The molecular determinants of NEDD8 specific recognition by human SENP8

Although neuronal-precursor-cell-expressed developmentally downregulated protein-8 (NEDD8) and ubiquitin share the highest level of sequence identity and structural similarity among several known ubiquitin-like proteins, their conjugation to a protein leads to distinct biological consequences. In the study, we first identified the NEDD8 protein of Chlamydomonas reinhardtii (CrNEDD8) and discovered that CrNEDD8 is fused at the C-terminus of a ubiquitin moiety (CrUb) in a head-to-tail arrangement. This CrUb-CrNEDD8 protein was termed CrRUB1 (related to ubiquitin 1) by analogy with a similar protein in Arabidopsis thaliana (AtRUB1). Since there is high sequence identity in comparison to the corresponding human proteins (97% for ubiquitin and 84% for NEDD8), a His-CrRUB1-glutathione S-transferase (GST) fusion construct was adopted as the alternative substrate to characterize the specificity of NEDD8-specific peptidase SENP8 for CrNEDD8. The data showed that SENP8 only cleaved the peptide bond beyond the di-glycine motif of CrNEDD8 and His-RUB1 was subsequently generated, confirming that SENP8 has exquisite specificity for CrNEDD8 but not CrUb. To further determine the basis of this specificity, site-directed mutagenesis at earlier reported putative molecular determinants of NEDD8 specific recognition by SENP8 was performed. We found that a single N51E mutation of CrNEDD8 completely inhibited its hydrolysis by SENP8. Conversely, a single E51N mutation of CrUb enabled this ubiquitin mutant to undergo hydrolysis by SENP8, revealing that a single residue difference at the position 51 contributes substantially to the substrate selectivity of SENP8. Moreover, the E51N/R72A double mutant of the CrUb subdomain can further increase the efficiency of cleavage by SENP8, indicating that the residue at position 72 is also important in substrate recognition. The E51N or R72A mutation of CrUb also inhibited the hydrolysis of CrUb by ubiquitin-specific peptidase USP2. However, USP2 cannot cleave the N51E/A72R double mutant of the CrNEDD8 subdomain, suggesting that USP2 requires additional recognition sites.     

Purification and characterization of arginyl-tRNA-protein transferase from rabbit reticulocytes. Its involvement in post-translational modification and degradation of acidic NH2 termini substrates of the ubiquitin pathway

Conjugation of ubiquitin to certain proteins can trigger their degradation. A major question concerns the structural features of a protein which make it susceptible to ubiquitin ligation. Recent studies have shown that the selection of proteins for degradation occurs most probably on a binding site of the ubiquitin-protein ligase (E3). It was shown that a free alpha-NH2 group is one important feature of the protein structure recognized by the ubiquitin-ligating enzyme. Proteins with basic or bulky hydrophobic residues in the NH2-terminal position are recognized by the ligase, marked by ubiquitin, and degraded. This is not true, however, for proteins with an acidic residue in this position. We have previously shown that a tRNA-dependent post-translational conjugation of arginine to acidic NH2 termini of proteins is essential for their degradation via the ubiquitin pathway, and we speculated that this modification is required for their recognition by the ligase. In the present study we have partially purified from rabbit reticulocytes the modifying enzyme, arginyl-tRNA-protein transferase, and characterized it. We have separated the enzyme from other known components of the ubiquitin system and shown that it is specifically required for degradation of proteins with either an aspartate or glutamate residue in their NH2-terminal position. We have shown that the action of the transferase is required for conjugation of ubiquitin to the substrate and most probably for its recognition by the ligase. The enzyme in its native form has a molecular mass of about 360 kDa. It appears to be a complex between several molecules of arginyl-tRNA synthetase and arginyl-tRNA-protein transferase.     

