A novel active site-directed probe specific for deubiquitylating enzymes reveals proteasome association of USP14

A C-terminally modified ubiquitin (Ub) derivative, ubiquitin vinyl sulfone (UbVS), was synthesized as an active site-directed probe that irreversibly modifies a subset of Ub C-terminal hydrolases (UCHs) and Ub-specific processing proteases (UBPs). Specificity of UbVS for deubiquitylating enzymes (DUBs) is demonstrated not only by inhibition of [(125)I]UbVS labeling with N-ethylmaleimide and Ub aldehyde, but also by genetic analysis. [(125)I]UbVS modifies six of the 17 known and putative yeast deubiquitylating enzymes (Yuh1p, Ubp1p, Ubp2p, Ubp6p, Ubp12p and Ubp15p), as revealed by analysis of corresponding mutant strains. In mammalian cells, greater numbers of polypeptides are labeled, most of which are likely to be DUBs. Using [(125)I]UbVS as a probe, we report the association of an additional DUB with the mammalian 26S proteasome. In addition to the 37 kDa enzyme reported to be part of the 19S cap, we identified USP14, a mammalian homolog of yeast Ubp6p, as being bound to the proteasome. Remarkably, labeling of 26S-associated USP14 with [(125)I]UbVS is increased when proteasome function is impaired, suggesting functional coupling between the activities of USP14 and the proteasome.     

Ubiquitinated Proteins Activate the Proteasomal ATPases by Binding to Usp14 or Uch37 Homologs

Degradation of ubiquitinated proteins by 26 S proteasomes requires ATP hydrolysis, but it is unclear how the proteasomal ATPases are regulated and how proteolysis, substrate deubiquitination, degradation, and ATP hydrolysis are coordinated. Polyubiquitinated proteins were shown to stimulate ATP hydrolysis by purified proteasomes, but only if the proteins contain a loosely folded domain. If they were not ubiquitinated, such proteins did not increase ATPase activity. However, they did so upon addition of ubiquitin aldehyde, which mimics the ubiquitin chain and binds to 26 S-associated deubiquitinating enzymes (DUBs): in yeast to Ubp6, which is essential for the ATPase activation, and in mammalian 26 S to the Ubp6 homolog, Usp14, and Uch37. Occupancy of either DUB by a ubiquitin conjugate leads to ATPase stimulation, thereby coupling deubiquitination and ATP hydrolysis. Thus, ubiquitinated loosely folded proteins, after becoming bound to the 26 S, interact with Ubp6/Usp14 or Uch37 to activate ATP hydrolysis and enhance their own destruction.     

Biochemical characterization of a multidomain deubiquitinating enzyme Ubp15 and the regulatory role of its terminal domains

Deubiquitinating enzymes (DUBs) have emerged as essential players in a myriad of cellular processes, yet the regulation of DUB function remains largely unknown. While some DUBs rely on the formation of complex for regulation of enzymatic activity, many DUBs utilize interdomain interactions to regulate catalysis. Here we report the biochemical characterization of a multidomain deubiquitinating enzyme, Ubp15, from Saccharomyces cerevisiae. Steady-state kinetic investigation showed that Ubp15 is a highly active DUB. We identified active-site residues that are required for catalysis. We have also identified key residues on Ubp15 required for ubiquitin binding and catalysis. We further demonstrated that Ubp15's enzymatic activity is regulated by the N- and C-terminal domains that flank the catalytic core domain. Moreover, we demonstrated that Ubp15 physically interacts with a WD40 repeat-containing protein, Cdh1, by copurification experiments. Interestingly, unlike other DUBs that specifically interact with WD40 repeat-containing proteins, Cdh1 does not function in stimulating Ubp15's activity. The possible cellular function of Ubp15 in cell cycle regulation is discussed in view of the specific interaction between Ubp15 and Cdh1, an activator of the anaphase-promoting complex/cyclosome (APC/C).     

Ubiquitin-specific proteases of Saccharomyces cerevisiae. Cloning of UBP2 and UBP3, and functional analysis of the UBP gene family.

