Structure of a diubiquitin conjugate and a model for interaction with ubiquitin conjugating enzyme (E2).

Covalent ligation of multiubiquitin chains targets eukaryotic proteins for degradation. In such multiubiquitin chains, successive ubiquitins are linked by an isopeptide bond involving the side chain of Lys48 and the carboxyl group of Gly76. The crystal structure of a diubiquitin conjugate has been determined and refined at 2.3-A resolution. The molecule has internal approximate 2-fold symmetry with multiple hydrophobic and hydrophilic contacts along the 2-fold axis. The structure of the diubiquitin conjugate suggests determinants for recognition of multiubiquitin chains. A model for the interaction of diubiquitin and a ubiquitin conjugating enzyme (E2) is proposed.     

E2/E3-mediated assembly of lysine 29-linked polyubiquitin chains.

Polyubiquitin (Ub) chains linked through Lys-48-Gly-76 isopeptide bonds represent the principal signal by which substrates of the Ub-dependent protein degradation pathway are targeted to the 26 S proteasome, but the mechanism(s) whereby these chains are assembled on substrate proteins is poorly understood. Nor have assembly mechanisms or definitive functions been assigned to polyubiquitin chains linked through several other lysine residues of ubiquitin. We show that rabbit reticulocyte lysate harbors enzymatic components that catalyze the assembly of unanchored Lys-29-linked polyubiquitin chains. This reaction can be reconstituted using the ubiquitin-conjugating enzyme (E2) known as UbcH5A, a 120-kDa protein(s) that behaves as a ubiquitin-protein ligase (E3), and ubiquitin-activating enzyme (E1). The same partially purified E3 preparation also catalyzes the assembly of unanchored chains linked through Lys-48. Kinetic studies revealed a K(m) of approximately 9 microM for the acceptor ubiquitin in the synthesis of diubiquitin; this value is similar to the concentration of free ubiquitin in most cells. Similar kinetic behavior was observed for conjugation to Lys-48 versus Lys-29 and for conjugation to tetraubiquitin versus monoubiquitin. The properties of these enzymes suggest that there may be distinct pathways for ubiquitin-ubiquitin ligation versus substrate-ubiquitin ligation in vivo.     

Mechanism of polyubiquitin chain recognition by the human ubiquitin conjugating enzyme Ube2g2

Ube2g2 is a human ubiquitin conjugating (E2) enzyme involved in the endoplasmic reticulum-associated degradation pathway, which is responsible for the identification and degradation of unfolded and misfolded proteins in the endoplasmic reticulum compartment. The Ube2g2-specific role is the assembly of Lys-48-linked polyubiquitin chains, which constitutes a signal for proteasomal degradation when attached to a substrate protein. NMR chemical shift perturbation and paramagnetic relaxation enhancement approaches were employed to characterize the binding interaction between Ube2g2 and ubiquitin, Lys-48-linked diubiquitin, and Lys-63-linked diubiquitin. Results demonstrate that ubiquitin binds to Ube2g2 with an affinity of 90 μM in two different orientations that are rotated by 180° in models generated by the RosettaDock modeling suite. The binding of Ube2g2 to Lys-48- and Lys-63-linked diubiquitin is primarily driven by interactions with individual ubiquitin subunits, with a clear preference for the subunit containing the free Lys-48 or Lys-63 side chain (i.e. the distal subunit). This preference is particularly striking in the case of Lys-48-linked diubiquitin, which exhibits an ～3-fold difference in affinities between the two ubiquitin subunits. This difference can be attributed to the partial steric occlusion of the subunit whose Lys-48 side chain is involved in the isopeptide linkage. As such, these results suggest that Lys-48-linked polyubiquitin chains may be designed to bind certain proteins like Ube2g2 such that the terminal ubiquitin subunit carrying the reactive Lys-48 side chain can be positioned properly for chain elongation regardless of chain length.     

