Crystal structure of a UBP-family deubiquitinating enzyme in isolation and in complex with ubiquitin aldehyde

The ubiquitin-specific processing protease (UBP) family of deubiquitinating enzymes plays an essential role in numerous cellular processes. HAUSP, a representative UBP, specifically deubiquitinates and hence stabilizes the tumor suppressor protein p53. Here, we report the crystal structures of the 40 kDa catalytic core domain of HAUSP in isolation and in complex with ubiquitin aldehyde. These studies reveal that the UBP deubiquitinating enzymes exhibit a conserved three-domain architecture, comprising Fingers, Palm, and Thumb. The leaving ubiquitin moiety is specifically coordinated by the Fingers, with its C terminus placed in the active site between the Palm and the Thumb. Binding by ubiquitin aldehyde induces a drastic conformational change in the active site that realigns the catalytic triad residues for catalysis.     

Cloning and functional analysis of the ubiquitin-specific protease gene UBP1 of Saccharomyces cerevisiae

In eukaryotes, both natural and engineered fusions of ubiquitin to itself or other proteins are cleaved by processing proteases after the last (Gly76) residue of ubiquitin. Using the method of sib selection, and taking advantage of the fact that bacteria such as Escherichia coli lack ubiquitin-specific enzymes, we have cloned a gene, named UBP1, of the yeast Saccharomyces cerevisiae that encodes a ubiquitin-specific processing protease. With the exception of polyubiquitin, the UBP1 protease cleaves at the carboxyl terminus of the ubiquitin moiety in natural and engineered fusions irrespective of their size or the presence of an amino-terminal ubiquitin extension. These properties of UBP1 distinguish it from the previously cloned yeast protease YUH1, which deubiquitinates relatively short ubiquitin fusions but is virtually inactive with longer fusions such as ubiquitin-beta-galactosidase. The amino acid sequence of the 809-residue UBP1 lacks significant similarities to other known proteins, including the 236-residue YUH1 protease. Null ubp1 mutants are viable, and retain the ability to deubiquitinate ubiquitin-beta-galactosidase, indicating that the family of ubiquitin-specific proteases in yeast is not limited to UBP1 and YUH1.     

Structure and mechanisms of the proteasome-associated deubiquitinating enzyme USP14

The ubiquitin-specific processing protease (UBP) family of deubiquitinating enzymes plays an essential role in numerous cellular processes. Mammalian USP14 (Ubp6 in yeast) is unique among known UBP enzymes in that it is activated catalytically upon specific association with the 26S proteasome. Here, we report the crystal structures of the 45-kDa catalytic domain of USP14 in isolation and in a complex with ubiquitin aldehyde, which reveal distinct structural features. In the absence of ubiquitin binding, the catalytic cleft leading to the active site of USP14 is blocked by two surface loops. Binding by ubiquitin induces a significant conformational change that translocates the two surface loops thereby allowing access of the ubiquitin C-terminus to the active site. These structural observations, in conjunction with biochemical characterization, identify important regulatory mechanisms for USP14.     

Multiple ubiquitin-specific protease genes are involved in degradation of yeast tryptophan permease Tat2 at high pressure

When Saccharomyces cerevisiae cells are exposed to high hydrostatic pressure, tryptophan permease Tat2 is degraded in a manner dependent on Rsp5 ubiquitin ligase. Consequently, cell growth is arrested in tryptophan auxotrophic strains. Here we show that of 17 ubiquitin-specific protease genes (UBP), deletion of DOA4, UBP6 or UBP14 causes stabilization of Tat2 and hence the cells can grow at 25 MPa. These disruptant cells displayed marked sensitivity to the arginine analogue canavanine. Internal free ubiquitin decreased 2- to 5-fold upon UBP deletion, although overproduction of ubiquitin did not affect their high-pressure growth and canavanine sensitivity. These results suggest that multiple ubiquitin-specific proteases are involved in pressure-induced degradation of Tat2, rather than free ubiquitin depletion.     