In eukaryotes, both natural and engineered ubiquitin (Ub) fusions to itself or other proteins are cleaved by processing proteases after the last (Gly76) residue of ubiquitin. YUH1 and UBP1, the genes for two ubiquitin-specific proteases of the yeast Saccharomyces cerevisiae, have been cloned previously and shown to encode nonhomologous proteins. Using an Escherichia coli-based genetic screen, we have isolated two other yeast genes for ubiquitin-specific proteases, named UBP2 and UBP3. Ubp2 (1,264 residues), Ubp3 (912 residues), and the previously cloned Ubp1 (809 residues) are largely dissimilar except for two short regions containing Cys and His which encompass their putative active sites. Neither of these proteases has sequence similarities to Yuh1. Both Ubp2 and the previously identified Ubp1 cleave in vitro at the C terminus of the ubiquitin moiety in natural and engineered fusions irrespective of their size, poly-Ub being the exception. However, both Ubp1 and Ubp2 are also capable of cleaving poly-Ub when coexpressed with it in E. coli, suggesting that such cleavage is largely cotranslational. Although inactive in E. coli extracts, Ubp3 was active with all of the tested ubiquitin fusions except poly-Ub when coexpressed with them in E. coli. Null yuh1 ubp1 ubp2 ubp3 quadruple mutants are viable and retain the ability to deubiquitinate ubiquitin fusions, indicating the presence of at least one more ubiquitin-specific processing protease in S. cerevisiae.     

Protein-linked ubiquitin chain structure restricts activity of deubiquitinating enzymes

The attachment of lysine 48 (Lys(48))-linked polyubiquitin chains to proteins is a universal signal for degradation by the proteasome. Here, we report that long Lys(48)-linked chains are resistant to many deubiquitinating enzymes (DUBs). Representative enzymes from this group, Ubp15 from yeast and its human ortholog USP7, rapidly remove mono- and diubiquitin from substrates but are slow to remove longer Lys(48)-linked chains. This resistance is lost if the structure of Lys(48)-linked chains is disrupted by mutation of ubiquitin or if chains are linked through Lys(63). In contrast to Ubp15 and USP7, Ubp12 readily cleaves the ends of long chains, regardless of chain structure. We propose that the resistance to many DUBs of long, substrate-attached Lys(48)-linked chains helps ensure that proteins are maintained free from ubiquitin until a threshold of ubiquitin ligase activity enables degradation.     

Complementary roles for Rpn11 and Ubp6 in deubiquitination and proteolysis by the proteasome

Substrates destined for degradation by the 26 S proteasome are labeled with polyubiquitin chains. These chains can be dismantled by deubiquitinating enzymes (DUBs). A number of reports have identified different DUBs that can hydrolyze ubiquitin from substrates bound to the proteasome. We measured deubiquitination by both isolated lid and base-core particle subcomplexes, suggesting that at least two different DUBs are intrinsic components of 26 S proteasome holoenzymes. In agreement, we find that highly purified proteasomes contain both Rpn11 and Ubp6, situated within the lid and base subcomplexes, respectively. To study their relative contributions, we purified proteasomes from a mutant in the putative metalloprotease domain of Rpn11 and from a ubp6 null. Interestingly, in both preparations we observed slower deubiquitination rates, suggesting that Rpn11 and Ubp6 serve complementary roles. In accord, the double mutant is synthetically lethal. In contrast to WT proteasomes, proteasomes lacking the lid subcomplex or those purified from the rpn11 mutant are less sensitive to metal chelators, supporting the prediction that Rpn11 may be a metalloprotein. Treatment of proteasomes with ubiquitin-aldehyde or with cysteine modifiers also inhibited deubiquitination but simultaneously promoted degradation of a monoubiquitinated substrate along with the ubiquitin tag. Degradation is unique to 26 S proteasome holoenzymes; we could not detect degradation of a ubiquitinated protein by "lidless" proteasomes, although they were competent for deubiquitination. The fascinating observation that a single ubiquitin moiety is sufficient for targeting an otherwise stable substrate to proteasomes exposes how rapid deubiquitination of poorly ubiquitinated substrates may counteract degradation.     

