Solution structure of Vps27 UIM-ubiquitin complex important for endosomal sorting and receptor downregulation

Monoubiquitylation is a well-characterized signal for the internalization and sorting of integral membrane proteins to distinct cellular organelles. Recognition and transmission of monoubiquitin signals is mediated by a variety of ubiquitin-binding motifs such as UIM, UBA, UEV, VHS and CUE in endocytic proteins. The yeast Vps27 protein requires two UIMs for efficient interactions with ubiquitin and for sorting cargo into multivesicular bodies. Here we show that the individual UIMs of Vps27 exist as autonomously folded alpha-helices that bind ubiquitin independently, non-cooperatively and with modest affinity. The Vps27 N-terminal UIM engages the Leu8-Ile44-Val70 hydrophobic patch of ubiquitin through a helical surface conserved in UIMs of diverse proteins, including that of the S5a proteasomal regulatory subunit. The Leu8-Ile44-Val70 ubiquitin surface is also the site of interaction for CUE and UBA domains in endocytic proteins, consistent with the view that ubiquitin-binding endocytic proteins act serially on the same monoubiquitylated cargo during transport from cell surface to the lysosome.     

Mechanism of ubiquitin recognition by the CUE domain of Vps9p

Coupling of ubiquitin conjugation to ER degradation (CUE) domains are approximately 50 amino acid monoubiquitin binding motifs found in proteins of trafficking and ubiquitination pathways. The 2.3 A structure of the Vps9p-CUE domain is a dimeric domain-swapped variant of the ubiquitin binding UBA domain. The 1.7 A structure of the CUE:ubiquitin complex shows that one CUE dimer binds one ubiquitin molecule. The bound CUE dimer is kinked relative to the unbound CUE dimer and wraps around ubiquitin. The CUE monomer contains two ubiquitin binding surfaces on opposite faces of the molecule that cannot bind simultaneously to a single ubiquitin molecule. Dimerization of the CUE domain allows both surfaces to contact a single ubiquitin molecule, providing a mechanism for high-affinity binding to monoubiquitin.     

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.     

Ubiquitin-binding domains and their role in the DNA damage response

The modification of eukaryotic proteins by covalent attachment of ubiquitin is a versatile signaling event with a wide range of possible consequences. Canonical poly-ubiquitination by Lys-48 linked chains usually destines a protein for degradation by the proteasome. By contrast, attachment of a single ubiquitin or ubiquitin chains linked through Lys-63 or Lys-6 serves a non-proteolytic role. Over the last years, evidence has accumulated that several nuclear proteins become ubiquitinated in response to DNA damage. Typically, these proteins carry mono-ubiquitin or non-classical ubiquitin chains and are localized close to the site of DNA damage. Of particular interest are PCNA and the variant histone H2AX, two key proteins whose ubiquitination serves to recruit factors needed by the cell to cope with the damage. A prerequisite for docking effector proteins to the site of the lesion is the detection of a specific ubiquitin modification, a process that can be mediated by a range of dedicated ubiquitin-binding domains (UBDs). As the same types of ubiquitin modification are involved in entirely different processes, the recognition of the ubiquitin mark has to go along with the recognition of the modified protein. Thus, ubiquitin-binding domains gain their specificity through combination with other recognition domains and motifs. This review discusses ubiquitin-binding domains relevant to the DNA damage response, including their binding mode, their specificity, and their interdependence with other factors. For several repair pathways, current knowledge of the events downstream of the ubiquitin mark is sketchy. A closer look at orphan UBD proteins might lead to the identification of missing pieces in the DNA response puzzle.     

