Ubiquitin enters the new millennium.

The latest advances in ubiquitin-mediated signaling were discussed at a recent FASEB meeting in Vermont. New findings show that besides signaling proteolysis, ubiquitination can be a signal for trafficking, kinase activation, and other nonproteolytic fates.

Molecular insights into polyubiquitin chain assembly: crystal structure of the Mms2/Ubc13 heterodimer.

While the signaling properties of ubiquitin depend on the topology of polyubiquitin chains, little is known concerning the molecular basis of specificity in chain assembly and recognition. UEV/Ubc complexes have been implicated in the assembly of Lys63-linked polyubiquitin chains that act as a novel signal in postreplicative DNA repair and I kappa B alpha kinase activation. The crystal structure of the Mms2/Ubc13 heterodimer shows the active site of Ubc13 at the intersection of two channels that are potential binding sites for the two substrate ubiquitins. Mutations that destabilize the heterodimer interface confer a marked UV sensitivity, providing direct evidence that the intact heterodimer is necessary for DNA repair. Selective mutations in the channels suggest a molecular model for specificity in the assembly of Lys63-linked polyubiquitin signals.

Mechanisms underlying ubiquitination.

The conjugation of ubiquitin to other cellular proteins regulates a broad range of eukaryotic cell functions. The high efficiency and exquisite selectivity of ubiquitination reactions reflect the properties of enzymes known as ubiquitin-protein ligases or E3s. An E3 recognizes its substrates based on the presence of a specific ubiquitination signal, and catalyzes the formation of an isopeptide bond between a substrate (or ubiquitin) lysine residue and the C terminus of ubiquitin. Although a great deal is known about the molecular basis of E3 specificity, much less is known about molecular mechanisms of catalysis by E3s. Recent findings reveal that all known E3s utilize one of just two catalytic domains--a HECT domain or a RING finger--and crystal structures have provided the first detailed views of an active site of each type. The new findings shed light on many aspects of E3 structure, function, and mechanism, but also emphasize that key features of E3 catalysis remain to be elucidated.

Distinct functional surface regions on ubiquitin.

The characterized functions of the highly conserved polypeptide ubiquitin are to target proteins for proteasome degradation or endocytosis. The formation of a polyubiquitin chain of at least four units is required for efficient proteasome binding. By contrast, monoubiquitin serves as a signal for the endocytosis of plasma membrane proteins. We have defined surface residues that are important for ubiquitin's vital functions in Saccharomyces cerevisiae. Surprisingly, alanine scanning mutagenesis showed that only 16 of ubiquitin's 63 surface residues are essential for vegetative growth in yeast. Most of the essential residues localize to two hydrophobic clusters that participate in proteasome recognition and/or endocytosis. The others reside in or near the tail region, which is important for conjugation and deubiquitination. We also demonstrate that the essential residues comprise two distinct functional surfaces: residues surrounding Phe(4) are required for endocytosis, whereas residues surrounding Ile(44) are required for both endocytosis and proteasome degradation.

In vitro assembly and recognition of Lys-63 polyubiquitin chains.

Polyubiquitin chains assembled through lysine 48 (Lys-48) of ubiquitin act as a signal for substrate proteolysis by 26 S proteasomes, whereas chains assembled through Lys-63 play a mechanistically undefined role in post-replicative DNA repair. We showed previously that the products of the UBC13 and MMS2 genes function in error-free post-replicative DNA repair in the yeast Saccharomyces cerevisiae and form a complex that assembles Lys-63-linked polyubiquitin chains in vitro. Here we confirm that the Mms2.Ubc13 complex functions as a high affinity heterodimer in the chain assembly reaction in vitro and report the results of a kinetic characterization of the polyubiquitin chain assembly reaction. To test whether a Lys-63-linked polyubiquitin chain can signal degradation, we conjugated Lys-63-linked tetra-ubiquitin to a model substrate of 26 S proteasomes. Although the noncanonical chain effectively signaled substrate degradation, the results of new genetic epistasis studies agree with previous genetic data in suggesting that the proteolytic activity of proteasomes is not required for error-free post-replicative repair.