Degradation of the Id2 developmental regulator: targeting via N-terminal ubiquitination

Degradation of cellular proteins via the ubiquitin-proteasome system (UPS) involves: (i) generation of a substrate-anchored polyubiquitin degradation signal and (ii) destruction of the tagged protein by the 26S proteasome with release of free and reusable ubiquitin. For most substrates, it is believed that the first ubiquitin moiety is conjugated to a epsilon-NH(2) group of an internal Lys residue. Recent findings indicate that for several proteins, the first ubiquitin moiety is fused, in a linear manner, to the free alpha-NH(2) group of the protein. Here, we demonstrate that the inhibitor of differentiation (or inhibitor of DNA binding) 2, Id2, that downregulates gene expression in undifferentiated and self-renewing cells, is degraded by the UPS following ubiquitination at its N-terminal residue. Lysine-less (LL) Id2 is degraded efficiently by the proteasome following ubiquitination. Fusion of a Myc tag to the N-terminal but not to the C-terminal residue of Id2 stabilizes the protein. Furthermore, deletion of the first 15 N-terminal residues of Id2 stabilizes the protein, suggesting that this domain serves as a recognition element, possibly for the ubiquitin ligase, E3. The mechanisms and structural motives that govern Id2 stability may have important implications to the regulation of the protein during normal differentiation and malignant transformation.     

Structure and evolutionary conservation of the plant N‐end rule pathway

The N‐end rule relates the in vivo half‐life of a protein to the identity of its N‐terminal amino acid residue. While some N‐terminal residues result in metabolically stable proteins, other, so‐called destabilizing residues, lead to rapid protein turnover. The N‐end rule pathway, which mediates the recognition and degradation of proteins with N‐terminal destabilizing residues, is present in all organisms examined, including prokaryotes. This protein degradation pathway has a hierarchical organization in which some N‐terminal residues, called primary destabilizing residues, are directly recognized by specific ubiquitin ligases. Other destabilizing residues, termed secondary and tertiary destabilizing residues, require modifications before the corresponding proteins can be targeted for degradation by ubiquitin ligases. In eukaryotes, the N‐end rule pathway is a part of the ubiquitin/proteasome system and is known to play essential roles in a broad range of biological processes in fungi, animals and plants. While the structure of the N‐end rule pathway has been extensively studied in yeast and mammals, knowledge of its organization in plants is limited. Using both tobacco and Arabidopsis, we identified the complete sets destabilizing and stabilizing N‐terminal residues. We also characterized the hierarchical organization of the plant N‐end rule by identifying and determining the specificity of two distinct N‐terminal amidohydrolases (Nt‐amidases) of Arabidopsis that are essential for the destabilizing activity of the tertiary destabilizing residues Asn and Gln. Our results indicate that both the N‐end rule itself and mechanistic aspects of the N‐end rule pathway in angiosperms are very similar to those of mammals.     

Conformational Dynamics and Structural Plasticity Play Critical Roles in the Ubiquitin Recognition of a UIM Domain

Ubiquitin-interacting motifs (UIMs) are an important class of protein domains that interact with ubiquitin or ubiquitin-like proteins. These approximately 20-residue-long domains are found in a variety of ubiquitin receptor proteins and serve as recognition modules towards intracellular targets, which may be individual ubiquitin subunits or polyubiquitin chains attached to a variety of proteins. Previous structural studies of interactions between UIMs and ubiquitin have shown that UIMs adopt an extended structure of a single α-helix, containing a hydrophobic surface with a conserved sequence pattern that interacts with key hydrophobic residues on ubiquitin. In light of this large body of structural studies, details regarding the presence and the roles of structural dynamics and plasticity are surprisingly lacking. In order to better understand the structural basis of ubiquitin-UIM recognition, we have characterized changes in the structure and dynamics of ubiquitin upon binding of a UIM domain from the yeast Vps27 protein. The solution structure of a ubiquitin-UIM fusion protein designed to study these interactions is reported here and found to consist of a well-defined ubiquitin core and a bipartite UIM helix. Moreover, we have studied the plasticity of the docking interface, as well as global changes in ubiquitin due to UIM binding at the picoseconds-to-nanoseconds and microseconds-to-milliseconds protein motions by nuclear magnetic resonance relaxation. Changes in generalized-order parameters of amide groups show a distinct trend towards increased structural rigidity at the UIM-ubiquitin interface relative to values determined in unbound ubiquitin. Analysis of ¹⁵N Carr-Purcell-Meiboom-Gill relaxation dispersion measurements suggests the presence of two types of motions: one directly related to the UIM-binding interface and the other induced to distal parts of the protein. This study demonstrates a case where localized interactions among protein domains have global effects on protein motions at timescales ranging from picoseconds to milliseconds.     

