In vitro ubiquitination of cyclin D1 by ROC1-CUL1 and ROC1-CUL3

Overexpression of cyclin D1 has been implicated in a variety of tumors, such as breast cancers, gastrointestinal cancers and lymphomas. Both gene amplification and protein degradation mediated by ubiquitin (Ub)-dependent proteolysis regulate the abundance of cyclin D1. Here we report that ROC1 interacted with all three D type cyclins in vivo but did not bind to other cyclins tested. The ROC1-CUL1 and ROC1-CUL3, but not ROC1-CUL2, -CUL3 and -CUL4, immunocomplexes promoted polyubiquitination of bacterially purified cyclin D1 in vitro. RING finger mutations of ROC1 eliminated the Ub ligase activity toward cyclin D1. In all cases the ubiquitination of cyclin D1 was accompanied by autoubiquitination of the cullins. The results suggest the involvement of ROC1-cullin ligases in cyclin D1 ubiquitination and a potential mechanism whereby the cullin subunit is ubiquitinated itself while ubiquitinating a substrate.     

Targeted ubiquitination of CDT1 by the DDB1-CUL4A-ROC1 ligase in response to DNA damage

Cullins assemble a potentially large number of ubiquitin ligases by binding to the RING protein ROC1 to catalyse polyubiquitination, as well as binding to various specificity factors to recruit substrates. The Cul4A gene is amplified in human breast and liver cancers, and loss-of-function of Cul4 results in the accumulation of the replication licensing factor CDT1 in Caenorhabditis elegans embryos and ultraviolet (UV)-irradiated human cells. Here, we report that human UV-damaged DNA-binding protein DDB1 associates stoichiometrically with CUL4A in vivo, and binds to an amino-terminal region in CUL4A in a manner analogous to SKP1, SOCS and BTB binding to CUL1, CUL2 and CUL3, respectively. As with SKP1-CUL1, the DDB1-CUL4A association is negatively regulated by the cullin-associated and neddylation-dissociated protein, CAND1. Recombinant DDB1 and CDT1 bind directly to each other in vitro, and ectopically expressed DDB1 bridges CDT1 to CUL4A in vivo. Silencing DDB1 prevented UV-induced rapid CDT1 degradation in vivo and CUL4A-mediated CDT1 ubiquitination in vitro. We suggest that DDB1 targets CDT1 for ubiquitination by a CUL4A-dependent ubiquitin ligase, CDL4A(DDB1), in response to UV irradiation.     

Differential phosphorylation of the signal-responsive domain of I kappa B alpha and I kappa B beta by I kappa B kinases

NF-kappa B activity is regulated by its association with the inhibitory I kappa B proteins, among which I kappa B alpha and I kappa B beta are the most abundant. I kappa B proteins are widely expressed in different cells and tissues and bind to similar combinations of NF-kappa B proteins. The degradation of I kappa B proteins allows nuclear translocation of NF-kappa B and hence plays a critical role in NF-kappa B activation. Previous studies have demonstrated that, although both I kappa B proteins are phosphorylated by the same I kappa B kinase (IKK) complex, and their ubiquitination and degradation following phosphorylation are carried out by the same ubiquitination/degradation machinery, their kinetics of degradation are quite different. To better understand the underlying mechanism of the differences in degradation kinetics, we have carried out a systematic, comparative analysis of the ability of the IKK catalytic subunits to phosphorylate I kappa B alpha and I kappa B beta. We found that, whereas IKK alpha is a weak kinase for the N-terminal serines of both I kappa B isoforms, IKK beta is an efficient kinase for those residues in I kappa B alpha. However, IKK beta phosphorylates the N-terminal serines of I kappa B beta far less efficiently, thereby providing an explanation for the slower rate of degradation observed for I kappa B beta. Mutational analysis indicated that the regions around the two N-terminal serines collectively influence the relative phosphorylation efficiency, and no individual residue is critical. These findings provide the first systematic analysis of the ability of I kappa B alpha and I kappa B beta to serve as substrates for IKKs and help provide a possible explanation for the differential degradation kinetics of I kappa B alpha and I kappa B beta.     