A HECT domain E3 enzyme assembles novel polyubiquitin chains.

Although polyubiquitin chains linked through Lys(29) of ubiquitin have been implicated in the targeting of certain substrates to proteasomes, the signaling properties of these chains are poorly understood. We previously described a ubiquitin-protein isopeptide ligase (E3) from erythroid cells that assembles polyubiquitin chains through either Lys(29) or Lys(48) of ubiquitin (Mastrandrea, L. D., You, J., Niles, E. G., and Pickart, C. M. (1999) J. Biol. Chem. 274, 27299-27306). Here we describe the purification of this E3 based on its affinity for a linear fusion of ubiquitin to the ubiquitin-conjugating enzyme UbcH5A. Among five major polypeptides in the affinity column eluate, the activity of interest was assigned to the product of a previously cloned human cDNA known as KIAA10 (Nomura, N., Miyajima, N., Sazuka, T., Tanaka, A., Kawarabayasi, Y., Sato, S., Nagase, T., Seki, N., Ishikawa, K., and Tabata, S. (1994) DNA Res. 1, 27-35). The KIAA10 protein is a member of the HECT (homologous to E6-AP carboxyl terminus) domain family of E3s. These E3s share a conserved C-terminal (HECT) domain that functions in the catalysis of ubiquitination, while their divergent N-terminal domains function in cognate substrate binding (Huibregtse, J. M., Scheffner, M., Beaudenon, S., and Howley, P. M. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 2563-2567). Recombinant KIAA10 catalyzed the assembly of both Lys(29)- and Lys(48)-linked polyubiquitin chains. Surprisingly, the C-terminal 428 residues of KIAA10 were both necessary and sufficient for this activity, suggesting that the ability to assemble polyubiquitin chains may be a general property of HECT domains. The N-terminal domain of KIAA10 interacted in vitro with purified 26 S proteasomes and with the isolated S2/Rpn1 subunit of the proteasome's 19 S regulatory complex, suggesting that the N-terminal domains of HECT E3s may function in proteasome binding as well as substrate binding.

Structure of a new crystal form of tetraubiquitin.

Polyubiquitin chains, in which the C-terminus and a lysine side chain of successive ubiquitin molecules are linked by an isopeptide bond, function to target substrate proteins for degradation by the 26S proteasome. Chains of at least four ubiquitin moieties appear to be required for efficient recognition by the 26S proteasome, although the conformations of the polyubiquitin chains recognized by the proteasome or by other enzymes involved in ubiquitin metabolism are currently unknown. A new crystal form of tetraubiquitin, which has two possible chain connectivities that are indistinguishable in the crystal, is reported. In one possible connectivity, the tetraubiquitin chain is extended and packs closely against the antiparallel neighbor chain in the crystal to conceal a hydrophobic surface implicated in 26S proteasome recognition. In the second possibility, the tetraubiqutitin forms a closed compact structure, in which that same hydrophobic surface is buried. Both of these conformations are quite unlike the structure of tetraubiquitin that was previously determined in a different crystal form [Cook et al. (1994), J. Mol. Biol. 236, 601--609]. The new structure suggests that polyubiquitin chains may possess a substantially greater degree of conformational flexibility than has previously been appreciated.

Ubiquitin in chains.

The ubiquitin-proteasome system fulfills an essential function in eukaryotes by controlling the levels of crucial intracellular regulatory proteins. In this system, a specific type of polyubiquitin chain acts as the proximal signal for targeting substrates to 26S proteasomes for degradation. Recent results have revealed important determinants of polyubiquitin-chain recognition by proteasomes, helping to explain the biological rationale behind this novel signaling mechanism.

Ubiquitin biology: an old dog learns an old trick.

Regulated protein degradation in eukaryotes occurs principally through covalent tagging of substrates with ubiquitin, thereby targeting them for destruction by 26S proteasomes. Classical allostery has now been added to the repertoire of mechanisms that can modulate ubiquitin tagging, allowing feed-forward regulation to be achieved through targeted protein destruction.