Uch2/Uch37 is the major deubiquitinating enzyme associated with the 26S proteasome in fission yeast

Conjugation of proteins to ubiquitin plays a central role for a number of cellular processes including endocytosis, DNA repair and degradation by the 26S proteasome. However, ubiquitination is reversible as a number of deubiquitinating enzymes mediate the disassembly of ubiquitin-protein conjugates. Some deubiquitinating enzymes are associated with the 26S proteasome contributing to and regulating the particle's activity. Here, we characterise fission yeast Uch2 and Ubp6, two proteasome associated deubiquitinating enzymes. The human orthologues of these enzymes are known as Uch37 and Usp14, respectively. We report that the subunit Uch2/Uch37 is the major deubiquitinating enzyme associated with the fission yeast 26S proteasome. In contrast, the activity of Ubp6 appears to play a more regulatory and/or structural role involving the proteasome subunits Mts1/Rpn9, Mts2/Rpt2 and Mts3/Rpn12, as Ubp6 becomes essential when activity of these subunits is compromised by conditional mutations. Finally, when the genes encoding Uch2/Uch37 and Ubp6 are disrupted, the cells are viable without showing obvious signs of impaired ubiquitin-dependent proteolysis, indicating that other deubiquitinating enzymes may remedy for the redundancy of these enzymes.     

In vivo disassembly of free polyubiquitin chains by yeast Ubp14 modulates rates of protein degradation by the proteasome.

Degradation of many eukaryotic proteins requires their prior ligation to polyubiquitin chains, which target substrates to the 26S proteasome, an abundant cellular protease. We describe a yeast deubiquitinating enzyme, Ubp14, that specifically disassembles unanchored ('free') ubiquitin chains in vitro, a specificity shared by mammalian isopeptidase T. Correspondingly, deletion of the UBP14 gene from yeast cells results in a striking accumulation of free ubiquitin chains, which correlates with defects in ubiquitin-dependent proteolysis. Increasing the steady-state levels of ubiquitin chains in wild-type cells (by expressing a derivative of ubiquitin with an altered C-terminus) inhibits protein degradation to a degree comparable with that observed in ubp14delta cells. Inhibition of degradation is also seen when an active site mutant of Ubp14 is overproduced in vivo. Surprisingly, overproduction of wild-type Ubp14 can inhibit degradation of some proteins as well. Finally, Ubp14 and human isopeptidase T are shown to be functional homologs by complementation analysis. We propose that Ubp14 and isopeptidase T facilitate proteolysis in vivo by preventing unanchored ubiquitin chains from competitively inhibiting polyubiquitin-substrate binding to the 26S proteasome.     

Rub1p processing by Yuh1p is required for wild-type levels of Rub1p conjugation to Cdc53p

In Saccharomyces cerevisiae, Rub1p, like ubiquitin, is conjugated to proteins. Before protein conjugation, the carboxyl-terminal asparagine residue of Rub1p is removed. Rub1p conjugation is dependent on the carboxyl-terminal processing enzyme Yuh1p, whereas Rub1p lacking the asparagine residue is conjugated without Yuh1p. Thus, Yuh1p is the major processing enzyme for Rub1p.     

A Global Census of Fission Yeast Deubiquitinating Enzyme Localization and Interaction Networks Reveals Distinct Compartmentalization Profiles and Overlapping Functions in Endocytosis and Polarity