The Arabidopsis mitochondrial membrane‐bound ubiquitin protease UBP27 contributes to mitochondrial morphogenesis

Mitochondria are essential organelles with dynamic morphology and function. Post‐translational modifications (PTMs), which include protein ubiquitination, are critically involved in animal and yeast mitochondrial dynamics. How PTMs contribute to plant mitochondrial dynamics is just beginning to be elucidated, and mitochondrial enzymes involved in ubiquitination have not been reported from plants. In this study, we identified an Arabidopsis mitochondrial localized ubiquitin protease, UBP27, through a screen that combined bioinformatics and fluorescent fusion protein targeting analysis. We characterized UBP27 with respect to its membrane topology and enzymatic activities, and analysed the mitochondrial morphological changes in UBP27T‐DNA insertion mutants and overexpression lines. We have shown that UBP27 is embedded in the mitochondrial outer membrane with an N_in–C_out orientation and possesses ubiquitin protease activities in vitro. UBP27 demonstrates similar sub‐cellular localization, domain structure, membrane topology and enzymatic activities with two mitochondrial deubiquitinases, yeast ScUBP16 and human HsUSP30, which indicated that these proteins are functional orthologues in eukaryotes. Although loss‐of‐function mutants of UBP27 do not show obvious phenotypes in plant growth and mitochondrial morphology, UBP27 overexpression can change mitochondrial morphology from rod to spherical shape and reduce the mitochondrial association of dynamin‐related protein 3 (DRP3) proteins, large GTPases that serve as the main mitochondrial fission factors. Thus, our study has uncovered a plant ubiquitin protease that plays a role in mitochondrial morphogenesis possibly through modulation of the function of organelle division proteins.     

Structural and functional studies of USP20 ZnF‐UBP domain by NMR

Deubiquitinase USP20/VDU2 has been demonstrated to play important roles in multiple cellular processes by controlling the life span of substrate proteins including hypoxia‐inducible factor HIF1α, and so forth. USP20 contains four distinct structural domains including the N‐terminal zinc‐finger ubiquitin binding domain (ZnF‐UBP), the catalytic domain (USP domain), and two tandem DUSP domains, and none of the structures for these four domains has been solved. Meanwhile, except for the ZnF‐UBP domain, the biological functions for USP20's catalytic domain and tandem DUSP domains have been at least partially clarified. Here in this study, we determined the solution structure of USP20 ZnF‐UBP domain and investigated its binding properties with mono‐ubiquitin and poly‐ubiquitin (K48‐linked di‐ubiquitin) by using NMR and molecular modeling techniques. USP20's ZnF‐UBP domain forms a spherically shaped fold consisting of a central β‐sheet with either one α‐helix or two α‐helices packed on each side of the sheet. However, although having formed a canonical core structure essential for ubiquitin recognition, USP20 ZnF‐UBP presents weak ubiquitin binding capacity. The structural basis for understanding USP20 ZnF‐UBP's ubiquitin binding capacity was revealed by NMR data‐driven docking. Although the electrostatic interactions between D264 of USP5 (E87 in USP20 ZnF‐UBP) and R74 of ubiquitin are kept, the loss of the extensive interactions formed between ubiquitin's di‐glycine motif and the conserved and non‐conserved residues of USP20 ZnF‐UBP domain (W41, E55, and Y84) causes a significant decrease in its binding affinity to ubiquitin. Our findings indicate that USP20 ZnF‐UBP domain might have a physiological role unrelated to its ubiquitin binding capacity.     

The ubiquitin binding domain ZnF UBP recognizes the C-terminal diglycine motif of unanchored ubiquitin

Ubiquitin binding proteins regulate the stability, function, and/or localization of ubiquitinated proteins. Here we report the crystal structures of the zinc-finger ubiquitin binding domain (ZnF UBP) from the deubiquitinating enzyme isopeptidase T (IsoT, or USP5) alone and in complex with ubiquitin. Unlike other ubiquitin binding domains, this domain contains a deep binding pocket where the C-terminal diglycine motif of ubiquitin is inserted, thus explaining the specificity of IsoT for an unmodified C terminus on the proximal subunit of polyubiquitin. Mutations in the domain demonstrate that it is required for optimal catalytic activation of IsoT. This domain is present in several other protein families, and the ZnF UBP domain from an E3 ligase also requires the C terminus of ubiquitin for binding. These data suggest that binding the ubiquitin C terminus may be necessary for the function of other proteins.     

多肽抗生素apidaecin基因在乳酸乳球菌中的融合表达

利用乳链菌肽(nisin)诱导表达系统,以泛素(ubiquitin)融合蛋白的形式在乳酸乳球菌(Lactococcus lactis)中表达了多肽抗生素apidaecin。利用TricineSDSPAGE和Western blotting均可在诱导后的宿主菌中检测到特异蛋白带。表达产物的最高产量可达宿主菌可溶性蛋白的7.2%左右。在体外用泛素特异性蛋白酶UBPI从融合蛋白中切除泛素后,产物具有明显的抗菌活性。     

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.     