Dihydroorotate dehydrogenase from Clostridium oroticum is a class 1B enzyme and utilizes a concerted mechanism of catalysis.

Dihydroorotate dehydrogenase from Clostridium oroticum was purified to apparent homogeneity and found to be a heterotetramer consisting of two alpha (32 kDa) and two beta (28 kDa) polypeptides. This subunit composition, coupled with known cofactor requirements and the ability to transfer electrons from L-dihydroorotate to NAD(+), defines the C. oroticum enzyme as a family 1B dihydroorotate dehydrogenase. The results of steady-state kinetic analyses and isotope exchange studies suggest that this enzyme utilizes a ping-pong steady-state kinetic mechanism. The pH-k(cat) profile is bell-shaped with a pK(a) of 6.4 +/- 0.1 for the ascending limb and 8. 9 +/- 0.1 for the descending limb; the pH-k(cat)/K(m) profile is similar but somewhat more complex. The pK(a) values of 6.4 and 8.9 are likely to represent the ionizations of cysteine and lysine residues in the active site which act as a general base and an electrostatic catalyst, respectively. At saturating levels of NAD(+), the isotope effects on (D)V and (D)(V/K(DHO)), obtained upon deuteration at both the C(5)-proR and C(5)-proS positions of L-dihydroorotate, increase from a value of unity at pH >9.0 to sizable values at low pH due to a high commitment to catalysis at high pH. At pH = 6.5, the magnitude of the double isotope effects (D)V and (D)(V/K(DHO)), obtained upon additional deuteration at C(6), is consistent with a mechanism in which C(5)-proS proton transfer and C(6)-hydride transfer occur in a single, partially rate-limiting step.

Inhibition of the ubiquitin-proteasome system in Alzheimer's disease.

Alzheimer's disease is the most common cause of dementia in the elderly. Although several genetic defects have been identified in patients with a family history of this disease, the majority of cases involve individuals with no known genetic predisposition. A mutant form of ubiquitin, termed Ub(+1), has been selectively observed in the brains of Alzheimer's patients, including those with nonfamilial Alzheimer's disease, but it has been unclear why Ub(+1) expression should be deleterious. Here we show that Ub(+1) is an efficient substrate for polyubiquitination in vitro and in transfected human cells. The resulting polyubiquitin chains are refractory to disassembly by deubiquitinating enzymes and potently inhibit the degradation of a polyubiquitinated substrate by purified 26S proteasomes. Thus, expression of Ub(+1) in aging brain could result in dominant inhibition of the Ub-proteasome system, leading to neuropathologic consequences.

Recognition of the polyubiquitin proteolytic signal.

Polyubiquitin chains linked through Lys48 are the principal signal for targeting substrates to the 26S proteasome. Through studies of structurally defined, polyubiquitylated model substrates, we show that tetraubiquitin is the minimum signal for efficient proteasomal targeting. The mechanism of targeting involves a simple increase in substrate affinity that is brought about by autonomous binding of the polyubiquitin chain. Assigning the proteasomal signaling function to a specific polymeric unit explains how a single ubiquitin can act as a functionally distinct signal, for example in endocytosis. The properties of the substrates studied here implicate substrate unfolding as a kinetically dominant step in the proteolysis of properly folded proteins, and suggest that extraproteasomal chaperones are required for efficient degradation of certain proteasome substrates.

Construct for high-level expression and low misincorporation of lysine for arginine during expression of pET-encoded eukaryotic proteins in Escherichia coli.

The arginine codon AGA is rarely used in E. coli but is common in eukaryotic genes. Prior studies have shown that the low level of tRNA(UCUArg) can lead to low expression and misincorporation of lysine for arginine, during expression of genes containing AGA codons in E. coli. The chloramphenicol-selectable plasmid pJY2 is designed to facilitate the expression of such genes cloned into pET vectors: it encodes T7 lysozyme (to depress constitutive expression of the cloned gene) and tRNA(UCUArg) (to suppress lysine misincorporation at AGA codons). Using pJY2, we observed robust and translationally faithful expression of mutant ubiquitin genes in which 14% (11 out of 76) of the total codons were AGA. Competent BL21(DE3)pJY2 cells can be used to suppress lysine misincorporation and achieve high-level expression of pET-encoded target genes without modification of AGA codons in the target gene sequence.