Ubiquitination and deubiquitination are reciprocal processes that tune protein stability, function, and/or localization. The removal of ubiquitin and remodeling of ubiquitin chains is catalyzed by deubiquitinating enzymes (DUBs), which are cysteine proteases or metalloproteases. Although ubiquitination has been extensively studied for decades, the complexity of cellular roles for deubiquitinating enzymes has only recently been explored, and there are still several gaps in our understanding of when, where, and how these enzymes function to modulate the fate of polypeptides. To address these questions we performed a systematic analysis of the 20 Schizosaccharomyces pombe DUBs using confocal microscopy, proteomics, and enzymatic activity assays. Our results reveal that S. pombe DUBs are present in almost all cell compartments, and the majority are part of stable protein complexes essential for their function. Interestingly, DUB partners identified by our study include the homolog of a putative tumor suppressor gene not previously linked to the ubiquitin pathway, and two conserved tryptophan-aspartate (WD) repeat proteins that regulate Ubp9, a DUB that we show participates in endocytosis, actin dynamics, and cell polarity. In order to understand how DUB activity affects these processes we constructed multiple DUB mutants and find that a quintuple deletion of ubp4 ubp5 ubp9 ubp15 sst2/amsh displays severe growth, polarity, and endocytosis defects. This mutant allowed the identification of two common substrates for five cytoplasmic DUBs. Through these studies, a common regulatory theme emerged in which DUB localization and/or activity is modulated by interacting partners. Despite apparently distinct cytoplasmic localization patterns, several DUBs cooperate in regulating endocytosis and cell polarity. These studies provide a framework for dissecting DUB signaling pathways in S. pombe and may shed light on DUB functions in metazoans.     

COP9 signalosome-specific phosphorylation targets p53 to degradation by the ubiquitin system

In higher eukaryotic cells, the p53 protein is degraded by the ubiquitin-26S proteasome system mediated by Mdm2 or the human papilloma virus E6 protein. Here we show that COP9 signalosome (CSN)-specific phosphorylation targets human p53 to ubiquitin-26S proteasome-dependent degradation. As visualized by electron microscopy, p53 binds with high affinity to the native CSN complex. p53 interacts via its N-terminus with CSN subunit 5/Jab1 as shown by far-western and pull-down assays. The CSN-specific phosphorylation sites were mapped to the core domain of p53 including Thr155. A phosphorylated peptide, Deltap53(145-164), specifically inhibits CSN-mediated phosphorylation and p53 degradation. Curcumin, a CSN kinase inhibitor, blocks E6-dependent p53 degradation in reticulocyte lysates. Mutation of Thr155 to valine is sufficient to stabilize p53 against E6-dependent degradation in reticulocyte lysates and to reduce binding to Mdm2. The p53T155V mutant accumulates in both HeLa and HL 60 cells and exhibits a mutant (PAb 240+) conformation. It induces the cyclin-dependent inhibitor p21. In HeLa and MCF-7 cells, inhibition of CSN kinase by curcumin or Deltap53(145-164) results in accumulation of endogenous p53.     

The catalytic activity of Ubp6 enhances maturation of the proteasomal regulatory particle

The 26S proteasome is a 2.5 MDa macromolecular machine responsible for targeted protein degradation. Recently, four chaperones were identified that promote the assembly of the 19S regulatory particle (RP). Here, we probe the dynamic architecture of the proteasome by applying quantitative proteomics and mass spectrometry (MS) of intact complexes to provide a detailed characterization of how Ubp6 assists this assembly process. Our MS data demonstrate stoichiometric binding of chaperones and Ubp6 to the basal part of the RP. Genetic interactions of Ubp6 with Hsm3, but not with the other chaperones, indicate a functional overlay with Hsm3. Our biochemical data identified Ubp6 as an additional member of the Hsm3 module. Deletions of ubp6 with hsm3 perturb 26S proteasome assembly, which we attribute to an accumulation of ubiquitylated substrates on these assembly precursors. We therefore propose that Ubp6 facilitates proteasomal assembly by clearing ubiquitylated substrates from assembly precursors by its deubiquitylating activity.     

Characterization of the antigenic domains of the major core protein (p26) of equine infectious anemia virus.

A panel of recombinant trpLE-gag fusion proteins and synthetic peptides was used in Western immunoblot and enzyme-linked immunosorbent assays to identify segments of the major core protein (p26) of equine infectious anemia virus that are antigenic in horses during experimental and natural infections with the virus. The predominant humoral immune response was directed toward a highly immunogenic domain composed of 83 amino acids from the carboxy terminus of p26. The observed immunogenicity of p26 resembled that reported for p24 of human immunodeficiency virus type 1, suggesting the conservation of structural motifs in the lentiviral core proteins which are responsible for their observed immunogenicity during persistent lentivirus infections.     