Structural basis for ubiquitin-mediated dimerization and activation of the ubiquitin protein ligase Cbl-b

Cbl proteins are E3 ubiquitin ligases that are negative regulators of many receptor tyrosine kinases. Cbl-b and c-Cbl contain a ubiquitin-associated (UBA) domain, which is present in a variety of proteins involved in ubiquitin-mediated processes. Despite high sequence identity, Cbl UBA domains display remarkably different ubiquitin-binding properties. Here, we report the crystal structure of the UBA domain of Cbl-b in complex with ubiquitin at 1.9 A resolution. The structure reveals an atypical mechanism of ubiquitin recognition by the first helix of the UBA. Helices 2 and 3 of the UBA domain form a second binding surface, which mediates UBA dimerization in the crystal and in solution. Site-directed mutagenesis demonstrates that Cbl-b dimerization is regulated by ubiquitin binding and required for tyrosine phosphorylation of Cbl-b and ubiquitination of Cbl-b substrates. These studies demonstrate a role for ubiquitin in regulating biological activity by promoting protein dimerization.     

Structure of the ubiquitin-interacting motif of S5a bound to the ubiquitin-like domain of HR23B

Ubiquitination, a modification in which single or multiple ubiquitin molecules are attached to a protein, serves signaling functions that control several cellular processes. The ubiquitination signal is recognized by downstream effectors, many of which carry a ubiquitin-interacting motif (UIM). Such interactions can be modulated by regulators carrying a ubiquitin-like (UbL) domain, which binds UIM by mimicking ubiquitination. Of them, HR23B regulates the proteasomal targeting of ubiquitinated substrates, DNA repair factors, and other proteins. Here we report the structure of the UIM of the proteasome subunit S5a bound to the UbL domain of HR23B. The UbL domain presents one hydrophobic and two polar contact sites for interaction with UIM. The residues in these contact sites are well conserved in ubiquitin, but ubiquitin also presents a histidine at the interface. The pH-dependent protonation of this residue interferes with the access of ubiquitin to the UIM and the ubiquitin-associated domain (UBA), and its mutation to a smaller residue increases the affinity of ubiquitin for UIM.     

Structure of the UBA domain of Dsk2p in complex with ubiquitin molecular determinants for ubiquitin recognition

The ubiquitin-associated (UBA) domain is one of the most frequently occurring motifs that recognize ubiquitin tags. Dsk2p, a UBA-containing protein from Saccharomyces cerevisiae, is involved in the ubiquitin-proteasome proteolytic pathway and has been implicated in spindle pole duplication. Here we present the solution structure of the UBA domain of Dsk2p (Dsk2(UBA)) in complex with ubiquitin. The structure reveals that the UBA domain uses a mode of ubiquitin recognition that is similar to that of the CUE domain, another ubiquitin binding motif that shares low sequence homology but high structural similarity with UBA domains. These two domains, as well as the structurally unrelated ubiquitin binding motif UIM, provide a common, crucial recognition site for ubiquitin, comprising a hydrogen-bonding acceptor for the amide group of Gly-47, and a methyl group that packs against the hydrophobic pocket of ubiquitin formed by Leu-8, Ile-44, His-68, and Val-70.     

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.     

From UBA to UBX: new words in the ubiquitin vocabulary

Ubiquitination is a versatile tool of eukaryotic cells for controlling the stability, function and subcellular localization of proteins. The variety of cellular processes regulated by ubiquitination demands high substrate specificity of the ubiquitination machinery as well as the existence of diverse downstream effector proteins interacting with ubiquitinated substrates. Most of these cellular effectors are characterized by a modular composition of ubiquitin-binding motifs and further domains mediating specific functions. Here, I give an overview of important ubiquitin-related protein motifs, including the UBA, UIM, UBD and UBX domains, and propose a model for the role of subclasses of UBA-domain-containing proteins in ubiquitin-mediated proteolysis.     

Recognition of polyubiquitin isoforms by the multiple ubiquitin binding modules of isopeptidase T