An NMR-based model of the ubiquitin-bound human ubiquitin conjugation complex Mms2.Ubc13. The structural basis for lysine 63 chain catalysis

A heterodimer composed of the catalytically active ubiquitin-conjugating enzyme hUbc13 and its catalytically inactive paralogue, hMms2, forms the catalytic core for the synthesis of an alternative type of multiubiquitin chain where ubiquitin molecules are tandemly linked to one another through a Lys-63 isopeptide bond. This type of linkage, as opposed to the more typical Lys-48-linked chains, serves as a non-proteolytic marker of protein targets involved in error-free post-replicative DNA repair and NF-kappa B signal transduction. Using a two-dimensional (1)H-(15)N NMR approach, we have mapped: 1) the interaction between the subunits of the human Ubc13.Mms2 heterodimer and 2) the interactions between each of the subunits or heterodimer with a non-covalently bound acceptor ubiquitin or a thiolester-linked donor ubiquitin. Using these NMR-derived constraints and an unbiased docking approach, we have assembled the four components of this catalytic complex into a three-dimensional model that agrees well with its catalytic function.     

Inhibition of proteolysis and cell cycle progression in a multiubiquitination-deficient yeast mutant.

The degradation of many proteins requires their prior attachment to ubiquitin. Proteolytic substrates are characteristically multiubiquitinated through the formation of ubiquitin-ubiquitin linkages. Lys-48 of ubiquitin can serve as a linkage site in the formation of such chains and is required for the degradation of some substrates of this pathway in vitro. We have characterized the recessive and dominant effects of a Lys-48-to-Arg mutant of ubiquitin (UbK48R) in Saccharomyces cerevisiae. Although UbK48R is expected to terminate the growth of Lys-48 multiubiquitin chains and thus to exert a dominant negative effect on protein turnover, overproduction of UbK48R in wild-type cells results in only a weak inhibition of protein turnover, apparently because the mutant ubiquitin can be removed from multiubiquitin chains. Surprisingly, expression of UbK48R complements several phenotypes of polyubiquitin gene (UB14) deletion mutants. However, UbK48R cannot serve as a sole source of ubiquitin in S. cerevisiae, as evidenced by its inability to rescue the growth of ubi1 ubi2 ubi3 ubi4 quadruple mutants. When provided solely with UbK48R, cells undergo cell cycle arrest with a terminal phenotype characterized by replicated DNA, mitotic spindles, and two-lobed nuclei. Under these conditions, degradation of amino acid analog-containing proteins is severely inhibited. Thus, multiubiquitin chains containing Lys-48 linkages play a critical role in protein degradation in vivo.     

Differential Ubiquitin Binding by the Acidic Loops of Ube2g1 and Ube2r1 Enzymes Distinguishes Their Lys-48-ubiquitylation Activities

The ubiquitin E2 enzymes, Ube2g1 and Ube2r1, are able to synthesize Lys-48-linked polyubiquitins without an E3 ligase but how that is accomplished has been unclear. Although both E2s contain essential acidic loops, only Ube2r1 requires an additional C-terminal extension (184–196) for efficient Lys-48-ubiquitylation activity. The presence of Tyr-102 and Tyr-104 in the Ube2g1 acidic loop enhanced both ubiquitin binding and Lys-48-ubiquitylation and distinguished Ube2g1 from the otherwise similar truncated Ube2r1^1–183 (Ube2r1C). Replacement of Gln-105–Ser-106–Gly-107 in the acidic loop of Ube2r1C (Ube2r1C^YGY) by the corresponding residues from Ube2g1 (Tyr-102–Gly-103–Tyr-104) increased Lys-48-ubiquitylation activity and ubiquitin binding. Two E2∼UB thioester mimics (oxyester and disulfide) were prepared to characterize the ubiquitin binding activity of the acidic loop. The oxyester but not the disulfide derivative was found to be a functional equivalent of the E2∼UB thioester. The ubiquitin moiety of the Ube2r1C^C93S-[¹⁵N]UB^K48R oxyester displayed two-state conformational exchange, whereas the Ube2r1C^C93S/YGY-[¹⁵N]UB^K48R oxyester showed predominantly one state. Together with NMR studies that compared UB^K48R oxyesters of the wild-type and the acidic loop mutant (Y102G/Y104G) forms of Ube2g1, in vitro ubiquitylation assays with various mutation forms of the E2s revealed how the intramolecular interaction between the acidic loop and the attached donor ubiquitin regulates Lys-48-ubiquitylation activity.     

