K. Matthew Scaglione

Certain Pairs of Ubiquitin-conjugating Enzymes (E2s) and Ubiquitin-Protein Ligases (E3s) Synthesize Nondegradable Forked Ubiquitin Chains Containing All Possible Isopeptide Linkages

It is generally assumed that a specific ubiquitin ligase (E3) links protein substrates to polyubiquitin chains containing a single type of isopeptide linkage, and that chains composed of linkages through Lys48, but not through Lys63, target proteins for proteasomal degradation. However, when we carried out a systematic analysis of the types of ubiquitin (Ub) chains formed by different purified E3s and Ub-conjugating enzymes (E2s), we found, using Ub mutants and mass spectrometry, that the U-box E3, CHIP, and Ring finger E3s, MuRF1 and Mdm2, with the E2, UbcH5, form a novel type of Ub chain that contains all seven possible linkages, but predominantly Lys48, Lys63, and Lys11 linkages. Also, these heterogeneous chains contain forks (bifurcations), where two Ub molecules are linked to the adjacent lysines at Lys6 + Lys11, Lys27 + Lys29, or Lys29 + Lys33 on the preceding Ub molecule. However, the HECT domain E3s, E6AP and Nedd4, with the same E2, UbcH5, form homogeneous chains exclusively, either Lys48 chains (E6AP) or Lys63 chains (Nedd4). Furthermore, with other families of E2s, CHIP and MuRF1 synthesize homogeneous Ub chains on the substrates. Using the dimeric E2, UbcH13/Uev1a, they attach Lys63 chains, but with UbcH1 (E2–25K), MuRF1 synthesizes Lys48 chains on the substrate. We then compared the capacity of the forked heterogeneous chains and homogeneous chains to support proteasomal degradation. When troponin I was linked by MuRF1 to a Lys48-Ub chain or, surprisingly, to a Lys63-Ub chain, troponin I was degraded rapidly by pure 26S proteasomes. However, when linked to the mixed forked chains, troponin I was degraded quite poorly, and its polyUb chain, especially the forked linkages, was disassembled slowly by proteasome-associated isopeptidases. Because these Ring finger and U-box E3s with UbcH5 target proteins for degradation in vivo, but Lys63 chains do not, cells probably contain additional factors that prevent formation of such nondegradable Ub-conjugates and that protect proteins linked to Lys63-Ub chains from proteasomal degradation.

The Deubiquitinating Enzyme Ataxin-3, a Polyglutamine Disease Protein, Edits Lys63 Linkages in Mixed Linkage Ubiquitin Chains

Ubiquitin chain complexity in cells is likely regulated by a diverse set of deubiquitinating enzymes (DUBs) with distinct ubiquitin chain preferences. Here we show that the polyglutamine disease protein, ataxin-3, binds and cleaves ubiquitin chains in a manner suggesting that it functions as a mixed linkage, chain-editing enzyme. Ataxin-3 cleaves ubiquitin chains through its amino-terminal Josephin domain and binds ubiquitin chains through a carboxyl-terminal cluster of ubiquitin interaction motifs neighboring the pathogenic polyglutamine tract. Ataxin-3 binds both Lys48- or Lys63-linked chains yet preferentially cleaves Lys63 linkages. Ataxin-3 shows even greater activity toward mixed linkage polyubiquitin, cleaving Lys63 linkages in chains that contain both Lys48 and Lys63 linkages. The ubiquitin interaction motifs regulate the specificity of this activity by restricting what can be cleaved by the protease domain, demonstrating that linkage specificity can be determined by elements outside the catalytic domain of a DUB. These findings establish ataxin-3 as a novel DUB that edits topologically complex chains.

Ubiquitination directly enhances activity of the deubiquitinating enzyme ataxin‐3

Deubiquitinating enzymes (DUBs) control the ubiquitination status of proteins in various cellular pathways. Regulation of the activity of DUBs, which is critically important to cellular homoeostasis, can be achieved at the level of gene expression, protein complex formation, or degradation. Here, we report that ubiquitination also directly regulates the activity of a DUB, ataxin‐3, a polyglutamine disease protein implicated in protein quality control pathways. Ubiquitination enhances ubiquitin (Ub) chain cleavage by ataxin‐3, but does not alter its preference for K63‐linked Ub chains. In cells, ubiquitination of endogenous ataxin‐3 increases when the proteasome is inhibited, when excess Ub is present, or when the unfolded protein response is induced, suggesting that the cellular functions of ataxin‐3 in protein quality control are modulated through ubiquitination. Ataxin‐3 is the first reported DUB in which ubiquitination directly regulates catalytic activity. We propose a new function for protein ubiquitination in regulating the activity of certain DUBs and perhaps other enzymes.

