The WD40-Repeat Protein-Containing Deubiquitinase Complex: Catalysis, Regulation, and Potential for Therapeutic Intervention

Ubiquitination has emerged as an essential signaling mechanism in eukaryotes. Deubiquitinases (DUBs) counteract the activities of the ubiquitination machinery and provide another level of control in cellular ubiquitination. Not surprisingly, DUBs are subjected to stringent regulations. Besides regulation by the noncatalytic domains present in the DUB sequences, DUB-interacting proteins are increasingly realized as essential regulators for DUB activity and function. This review focuses on DUBs that are associated with WD40-repeat proteins. Many human ubiquitin-specific proteases (USPs) were found to interact with WD40-repeat proteins, but little is known as to how this interaction regulates the activity and function of USPs. In recent years, significant progress has been made in understanding a prototypical WD40-repeat protein-containing DUB complex that comprises USP1 and USP1-associated factor 1 (UAF1). It has been shown that UAF1 activates USP1 through a potential active-site modulation, and the complex formation between USP1 and UAF1 is regulated by serine phosphorylation. Recently, human USPs have been recognized as a promising target class for inhibitor discovery. Small molecule inhibitors targeting several human USPs have been reported. USP1 is involved in two major DNA damage response pathways, DNA translesion synthesis and the Fanconi anemia pathway. Inhibiting the USP1/UAF1 deubiquitinase complex represents a new strategy to potentiate cancer cells to DNA-crosslinking agents and to overcome resistance that has plagued clinical cancer chemotherapy. The progress in inhibitor discovery against USPs and the WD40-repeat protein-containing USP complex will be discussed.     

High incidence of ubiquitin-like domains in human ubiquitin-specific proteases

Ubiquitin-specific proteases (USPs) emerge as key regulators of numerous cellular processes and account for the bulk of human deubiquitinating enzymes (DUBs). Their modular structure, mostly annotated by sequence homology, is believed to determine substrate recognition and subcellular localization. Currently, a large proportion of known human USP sequences are not annotated either structurally or functionally, including regions both within and flanking their catalytic cores. To extend the current understanding of human USPs, we applied consensus fold recognition to the unannotated content of the human USP family. The most interesting discovery was the marked presence of reliably predicted ubiquitin-like (UBL) domains in this family of enzymes. The UBL domain thus appears to be the most frequently occurring domain in the human USP family, after the characteristic catalytic domain. The presence of multiple UBL domains per USP protein, as well as of UBL domains embedded in the USP catalytic core, add to the structural complexity currently recognized for many DUBs. Possible functional roles of the newly uncovered UBL domains of human USPs, including proteasome binding, and substrate and protein target specificities, are discussed.     

Regulation of Neuronal Morphogenesis and Positioning by Ubiquitin-Specific Proteases in the Cerebellum

Ubiquitin signaling mechanisms play fundamental roles in the cell-intrinsic control of neuronal morphogenesis and connectivity in the brain. However, whereas specific ubiquitin ligases have been implicated in key steps of neural circuit assembly, the roles of ubiquitin-specific proteases (USPs) in the establishment of neuronal connectivity have remained unexplored. Here, we report a comprehensive analysis of USP family members in granule neuron morphogenesis and positioning in the rodent cerebellum. We identify a set of 32 USPs that are expressed in granule neurons. We also characterize the subcellular localization of the 32 USPs in granule neurons using a library of expression plasmids encoding GFP-USPs. In RNAi screens of the 32 neuronally expressed USPs, we uncover novel functions for USP1, USP4, and USP20 in the morphogenesis of granule neuron dendrites and axons and we identify a requirement for USP30 and USP33 in granule neuron migration in the rodent cerebellar cortex in vivo. These studies reveal that specific USPs with distinct spatial localizations harbor key functions in the control of neuronal morphogenesis and positioning in the mammalian cerebellum, with important implications for our understanding of the cell-intrinsic mechanisms that govern neural circuit assembly in the brain.     