Complex Structure of OspI and Ubc13: The Molecular Basis of Ubc13 Deamidation and Convergence of Bacterial and Host E2 Recognition

Ubc13 is an important ubiquitin-conjugating (E2) enzyme in the NF-κB signaling pathway. The Shigella effector OspI targets Ubc13 and deamidates Gln100 of Ubc13 to a glutamic acid residue, leading to the inhibition of host inflammatory responses. Here we report the crystal structure of the OspI-Ubc13 complex at 2.3 Å resolution. The structure reveals that OspI uses two differently charged regions to extensively interact with the α1 helix, L1 loop and L2 loop of Ubc13. The Gln100 residue is bound within the hydrophilic catalytic pocket of OspI. A comparison between Ubc13-bound and wild-type free OspI structures revealed that Ubc13 binding induces notable structural reassembly of the catalytic pocket, suggesting that substrate binding might be involved in the catalysis of OspI. The OspI-binding sites in Ubc13 largely overlap with the binding residues for host ubiquitin E3 ligases and a deubiquitinating enzyme, which suggests that the bacterial effector and host proteins exploit the same surface on Ubc13 for specific recognition. Biochemical results indicate that both of the differently charged regions in OspI are important for the interaction with Ubc13, and the specificity determinants in Ubc13 for OspI recognition reside in the distinct residues in the α1 helix and L2 region. Our study reveals the molecular basis of Ubc13 deamidation by OspI, as well as a convergence of E2 recognition by bacterial and host proteins.     

Ufd1 exhibits the AAA-ATPase fold with two distinct ubiquitin interaction sites

Ufd1 mediates ubiquitin fusion degradation by association with Npl4 and Cdc48/p97. The Ufd1-ubiquitin interaction is essential for transfer of substrates to the proteasome. However, the mechanism and specificity of ubiquitin recognition by Ufd1 are poorly understood due to the lack of detailed structural information. Here, we present the solution structure of yeast Ufd1 N domain and show that it has two distinct binding sites for mono- and polyubiquitin. The structure exhibits striking similarities to the Cdc48/p97 N domain. It contains the double-psi beta barrel motif, which is thus identified as a ubiquitin binding domain. Significantly, Ufd1 shows higher affinity toward polyubiquitin than monoubiquitin, attributable to the utilization of separate binding sites with different affinities. Further studies revealed that the Ufd1-ubiquitin interaction involves hydrophobic contacts similar to those in well-characterized ubiquitin binding proteins. Our results provide a structural basis for a previously proposed synergistic binding of polyubiquitin by Cdc48/p97 and Ufd1.     

The active site cysteine of ubiquitin-conjugating enzymes has a significantly elevated pKa: functional implications

Ubiquitin-conjugating enzymes (E2s or Ubcs) are essential components in the ubiquitination apparatus. These enzymes accept ubiquitin from an E1 enzyme and then, usually with the aid of an E3 enzyme, donate the ubiquitin to the target protein. The function of E2 relies critically on the chemistry of its active site cysteine residue since this residue must form a thioester bond with the carboxyl terminus of ubiquitin. Despite the plethora of structural information that is available, there has been a notable dearth of information regarding the chemical basis of E2 function. Toward filling this large void in our understanding of E2 function, we have examined the pK(a) of the active site cysteine using a combination of experimental and theoretical approaches. We find, remarkably, that the pK(a) of the active site cysteine residue is elevated by approximately 2 pH units above that of a free cysteine. We have identified residues that contribute to the increase in this pK(a). On the basis of experimental values obtained with three different E2 proteins, we believe this to be a general and important characteristic of E2 protein chemistry. Sequence comparison suggests that the electrostatic environment is maintained not through strict residue conservation but through different combinations of residues near the active site. We propose that the elevated pK(a) is a regulatory mechanism that prevents the highly exposed cysteine residue in free E2 from reacting promiscuously with electron deficient chemical moieties in the cell.     