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.

Noncanonical MMS2-encoded ubiquitin-conjugating enzyme functions in assembly of novel polyubiquitin chains for DNA repair.

Ubiquitin-conjugating enzyme variant (UEV) proteins resemble ubiquitin-conjugating enzymes (E2s) but lack the defining E2 active-site residue. The MMS2-encoded UEV protein has been genetically implicated in error-free postreplicative DNA repair in Saccharomyces cerevisiae. We show that Mms2p forms a specific heteromeric complex with the UBC13-encoded E2 and is required for the Ubc13p-dependent assembly of polyubiquitin chains linked through lysine 63. A ubc13 yeast strain is UV sensitive, and single, double, and triple mutants of the UBC13, MMS2, and ubiquitin (ubiK63R) genes display a comparable phenotype. These findings support a model in which an Mms2p/Ubc13p complex assembles novel polyubiquitin chains for signaling in DNA repair, and they suggest that UEV proteins may act to increase diversity and selectivity in ubiquitin conjugation.

Crystal structure of the human ubiquitin-like protein NEDD8 and interactions with ubiquitin pathway enzymes.

The NEDD8/Rub1 class of ubiquitin-like proteins has been implicated in progression of the cell cycle from G1 into S phase. These molecules undergo a metabolism that parallels that of ubiquitin and involves specific interactions with many different proteins. We report here the crystal structure of recombinant human NEDD8 refined at 1.6-A resolution to an R factor of 21.9%. As expected from the high sequence similarity (57% identical), the NEDD8 structure closely resembles that reported previously for ubiquitin. We also show that recombinant human NEDD8 protein is activated, albeit inefficiently, by the ubiquitin-activating (E1) enzyme and that NEDD8 can be transferred from E1 to the ubiquitin conjugating enzyme E2-25K. E2-25K adds NEDD8 to a polyubiquitin chain with an efficiency similar to that of ubiquitin. A chimeric tetramer composed of three ubiquitins and one histidine-tagged NEDD8 binds to the 26 S proteasome with an affinity similar to that of tetraubiquitin. Seven residues that differ from the corresponding residues in ubiquitin, but are conserved between NEDD8 orthologs, are candidates for mediating interactions with NEDD8-specific partners. One such residue, Ala-72 (Arg in ubiquitin), is shown to perform a key role in selecting against reaction with the ubiquitin E1 enzyme, thereby acting to prevent the inappropriate diversion of NEDD8 into ubiquitin-specific pathways.

Core domain mutation (S86Y) selectively inactivates polyubiquitin chain synthesis catalyzed by E2-25K.

The mammalian ubiquitin conjugating enzyme known as E2-25K catalyzes the synthesis of polyubiquitin chains linked exclusively through K48-G76 isopeptide bonds. The properties of truncated and chimeric forms of E2-25K suggest that the polyubiquitin chain synthesis activity of this E2 depends on specific interactions between its conserved 150-residue core domain and its unique 50-residue tail domain [Haldeman, M. T., Xia, G., Kasperek, E. M., and Pickart, C. M. (1997) Biochemistry 36, 10526-10537]. In the present study, we provide strong support for this model by showing that a point mutation in the core domain (S86Y) mimics the effect of deleting the entire tail domain: the ability to form an E2 approximately ubiquitin thiol ester is intact, while conjugation activity is severely inhibited (>/=100-fold reduction in kcat/Km). The properties of E2-25K enzymes carrying the S86Y mutation indicate that this mutation strengthens the interaction between the core and tail domains: both free and ubiquitin-bound forms of S86Y-25K are completely resistant to tryptic cleavage at K164 in the tail domain, whereas wild-type enzyme is rapidly cleaved at this site. Other properties of S86Y-26K suggest that the active site of this mutant enzyme is more occluded than the active site of the wild-type enzyme. (1) Free S86Y-25K is alkylated by iodoacetamide 2-fold more slowly than the wild-type enzyme. (2) In assays of E2 approximately ubiquitin thiol ester formation, S86Y-25K shows a 4-fold reduced affinity for E1. (3) The ubiquitin thiol ester adduct of S86Y-25K undergoes (uncatalyzed) reaction with dithiothreitol 3-fold more slowly than the wild-type thiol ester adduct. One model to accommodate these findings postulates that an enhanced interaction between the core and tail domains, induced by the S86Y mutation, causes a steric blockade at the active site which prevents access of the incoming ubiquitin acceptor to the thiol ester bond. Consistent with this model, the S86Y mutation inhibits ubiquitin transfer to macromolecular acceptors (ubiquitin and polylysine) more strongly than transfer to small-molecule acceptors (free lysine and short peptides). These results suggest that unique residues proximal to E2 active sites may influence specific function by mediating intramolecular interactions.