The mechanism of linkage-specific ubiquitin chain elongation by a single-subunit E2

Ubiquitin chains of different topologies trigger distinct functional consequences, including protein degradation and reorganization of complexes. The assembly of most ubiquitin chains is promoted by E2s, yet how these enzymes achieve linkage specificity is poorly understood. We have discovered that the K11-specific Ube2S orients the donor ubiquitin through an essential noncovalent interaction that occurs in addition to the thioester bond at the E2 active site. The E2-donor ubiquitin complex transiently recognizes the acceptor ubiquitin, primarily through electrostatic interactions. The recognition of the acceptor ubiquitin surface around Lys11, but not around other lysines, generates a catalytically competent active site, which is composed of residues of both Ube2S and ubiquitin. Our studies suggest that monomeric E2s promote linkage-specific ubiquitin chain formation through substrate-assisted catalysis.     

Ubiquitin conjugation by the yeast RAD6 and CDC34 gene products. Comparison to their putative rabbit homologs, E2(20K) AND E2(32K).

The recombinant yeast RAD6 and CDC34 gene products were expressed in Escherichia coli extracts and purified to apparent homogeneity. The physical and catalytic properties of RAD6 and CDC34 were similar but distinct from their putative rabbit reticulocyte homologs, E2(20k) and E2(32k), respectively. Like their reticulocyte counterparts, RAD6 and CDC34 are bifunctional enzymes competent in both ubiquitin:protein ligase (E3)-independent and E3-dependent conjugation reactions. RAD6 and E2(20k) exhibit marked specificity for the conjugation of core histones and catalyze the processive ligation of up to three ubiquitin moieties directly to such model substrates. RAD6 differed from its putative E2(20k) homolog in exhibiting simple saturation behavior in the kinetics of histone conjugation and in being unable to distinguish kinetically between core histones H2A and H2B, yielding identical values of kcat (1.9 min-1) and Km (20 microM). A slow rate of multiubiquitination involving formation of extended ubiquitin homopolymers on the histones was also observed with RAD6 and E2(20k). Comparison of conjugate patterns among native, reductively methylated, and K48R ubiquitin variants demonstrated that the linkage between ubiquitin moieties formed by E2(20k) and RAD6 was not through Lys-48 of ubiquitin, the site previously demonstrated as a strong signal for degradation of the target protein. In contrast, CDC34 differs from its putative homolog, E2(32k), in showing a specificity for conjugation to bovine serum albumin rather than to core histones. Both CDC34 and E2(32k) exhibit a marked kinetic selectivity for processive multiubiquitination via Lys-48 of ubiquitin. Calculations based on a model ubiquitin conjugation reaction indicated that E2(32k) and CDC34 preferentially catalyzed multiubiquitination over ligation of the polypeptide directly to target proteins. Formation of such multiubiquitin homopolymers by E2(32k) and CDC34 suggests these enzymes may commit their respective target proteins to degradation via an E3-independent pathway.     

NMR reveals a different mode of binding of the Stam2 VHS domain to ubiquitin and diubiquitin

The VHS domain of the Stam2 protein is a ubiquitin binding domain involved in the recognition of ubiquitinated proteins committed to lysosomal degradation. Among all VHS domains, the VHS domain of Stam proteins is the strongest binder to monoubiqiuitin and exhibits preferences for K63-linked chains. In the present paper, we report the solution NMR structure of the Stam2-VHS domain in complex with monoubiquitin by means of chemical shift perturbations, spin relaxation, and paramagnetic relaxation enhancements. We also characterize the interaction of Stam2-VHS with K48- and K63-linked diubiquitin chains and report the first evidence that VHS binds differently to these two chains. Our data reveal that VHS enters the hydrophobic pocket of K48-linked diubiquitin and binds the two ubiquitin subunits with different affinities. In contrast, VHS interacts with K63-linked diubiquitin in a mode similar to its interaction with monoubiquitin. We also suggest possible structural models for both K48- and K63-linked diubiquitin in interaction with VHS. Our results, which demonstrate a different mode of binding of VHS for K48- and K63-linked diubiquitin, may explain the preference of VHS for K63- over K48-linked diubiquitin chains and monoubiquitin.     

Isolation of a cDNA encoding a mammalian multiubiquitinating enzyme (E225K) and overexpression of the functional enzyme in Escherichia coli.

