Nanobody-targeted E3-ubiquitin ligase complex degrades nuclear proteins (original) (raw)
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Journal of Biological Chemistry, 2014
Background: Techniques that harness the power of the ubiquitin-proteasome pathway (UPP) for protein knockout are limited to a narrow set of protein targets. Results: Engineered "ubiquibodies" specifically and systematically removed exogenous target proteins. Conclusion: Diverse protein targets can be redirected to the UPP using this new protein silencing method. Significance: Ubiquibodies offer a simple, reproducible, and customizable technique for selectively and controllably depleting cellular proteins.
Nature protocols, 2016
Ubiquitination is an essential protein modification that influences eukaryotic processes ranging from substrate degradation to nonproteolytic pathway alterations, including DNA repair and endocytosis. Previous attempts to analyze substrates via physical association with their respective ubiquitin ligases have had some success. However, because of the transient nature of enzyme-substrate interactions and rapid protein degradation, detection of substrates remains a challenge. Ligase trapping is an affinity purification approach in which ubiquitin ligases are fused to a polyubiquitin-binding domain, which allows the isolation of ubiquitinated substrates. Immunoprecipitation is first used to enrich for proteins that are bound to the ligase trap. Subsequently, affinity purification is used under denaturing conditions to capture proteins conjugated with hexahistidine-tagged ubiquitin. By using this protocol, ubiquitinated substrates that are specific for a given ligase can be isolated for...
Specific and Covalent Targeting of Conjugating and Deconjugating Enzymes of Ubiquitin-Like Proteins
Molecular and Cellular Biology, 2004
processes, including cell cycle progression, nuclear transport, and autophagy. Protein modification occurs via UBL-conjugating and -deconjugating enzymes, which presumably exert a regulatory function by determining the conjugation status of the substrate proteins. To target and identify UBL-modifying enzymes, we produced Nedd8, ISG15, and SUMO-1 in Escherichia coli and equipped them with a C-terminal electrophilic trap (vinyl sulfone [VS]) via an intein-based method. These C-terminally modified UBL probes reacted with purified UBL-activating (E1), -conjugating (E2), and -deconjugating enzymes in a covalent fashion. Modified UBLs were radioiodinated and incubated with cell lysates prepared from mouse cell lines and tissues to allow visualization of polypeptides reactive with individual UBL probes. The cell type-and tissue-specific labeling patterns observed for the UBL probes reflect distinct expression profiles of active enzymes, indicating tissuespecific functions of UBLs. We identify Ub C-terminal hydrolase L1 (UCH-L1) and DEN1/NEDP1/SENP8, in addition to UCH-L3, as proteases with specificity for Nedd8. The Ub-specific protease isopeptidase T/USP5 is shown to react with ISG15-VS. Furthermore, we demonstrate that the desumoylation enzyme SuPr-1 can be modified by SUMO-1-VS, a modification that is dependent on the SuPr-1 active-site cysteine. The UBL probes described here will be valuable tools for the further characterization of the enzymatic pathways that govern modification by UBLs.
Efficient protection and isolation of ubiquitylated proteins using tandem ubiquitin-binding entities
EMBO reports, 2009
Post-translational modification with ubiquitin is one of the most important mechanisms in the regulation of protein stability and function. However, the high reversibility of this modification is the main obstacle for the isolation and characterization of ubiquitylated proteins. To overcome this problem, we have developed tandem-repeated ubiquitin-binding entities (TUBEs) based on ubiquitin-associated (UBA) domains. TUBEs recognize tetra-ubiquitin with a markedly higher affinity than single UBA domains, allowing poly-ubiquitylated proteins to be efficiently purified from cell extracts in native conditions. More significant is the fact that TUBEs protect poly-ubiquitin-conjugated proteins, such as p53 and IjBa, both from proteasomal degradation and de-ubiquitylating activity present in cell extracts, as well as from existing proteasome and cysteine protease inhibitors. Therefore, these new 'molecular traps' should become valuable tools for purifying endogenous poly-ubiquitylated proteins, thus contributing to a better characterization of many essential functions regulated by these post-translational modifications.
In the last decade, the ubiquitin–proteasome system has emerged as a valid target for the development of novel therapeutics. E3 ubiquitin ligases are particularly attractive targets because they confer substrate specificity on the ubiquitin system. CRLs [Cullin–RING (really interesting new gene) E3 ubiquitin ligases] draw particular attention, being the largest family of E3s. The CRLs assemble into functional multisubunit complexes using a repertoire of substrate receptors, adaptors, Cullin scaffolds and RING-box proteins. Drug discovery targeting CRLs is growing in importance due to mounting evidence pointing to significant roles of these enzymes in diverse biological processes and human diseases, including cancer, where CRLs and their substrates often function as tumour suppressors or oncogenes. In the present review, we provide an account of the assembly and structure of CRL complexes, and outline the current state of the field in terms of available knowledge of small-molecule inhibitors and modulators of CRL activity. A comprehensive overview of the reported crystal structures of CRL subunits, components and full-size complexes, alone or with bound small molecules and substrate peptides, is included. This information is providing increasing opportunities to aid the rational structure-based design of chemical probes and potential small-molecule therapeutics targeting CRLs.