A Panel of Engineered Ubiquitin Variants Targeting the Family of Domains Found in Ubiquitin Specific Proteases (DUSPs)

Domains found in ubiquitin specific proteases (DUSPs) occur in seven members of the ubiquitin specific protease (USP) family. DUSPs are defined by a distinct structural fold but their functions remain largely unknown, although studies with USP4 suggest that its DUSP enhances deubiquitination activity. We used phage-displayed libraries of ubiquitin variants (UbVs) to derive protein-based tools to target DUSP family members with high affinity and specificity. We designed a UbV library based on insights from the structure of a previously identified UbV bound to the DUSP of USP15. The new library yielded 33 unique UbVs that bound to DUSPs from five different USPs (USP4, USP11, USP15, USP20 and USP33). For each USP, we were able to identify at least one DUSP that bound with high affinity and absolute specificity relative to the other DUSPs. We showed that UbVs targeting the DUSPs of USP15, USP11 and USP20 inhibited the catalytic activity of the enzyme, despite the fact that the DUSP is located outside of the catalytic domain. These findings provide an alternative means of inhibiting USP activity by targeting DUSPs, and this mechanism could be potentially extended other DUSP-containing USPs.     

Identification, Functional Characterization, and Chromosomal Localization of USP15, a Novel Human Ubiquitin-Specific Protease Related to the UNP Oncoprotein, and a Systematic Nomenclature for Human Ubiquitin-Specific Proteases

We have identified a novel gene, USP15, encoding a human ubiquitin-specific protease (USP). The USP15 protein consists of 952 amino acids with a predicted molecular mass of 109.2 kDa and contains the highly conserved Cys and His boxes present in all members of the UBP family of deubiquitinating enzymes. USP15 shares 60.5% sequence identity and 76% sequence similarity with the human homolog (UNP/Unph/USP4) of the mouse Unp proto-oncogene. Recombinant USP15 demonstrated ubiquitin-specific protease activity against engineered linear fusions of ubiquitin to beta-galactosidase and glutathione S-transferase. USP15 can also cleave the ubiquitin-proline bond, a property previously unique to Unp/UNP. Chromosomal mapping by fluorescence in situ hybridization and radiation hybrid analyses localized the USP15 gene to chromosome band 12q14, a different location than that of UNP (3p21.3). Analysis of expressed sequence tag databases reveals evidence of alternate polyadenylation sites in the USP15 gene and also indicates that the gene may possess an exon/intron structure similar to that of the Unp gene, suggesting they have descended from a common ancestor. A systematic nomenclature for the human USPs is proposed.     

Development of a highly reliable assay for ubiquitin-specific protease 2 inhibitors

The dynamic modification of proteins with ubiquitin plays crucial roles in major celluar functions, and is associated with a number of pathological conditions. Ubiquitin-specific proteases (USPs) cleave ubiquitin from substrate proteins, and rescue them from proteasomal degradation. Among them, USP2 is overexpressed and plays important roles in various cancers including prostate cancer. Thus, it represents an attractive target for drug discovery. In order to develop potent and selective USP2 inhibitors, a highly reliable assay is needed for in-depth structure-activity relationship study. We report the cloning, expression, and purification of USP2 and UBA52, and the development of a highly reliable assay based on readily available SDS-PAGE-Coomassie systeme using UBA52 as the substrate protein. A number of effective USP2 inhibitors were also identified using this assay.     