Conjugation of Nedd8 to CUL1 enhances the ability of the ROC1-CUL1 complex to promote ubiquitin polymerization

The SCF-ROC1 ubiquitin-protein isopeptide ligase (E3) ubiquitin ligase complex targets the ubiquitination and subsequent degradation of protein substrates required for the regulation of cell cycle progression and signal transduction pathways. We have previously shown that ROC1-CUL1 is a core subassembly within the SCF-ROC1 complex, capable of supporting the polymerization of ubiquitin. This report describes that the CUL1 subunit of the bacterially expressed, unmodified ROC1-CUL1 complex is conjugated with Nedd8 at Lys-720 by HeLa cell extracts or by a purified Nedd8 conjugation system (consisting of APP-BP1/Uba3, Ubc12, and Nedd8). This covalent linkage of Nedd8 to CUL1 is both necessary and sufficient to markedly enhance the ability of the ROC1-CUL1 complex to promote ubiquitin polymerization. A mutation of Lys-720 to arginine in CUL1 eliminates the Nedd8 modification, abolishes the activation of the ROC1-CUL1 ubiquitin ligase complex, and significantly reduces the ability of SCF(HOS/beta)(-TRCP)-ROC1 to support the ubiquitination of phosphorylated IkappaBalpha. Thus, although regulation of the SCF-ROC1 action has been previously shown to preside at the level of recognition of a phosphorylated substrate, we demonstrate that Nedd8 is a novel regulator of the efficiency of polyubiquitin chain synthesis and, hence, promotes rapid turnover of protein substrates.     

The Nedd8-conjugated ROC1-CUL1 core ubiquitin ligase utilizes Nedd8 charged surface residues for efficient polyubiquitin chain assembly catalyzed by Cdc34.

Lysine 48-linked polyubiquitin chains are the principle signal for targeting proteins for degradation by the 26 S proteasome. Here we report that the conjugation of Nedd8 to ROC1-CUL1, a subcomplex of the SCF-ROC1 E3 ubiquitin ligase, selectively stimulates Cdc34-catalyzed lysine 48-linked multiubiquitin chain assembly. We have further demonstrated that separate regions within the human Cdc34 C-terminal tail are responsible for multiubiquitin chain assembly and for physical interactions with the Nedd8-conjugated ROC1-CUL1 to assemble extensive ubiquitin polymers. Structural comparisons between Nedd8 and ubiquitin reveal that six charged residues (Lys4, Glu12, Glu14, Arg25, Glu28, and Glu31) are uniquely present on the surface of Nedd8. Replacement of each of the six residues with the corresponding amino acid in ubiquitin decreases the ability of Nedd8 to activate the ubiquitin ligase activity of ROC1-CUL1. Moreover, maintenance of the proper charges at amino acid positions 14 and 25 are necessary for retaining wild type levels of activity, whereas introduction of the opposite charges at these positions abolishes the Nedd8 activation function. These results suggest that Nedd8 charged surface residues mediate the activation of ROC1-CUL1 to specifically support Cdc34-catalyzed ubiquitin polymerization.     

Regulation of autophagy by E3 ubiquitin ligase RNF216 through BECN1 ubiquitination

Autophagy is an evolutionarily conserved biological process involved in an array of physiological and pathological events. Without proper control, autophagy contributes to various disorders, including cancer and autoimmune and inflammatory diseases. It is therefore of vital importance that autophagy is under careful balance. Thus, additional regulators undoubtedly deepen our understanding of the working network, and provide potential therapeutic targets for disorders. In this study, we found that RNF216 (ring finger protein 216), an E3 ubiquitin ligase, strongly inhibits autophagy in macrophages. Further exploration demonstrates that RNF216 interacts with BECN1, a key regulator in autophagy, and leads to ubiquitination of BECN1, thereby contributing to BECN1 degradation. RNF216 was involved in the ubiquitination of lysine 48 of BECN1 through direct interaction with the triad (2 RING fingers and a DRIL [double RING finger linked]) domain. We further showed that inhibition of autophagy through overexpression of RNF216 in alveolar macrophages promotes Listeria monocytogenes growth and distribution, while knockdown of RNF216 significantly inhibited these outcomes. These effects were confirmed in a mouse model of L. monocytogenes infection, suggesting that manipulating RNF216 expression could be a therapeutic approach. Thus, our study identifies a novel negative regulator of autophagy and suggests that RNF216 may be a target for treatment of inflammatory diseases.     

Regulation of autophagy by E3 ubiquitin ligase RNF216 through BECN1 ubiquitination

Autophagy is an evolutionarily conserved biological process involved in an array of physiological and pathological events. Without proper control, autophagy contributes to various disorders, including cancer and autoimmune and inflammatory diseases. It is therefore of vital importance that autophagy is under careful balance. Thus, additional regulators undoubtedly deepen our understanding of the working network, and provide potential therapeutic targets for disorders. In this study, we found that RNF216 (ring finger protein 216), an E3 ubiquitin ligase, strongly inhibits autophagy in macrophages. Further exploration demonstrates that RNF216 interacts with BECN1, a key regulator in autophagy, and leads to ubiquitination of BECN1, thereby contributing to BECN1 degradation. RNF216 was involved in the ubiquitination of lysine 48 of BECN1 through direct interaction with the triad (2 RING fingers and a DRIL [double RING finger linked]) domain. We further showed that inhibition of autophagy through overexpression of RNF216 in alveolar macrophages promotes Listeria monocytogenes growth and distribution, while knockdown of RNF216 significantly inhibited these outcomes. These effects were confirmed in a mouse model of L. monocytogenes infection, suggesting that manipulating RNF216 expression could be a therapeutic approach. Thus, our study identifies a novel negative regulator of autophagy and suggests that RNF216 may be a target for treatment of inflammatory diseases.     