Proteasome recruitment and activation of the Uch37 deubiquitinating enzyme by Adrm1

Uch37 is one of the three principal deubiquitinating enzymes (DUBs), and the only ubiquitin carboxy-terminal hydrolase (UCH)-family protease, that is associated with mammalian proteasomes. We show that Uch37 is responsible for the ubiquitin isopeptidase activity in the PA700 (19S) proteasome regulatory complex. PA700 isopeptidase disassembles Lys 48-linked polyubiquitin specifically from the distal end of the chain, a property that may be used to clear poorly ubiquitinated or unproductively bound substrates from the proteasome. To better understand Uch37 function and the mechanism responsible for its specificity, we investigated how Uch37 is recruited to proteasomes. Uch37 binds through Adrm1, a previously unrecognized orthologue of Saccharomyces cerevisiae Rpn13p, which in turn is bound to the S1 (also known as Rpn2) subunit of the 19S complex. Adrm1 (human Rpn13, hRpn13) binds the carboxy-terminal tail of Uch37, a region that is distinct from the UCH catalytic domain, which we show inhibits Uch37 activity. Following binding, Adrm1 relieves Uch37 autoinhibition, accelerating the hydrolysis of ubiquitin-7-amido-4-methylcoumarin (ubiquitin-AMC). However, neither Uch37 alone nor the Uch37-Adrm1 or Uch37-Adrm1-S1 complexes can hydrolyse di-ubiquitin efficiently; rather, incorporation into the 19S complex is required to enable processing of polyubiquitin chains.     

Active site alanine mutations convert deubiquitinases into high‐affinity ubiquitin‐binding proteins

A common strategy for exploring the biological roles of deubiquitinating enzymes (DUBs) in different pathways is to study the effects of replacing the wild‐type DUB with a catalytically inactive mutant in cells. We report here that a commonly studied DUB mutation, in which the catalytic cysteine is replaced with alanine, can dramatically increase the affinity of some DUBs for ubiquitin. Overexpression of these tight‐binding mutants thus has the potential to sequester cellular pools of monoubiquitin and ubiquitin chains. As a result, cells expressing these mutants may display unpredictable dominant negative physiological effects that are not related to loss of DUB activity. The structure of the SAGA DUB module bound to free ubiquitin reveals the structural basis for the 30‐fold higher affinity of Ubp8^C146A for ubiquitin. We show that an alternative option, substituting the active site cysteine with arginine, can inactivate DUBs while also decreasing the affinity for ubiquitin.     

The zinc finger of the CSN-associated deubiquitinating enzyme USP15 is essential to rescue the E3 ligase Rbx1

The COP9 signalosome (CSN) is a conserved protein complex found in all eukaryotic cells and involved in the regulation of the ubiquitin (Ub)/26S proteasome system. It binds numerous proteins, including the Ub E3 ligases and the deubiquitinating enzyme Ubp12p, the S. pombe ortholog of human USP15. We found that USP15 copurified with the human CSN complex. Isolated CSN complex exhibited protease activity that deubiquitinated poly-Ub substrates and was completely inhibited by o-phenanthroline (OPT), a metal-chelating agent. Surprisingly, the recombinant USP15 was also not able to cleave isopeptide bonds of poly-Ub chains in presence of OPT. Detailed analysis of USP sequences led to the discovery of a novel zinc (Zn) finger in USP15 and related USPs. Mutation of a single conserved cysteine residue in the predicted Zn binding motif resulted in the loss of USP15 capability to degrade poly-Ub substrates, indicating that the Zn finger is essential for the cleavage of poly-Ub chains. Moreover, pulldown experiments demonstrated diminished binding of tetra-Ub to mutated USP15. Cotransfection of USP15 and the Ub ligase Rbx1 revealed that the wild-type deubiquitinating enzyme, but not the USP15 mutant with a defective Zn finger, stabilized Rbx1 toward the Ub system, most likely by reversing poly/autoubiquitination. In summary, a functional Zn finger of USP15 is needed to maintain a conformation essential for disassembling poly-Ub chains, a prerequisite for rescuing the E3 ligase Rbx1.     