Enabling high-throughput ligation-independent cloning and protein expression for the family of ubiquitin specific proteases

High-throughput methods to produce a large number of soluble recombinant protein variants are particularly important in the process of determining the three-dimensional structure of proteins and their complexes. Here, we describe a collection of protein expression vectors for ligation-independent cloning, which allow co-expression strategies by implementing different affinity tags and antibiotic resistances. Since the same PCR product can be inserted in all but one of the vectors, this allows efficiency in versatility while screening for optimal expression strategies. We first demonstrate the use of these vectors for protein expression in Escherichia coli, on a set of proteins belonging to the ubiquitin specific protease (USP) Family. We have selected 35 USPs, created 145 different expression constructs into the pETNKI-His-3C-LIC-kan vector, and obtained 38 soluble recombinant proteins for 21 different USPs. Finally, we exemplify the use of our vectors for bacterial co-expression and for expression in insect cells, with USP4 and USP7 respectively. We conclude that our ligation-independent cloning strategy allows for high-throughput screening for the expression of soluble proteins in a variety of vectors in E. coli and in insect cells. In addition, the same vectors can be used for co-expression studies, at least for simple binary complexes. Application in the family of ubiquitin specific proteases led to a number of soluble USPs that are used for functional and crystallization studies.     

USP4 inhibits p53 through deubiquitinating and stabilizing ARF-BP1

Tumour suppressor p53 levels in the cell are tightly regulated by controlled degradation through ubiquitin ligases including Mdm2, COP1, Pirh2, and ARF-BP1. The ubiquitination process is reversible via deubiquitinating enzymes, such as ubiquitin-specific peptidases (USPs). In this study, we identified ubiquitin-specific peptidase 4 (USP4) as an important regulator of p53. USP4 interacts directly with and deubiquitinates ARF-BP1, leading to the stabilization of ARF-BP1 and subsequent reduction of p53 levels. Usp4 knockout mice are viable and developmentally normal, but showed enhanced apoptosis in thymus and spleen in response to ionizing radiation. Compared with wild-type mouse embryonic fibroblasts (MEFs), Usp4-/- MEFs exhibited retarded growth, premature cellular senescence, resistance to oncogenic transformation, and hyperactive DNA damage checkpoints, consistent with upregulated levels and activity of p53 in the absence of USP4. Finally, we showed that USP4 is overexpressed in several types of human cancer, suggesting that USP4 is a potential oncogene.     

Polyubiquitin binding and cross-reactivity in the USP domain deubiquitinase USP21

Modification of proteins by ubiquitin (Ub) and Ub-like (Ubl) modifiers regulates a variety of cellular functions. The ability of Ub to form chains of eight structurally and functionally distinct types adds further complexity to the system. Ub-specific proteases (USPs) hydrolyse polyUb chains, and some have been suggested to be cross-reactive with Ubl modifiers, such as neural precursor cell expressed, developmentally downregulated 8 (NEDD8) and interferon-stimulated gene 15 (ISG15). Here, we report that USP21 cleaves Ub polymers, and with reduced activity also targets ISG15, but is inactive against NEDD8. A crystal structure of USP21 in complex with linear diUb aldehyde shows how USP21 interacts with polyUb through a previously unidentified second Ub- and ISG15-binding surface on the USP domain core. We also rationalize the inability of USP21 to target NEDD8 and identify differences that allow USPs to distinguish between structurally related modifications.     

The role of UBL domains in ubiquitin-specific proteases

Ubiquitin conjugation and deconjugation provides a powerful signalling system to change the fate of its target enzymes. Ubiquitination levels are organized through a balance between ubiquitinating E1, E2 and E3 enzymes and deubiquitination by DUBs (deubiquitinating enzymes). These enzymes are tightly regulated to control their activity. In the present article, we discuss the different ways in which DUBs of the USP (ubiquitin-specific protease) family are regulated by internal domains with a UBL (ubiquitin-like) fold. The UBL domain in USP14 is important for its localization at the proteasome, which enhances catalysis. In contrast, a UBL domain in USP4 binds to the catalytic domain and competes with ubiquitin binding. In this process, the UBL domain mimics ubiquitin and partially inhibits catalysis. In USP7, there are five consecutive UBL domains, of which the last two affect catalytic activity. Surprisingly, they do not act like ubiquitin and activate catalysis rather than inhibiting it. These C-terminal UBL domains promote a conformational change that allows ubiquitin binding and organizes the catalytic centre. Thus it seems that UBL domains have different functions in different USPs. Other proteins can modulate the roles of UBL domains in USP4 and USP7. On one hand, the inhibition of USP4 can be relieved when the UBL is sequestered by another USP. On the other, the activation of USP7 is increased, when the UBL-activated state is stabilized by allosteric binding of GMP synthetase. Altogether, UBL domains appear to be able to regulate catalytic activity in USPs, but they can use widely different mechanisms of action, in which they may, as in USP4, or may not, as in USP7, use the direct resemblance to ubiquitin.     