Recognition and ubiquitination of Notch by Itch, a hect-type E3 ubiquitin ligase

Genetic studies identified Itch, which is a homologous to the E6-associated protein carboxyl terminus (Hect) domain-containing E3 ubiquitin-protein ligase that is disrupted in non-agouti lethal mice or Itchy mice. Itch-deficiency results in abnormal immune responses and constant itching in the skin. Here, Itch was shown to associate with Notch, a protein involved in cell fate decision in many mammalian cell types, including cells in the immune system. Itch binds to the N-terminal portion of the Notch intracellular domain via its WW domains and promotes ubiquitination of Notch through its Hect ubiquitin ligase domain. Thus, Itch may participate in the regulation of immune responses by modifying Notch-mediated signaling.     

Ribosomal protein S6 kinase 1 interacts with and is ubiquitinated by ubiquitin ligase ROC1

Ribosomal protein S6 kinase (S6K) is involved in the regulation of cell growth and cellular metabolism. The activation of S6K in response to diverse extracellular stimuli is mediated by multiple phosphorylations coordinated by the mTOR and PI3K signaling pathways. We have recently found that both forms of S6K are modified by ubiquitination. Following these findings, we demonstrate here for the first time that S6K1 associates specifically with ubiquitin ligase ROC1 in vitro and in vivo. The interaction was initially identified in the yeast two-hybrid screening and further confirmed by pull-down and co-immunoprecipitation assays. Furthermore, the overexpression of ROC1 leads to an increase in S6K1 ubiquitination. Consistent with this observation, we showed that the steady-state level of S6K1 is regulated by ROC1, since downregulation of ROC1 by specific siRNA promotes stabilization of S6K1 protein. The results suggest the involvement of ROC1 in S6K1 ubiquitination and subsequent proteasomal degradation.     

Docking-dependent ubiquitination of the interferon regulatory factor-1 tumor suppressor protein by the ubiquitin ligase CHIP

Characteristically for a regulatory protein, the IRF-1 tumor suppressor turns over rapidly with a half-life of between 20-40 min. This allows IRF-1 to reach new steady state protein levels swiftly in response to changing environmental conditions. Whereas CHIP (C terminus of Hsc70-interacting protein), appears to chaperone IRF-1 in unstressed cells, formation of a stable IRF-1·CHIP complex is seen under specific stress conditions. Complex formation, in heat- or heavy metal-treated cells, is accompanied by a decrease in IRF-1 steady state levels and an increase in IRF-1 ubiquitination. CHIP binds directly to an intrinsically disordered domain in the central region of IRF-1 (residues 106-140), and this site is sufficient to form a stable complex with CHIP in cells and to compete in trans with full-length IRF-1, leading to a reduction in its ubiquitination. The study reveals a complex relationship between CHIP and IRF-1 and highlights the role that direct binding or "docking" of CHIP to its substrate(s) can play in its mechanism of action as an E3 ligase.     

E3 ubiquitin ligase SIAH1 mediates ubiquitination and degradation of TRB3

Tribbles 3 homolog (TRB3) is recently identified as a scaffold-like regulator of various signal transducers and has been implicated in several processes including insulin signaling, NF-kappaB signaling, lipid metabolism and BMP signaling. To further understand cellular mechanisms of TRB3 regulation, we performed a yeast two-hybrid screen to identify novel TRB3 interacting proteins and totally obtained ten in-frame fused preys. Candidate interactions were validated by co-immunoprecipitation assays in mammalian cells. We further characterized the identified proteins sorted by Gene Ontology Annotation. Its interaction with the E3 ubiquitin ligase SIAH1 was further investigated. SIAH1 could interact with TRB3 both in vitro and in vivo. Importantly, SIAH1 targeted TRB3 for proteasome-dependent degradation. Cotransfection of SIAH1 could withdraw up-regulation of TGF-beta signaling by TRB3, suggesting SIAH1-induced degradation of TRB3 represents a potential regulatory mechanism for TGF-beta signaling.     