Cloning and characterization of a novel human ubiquitin-specific protease, a homologue of murine UBP43 (Usp18)

The ubiquitin-specific proteases (UBP) are a family of enzymes that cleave ubiquitin from ubiquitinated protein substrates. We have recently cloned UBP43, a novel member of this family from AML1-ETO knock-in mice. To analyze the role of UBP43 in hematopoiesis and leukemogenesis, we have cloned a full-length human UBP43 cDNA by screening a human monocytic cDNA library as well as by 5'- and 3'-rapid amplification of cDNA ends analyses. This cDNA encodes a polypeptide of 372 amino acids with all of the structural motifs of a deubiquitinating enzyme. The human UBP43 mRNA is strongly expressed in human liver and thymus. Transfection analysis has demonstrated that UBP43 is a nuclear protein. Interestingly, the gene encoding human UBP43 maps to chromosome 22q11.2. This region, known as DiGeorge syndrome critical region, contains a minimal area of 2 Mb and is consistently deleted in DiGeorge syndrome and related disorders. The syndrome is marked by thymic aplasia or hypoplasia, parathyroid hypoplasia, or congenital cardiac abnormalities. Taken together, our results broaden the understanding of a new human ubiquitin-specific protease, UBP43, and suggest that this gene may also be related to DiGeorge syndrome.     

The solution structure of the ZnF UBP domain of USP33/VDU1

USP33/VDU1 is a deubiquitinating enzyme that binds to the von Hippel-Lindau tumor suppressor protein. It also regulates thyroid hormone activation by deubiquitinating type 2 iodothyronine deiodinase. USP33/VDU1 contains a ZF UBP domain, a protein module found in many proteins in the ubiquitin-proteasome system. Several ZF UBP domains have been shown to bind ubiquitin, and a structure of a complex of the ZF UBP domain of isoT/USP5 and ubiquitin is available. In the present work, the solution structure of the ZF UBP domain of USP33/VDU1 has been determined by NMR spectroscopy. The structure differs from that of the USP5 domain, which contains only one of the three Zn ions present in the USP33/VDU1 structure. The USP33/VDU1 ZnF UBP domain does not bind to ubiquitin.     

At UBP3 and At UBP4 are two closely related Arabidopsis thaliana ubiquitin-specific proteases present in the nucleus

The ubiquitin-specific proteases (UBPs) are a class of enzymes vital to the ubiquitin pathway. These enzymes cleave ubiquitin at its C-terminus from two types of substrates containing (i) ubiquitin in an α-amino linkage, as found in the primary ubiquitin translation products, polyubiquitin and ubiquitin-ribosomal fusion proteins, or (ii) ubiquitin in an ?-amino linkage, as found in multiubiquitin chains either unattached or conjugated to cellular proteins. We have isolated cDNAs for two Arabidopsis thaliana genes, AtUBP3 and AtUBP4, which encode UBPs that are 93% identical. These two cDNAs represent the only two members of this subgroup and encode the smallest UBPs described to date in any organism. Using in vivo assays in Escherichia coli that allow the coexpression of a UBP with a putative substrate, we have shown that AtUBP3 and AtUBP4 can specifically deubiquitinate the artificial substrate Ub-X-β-gal but cannot act upon the natural α-amino-linked ubiquitin fusions Arabidopsis Ub-CEP52 and Arabidopsis polyubiquitin. Affinity-purified antibody prepared against AtUBP3 expressed in E. coli recognizes both AtUBP3 and AtUBP4. AtUBP3 and/or AtUBP4 are present in all Arabidopsis organs examined and at multiple developmental stages. Subcellular localization studies show that AtUBP3 and/or AtUBP4 are present in nuclear extracts. Possible physiological roles for these UBPs are discussed.     

At UBP3 and At UBP4 are two closely related Arabidopsis thaliana ubiquitin-specific proteases present in the nucleus