Structural basis of ubiquitin recognition by the deubiquitinating protease USP2

Deubiquitinating proteases reverse protein ubiquitination and rescue their target proteins from destruction by the proteasome. USP2, a cysteine protease and a member of the ubiquitin specific protease family, is overexpressed in prostate cancer and stabilizes fatty acid synthase, which has been associated with the malignancy of some aggressive prostate cancers. Here, we report the structure of the human USP2 catalytic domain in complex with ubiquitin. Ubiquitin uses two major sites for the interaction with the protease. Both sites are required simultaneously, as shown by USP2 inhibition assays with peptides and ubiquitin mutants. In addition, a layer of ordered water molecules mediates key interactions between ubiquitin and USP2. As several of those molecules are found at identical positions in the previously solved USP7/ubiquitin-aldehyde complex structure, we suggest a general mechanism of water-mediated ubiquitin recognition by USPs.     

The osteoprotective role of USP26 in coordinating bone formation and resorption

Bone homeostasis is maintained through a balance of bone formation by osteoblasts and bone resorption by osteoclasts. Ubiquitin-specific proteases (USPs) are involved in regulating bone metabolism by preserving bone formation or antagonizing bone resorption. However, the specific USPs that maintain bone homeostasis by orchestrating bone formation and bone resorption simultaneously are poorly understood. Here, we identified USP26 as a previously unknown regulator of bone homeostasis that coordinates bone formation and resorption. Mechanistically, USP26 stabilizes β-catenin to promote the osteogenic activity of mesenchymal cells (MSCs) and impairs the osteoclastic differentiation of bone myelomonocytes (BMMs) by stabilizing inhibitors of NF-κBα (IκBα). Gain-of-function experiments revealed that Usp26 supplementation significantly increased bone regeneration in bone defects in aged mice and decreased bone loss resulting from ovariectomy. Taken together, these data show the osteoprotective effect of USP26 via the coordination of bone formation and resorption, suggesting that USP26 represents a potential therapeutic target for osteoporosis.Subject terms: Deubiquitylating enzymes, Deubiquitylating enzymes, Endocrine system and metabolic diseases, Immunopathogenesis     

Vialinin A is a ubiquitin-specific peptidase inhibitor

Vialinin A, a small compound isolated from the Chinese mushroom Thelephora vialis, exhibits more effective anti-inflammatory activity than the widely used immunosuppressive drug tacrolimus (FK506). Here, we show that ubiquitin-specific peptidase 5/isopeptidase T (USP5/IsoT) is a target molecule of vialinin A, identified by using a beads-probe method. Vialinin A inhibited the peptidase activity of USP5/IsoT and also inhibited the enzymatic activities of USP4 among deubiquitinating enzymes tested. Although USPs are a member of thiol protease family, vialinin A exhibited no inhibitions for other thiol proteases, such as calpain and cathepsin.     

A noncanonical cysteine protease USP1 is activated through active site modulation by USP1-associated factor 1