Calcium-sensing receptor ubiquitination and degradation mediated by the E3 ubiquitin ligase dorfin

Calcium-sensing receptors (CaR) contribute to regulation of systemic calcium homeostasis by activation of G(q)- and G(i)-linked signaling pathways in the parathyroids, kidney, and intestine. Little is known about the mechanisms regulating CaR synthesis and degradation. Screening of a human kidney yeast two-hybrid library identified the E3 ubiquitin ligase dorfin as a binding partner for the intracellular carboxyl terminus of CaR. Interaction between CaR and dorfin was confirmed by coimmunoprecipitation from HEK293 cells. Ubiquitination of CaR was observed in the presence of the proteasomal inhibitor MG132; mutation of all putative intracellular loop and carboxyl-terminal lysine residues abolished ubiquitination of CaR. Coexpression with dorfin decreased the amount of total CaR protein and increased CaR ubiquitination, whereas a dominant negative fragment of dorfin had opposite effects. The AAA-ATPase p97/valosin-containing protein associates with both CaR and dorfin in HEK293 cells. Treatment with tunicamycin, an inhibitor of N-linked glycosylation, induced the appearance of the unglycosylated 115-kDa CaR form, which was further increased by exposure to MG132, or upon transfection with a dorfin dominant negative construct, suggesting that dorfin-mediated proteasomal degradation of immature CaR occurs from the endoplasmic reticulum. Because endogenous CaR in Madin-Darby canine kidney cells is also subject to degradation from the endoplasmic reticulum, dorfin-mediated ubiquitination may contribute to a general mechanism for CaR quality control during biosynthesis.     

Recognition and ubiquitination of Salmonella type III effector SopA by a ubiquitin E3 ligase, HsRMA1

Salmonella translocate bacterial effectors into host cells to confer bacterial entry and survival. It is not known how the host cells cope with the influx of these effectors. We report here that the Salmonella effector, SopA, interacts with host HsRMA1, a ubiquitin E3 ligase with a previously unknown function. SopA is ubiquitinated and degraded by the HsRMA1-mediated ubiquitination pathway. A sopA mutant escapes out of the Salmonella-containing vacuoles less frequently to the cytosol than wild type Salmonella in HeLa cells in a HsRMA1-dependent manner. Our data suggest that efficient bacterial escape into the cytosol of epithelial cells requires HsRMA1-mediated SopA ubiquitination and contributes to Salmonella-induced enteropathogenicity.     

Evaluation of a diffusion-driven mechanism for substrate ubiquitination by the SCF-Cdc34 ubiquitin ligase complex

Release of ubiquitin-charged Cdc34 from the SCF ubiquitin ligase followed by diffusion-driven collision with substrate has been proposed to underlie ubiquitination of the canonical SCF substrate Sic1. Cdc34 F72V, reported to be defective in dissociation from SCF, served as key validation. Here, we test predictions of this "hit-and-run" hypothesis. We find that Cdc34 F72V is generally defective in SCF-mediated activation but, contrary to expectation, does not compete with wild-type Cdc34 in vitro or in vivo and can fulfill the physiological role of Cdc34 with only moderate delay in Sic1 turnover. Whereas a hit-and-run mechanism might explain how Cdc34 can transfer ubiquitin to the ends of growing ubiquitin chains on SCF-bound substrates, molecular modeling suggests that an E2 docked to SCF can do so without dissociating. We propose that interactions between Cdc34 approximately Ub and SCF directly activate ubiquitin transfer within a substrate-SCF-Cdc34 approximately Ub ternary complex.     

Mechanism of I kappa B alpha binding to NF-kappa B dimers

X-ray crystal structures of the NF-kappa B.I kappa B alpha complex revealed an extensive and complex protein-protein interface involving independent structural elements present in both I kappa B alpha and NF-kappa B. In this study, we employ a gel electrophoretic mobility shift assay to assess and quantitate the relative contributions of the observed interactions toward overall complex binding affinity. I kappa B alpha preferentially binds to the p50/p65 heterodimer and p65 homodimer, with binding to p50 homodimer being significantly weaker. Our results indicate that the nuclear localization sequence and the region C-terminal to it of the NF-kappa B p65 subunit is a major contributor to NF-kappa B. I kappa B alpha complex formation. Additionally, there are no contacts between the corresponding nuclear localization signal tetrapeptide of p50 and I kappa B alpha. A second set of interactions involving the acidic C-terminal/PEST-like region of I kappa B alpha and the NF-kappa B p65 subunit N-terminal domain also contributes binding energy toward formation of the complex. This interaction is highly dynamic and nonspecific in nature, as shown by oxidative cysteine cross-linking. Phosphorylation of the C-terminal/PEST-like region by casein kinase II further enhances binding.