定量蛋白质组学揭示酵母去泛素化酶Ubp14生物学功能

泛素化是一种动态可逆的蛋白质翻译后修饰,泛素分子在泛素激活酶、泛素结合酶和泛素连接酶的级联酶促反应催化下共价连接到底物蛋白上。去泛素化酶将泛素分子从底物上移除,动态可逆地调控泛素化修饰,在成熟泛素的生成、泛素链的移除与修剪、游离泛素链的回收等过程中发挥着关键的调控作用。本文的研究对象是酵母中泛素特异性蛋白酶(ubiquitin specific protease, USP)家族成员Ubp14,负责回收细胞内游离的泛素链。本研究定量比较了酵母细胞中Ubp14缺失对全蛋白质组的影响,进而找出其潜在的调控通路和分子功能。首先,通过同源重组技术构建了ubp14?菌株,发现其生长速度低于野生型酵母。利用稳定同位素氨基酸代谢标记技术结合深度覆盖的蛋白质组学分析技术,系统比较了ubp14?菌株相对于野生型菌株的差异蛋白,共计鉴定3 685个蛋白,通过统计学分析筛选得到109个差异蛋白。基因本体论分析发现,Ubp14缺失引起的差异蛋白主要参与了包括氨基酸代谢、氧化还原和热应激等生物学过程。本研究为深入探究去泛素化酶Ubp14的生物学功能,进而深刻理解游离泛素的稳态平衡与生物学过程调控提供了高可信的蛋白...     

NADH Binds and Stabilizes the 26S Proteasomes Independent of ATP

The 26S proteasome is the end point of the ubiquitin- and ATP-dependent degradation pathway. The 26S proteasome complex (26S PC) integrity and function has been shown to be highly dependent on ATP and its homolog nucleotides. We report here that the redox molecule NADH binds the 26S PC and is sufficient in maintaining 26S PC integrity even in the absence of ATP. Five of the 19S proteasome complex subunits contain a putative NADH binding motif (GxGxxG) including the AAA-ATPase subunit, Psmc1 (Rpt2). We demonstrate that recombinant Psmc1 binds NADH via the GxGxxG motif. Introducing the ΔGxGxxG Psmc1 mutant into cells results in reduced NADH-stabilized 26S proteasomes and decreased viability following redox stress induced by the mitochondrial inhibitor rotenone. The newly identified NADH binding of 26S proteasomes advances our understanding of the molecular mechanisms of protein degradation and highlights a new link between protein homeostasis and the cellular metabolic/redox state.     

Characterization of the ubiquitin-specific protease activity of the mouse/human Unp/Unph oncoprotein

The ubiquitin-specific proteases (Ubps) are a family of largely dissimilar enzymes with two major conserved sequence regions, containing either a conserved cysteine residue or two conserved histidine residues, respectively. The murine Unp oncoprotein and its human homologue, Unph, both contain regions similar to the conserved Cys and His boxes common to all the Ubps. In this study we show that Unp and Unph are active deubiquitinating enzymes, being able to cleave ubiquitin from both natural and engineered linear ubiquitin-protein fusions, including the polyubiquitin precursor. Mutation of the conserved Unp Cys and His residues abolishes this activity, and identifies the likely His residue in the catalytic triad. Unp is tumorigenic when overexpressed in mice, leading to the suggestion that Unp may play a role in the regulation of ubiquitin-dependent protein degradation. We have demonstrated here that the high-level expression of Unp in yeast does not disrupt the degradation of the N-end rule substrate Tyr-beta-galactosidase (betagal), the non-N-end rule substrate ubiquitin-Pro-betagal, or the degradation of abnormal, canavanine-containing proteins. These data suggest that Unp is not a general modulator of ubiquitin-dependent proteolysis. However, Unp may have a role in the regulation of the degradation of a specific, as yet undescribed, substrate(s).