Ubiquitin-specific proteases (USPs) constitute the largest family of the human deubiquitinating enzymes. USP1 belongs to the cysteine protease family and contains a catalytic triad comprised of C90, H593, and D751. Notably, the catalytic activity of USP1 is stimulated through the formation of a tight complex with a WD40 repeat protein UAF1 (USP1-associated factor 1). Our kinetic analyses revealed a general base catalysis in USP1/UAF1, in contrast to an ion-pair mechanism as demonstrated for papain and cathepsin. The pK(a) value of the catalytic cysteine was determined to be 8.67 ± 0.07 in a pH-dependent inactivation study of USP1/UAF1 by iodoacetamide. A normal solvent kinetic isotope effect of 2.8 for k(cat) and 3.0 for k(cat)/K(m) was observed in the USP1/UAF1-catalyzed hydrolysis of ubiquitin-AMC substrate. Moreover, proton inventory analysis supported the transfer of a single solvent-derived proton in the transition state. Our study also revealed the molecular basis for the activation of USP1 by UAF1. Although the pK(a) of the catalytic cysteine in USP1 and USP1/UAF1 was almost identical, the pK(a) of the catalytic histidine in USP1/UAF1 was 0.43 pH unit lower than that in USP1, which facilitates general base catalysis at a neutral pH and contributes to the elevated catalytic efficiency. We ruled out that the higher catalytic efficiency is due to a tighter binding of ubiquitin. Our results support a regulatory mechanism in which UAF1 activates USP1 by modulating its active site conformation. This finding has a general implication for the regulation of USPs that form complex with partner proteins.     

When the chains do not break: the role of USP10 in physiology and pathology

Deubiquitination is now understood to be as important as its partner ubiquitination for the maintenance of protein half-life, activity, and localization under both normal and pathological conditions. The enzymes that remove ubiquitin from target proteins are called deubiquitinases (DUBs) and they regulate a plethora of cellular processes. DUBs are essential enzymes that maintain intracellular protein homeostasis by recycling ubiquitin. Ubiquitination is a post-translational modification where ubiquitin molecules are added to proteins thus influencing activation, localization, and complex formation. Ubiquitin also acts as a tag for protein degradation, especially by proteasomal or lysosomal degradation systems. With ~100 members, DUBs are a large enzyme family; the ubiquitin-specific peptidases (USPs) being the largest group. USP10, an important member of this family, has enormous significance in diverse cellular processes and many human diseases. In this review, we discuss recent studies that define the roles of USP10 in maintaining cellular function, its involvement in human pathologies, and the molecular mechanisms underlying its association with cancer and neurodegenerative diseases. We also discuss efforts to modulate USPs as therapy in these diseases.Subject terms: Cell biology, Cell signalling     

Zinc-finger UBPs: regulators of deubiquitylation

Deubiquitylating enzymes have key regulatory roles in multiple cellular processes by mediating ubiquitin removal and processing. The ubiquitin-specific processing proteases (USPs) represent the largest subclass of deubiquitylases. Recently, several USPs that recognize the monoubiquitylated histones H2A and/or H2B have been identified. Among these enzymes, three USPs contain a zinc-finger ubiquitin-specific protease (ZnF-UBP) domain, indicating that this domain plays a crucial part in regulating their activity. To address the putative function of this domain, we systematically analysed and aligned yeast and human ZnF-UBP-containing proteins. By complementing our analysis with structural and functional data, we present a classification of the different ZnF-UBP-containing proteins and a model for their regulation.     

Ubiquitin-specific cysteine protease 2a (USP2a) regulates the stability of Aurora-A

The ubiquitin/proteasome pathway plays critical roles in virtually all aspects of cell biology. Enzymes of the ubiquitin pathway add (ligases) or remove (deubiquitinases) ubiquitin tags to or from their target proteins in a selective fashion. USP2a is a member of a subfamily of deubiquitinases, called ubiquitin-specific cysteine proteases (USPs). Although USP2a has been reported to be a bona fide oncogene that regulates the stability of MDM2, MDMX, and FAS, it is likely that there are other unidentified substrates for USP2a. In this study, we show that USP2a mediates mitotic progression by regulating the stability of Aurora-A. Through cell-based screening of a USP siRNA library, we discovered that knockdown of USP2a reduced the protein levels of Aurora-A. USP2a interacts with Aurora-A directly in vitro and in vivo. In addition, Aurora-A is a substrate for USP2a in vitro and in vivo. Our study provides a novel mechanism for the role of USP2a in mediating the stability of Aurora-A.