In vivo relevance of substrate recognition function of major Arabidopsis ubiquitin receptors

Ubiquitylation marks proteins for destruction by the 26S proteasome. These signals are deciphered and targeted by distinct direct and indirect pathways involving a set of evolutionarily conserved ubiquitin receptors. Although biochemical and structural studies have revealed the mechanistic complexity of these substrate recognition pathways, conclusive evidence of the in vivo relevance of their substrate recognition function is currently not available. We recently showed that the structural elements involved in substrate recognition are not responsible for the important roles of the ubiquitin receptor RPN10 in vegetative and reproductive growth or for the abundance of the two-capped proteasomes (RP2-CP). Moreover, Arabidopsis plants subjected to severe knockdown or knockout any of the major ubiquitin receptors displayed wild-type phenotypes. Our results clearly suggest a functional redundancy of the major Arabidopsis ubiquitin receptors, and this evolved multiplicity is probably used to secure the substrates delivery. Based on the reduced abundance of RP2-CP in rpn10-2 and a role of RPN10 in lid-base association, a structural role of RPN10 in 26S proteasome stability is likely to be more relevant in vivo. Further efforts using structural and functional analyses in higher-order mutants to identify the specific biological functions of substrate recognition for the major Arabidopsis ubiquitin receptors are described here.     

N-terminal ubiquitination: more protein substrates join in

The ubiquitin-proteasome system (UPS) is involved in selective targeting of innumerable cellular proteins through a complex pathway that plays important roles in a broad array of processes. An important step in the proteolytic cascade is specific recognition of the substrate by one of many ubiquitin ligases, E3s, which is followed by generation of the polyubiquitin degradation signal. For most substrates, it is believed that the first ubiquitin moiety is conjugated, through its C-terminal Gly76 residue, to an sigma-NH2 group of an internal Lys residue. Recent findings indicate that, for several proteins, the first ubiquitin moiety is fused linearly to the alpha-NH2 group of the N-terminal residue. An important biological question relates to the evolutionary requirement for an alternative mode of ubiquitination.     

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.     

Substrate recognition of isopeptidase: specific cleavage of the epsilon-(alpha-glycyl)lysine linkage in ubiquitin-protein conjugates

The structural chromatin protein A24 (uH2A) is a conjugate of histone H2A and a non-histone protein, ubiquitin. Eukaryotic cells contain an enzyme, generically termed isopeptidase, which can cleave A24 stoichiometrically into H2A and ubiquitin in vitro. Isopeptidase, free of proteinase activity, has been partially purified from calf thymus by ion-exchange chromatography, gel filtration and affinity chromatography, and analyzed for its substate specificity. There are three major types of isopeptide bonds besides the epsilon-(alpha-glycyl)lysine bond between H2A and ubiquitin; namely, the disulfide bridge, the aldol and aldimide bonds and the epsilon-(gamma-glutamyl)lysine crosslink. Under conditions where A24 was completely cleaved into H2A and ubiquitin, none of these naturally occurring isopeptide bonds was cleaved by isopeptidase. Furthermore, the bonds formed in vitro by transglutaminase reaction between casein and putrescine, through the gamma-NH2 of glutamine residue and the NH2 of putrescine, were not cleaved by the enzyme. The enzyme also failed to cleave the glycyl-lysyl and other orthodox peptide linkages within proteins. Among various proteins examined, the substrates for isopeptidase reaction were confined to conjugates between ubiquitin and other proteins, formed through epsilon-(alpha-glycyl)lysine bonds. Since ubiquitin released by isopeptidase is re-usable for an ATP-dependent conjugation with other proteins, its carboxyl terminal -Gly-Gly-COOH most likely is preserved intact, and is not blocked. These results suggest that isopeptidase specifically recognizes and cleaves the epsilon-(alpha-glycyl)lysine bond. A possible biological significance of this enzyme is discussed.     

