Ubiquitination of proteins modifies protein function by either altering their activities, promoting their degradation, or altering their subcellular localization. Deubiquitinating enzymes are proteases that reverse this ubiquitination. Previous studies demonstrate that proteins that contain an ovarian tumor (OTU) domain possess deubiquitinating activity. This domain of ϳ130 amino acids is weakly similar to the papain family of proteases and is highly conserved from yeast to mammals. Here we report structural and functional studies on the OTU domain-containing protein from yeast, Otu1. We show that Otu1 binds polyubiquitin chain analogs more tightly than monoubiquitin and preferentially hydrolyzes longer polyubiquitin chains with Lys 48 linkages, having little or no activity on Lys 63 -and Lys 29 -linked chains. We also show that Otu1 interacts with Cdc48, a regulator of the ER-associated degradation pathway. We also report the x-ray crystal structure of the OTU domain of Otu1 covalently complexed with ubiquitin and carry out structure-guided mutagenesis revealing a novel mode of ubiquitin recognition and a variation on the papain protease catalytic site configuration that appears to be conserved within the OTU family of ubiquitin hydrolases. Together, these studies provide new insights into ubiquitin binding and hydrolysis by yeast Otu1 and other OTU domain-containing proteins.
A series of nonhydrolyzable ubiquitin dimer analogues has been synthesized and evaluated as inhibitors of ubiquitin-dependent processes. Dimer analogues were synthesized by cross-linking ubiquitin containing a terminal cysteine (G76C) to ubiquitin containing cysteine at position 11 ((76-11)Ub(2)), 29 ((76-29)Ub(2)), 48 ((76-48)Ub(2)), or 63 ((76-63)Ub(2)). A head-to-head dimer of cysteine G76C ((76-76)Ub(2)) served as a control. These analogues are mimics of the different chain linkages observed in natural polyubiquitin chains. All analogues showed weak inhibition toward the catalytic domain of UCH-L3 and a UBP pseudogene. In the absence of ubiquitin, isopeptidase T was inhibited only by the dimer linked through residue 29. In the presence of 0.5 microM ubiquitin, isopeptidase T was inhibited by several of the dimer analogues, with the (76-29)Ub(2) dimer exhibiting a K(i) of 1.8 nM. However, USP14, the human homologue of yeast Ubp6, was not inhibited at the concentrations tested. Some analogues of ubiquitin dimer also acted as selective inhibitors of conjugation and deconjugation of ubiquitin catalyzed by reticulocyte fraction II. (76-76)Ub(2) and (76-11)Ub(2) did not inhibit the conjugation of ubiquitin, while (76-29)Ub(2), (76-48)Ub(2), and (76-63)Ub(2) were potent inhibitors of conjugation. This specificity is consistent with the known ability of cells to form K29-, K48-, and K63-linked polyubiquitin chains. While (76-11)Ub(2), (76-29)Ub(2), and (76-63)Ub(2) inhibited release of ubiquitin from a pool of total conjugates, (76-48)Ub(2) and (76-76)Ub(2) showed no significant inhibition. Isopeptidase T was shown to specifically disassemble two conjugates (assumed to be di- and triubiquitin with masses of 26 and 17 kDa) formed in the reticulocyte lysate system. This activity was inhibited differentially by all dimer analogues. The inhibitor selectivity for deconjugation of the 26 and 17 kDa conjugates was similar to that observed for isopeptidase T. The observations suggest that these two conjugated proteins of the reticulocyte lysate are specific substrates for isopeptidase T in lysates.
Lysine 48-linked polyubiquitin chains are the best understood form of polyubiquitin and are necessary for the function of the ubiquitin-proteasome system. However, other forms of polyubiquitin (e.g., K29- and K63-linked chains) are also present in vivo. Less is known about the functional roles of these linkages or the proteins specifically interacting with these forms of polyubiquitin. Use of native polyubiquitin chains to identify binding proteins is complicated by the difficulties of synthesis and stability. Here, we report the synthesis of a nonhydrolyzable analogue of 29-linked polyubiquitin chains on an affinity support and its use in identifying proteins that bind 29-linked polyubiquitin chains. The 29-linked Ub4 resin was stable and tightly bound recombinant human Isopeptidase T (USP5), a deubiquitinating enzyme known to bind the 29-linked polyubiquitin chains. Two high affinity interactors of the 29-linked polyubiquitin analogues were identified from Saccharomyces cerevisiae lysates. They were identified as Ubp14, the yeast ortholog of Isopeptidase T, and Ufd3, a member of the ubiquitin-fusion degradation pathway with unknown function. Purified recombinant Ufd3 bound to the resin as well, confirming that Ufd3 is a novel binding partner of polyubiquitin. These results demonstrate the efficacy of using polyubiquitin analogue affinity supports to identify novel binding partners of specifically linked polyubiquitin chains. Identification of these proteins will lead to a greater understanding of the physiological relevance of different polyubiquitin linkages.
Despite the identification of numerous deubiquitinating enzymes (DUBs) in recent years, the large majority of this class of enzymes has not been well characterized. This chapter describes biochemical methods that can be used to characterize the function and substrate specificity of DUBs. Methods described will include: fluorescence assay using ubiquitin-amidomethylcoumarin (AMC); a high-performance liquid chromatography assay using ubiquitin ethyl ester or ubiquitin fusion peptides as model substrates to monitor DUB activity; and the purification of a recombinant human DUB, isopeptidase T, in E. coli using low-temperature expression as well as ion-exchange and affinity chromatography.
To further understand ubiquitin‐binding proteins, we have developed a panel of monoubiquitin affinity resins linked through six different positions: residues 6, 11, 29, 48, 63, and 76. Each resin bound a different subset of yeast proteins. MALDI‐TOF MS analysis of the eluted proteins identified several of these proteins. Adding excess free ubiquitin competes for the binding of specific ubiquitin‐binding proteins. Thus, putative monoubiquitin‐binding proteins could be identified by this method. Analysis of yeast protein with this panel of resins demonstrates clear differences in the protein‐binding pattern, depending on what ubiquitin residue is coupled to the resin. The results suggested that certain proteins show a preference for binding to different faces of ubiquitin. Sap185, an effector of the Sit4 protein phosphatase, has been identified as a putative ubiquitin‐binding protein that binds to a face of ubiquitin other than that containing the hydrophobic patch. The combined affinity chromatography and mass spectrometry approach is a powerful tool for identifying ubiquitin‐binding proteins.
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