The conjugation of polyubiquitin to target proteins acts as a signal that regulates target stability, localization, and function. Several ubiquitin binding domains have been described, and while much is known about ubiquitin binding to the isolated domains, little is known with regard to how the domains interact with polyubiquitin in the context of full-length proteins. Isopeptidase T (IsoT/USP5) is a deubiquitinating enzyme that is largely responsible for the disassembly of unanchored polyubiquitin in the cell. IsoT has four ubiquitin binding domains: a zinc finger domain (ZnF UBP), which binds the proximal ubiquitin, a UBP domain that forms the active site, and two ubiquitin-associated (UBA) domains whose roles are unknown. Here, we show that the UBA domains are involved in binding two different polyubiquitin isoforms, linear and K48-linked. Using isothermal titration calorimetry, we show that IsoT has at least four ubiquitin binding sites for both polyubiquitin isoforms. The thermodynamics of the interactions reveal that the binding is enthalpy-driven. Mutation of the UBA domains suggests that UBA1 and UBA2 domains of IsoT interact with the third and fourth ubiquitins in both polyubiquitin isoforms, respectively. These data suggest that recognition of the polyubiquitin isoforms by IsoT involves considerable conformational mobility in the polyubiquitin ligand, in the enzyme, or in both.     

Specificity of the interaction between ubiquitin-associated domains and ubiquitin

Ubiquitin-associated (UBA) domains are found in a large number of proteins with diverse functions involved in ubiquitination, DNA repair, and signaling pathways. Recent studies have shown that several UBA domain proteins interact with ubiquitin (Ub), specifically p62, the phosphotyrosine-independent ligand of the SH2 domain of p56(lck); HHR23A, a human nucleotide excision repair protein; and DDI1, another damage-inducible protein. NMR chemical shift mapping reveals that Ub binds specifically but weakly to a conserved hydrophobic epitope on HHR23A UBA(1) and UBA(2) and that the UBA domains bind on the hydrophobic patch on the surface of the five-stranded beta-sheet of Ub. Models of the UBA(1)-Ub and UBA(2)-Ub complexes obtained from de novo docking reveal different orientations of the UBA domains on the Ub surface compared with those obtained by homology modeling with the related CUE domains, which also bind Ub. Our results suggest that UBA domains may interact with Ub as well as other proteins in more than one way while utilizing the same binding surface.     

Epsins and Vps27p/Hrs contain ubiquitin-binding domains that function in receptor endocytosis

Ubiquitin functions as a signal for sorting cargo at multiple steps of the endocytic pathway and controls the activity of trans-acting components of the endocytic machinery (reviewed in refs 1, and 2). By contrast to proteasome degradation, which generally requires a polyubiquitin chain that is at least four subunits long, internalization and sorting of endocytic cargo at the late endosome are mediated by mono-ubiquitination. Here, we demonstrate that ubiquitin-interacting motifs (UIMs) found in epsins and Vps27p (ref. 9) from Saccharomyces cerevisiae are required for ubiquitin binding and protein transport. Epsin UIMs are important for the internalization of receptors into vesicles at the plasma membrane. Vps27p UIMs are necessary to sort biosynthetic and endocytic cargo into vesicles that bud into the lumen of a late endosomal compartment, the multivesicular body. We propose that mono-ubiquitin regulates internalization and endosomal sorting by interacting with modular ubiquitin-binding domains in core components of the protein transport machinery. UIM domains are found in a broad spectrum of proteins, consistent with the idea that mono-ubiquitin can function as a regulatory signal to control diverse biological activities.     

Molecular mechanisms of coupled monoubiquitination

Many proteins contain ubiquitin-binding domains or motifs (UBDs), such as the UIM (ubiquitin-interacting motif) and are referred to as ubiquitin receptors. Ubiquitin receptors themselves are frequently monoubiquitinated by a process that requires the presence of a UBD and is referred to as coupled monoubiquitination. Using a UIM-containing protein, eps15, as a model, we show here that coupled monoubiquitination strictly depends on the ability of the UIM to bind to monoubiquitin (mUb). We found that the underlying molecular mechanism is based on interaction between the UIM and a ubiquitin ligase (E3), which has itself been modified by ubiquitination. Furthermore, we demonstrate that the in vivo ubiquitination of members of the Nedd4 family of E3 ligases correlates with their ability to monoubiquitinate eps15. Thus, our results clarify the mechanism of coupled monoubiquitination and identify the ubiquitination of E3 ligases as a critical determinant in this process.     

Structural and functional analysis of ataxin-2 and ataxin-3.