The ubiquitin (Ub)-conjugating enzyme E2(25K) catalyzes the synthesis of multi-Ub chains in which successive Ub units are linked by an isopeptide bond involving the epsilon-amino group of Lys-48 of Ubn, and the COOH-terminal Gly residue of Ubn+1 (Chen, Z., and Pickart, C. M. (1990) J. Biol. Chem., 265, 21835-21842). We now describe the polymerase chain reaction (PCR)-based cloning of an E2(25K)-encoding cDNA from a bovine thymus library, using degenerate oligonucleotide primers based on the sequences of two E2(25K) peptides. The cDNA encodes a 200-residue protein whose sequence bears similarities of 66 and 59%, respectively, to the sequences of the Ub-conjugating enzymes encoded by the UBC1 and UBC4/UBC5 genes of the yeast Saccharomyces cerevisiae. These three yeast E2s play key roles in Ub-dependent proteolysis (Seufert, W., McGrath, J. P., and Jentsch, S. (1990) EMBO J. 9, 4535-4541). Comparison of the amino acid sequence of E2(25K) with other known E2 sequences strongly suggests that Cys-92, one of two E2(25K) Cys residues, forms the Ub thiol ester adduct that is an intermediate in E2-catalyzed multiubiquitination. The E2(25K)-encoding cDNA was overexpressed in Escherichia coli, and the recombinant E2(25K) protein was purified to electrophoretic homogeneity; enzymatic assays showed that its multiubiquitinating activity was quantitatively identical with that of the native protein. The availability of a cloned cDNA will allow us to assess the physiological role of E2(25K).     

A ubiquitin mutant with specific defects in DNA repair and multiubiquitination.

The degradation of many proteins involves the sequential ligation of ubiquitin molecules to the substrate to form a multiubiquitin chain linked through Lys-48 of ubiquitin. To test for the existence of alternate forms of multiubiquitin chains, we examined the effects of individually substituting each of six other Lys residues in ubiquitin with Arg. Substitution of Lys-63 resulted in the disappearance of a family of abundant multiubiquitin-protein conjugates. The UbK63R mutants were not generally impaired in ubiquitination, because they grew at a wild-type rate, were fully proficient in the turnover of a variety of short-lived proteins, and exhibited normal levels of many ubiquitin-protein conjugates. The UbK63R mutation also conferred sensitivity to the DNA-damaging agents methyl methanesulfonate and UV as well as a deficiency in DNA damage-induced mutagenesis. Induced mutagenesis is mediated by a repair pathway that requires Rad6 (Ubc2), a ubiquitin-conjugating enzyme. Thus, the UbK63R mutant appears to be deficient in the Rad6 pathway of DNA repair. However, the UbK63R mutation behaves as a partial suppressor of a rad6 deletion mutation, indicating that an effect of UbK63R on repair can be manifest in the absence of the Rad6 gene product. The UbK63R mutation may therefore define a new role of ubiquitin in DNA repair. The results of this study suggest that Lys-63 is used as a linkage site in the formation of novel multiubiquitin chain structures that play an important role in DNA repair.     

An in vitro method for selective detection of free monomeric ubiquitin by using a C-terminally biotinylated form of ubiquitin

In an effort to design a selective assay allowing detection of free monomeric ubiquitin, an approach based on a C-terminally biotinylated form of ubiquitin is proposed. In the form of a polyubiquitin chain, ubiquitin marks proteins for degradation by the 26S proteasome. This covalently attached signal is assembled from multiple ubiquitins linked to each other via the C-terminus of one ubiquitin and the epsilon-amine of Lys48 of another ubiquitin. In the present study, a form of ubiquitin having the C-terminus modified with the addition of a biotinylation peptide tag was prepared. After expression, this modified ubiquitin was biotinylated in vitro using recombinant biotin ligase. Biotinylated ubiquitin was further purified using affinity chromatography on immobilized monovalent avidin. This tagged form of ubiquitin is blocked at the C-terminus and therefore can only act as an acceptor (Lys-48 donor) in polyubiquitin chain synthesis. In vitro enzymatic assembly of multiubiquitin chains from biotinylated monoubiquitin and natural monoubiquitin is demonstrated by Western blot analysis using horseradish peroxidase-conjugated streptavidin. Data obtained with this assay indicate potential uses of the C-terminally biotinylated form of ubiquitin for selective detection of monoubiquitin contamination in a cell extract experimentally depleted of ubiquitin, i.e. lysate Fraction II. Cell-free systems established for in vitro examination of ubiquitin involvement in proteolytic processes usually employ Fraction II, which should be essentially ubiquitin-free. It is suggested that the assay using biotinylated monoubiquitin can be useful to exclude the possibility that ubiquitin contamination of laboratory prepared lysate Fraction II accounts for protein degradation in this fraction.     