Accelerated neurodegeneration through chaperone-mediated oligomerization of tau

Aggregation of tau protein in the brain is associated with a class of neurodegenerative diseases known as tauopathies. FK506 binding protein 51 kDa (FKBP51, encoded by FKBP5) forms a mature chaperone complex with Hsp90 that prevents tau degradation. In this study, we have shown that tau levels are reduced throughout the brains of Fkbp5-/- mice. Recombinant FKBP51 and Hsp90 synergized to block tau clearance through the proteasome, resulting in tau oligomerization. Overexpression of FKBP51 in a tau transgenic mouse model revealed that FKBP51 preserved the species of tau that have been linked to Alzheimers disease (AD) pathogenesis, blocked amyloid formation, and decreased tangle load in the brain. Alterations in tau turnover and aggregate structure corresponded with enhanced neurotoxicity in mice. In human brains, FKBP51 levels increased relative to age and AD, corresponding with demethylation of the regulatory regions in the FKBP5 gene. We also found that higher FKBP51 levels were associated with AD progression. Our data support a model in which age-associated increases in FKBP51 levels and its interaction with Hsp90 promote neurotoxic tau accumulation. Strategies aimed at attenuating FKBP51 levels or its interaction with Hsp90 have the potential to be therapeutically relevant for AD and other tauopathies.

Release of Ubiquitin-Charged Cdc34-S∼Ub from the RING Domain Is Essential for Ubiquitination of the SCFCdc4-Bound Substrate Sic1

The S. cerevisiae SCF(Cdc4) is a prototype of RING-type SCF E3s, which recruit substrates for polyubiquitination by the Cdc34 ubiquitin-conjugating enzyme. Current models propose that Cdc34 ubiquitinates the substrate while remaining bound to the RING domain. In contrast, we found that the formation of a ubiquitin thiol ester regulates the Cdc34/SCF(Cdc4) binding equilibrium by increasing the dissociation rate constant, with only a minor effect on the association rate. By using a F72VCdc34 mutant with increased affinity for the RING domain, we demonstrate that release of ubiquitin-charged Cdc34-S - Ub from the RING is essential for ubiquitination of the SCF(Cdc4)-bound substrate Sic1. Release of ubiquitin-charged E2 from E3 prior to ubiquitin transfer is a previously unrecognized step in ubiquitination, which can explain both the modification of multiple lysines on the recruited substrate and the extension of polyubiquitin chains. We discuss implications of this finding for function of other ubiquitin ligases.

Activity and Cellular Functions of the Deubiquitinating Enzyme and Polyglutamine Disease Protein Ataxin-3 Are Regulated by Ubiquitination at Lysine 117

Deubiquitinating enzymes (DUbs) play important roles in many ubiquitin-dependent pathways, yet how DUbs themselves are regulated is not well understood. Here, we provide insight into the mechanism by which ubiquitination directly enhances the activity of ataxin-3, a DUb implicated in protein quality control and the disease protein in the polyglutamine neurodegenerative disorder, Spinocerebellar Ataxia Type 3. We identify Lys-117, which resides near the catalytic triad, as the primary site of ubiquitination in wild type and pathogenic ataxin-3. Further studies indicate that ubiquitin-dependent activation of ataxin-3 at Lys-117 is important for its ability to reduce high molecular weight ubiquitinated species in cells. Ubiquitination at Lys-117 also facilitates the ability of ataxin-3 to induce aggresome formation in cells. Finally, structure-function studies support a model of activation whereby ubiquitination at Lys-117 enhances ataxin-3 activity independent of the known ubiquitin-binding sites in ataxin-3, most likely through a direct conformational change in or near the catalytic domain.