Spinocerebellar ataxia types 2 (SCA2) and 3 (SCA3) are autosomal-dominantly inherited, neurodegenerative diseases caused by CAG repeat expansions in the coding regions of the genes encoding ataxin-2 and ataxin-3, respectively. To provide a rationale for further functional experiments, we explored the protein architectures of ataxin-2 and ataxin-3. Using structure-based multiple sequence alignments of homologous proteins, we investigated domains, sequence motifs, and interaction partners. Our analyses focused on presumably functional amino acids and the construction of tertiary structure models of the RNA-binding Lsm domain of ataxin-2 and the deubiquitinating Josephin domain of ataxin-3. We also speculate about distant evolutionary relationships of ubiquitin-binding UIM, GAT, UBA and CUE domains and helical ANTH and UBX domain extensions.     

Solution structure of a CUE-ubiquitin complex reveals a conserved mode of ubiquitin binding

Monoubiquitination serves as a regulatory signal in a variety of cellular processes. Monoubiquitin signals are transmitted by binding to a small but rapidly expanding class of ubiquitin binding motifs. Several of these motifs, including the CUE domain, also promote intramolecular monoubiquitination. The solution structure of a CUE domain of the yeast Cue2 protein in complex with ubiquitin reveals intermolecular interactions involving conserved hydrophobic surfaces, including the Leu8-Ile44-Val70 patch on ubiquitin. The contact surface extends beyond this patch and encompasses Lys48, a site of polyubiquitin chain formation. This suggests an occlusion mechanism for inhibiting polyubiquitin chain formation during monoubiquitin signaling. The CUE domain shares a similar overall architecture with the UBA domain, which also contains a conserved hydrophobic patch. Comparative modeling suggests that the UBA domain interacts analogously with ubiquitin. The structure of the CUE-ubiquitin complex may thus serve as a paradigm for ubiquitin recognition and signaling by ubiquitin binding proteins.     

Ubiquitin binding modulates IAP antagonist-stimulated proteasomal degradation of c-IAP1 and c-IAP2(1)

A family of anti-apoptotic regulators known as IAP (inhibitor of apoptosis) proteins interact with multiple cellular partners and inhibit apoptosis induced by a variety of stimuli. c-IAP (cellular IAP) 1 and 2 are recruited to TNFR1 (tumour necrosis factor receptor 1)-associated signalling complexes, where they mediate receptor-induced NF-kappaB (nuclear factor kappaB) activation. Additionally, through their E3 ubiquitin ligase activities, c-IAP1 and c-IAP2 promote proteasomal degradation of NIK (NF-kappaB-inducing kinase) and regulate the non-canonical NF-kappaB pathway. In the present paper, we describe a novel ubiquitin-binding domain of IAPs. The UBA (ubiquitin-associated) domain of IAPs is located between the BIR (baculovirus IAP repeat) domains and the CARD (caspase activation and recruitment domain) or the RING (really interesting new gene) domain of c-IAP1 and c-IAP2 or XIAP (X-linked IAP) respectively. The c-IAP1 UBA domain binds mono-ubiquitin and Lys(48)- and Lys(63)-linked polyubiquitin chains with low-micromolar affinities as determined by surface plasmon resonance or isothermal titration calorimetry. NMR analysis of the c-IAP1 UBA domain-ubiquitin interaction reveals that this UBA domain binds the classical hydrophobic patch surrounding Ile(44) of ubiquitin. Mutations of critical amino acid residues in the highly conserved MGF (Met-Gly-Phe) binding loop of the UBA domain completely abrogate ubiquitin binding. These mutations in the UBA domain do not overtly affect the ubiquitin ligase activity of c-IAP1 or the participation of c-IAP1 and c-IAP2 in the TNFR1 signalling complex. Treatment of cells with IAP antagonists leads to proteasomal degradation of c-IAP1 and c-IAP2. Deletion or mutation of the UBA domain decreases this degradation, probably by diminishing the interaction of the c-IAPs with the proteasome. These results suggest that ubiquitin binding may be an important mechanism for rapid turnover of auto-ubiquitinated c-IAP1 and c-IAP2.     