Gly-Gly-X, a novel consensus sequence for the proteolytic processing of viral and cellular proteins

Three African swine fever virus structural proteins of relative molecular weights 150,000, 37,000, and 34,000 (p150, p37, and p34) are derived from precursors with relative molecular weights 220,000, 60,000, and 39,000 (pp220, pp60, and pp39) by proteolytic cleavage after the second Gly residue in the sequence Gly-Gly-Ala/Gly. A search of the National Biomedical Research Foundation Data Bank revealed that several adenovirus proteins, ubiquitin, and an interferon-induced 15-kDa protein are also derived from precursors that are cleaved at the sequence Gly-Gly-X, where X is often an amino acid residue with a hydrophobic side chain. The sequence Gly-Gly-X together with other physical properties of the protein seems to be a recognition sequence for the processing of a variety of viral and cellular proteins.     

Q2N and S65D Substitutions of Ubiquitin Unravel Functional Significance of the Invariant Residues Gln2 and Ser65

Ubiquitin is a small, globular protein, structure of which has been perfected and conserved through evolution to manage diverse functions in the macromolecular metabolism of eukaryotic cells. Several non-homologous proteins interact with ubiquitin through entirely different motifs. Though the roles of lysines in the multifaceted functions of ubiquitin are well documented, very little is known about the contribution of other residues. In the present study, the importance of two invariant residues, Gln2 and Ser65, have been examined by substituting them with Asn and Asp, respectively, generating single residue variants of ubiquitin UbQ2N and UbS65D. Gln2 and Ser65 form part of parallel G1 β-bulge adjacent to Lys63, a residue involved in DNA repair, cell-cycle regulated protein synthesis and imparting resistance to protein synthesis inhibitors. The secondary structure of variants is similar to that of UbF45W, a structural homologue of wild-type ubiquitin (UbWt). However, there are certain functional differences observed in terms of resistance to cycloheximide, while there are no major differences pertaining to growth under normal conditions, adherence to N-end rule and survival under heat stress. Further, expression of UbQ2N impedes protein degradation by ubiquitin fusion degradation (UFD) pathway. Such differential responses with respect to functions of ubiquitin produced by mutations may be due to interference in the interactions of ubiquitin with selected partner proteins, hint at biomedical implications.     

Post-translational addition of an arginine moiety to acidic NH2 termini of proteins is required for their recognition by ubiquitin-protein ligase

Recent studies have shown that selection of proteins for degradation by the ubiquitin system occurs most probably by binding to specific sites of the ubiquitin-protein ligase, E3. A free alpha-NH2 residue of the substrate is one important determinant recognized by the ligase. Selective binding sites have been described for basic and bulky-hydrophobic NH2 termini (Reiss, Y., Kaim, D., and Hershko, A. (1988) J. Biol. Chem. 263, 2693-2698) and for alanine, serine, and threonine at the NH2-terminal position (Gonda, D. K., Bachmair, A., Wünning, I., Tobias, J. W., Lane, W. S., and Varshavsky, A. (1989) J. Biol. Chem. 264, 16700-16712). Proteins with acidic NH2-terminal residues are degraded by the ubiquitin system only following conversion of the acidic residue to a basic residue by the addition of an arginine moiety (Ferber, S., and Ciechanover, A. (1987) Nature 326, 808-811). Although the enzymes involved in this post-translational modification have been characterized, the underlying mechanism has been obscure. By using a chemical cross-linking technique, we demonstrate that proteins with acidic NH2 termini do not bind to E3 without prior modification of this residue by the addition of arginine. In contrast, proteins with a basic NH2-terminal residue bind to the ligase without any modification. The recognition of acidic NH2-terminal substrates by E3 is dependent upon the addition of all the components of the modifying machinery, arginyl-tRNA-protein transferase, arginyl-tRNA synthetase, tRNA, and arginine. The ligase-bound modified proteins are converted to ubiquitin conjugates in a "pulse-chase" experiment, indicating that the binding is functional and that the enzyme-substrate complex is an obligatory intermediate in the conjugation process. Chemical modification of the carboxyl groups, which results in their neutralization, generates substrates that bind to E3 without modification. This finding suggests that the amino-terminal binding site of E3 is negatively charged, and only positively charged amino-terminal residues may bind to it. Negatively charged (acidic) NH2-terminal residues will bind only following neutralization or reversal of the charge.     