A 25-kilodalton ubiquitin carrier protein (E2) catalyzes multi-ubiquitin chain synthesis via lysine 48 of ubiquitin

Target protein multi-ubiquitination involving lysine 48 of ubiquitin (Ub) is known to occur during protein degradation in the ATP- and Ub-dependent proteolytic pathway (Chau, V., Tobias, J. W., Bachmair, A., Marriott, D., Ecker, D. J., Gonda, D. K., and Varshavsky, A. (1989) Science 243, 1576-1583). However, little is known about the enzymatic mechanism of multi-ubiquitination. We show that a purified Ub carrier protein, E2(25)K, catalyzes multi-Ub chain synthesis from purified Ub. Incubation of E2(25)K with Ub activating enzyme (E1), MgATP, and radiolabeled Ub (Mr = 8500) resulted in time dependent appearance of a "ladder" of radiolabeled Ub conjugates with molecular masses of 8.5n kDa, where n = 1, 2, 3, 4... (up to at least n = 10). The kinetics of this conjugative process were consistent with Ub2 acting as a steady-state intermediate. The putative Ub2 product of E2(25)K catalysis was purified and cleaved with a partially purified isopeptidase preparation. The sole cleavage product (Mr = 8500) had a tryptic digest identical to that of authentic Ub, confirming that the original conjugate was Ub2. Tryptic digestion of intact Ub2 gave products consistent with the existence of an isopeptide linkage between the COOH terminus of one Ub and Lys-48 of the other; this structure was confirmed by sequence analysis of the unique Ub2 tryptic fragment. Tryptic digestion of higher order Ubn adducts (n greater than or equal to 4) yielded fragments identical to those of Ub2, indicating that E2(25)K ligates successive Ub molecules primarily or exclusively via Lys-48. Although several other E2s supported synthesis of an apparent Ub2 adduct of undetermined linkage, only E2(25)K was capable of synthesizing multi-Ub chains from isolated Ub. Quantitative analysis of single turnovers showed that transfer from E2(25)K-Ub to Ub and Ub2 occurred with kappa 2 = 488 and 1170 M-1 min-1, respectively, at pH 7.3 and 37 degrees C. These results show that increasing the number of Ub molecules in a chain increases susceptibility to further ubiquitination by E2(25)K. Ub2 was a good substrate for activation by E1 and was readily transferred to E2(25)K. The labile E2(25)K-Ub2 adduct was catalytically active, and exhibited preference for Ub2 (versus Ub) as acceptor. These results suggest that E2(25)K may function as a multi-ubiquitinating enzyme in the Ub-dependent proteolytic pathway.     

Structural basis for specific recognition of K6-linked polyubiquitin chains by the TAB2 NZF domain

TAK1-binding protein 2 (TAB2) has generally been considered to bind specifically to K63-linked polyubiquitin chains via its C-terminal Npl4 zinc-finger (NZF) domain. However, a recent study showed that the NZF domain of TAB2 (TAB2-NZF) could also interact with K6-linked polyubiquitin chains. Here, we report the crystal structure of TAB2-NZF in complex with K6-linked diubiquitin (K6-Ub₂) at 1.99-Å resolution. TAB2-NZF simultaneously interacts with the distal and proximal ubiquitin moieties of K6-Ub₂. By comparing the structures of TAB2-NZF in complex with K6-Ub₂ and with K63-linked diubiquitin (K63-Ub₂), we reveal that the binding mechanism of TAB2-NZF with K6-Ub₂ is similar to that with K63-Ub₂, except for the flexible C-terminal region of the distal ubiquitin. Therefore, we conclude that the C-terminal flexibility of the distal ubiquitin contributes to the dual specificity of TAB2-NZF toward K6- and K63-linked ubiquitin chains. This study provides important insights into the functions of K6-linked ubiquitin chains, which are currently unclear.     