The ubiquitin-specific proteases (UBPs) are a class of enzymes vital to the ubiquitin pathway. These enzymes cleave ubiquitin at its C-terminus from two types of substrates containing (i) ubiquitin in an α-amino linkage, as found in the primary ubiquitin translation products, polyubiquitin and ubiquitin-ribosomal fusion proteins, or (ii) ubiquitin in an ɛ-amino linkage, as found in multiubiquitin chains either unattached or conjugated to cellular proteins. We have isolated cDNAs for two Arabidopsis thaliana genes, AtUBP3 and AtUBP4, which encode UBPs that are 93% identical. These two cDNAs represent the only two members of this subgroup and encode the smallest UBPs described to date in any organism. Using in vivo assays in Escherichia coli that allow the coexpression of a UBP with a putative substrate, we have shown that AtUBP3 and AtUBP4 can specifically deubiquitinate the artificial substrate Ub-X-β-gal but cannot act upon the natural α-amino-linked ubiquitin fusions Arabidopsis Ub-CEP52 and Arabidopsis polyubiquitin. Affinity-purified antibody prepared against AtUBP3 expressed in E. coli recognizes both AtUBP3 and AtUBP4. AtUBP3 and/or AtUBP4 are present in all Arabidopsis organs examined and at multiple developmental stages. Subcellular localization studies show that AtUBP3 and/or AtUBP4 are present in nuclear extracts. Possible physiological roles for these UBPs are discussed. Received: 14 November 1996 / Accepted: 6 February 1997     

ISG15, not just another ubiquitin-like protein

ISG15 is a ubiquitin-like protein containing two ubiquitin homology domains and becomes conjugated to a variety of proteins when cells are treated with type I interferon or lipopolysaccharide. Although ISG15 shares several common properties with those of other ubiquitin-like molecules, it is a unique member, whose expression and conjugation to target proteins are tightly regulated by specific signaling pathways, indicating it may be associated with specialized functions in innate immune system. Loss of UBP43 (USP18), a protease that specifically removes ISG15 from ISG15-modified proteins, in mice leads to decreased life span, brain cell injury, and hypersensitivity to interferon stimulation. In UBP43 deficient cells, interferon induces a prolonged Stat1 tyrosine phosphorylation and DNA binding, which result in a prolonged and enhanced activation of interferon-stimulated genes.     

Ubiquitin-Yop hybrids as probes for post-translational transport by the Yersinia type III secretion pathway

Yersinia enterocolitica uses type III secretion to transport Yop proteins into the cytoplasm of host cells. Previous work generated hypotheses for both co- and post-translational transport mechanisms in the Yersinia type III pathway. Here, we used ubiquitin (Ub) and UBP1, the Ub-specific protease, to examine whether Yops can be secreted when synthesized prior to recognition by the type III machinery. Fusion of Ub to the N-terminus of Yops blocked substrate recognition and secretion of hybrids generated with YopE, YopQ or YopR. UBP1 removed Ub from the N-terminus of these hybrids and allowed YopE, YopQ or YopR cleavage products to enter the secretion pathway. Following the release of Ub, Yersinia type III machines also transported the YopE cleavage product into the cytosol of tissue culture cells. Minimal secretion signals were also examined with the Ub/UBP1 system and some, but not all, of these signals promoted type III secretion even after polypeptides had been freed from Ub. These results suggest that recognition and secretion of Yop substrates by the type III machinery can occur by a post-translational mechanism.     

Engineered bakers yeast as a sensitive bioassay indicator organism for the trichothecene toxin deoxynivalenol

The aim of this study was to increase the sensitivity of Saccharomyces cerevisiae towards trichothecene toxins, in particular to deoxynivalenol (DON), in order to improve the utility of this yeast as a bioassay indicator organism. We report the construction of a strain with inactivated genes (PDR5, PDR10, PDR15) encoding ABC transporter proteins with specificity for the trichothecene deoxynivalenol, with inactivated AYT1 (encoding a trichothecene-3-O-acetyltransferase), and inactivated UBI4 and UBP6 genes. Inactivation of the stress inducible polyubiquitin gene UBI4 or the ubiquitin protease UBP6 increased DON sensitivity, the inactivation of both genes had a synergistic effect. The resulting pdr5 pdr10 pdr15 ayt1 ubp6 ubi4 mutant strain showed 50% growth inhibition at a DON concentration of 5 mg/l under optimal conditions. The development of a simple two step assay for microbial DON degradation in 96 well microtiter format and its testing with the DON detoxifying bacterium BBSH 797 is reported.     

Characterization of alternatively spliced products and tissue-specific isoforms of USP28 and USP25

Background  

The ubiquitin-dependent protein degradation pathway is essential for the proteolysis of intracellular proteins and peptides. Deubiquitinating enzymes constitute a complex protein family involved in a multitude of cellular processes. The ubiquitin-specific proteases (UBP) are a group of enzymes whose predicted function is to reverse the ubiquitinating reaction by removing ubiquitin from a large variety of substrates. We have lately reported the characterization of human USP25, a specific-ubiquitin protease gene at 21q11.2, with a specific pattern of expression in murine fetal brains and adult testis.