP33 also resides on COPII vesicles and on the Golgi Apparatus. Its distribution can be shifted according to which splice variant is expressed, such that variant 3 selectively accumulates on the Golgi apparatus [77].
During mitosis, the Golgi complex fragments in order to achieve an equal distribution of organelle between progeny cells. Reassembly requires SNARE proteins, in common with the majority of intracellular membrane fusion events [10]. A fraction of the Golgi t-SNARE, syntaxin 5 is monoubiquitylated by the E3ligase HACE1 in early mitosis leading to a block in the interaction with its cognate v-SNARE Bet1 [122,123]. It concomitantly increases interaction with the p97/p47 complex, which then promotes postmitotic Golgi assembly following ubiquitin removal by its interacting DUB VCIP135 [123][124][125][126]. Temporal control is strengthened through phosphorylation-dependent inactivation of VCIP135 early in mitosis and reversal by phosphatase activity late in mitosis [126,127].
Anterograde trafficking from the Trans-Golgi Network routes cargo to the plasma membrane or to the lysosome. Studies with mutant ubiquitin molecules suggest distinct roles for Lys33-and Lys63-linked chains in post-Golgi trafficking [128]. The CUL3-KLHL20 E3-ligase promotes Lys33-linked ubiquitin chain formation on Coronin 7 which is then recruited by a Golgi-localised fraction of EPS15. This is proposed to promote F-actin assembly which in turn favours the budding of transport carriers destined for the plasma membrane (e.g. VSV G protein) or the endo-lysosomal pathway (e.g. ciM6PR) [128].

Concluding remarks
Deubiquitylating enzymes are most simply conceived as negative regulators of ubiquitin-dependent processes. This holds true for their control of several ubiquitin-mediated protein-sorting events, where they may directly deubiquitylate cargo proteins. Similarly, we also expect more DUBs to be discovered that dampen signals for selective autophagy events, in addition to USP30. However, the preceding text also highlights positive roles for DUBs in more complex pathways, which might require cycles of ubiquitylation and deubiquitylation. Several generic reasons for this may be envisaged: (a) ubiquitin chain editing to switch or harmonise a linkage type, (b) release from a ubiquitin receptor, (c) control of stability of cognate E3-ligases by opposing their autoubiquitylation, (d) control of stability of other accessory factors. The current survey illustrates that a significant fraction of the~100 DUB components of the ubiquitin system impact upon the cellular membrane trafficking system. However, several specific membrane trafficking events have been shown to be ubiquitin-dependent, without relevant DUB activities so far being characterised. Some DUBs show distinct subcellular distributions, without a clear understanding of their localised function. DUBs help shape the cellular architecture, but then use this foundation to influence further systems, such as cell signalling. For example, since USP30 can influence mitochondrial dynamics, we might further expect it to influence ubiquitin-dependent signalling systems associated with mitochondria. To progress our understanding of the ubiquitin system we will need to have an idea of its demographics (the abundance of each functional component [5]) as well as its geography (distribution and landscape).