Structural analysis of the UBA domain of X-linked inhibitor of apoptosis protein reveals different surfaces for ubiquitin-binding and self-association

Background

Inhibitor of apoptosis proteins (IAPs) belong to a pivotal antiapoptotic protein family that plays a crucial role in tumorigenesis, cancer progression, chemoresistance and poor patient-survival. X-linked inhibitor of apoptosis protein (XIAP) is a prominent member of IAPs attracting intense research because it has been demonstrated to be a physiological inhibitor of caspases and apoptosis. Recently, an evolutionarily conserved ubiquitin-associated (UBA) domain was identified in XIAP and a number of RING domain-bearing IAPs. This has placed the IAPs in the group of ubiquitin binding proteins. Here, we explore the three-dimensional structure of the XIAP UBA domain (XIAP-UBA) and how it interacts with mono-ubiquitin and diubiquitin conjugates.

Principal Findings

The solution structure of the XIAP-UBA domain was determined by NMR spectroscopy. XIAP-UBA adopts a typical UBA domain fold of three tightly packed α-helices but with an additional N-terminal 3₁₀ helix. The XIAP-UBA binds mono-ubiquitin as well as Lys48-linked and linear-linked diubiquitins at low-micromolar affinities. NMR analysis of the XIAP-UBA–ubiquitin interaction reveals that it involves the classical hydrophobic patches surrounding Ile44 of ubiquitin and the conserved MGF/LV motif surfaces on XIAP-UBA. Furthermore, dimerization of XIAP-UBA was observed. Mapping of the self-association surface of XIAP-UBA reveals that the dimerization interface is formed by residues in the N-terminal 3₁₀ helix, helix α1 and helix α2, separate from the ubiquitin-binding surface.

Conclusion

Our results provide the first structural information of XIAP-UBA and map its interaction with mono-ubiquitin, Lys48-linked and linear-linked diubiquitins. The notion that XIAP-UBA uses different surfaces for ubiquitin-binding and self-association provides a plausible model to explain the reported selectivity of XIAP in binding polyubiquitin chains with different linkages.     

Structural basis for monoubiquitin recognition by the Ede1 UBA domain

Monoubiquitination is a general mechanism for downregulating the activity of cell surface receptors by consigning these proteins for lysosome-mediated degradation through the endocytic pathway. The yeast Ede1 protein functions at the internalization step of endocytosis and binds monoubiquitinated proteins through a ubiquitin associated (UBA) domain. UBA domains are found in a broad range of cellular proteins but previous studies have suggested that the mode of ubiquitin recognition might not be universally conserved. Here we present the solution structure of the Ede1 UBA domain in complex with monoubiquitin. The Ede1 UBA domain forms a three-helix bundle structure and binds ubiquitin through a largely hydrophobic surface in a manner reminiscent of the Dsk2 UBA and the remotely homologous Cue2 CUE domains, for which high-resolution structures have been described. However, the interaction is dissimilar to the molecular models proposed for the hHR23A UBA domains bound to either monoubiquitin or Lys48-linked diubiquitin. Our mutational analyses of the Ede1 UBA domain-ubiquitin interaction reveal several key affinity determinants and, unexpectedly, a negative affinity determinant in the wild-type Ede1 protein, implying that high-affinity interactions may not be the sole criterion for optimal function of monoubiquitin-binding endocytic proteins.     

Structural determinants for the binding of ubiquitin-like domains to the proteasome

HHR23A, a protein implicated in nucleotide excision repair, belongs to a class of proteins containing both a ubiquitin-like (Ubl) domain and one or more ubiquitin-associated (UBA) domains, suggesting a role in the ubiquitin-proteasome pathway as well. The Ubl domain binds with high affinity to the second ubiquitin-interacting motif (UIM) of the S5a subunit of the proteasome. Here we present the solution structures of the HHR23A Ubl domain, the second UIM of S5a (UIM-2), and the Ubl:S5a-UIM-2 complex. The HHR23A Ubl domain is structurally similar to ubiquitin. The S5a UIM forms an alpha-helix with an unexpected hairpin loop that contributes to the binding interface with Ubl. The molecular determinants of the Ubl-proteasome interaction are revealed by analysis of the structures, chemical shift mapping, mutant binding studies and sequence conservation.