Affinity makes the difference: nonselective interaction of the UBA domain of Ubiquilin-1 with monomeric ubiquitin and polyubiquitin chains

Ubiquilin/PLIC proteins belong to the family of UBL-UBA proteins implicated in the regulation of the ubiquitin-dependent proteasomal degradation of cellular proteins. A human presenilin-interacting protein, ubiquilin-1, has been suggested as potential therapeutic target for treating Huntington's disease. Ubiquilin's interactions with mono- and polyubiquitins are mediated by its UBA domain, which is one of the tightest ubiquitin binders among known ubiquitin-binding domains. Here we report the three-dimensional structure of the UBA domain of ubiquilin-1 (UQ1-UBA) free in solution and in complex with ubiquitin. UQ1-UBA forms a compact three-helix bundle structurally similar to other known UBAs, and binds to the hydrophobic patch on ubiquitin with a K_d of 20 μM. To gain structural insights into UQ1-UBA's interactions with polyubiquitin chains, we have mapped the binding interface between UQ1-UBA and Lys48- and Lys63-linked di-ubiquitins and characterized the strength of UQ1-UBA binding to these chains. Our NMR data show that UQ1-UBA interacts with the individual ubiquitin units in both chains in a mode similar to its interaction with mono-ubiquitin, although with an improved binding affinity for the chains. Our results indicate that, in contrast to UBA2 of hHR23A that has strong binding preference for Lys48-linked chains, UQ1-UBA shows little or no binding selectivity toward a particular chain linkage or between the two ubiquitin moieties in the same chain. The structural data obtained in this study provide insights into the possible structural reasons for the diversity of polyubiquitin chain recognition by UBA domains.     

A novel type of deubiquitinating enzyme

A previous report from this laboratory described two novel proteins that have sequence similarity to A20, a negative regulator of NF-kappaB (Evans, P. C., Taylor, E. R., Coadwell, J., Heyninck, K., Beyaert, R., and Kilshaw, P. J. (2001) Biochem. J. 357, 617-623). One of these molecules, cellular zinc finger anti-NF-kappaB (Cezanne), a 100-kDa cytoplasmic protein, also suppressed NF-kappaB. Here we demonstrate that Cezanne is a novel deubiquitinating enzyme, distinct from the two known families of deubiquitinases, Types I and II. We show that Cezanne contains an N-terminal catalytic domain that belongs to the recently discovered ovarian tumor protein (OTU) superfamily, a group of proteins displaying structural similarity to cysteine proteases but having no previously described function. Recombinant Cezanne cleaved ubiquitin monomers from linear or branched synthetic ubiquitin chains and from ubiquitinated proteins. Mutation of a conserved cysteine residue in the catalytic site of the proteolytic domain caused Cezanne to co-precipitate polyubiquitinated cellular proteins. We also provide evidence for an additional ubiquitin binding site in the C-terminal part of the molecule. Our data provide the first demonstration of functional activity among OTU proteins.     