Ubiquitin binding site of the ubiquitin E2 variant (UEV) protein Mms2 is required for DNA damage tolerance in the yeast RAD6 pathway

Different ubiquitin modifications to proliferating cell nuclear antigen (PCNA) signal distinct modes of lesion bypass in the RAD6 pathway of DNA damage tolerance. The modification of PCNA with monoubiquitin signals an error-prone bypass, whereas the extension of this modification into a Lys-63-linked polyubiquitin chain promotes error-free bypass. Chain formation is catalyzed by the Mms2/Ubc13 conjugating enzyme variant/conjugating enzyme (UEV.E2) complex together with the Rad5 ubiquitin ligase. In vitro studies of this UEV.E2 complex have identified a ubiquitin binding site that is mainly localized on Mms2. However, the role of this site in DNA damage tolerance and the molecular features of the ubiquitin/Mms2 interaction are poorly understood. Here we identify two molecular determinants, the side chains of Mms2-Ile-57 and ubiquitin-Ile-44, that are required for chain assembly in vitro and error-free lesion bypass in vivo. Mutating either of these side chains to alanine elicits a severe 10-20-fold inhibition of chain synthesis that is caused by compromised binding of the acceptor ubiquitin to Mms2. These results suggest that the ubiquitin binding site of Mms2 is necessary for error-free lesion bypass in the RAD6 pathway and provide new insights into ubiquitin recognition by UEV proteins.     

Ubiquitin lysine 63 chain forming ligases regulate apical dominance in Arabidopsis

Lys-63-linked multiubiquitin chains play important roles in signal transduction in yeast and in mammals, but the functions for this type of chain in plants remain to be defined. The RING domain protein RGLG2 (for RING domain Ligase2) from Arabidopsis thaliana can be N-terminally myristoylated and localizes to the plasma membrane. It can form Lys-63-linked multiubiquitin chains in an in vitro reaction. RGLG2 has overlapping functions with its closest sequelog, RGLG1, and single mutants in either gene are inconspicuous. rglg1 rglg2 double mutant plants exhibit loss of apical dominance and altered phyllotaxy, two traits critically influenced by the plant hormone auxin. Auxin and cytokinin levels are changed, and the plants show a decreased response to exogenously added auxin. Changes in the abundance of PIN family auxin transport proteins and synthetic lethality with a mutation in the auxin transport regulator BIG suggest that the directional flow of auxin is modulated by RGLG activity. Modification of proteins by Lys-63-linked multiubiquitin chains is thus important for hormone-regulated, basic plant architecture.     

Epidermal Growth Factor Receptor Protects Proliferating Cell Nuclear Antigen from Cullin 4A Protein-mediated Proteolysis

Proliferating cell nuclear antigen (PCNA) is an essential component for DNA synthesis upon growth stimulation. It has been shown that phosphorylation of PCNA at Tyr-211 by the EGF receptor (EGFR) protects PCNA from polyubiquitylation and degradation, whereas blocking phosphorylation induces ubiquitylation-mediated degradation of the chromatin-bound, but not the -unbound, PCNA, and suppresses cell proliferation. However, the ubiquitin E3 ligase linking growth signaling to the proteolysis of PCNA and the underlying regulatory mechanism remain to be identified. Here we show that, in the absence of Tyr-211 phosphorylation, PCNA is subject to polyubiquitylation at Lys-164 by the CUL4A E3 ligase, resulting in the degradation of PCNA. Mutation of Lys-164 to arginine prevents PCNA ubiquitylation and rescues the degradation of the K164R/Y211F PCNA double mutant. Activation of EGFR inhibits the interaction of PCNA with CUL4A, whereas inhibition of EGFR leads to increased CUL4A-PCNA interaction and CUL4A-dependent ubiquitin-mediated degradation of PCNA. Substitution of endogenous PCNA with the Y211F mutant PCNA conveys enhanced sensitization to EGFR inhibition. Our findings identify CUL4A as the ubiquitin ligase linking the down-regulation of cell surface receptor tyrosine kinase to the nuclear DNA replication machinery in cancer cells.     