Analysis of the Tau-Associated Proteome Reveals that Exchange of Hsp70 for Hsp90 Is Involved in Tau Degradation

The microtubule associated protein tau (MAPT/tau) aberrantly accumulates in 15 neurodegenerative diseases, termed tauopathies. One way to treat tauopathies may be to accelerate tau clearance, but the molecular mechanisms governing tau stability are not yet clear. We recently identified chemical probes that markedly accelerate the clearance of tau in cellular and animal models. In the current study, we used one of these probes in combination with immunoprecipitation and mass spectrometry to identify 48 proteins whose association with tau changes during the first 10 min after treatment. These proteins included known modifiers of tau proteotoxicity, such as ILF-2 (NFAT), ILF-3, and ataxin-2. A striking observation from the data set was that tau binding to heat shock protein 70 (Hsp70) decreased, whereas binding to Hsp90 significantly increased. Both chaperones have been linked to tau homeostasis, but their mechanisms have not been established. Using peptide arrays and binding assays, we found that Hsp70 and Hsp90 appeared to compete for binding to shared sites on tau. Further, the Hsp90-bound complex proved to be important in initiating tau clearance in cells. These results suggest that the relative levels of Hsp70 and Hsp90 may help determine whether tau is retained or degraded. Consistent with this model, analysis of reported microarray expression data from Alzheimers disease patients and age-matched controls showed that the levels of Hsp90 are reduced in the diseased hippocampus. These studies suggest that Hsp70 and Hsp90 work together to coordinate tau homeostasis.

Intrinsic disorder drives N-terminal ubiquitination by Ube2w

Ubiquitination of the αN-terminus of protein substrates has been reported sporadically over the past twenty years. However the identity of an enzyme responsible for this unique ubiquitin (Ub) modification has only recently been elucidated. We show the ubiquitin-conjugating enzyme (E2) Ube2w employs a novel mechanism to facilitate the specific ubiquitination of the α-amino group of its substrates that involves recognition of backbone atoms of intrinsically disordered N-termini. We present the NMR-based solution ensemble of full-length Ube2w that reveals a structural architecture unlike any other E2, in which its C-terminus is partly disordered and flexible to accommodate variable substrate N-termini. Flexibility of the substrate is critical for recognition by Ube2w and point mutations in, or removal of, the flexible C-terminus of Ube2w inhibits substrate binding and modification. Mechanistic insights reported here provide guiding principles for future efforts to define the N-terminal-Ubiquitome in cells.

A bipartite interaction between Hsp70 and CHIP regulates ubiquitination of chaperoned client proteins.

The ubiquitin ligase CHIP plays an important role in cytosolic protein quality control by ubiquitinating proteins chaperoned by Hsp70/Hsc70 and Hsp90, thereby targeting such substrate proteins for degradation. We present a 2.91 Å resolution structure of the tetratricopeptide repeat (TPR) domain of CHIP in complex with the α-helical lid subdomain and unstructured tail of Hsc70. Surprisingly, the CHIP-TPR interacts with determinants within both the Hsc70-lid subdomain and the C-terminal PTIEEVD motif of the tail, exhibiting an atypical mode of interaction between chaperones and TPR domains. We demonstrate that the interaction between CHIP and the Hsc70-lid subdomain is required for proper ubiquitination of Hsp70/Hsc70 or Hsp70/Hsc70-bound substrate proteins. Posttranslational modifications of the Hsc70 lid and tail disrupt key contacts with the CHIP-TPR and may regulate CHIP-mediated ubiquitination. Our study shows how CHIP docks onto Hsp70/Hsc70 and defines a bipartite mode of interaction between TPR domains and their binding partners.

Ubiquitin-binding site 2 of ataxin-3 prevents its proteasomal degradation by interacting with Rad23

Polyglutamine repeat expansion in ataxin-3 causes neurodegeneration in the most common dominant ataxia, Spinocerebellar Ataxia Type 3 (SCA3). Since reducing levels of disease proteins improves pathology in animals, we investigated how ataxin-3 is degraded. Here we show that, unlike most proteins, ataxin-3 turnover does not require its ubiquitination, but is regulated by Ubiquitin-Binding Site 2 (UbS2) on its N terminus. Mutating UbS2 decreases ataxin-3 protein levels in cultured mammalian cells and in Drosophila melanogaster by increasing its proteasomal turnover. Ataxin-3 interacts with the proteasome-associated proteins Rad23A/B through UbS2. Knockdown of Rad23 in cultured cells and in Drosophila results in lower levels of ataxin-3 protein. Importantly, reducing Rad23 suppresses ataxin-3-dependent degeneration in flies. We present a mechanism for ubiquitination-independent degradation that is impeded by protein interactions with proteasome-associated factors. We conclude that UbS2 is a potential target through which to enhance ataxin-3 degradation for SCA3 therapy.