Homologs of the essential ubiquitin conjugating enzymes UBC1, 4, and 5 in yeast are encoded by a multigene family in Arabidopsis thaliana

The covalent attachment of the 76 amino acid protein ubiquitin is an important prerequisite for the degradation of many eukaryotic proteins. The specificity of this ligation is accomplished in part by a family of distinct ubiquitin conjugating enzymes (E2s) working in concert with specific ubiquitin-protein ligases (E3s). Three essential E2s in yeast encoded by ScUBC1, −4 , and − 5 comprise a functionally overlapping E2 subfamily that appears responsible for degrading most abnormal and short-lived proteins. A 15 kDa E2 protein homologous to this family has been identified previously in wheat germ, designated Ta E2_15kDa (Girod and Vierstra (1993) J. Biol. Chem. 268, 955–960). This E2 is responsible for much of the ubiquitin conjugating activity observed in wheat germ extracts and works together with a unique E3 (designated E3γ) for substrate recognition. In this paper, the cloning of five genes encoding E2_15kDa from Arabidiopsis thaliana is described (designated AtUBC8—12 ). They encode 149 amino acid basic proteins 94–98% similar to each other and 88–92% similar to ScUBC4 at the amino acid sequence level. In contrast, AtUBC8—12 are only 55–65% similar to the Arabidopsis E2s encoded by AtUBC1, −4, and − 7 . The At UBC8—12 proteins do not contain N- or C-terminal extensions and have the active site at residue Cys-86, based on their homology with other E2s. Analyses of genomic Southern blots are consistent with the existence of multiple members encoding this E2 subfamily. AtUBC8—12 are transcribed to yield about 800 nucleotide mRNAs that, unlike ScUBC4 and − 5 , are not strongly induced by heat shock. Expression of AtUBC8 in Escherichia coli results in substantial production of functional E2_15kDa that works together with wheat E3γ in conjugating ubiquitin to endogenous or added substrates in vitro .     

Structural basis for E2-mediated SUMO conjugation revealed by a complex between ubiquitin-conjugating enzyme Ubc9 and RanGAP1

E2 enzymes catalyze attachment of ubiquitin and ubiquitin-like proteins to lysine residues directly or through E3-mediated reactions. The small ubiquitin-like modifier SUMO regulates nuclear transport, stress response, and signal transduction in eukaryotes and is essential for cell-cycle progression in yeast. In contrast to most ubiquitin conjugation, the SUMO E2 enzyme Ubc9 is sufficient for substrate recognition and lysine modification of known SUMO targets. Crystallographic analysis of a complex between mammalian Ubc9 and a C-terminal domain of RanGAP1 at 2.5 A reveals structural determinants for recognition of consensus SUMO modification sequences found within SUMO-conjugated proteins. Structure-based mutagenesis and biochemical analysis of Ubc9 and RanGAP1 reveal distinct motifs required for substrate binding and SUMO modification of p53, IkappaBalpha, and RanGAP1.     

Interaction of the tail with the catalytic region of a class II E2 conjugating enzyme

Ubiquitination plays an important role in many biological processes, including DNA repair, cell cycle regulation, and protein degradation. In the latter pathway the ubiquitin-conjugating enzymes or E2 enzymes are important proteins forming a key E2-ubiquitin thiolester prior to substrate labelling. While the structure of the 150-residue catalytic domain has been well characterized, a subset of E2 enzymes (class II) carry a variable length C-terminal `tail' where structural detail is not available. The presence of this C-terminal extension plays an important role in target recognition, ubiquitin chain assembly and oligomerization. In this work NMR spectroscopy was used to determine the secondary structure of the 215-residue yeast E2 protein Ubc1 and the interactions of its C-terminus with the catalytic domain. The C-terminal tail of Ubc1 was found to contain three -helices between residues D169-S176, K183-L193 and N203-L213 providing the first evidence for a well-defined secondary structure in this region. Chemical shift mapping indicated that residues in the L2 loop of the catalytic domain were most affected indicating the C-terminus of Ubc1 likely interacts with this region. This site of interaction is distinct from that observed in the E2-ubiquitin thiolester and may act to protect the catalytic C88 residue and direct the interaction of ubiquitin in the thiolester intermediate.