2017
Here we present initial in vitro work on a new tool to study the ubiquitin-proteasome system (UPS), named “The Targeted Charging of Ubiquitin to E2” or “tCUbE.” This approach will allow us to uncover the complex enzymatic cascades of the UPS by connecting ubiquitinated target proteins to the activity of a specific ubiquitin-conjugating enzyme, or E2, of interest. While developing this assay in mammalian cells, we worked to purify each engineered protein construct for use in complementary in vitro studies, as well as mutated constructs for control experiments. These in vitro assays allow us to confirm that each component of tCUbE is functioning as designed and can interact with native UPS enzymes. Introduction: The ubiquitin-proteasome system (UPS), most well-known for its role in protein degradation, is also a dynamic signaling pathway that regulates a variety of cellular processes, including cell cycle control and the immune response.1,2 The UPS mediates these essential functions b...
Frontiers in Bioengineering and Biotechnology
Targeted protein degradation is a powerful tool for determining the function of specific proteins nowadays. Survivin is the smallest member of the inhibitor of the apoptosis protein (IAP) family. It exists in the cytoplasm and nucleus of cells, but the exact function of survivin in different subcellular locations retained unclear updates due to the lack of effective and simple technical means. In this study, we created a novel nanoantibody-based molecular toolkit, namely, the ubiquitin–proteasome system (Nb4A-Fc-T2A-TRIM21), that can target to degrade survivin localized in cytoplasmic and cell nuclear by ubiquitinating, and by which to verify the potential roles of survivin subcellular localization. Also, the results showed that the cytoplasmic survivin mainly plays an anti-apoptotic function by directly or indirectly inhibiting the caspase pathway, and the nuclear survivin mainly promotes cell proliferation and participates in the regulation of the cell cycle. In addition, the Nb4A...
Biochemistry, 2009
The class III ubiquitin conjugating enzymes (E2s) are distinguished from other E2s by the presence of unique N-terminal domains, and the utilization of importin-11 for transport into the nucleus in an activation dependent fashion. To begin determining the physiological roles of these enzymes, we carried out a yeast two-hybrid screen with the class III E2, UbcM2. This screen retrieved RCBTB1, a putative substrate adaptor for a cullin3 (CUL3) E3 ligase. We initially established through biochemical studies that RCBTB1 has the properties of a CUL3 substrate adaptor. Further analysis of the UbcM2-RCBTB1 complex led to the discovery and characterization of the following novel interactions: (i) UbcM2 binds an N-terminal domain of CUL3 requiring the first 57 amino acids, the same domain that binds to RCBTB1 and other substrate adaptors; (ii) UbcM2 does not bind mutants of CUL3 that are deficient in substrate adaptor recruitment; (iii) UbcM2 interacts with CUL3 independent of a bridging RING-finger protein; and (iv) can engage the neddylated (i.e., activated) form of CUL3. We also present evidence that UbcM2 can bind to the N-terminal halves of multiple cullins, implying that this E2 is a general cofactor for this class of ligases. Together, these studies represent the first evidence that UbcM2, in concert with substrate adaptors, engages activated CUL3 ligases, thus suggesting that class III E2s are novel regulators of cullin ligases. Ubiquitin is a small, highly conserved, eukaryotic protein that is post-translationally attached to substrates. Proteins tagged with ubiquitin can be targeted to the 26S proteasome for degradation or marked for nonproteolytic outcomes such as transcriptional activation, endocytic sorting, and DNA repair (reviewed in refs 1-3). In vivo, most ubiquitin conjugation is mediated by a hierarchical, three-enzyme cascade consisting of a ubiquitin-activating enzyme (E1), a ubiquitin-conjugating enzyme (E2), and a ubiquitin ligase (E3). Ubiquitin is first activated in an ATP-dependent manner by E1. The activated ubiquitin is then transferred to the active site cysteine of an E2 in a transesterification reaction. E2s typically partner with an E3 to transfer the activated ubiquitin to a substrate but can also monoubiquitylate ubiquitinbinding domains independent of a partnering E3 (4). E3s can be single proteins or multisubunit complexes, and they confer substrate selection and specificity to the ubiquitin system. They
A ubiquitin-like protein unleashes ubiquitin ligases
Cell, 2008
Modification of cullin-RING ubiquitin ligases by the ubiquitin-like molecule Nedd8 promotes substrate ubiquitination. A crystal structure of a cullin modified by Nedd8 recently reported in Cell (Duda et al., 2008) and a biochemical study in Molecular Cell (Saha and Deshaies, 2008) reveal the dramatic impact on the ligase machinery by conjugation of ubiquitin or ubiquitin-like proteins.