Activated inositol 1,4,5-trisphosphate receptors are modified by homogeneous Lys-48- and Lys-63-linked ubiquitin chains, but only Lys-48-linked chains are required for degradation

Inositol 1,4,5-trisphosphate (IP(3)) receptors (IP(3)Rs) are large, ubiquitously expressed, endoplasmic reticulum membrane proteins that form tetrameric IP(3) and Ca(2+)-gated Ca(2+) channels. Endogenous IP(3)Rs provide very appealing tools for studying the ubiquitin-proteasome pathway in intact mammalian cells because, upon activation, they are rapidly ubiquitinated and degraded. Using mass spectrometry, we previously examined the ubiquitination of IP(3)R1 in αT3-1 pituitary gonadotrophs and found that IP(3)R1 ubiquitination is highly complex, with receptors being modified at multiple sites by monoubiquitin and polyubiquitin chains formed through both Lys-48 and Lys-63 linkages (Sliter, D. A., Kubota, K., Kirkpatrick, D. S., Alzayady, K. J., Gygi, S. P., and Wojcikiewicz, R. J. H. (2008) J. Biol. Chem. 283, 35319-35328). Here, we have extended these studies to determine whether IP(3)R2 and IP(3)R3 are similarly modified and if ubiquitination is cell type-dependent. Using mass spectrometry and linkage-specific ubiquitin antibodies, we found that all IP(3)R types are subject to ubiquitination at approximately the same locations and that, independent of cell type, IP(3)Rs are modified by monoubiquitin and Lys-48- and Lys-63-linked ubiquitin chains, although in differing proportions. Remarkably, the attached Lys-48- and Lys-63-linked ubiquitin chains are homogeneous and are segregated to separate IP(3)R subunits, and Lys-48-linked ubiquitin chains, but not Lys-63-linked chains, are required for IP(3)R degradation. Together, these data provide unique insight into the complexities of ubiquitination of an endogenous ubiquitin-proteasome pathway substrate in unperturbed mammalian cells. Importantly, although Lys-48-linked ubiquitin chains appear to trigger proteasomal degradation, the presence of Lys-63-linked ubiquitin chains suggests that ubiquitination of IP(3)Rs may have physiological consequences beyond signaling for degradation.     

Cell cycle-regulated modification of the ribosome by a variant multiubiquitin chain

Ubiquitin is ligated to L28, a component of the large ribosomal subunit, to form the most abundant ubiquitin-protein conjugate in S. cerevisiae. The human ortholog of L28 is also ubiquitinated, indicating that this modification is highly conserved in evolution. During S phase of the yeast cell cycle, L28 is strongly ubiquitinated, while reduced levels of L28 ubiquitination are observed in G1 cells. L28 ubiquitination is inhibited by a Lys63 to Arg substitution in ubiquitin, indicating that L28 is modified by a variant, Lys63-linked multiubiquitin chain. The K63R mutant of ubiquitin displays defects in ribosomal function in vivo and in vitro, including a dramatic sensitivity to translational inhibitors. L28, like other ribosomal proteins, is metabolically stable. Therefore, these data suggest a regulatory role for multiubiquitin chains that is reversible and does not function to target the acceptor protein for degradation.     

Alpha-synuclein and parkin contribute to the assembly of ubiquitin lysine 63-linked multiubiquitin chains

Mutations in alpha-synuclein, Parkin, and UCH-L1 cause heritable forms of Parkinson disease. Unlike alpha-synuclein, for which no precise biochemical function has been elucidated, Parkin functions as a ubiquitin E3 ligase, and UCH-L1 is a deubiquitinating enzyme. The E3 ligase activity of Parkin in Parkinson disease is poorly understood and is further obscured by the fact that multiubiquitin chains can be formed through distinct types of linkages that regulate diverse cellular processes. For instance, ubiquitin lysine 48-linked multiubiquitin chains target substrates to the proteasome, whereas ubiquitin lysine 63-linked chains control ribosome function, protein sorting and trafficking, and endocytosis of membrane proteins. It is notable in this regard that ubiquitin lysine 63-linked chains promote the degradation of membrane proteins by the lysosome. Because both Parkin and alpha-synuclein can regulate the activity of the dopamine transporter, we investigated whether they influenced ubiquitin lysine 63-linked chain assembly. These studies revealed novel biochemical activities for both Parkin and alpha-synuclein. We determined that Parkin functions with UbcH13/Uev1a, a dimeric ubiquitin-conjugating enzyme, to assemble ubiquitin lysine 63-linked chains. Our results and the results of others indicate that Parkin can promote both lysine 48- and lysine 63-linked ubiquitin chains. alpha-Synuclein also stimulated the assembly of lysine 63-linked ubiquitin chains. Because UCH-L1, a ubiquitin hydrolase, was recently reported to form lysine 63-linked conjugates, it is evident that three proteins that are genetically linked to Parkinson disease can contribute to lysine 63 multiubiquitin chain formation.