The hydrophobic effect contributes to polyubiquitin chain recognition.

The principal targeting signal used in the ubiquitin-proteasome degradation pathway is a homopolymeric, K48-linked polyubiquitin chain: the chain is recognized by a specific factor(s) in the 19S regulatory complex of the 26S proteasome, while the substrate is degraded by the 20S catalytic complex. We have previously presented evidence implicating the side chains of L8, I44, and V70 in the recognition of K48-linked chains. In the crystal structure of tetraubiquitin, these side chains form a repeating, surface-exposed hydrophobic patch. To test the hypothesis that a close-packing interaction involving this patch is important for the chain recognition, residue 8 was mutated to a series of smaller aliphatic amino acids (G, A, V). The effects of these mutations were first investigated in rabbit reticulocyte fraction II; even the severest truncating mutation (L8G) had only a modest inhibitory effect on the degradation of a model substrate (125I-lactalbumin). We show that these steady-state degradation data substantially underestimate the deleterious effects of these mutations on chain recognition by the proteasome, because the recognition step does not contribute to rate limitation in the fraction II system. Much stronger inhibition was observed when chain binding was measured in a competition assay using purified 26S proteasomes, and the change in binding free energy depended linearly on the surface area of the side chain. This behavior is consistent with a mode of binding in which the hydrophobic effect makes a favorable contribution; i.e., one or more L8 side chains is shielded from solvent when the chain binds to the 19S complex. A similar linear dependence of binding energy on side chain area was observed for chain binding to the 19S subunit known as S5a (as assayed using recombinant S5a bound to nickel beads). Octa-ubiquitin (K0.5 = 1.6 microM) bound to S5a 4.2-fold more tightly than tetra-ubiquitin; this is similar to the factor of 5. 8-fold relating the affinities of the same two chains for the 26S proteasome. Altogether, these findings indicate that the interaction of K48-linked chains with the 19S complex is substantially similar to the interaction of chains with isolated S5a. The results further suggest that the hydrophobic patch is part of a minimum element which allows for specific recognition of the polyubiquitin degradation signal by the 26S proteasome.

Characterization of two polyubiquitin binding sites in the 26 S protease subunit 5a.

Ubiquitylated proteins are degraded by the 26 S protease, an enzyme complex that contains 30 or more unique subunits. One of these proteins, subunit 5a (S5a), has been shown to bind ubiquitin-lysozyme conjugates and free polyubiquitin chains. Using deletional analysis, we have identified in the carboxyl-terminal half of human S5a, two independent polyubiquitin binding sites whose sequences are highly conserved among higher eukaryotic S5a homologs. The sites are approximately 30-amino acids long and are separated by 50 intervening residues. When expressed as small fragments or when present in full-length S5a molecules, the sites differ at least 10-fold in their apparent affinity for polyubiquitin chains. Each binding site contains 5 hydrophobic residues that form an alternating pattern of large and small side chains, e.g. Leu-Ala-Leu-Ala-Leu, and this pattern is essential for binding ubiquitin chains. Based on the importance of the alternating hydrophobic residues in the binding sites and previous studies showing that a hydrophobic patch on the surface of ubiquitin is essential for proteolytic targeting, we propose a model for molecular recognition of polyubiquitin chains by S5a.