Nonenzymatic assembly of natural polyubiquitin chains of any linkage composition and isotopic labeling scheme

A Versatile Strategy for the Semisynthetic Production of Ser65 Phosphorylated Ubiquitin and Its Biochemical and Structural Characterisation

Ubiquitin phosphorylation is emerging as an important regulatory layer in the ubiquitin system. This is exemplified by the phosphorylation of ubiquitin on Ser65 by the Parkinson's disease-associated kinase PINK1, which mediates the activation of the E3 ligase Parkin. Additional phosphorylation sites on ubiquitin might also have important cellular roles. Here we report a versatile strategy for preparing phosphorylated ubiquitin. We biochemically and structurally characterise semisynthetic phospho-Ser65-ubiquitin. Unexpectedly, we observed disulfide bond formation between ubiquitin molecules, and hence a novel crystal form. The method outlined provides a direct approach to study the combinatorial effects of phosphorylation on ubiquitin function. Our analysis also suggests that disulfide engineering of ubiquitin could be a useful strategy for obtaining alternative crystal forms of ubiquitin species thereby facilitating structural validation.

Peeling away the layers of ubiquitin signaling complexities with synthetic ubiquitin-protein conjugates

Covalent attachment of ubiquitin, a process termed ubiquitination, affects the location, function, and stability of modified proteins. Significant advances have been made in building synthetic ubiquitin-protein conjugates that can be used to investigate how ubiquitin regulates diverse biological processes. Herein we describe recent advances and discuss how chemical methods have been implemented to address the molecular underpinnings of ubiquitin-dependent cellular signaling.

Nonspecific yet decisive: Ubiquitination can affect the native-state dynamics of the modified protein

Ubiquitination is one of the most common post-translational modifications of proteins, and mediates regulated protein degradation among other cellular processes. A fundamental question regarding the mechanism of protein ubiquitination is whether and how ubiquitin affects the biophysical nature of the modified protein. For some systems, it was shown that the position of ubiquitin within the attachment site is quite flexible and ubiquitin does not specifically interact with its substrate. Nevertheless, it was revealed that polyubiquitination can decrease the thermal stability of the modified protein in a site-specific manner because of alterations of the thermodynamic properties of the folded and unfolded states. In this study, we used detailed atomistic simulations to focus on the molecular effects of ubiquitination on the native structure of the modified protein. As a model, we used Ubc7, which is an E2 enzyme whose in vivo ubiquitination process is well characterized and known to lead to degradation. We found that, despite the lack of specific direct interactions between the ubiquitin moiety and Ubc7, ubiquitination decreases the conformational flexibility of certain regions of the substrate Ubc7 protein, which reduces its entropy and thus destabilizes it. The strongest destabilizing effect was observed for systems in which Lys48-linked tetra-ubiquitin was attached to sites used for in vivo degradation. These results reveal how changes in the configurational entropy of the folded state may modulate the stability of the protein's native state. Overall, our results imply that ubiquitination can modify the biophysical properties of the attached protein in the folded state and that, in some proteins, different ubiquitination sites will lead to different biophysical outcomes. We propose that this destabilizing effect of polyubiquitin on the substrate is linked to the functions carried out by the modification, and in particular, regulatory control of protein half-life through proteasomal degradation.

Genetic encoding of the post-translational modification 2-hydroxyisobutyryl-lysine

We report the synthesis and genetic encoding of a recently discovered post-translational modification, 2-hydroxyisobutyryl-lysine, to the genetic code of E. coli. The production of homogeneous proteins containing this amino acid will facilitate the study of modification in full-length proteins.

Native chemical ubiquitination using a genetically incorporated azidonorleucine

A robust chemical ubiquitination method was developed. The method employed a genetically incorporated azidonorleucine as an orthogonal lysine precursor for the installation of a Gly residue bearing an Nα-auxiliary which mediated the ligation between ubiquitin(1-75)-thioester and the target protein. To demonstrate our methodology, a model protein, K48-linked diubiquitin, was synthesized with an overall yield of 35%.

Ubiquitination of the Dishevelled DIX domain blocks its head-to-tail polymerization

Dishevelled relays Wnt signals from the plasma membrane to different cytoplasmic effectors. Its signalling activity depends on its DIX domain, which undergoes head-to-tail polymerization to assemble signalosomes. The DIX domain is ubiquitinated in vivo at multiple lysines, which can be antagonized by various deubiquitinases (DUBs) including the CYLD tumour suppressor that attenuates Wnt signalling. Here, we generate milligram quantities of pure human Dvl2 DIX domain mono-ubiquitinated at two lysines (K54 and K58) by genetically encoded orthogonal protection with activated ligation (GOPAL), to investigate their effect on DIX polymerization. We show that the ubiquitination of DIX at K54 blocks its polymerization in solution, whereas DIX58-Ub remains oligomerization-competent. DUB profiling identified 28 DUBs that cleave DIX-ubiquitin conjugates, half of which prefer, or are specific for, DIX54-Ub, including Cezanne and CYLD. These DUBs thus have the potential to promote Dvl polymerization and signalosome formation, rather than antagonize it as previously thought for CYLD.

Base-CP proteasome can serve as a platform for stepwise lid formation

26S proteasome, a major regulatory protease in eukaryotes, consists of a 20S proteolytic core particle (CP) capped by a 19S regulatory particle (RP). The 19S RP is divisible into base and lid sub-complexes. Even within the lid, subunits have been demarcated into two modules: module 1 (Rpn5, Rpn6, Rpn8, Rpn9 and Rpn11), which interacts with both CP and base sub-complexes and module 2 (Rpn3, Rpn7, Rpn12 and Rpn15) that is attached mainly to module 1. We now show that suppression of RPN11 expression halted lid assembly yet enabled the base and 20S CP to pre-assemble and form a base-CP. A key role for Regulatory particle non-ATPase 11 (Rpn11) in bridging lid module 1 and module 2 subunits together is inferred from observing defective proteasomes in rpn11–m1, a mutant expressing a truncated form of Rpn11 and displaying mitochondrial phenotypes. An incomplete lid made up of five module 1 subunits attached to base-CP was identified in proteasomes isolated from this mutant. Re-introducing the C-terminal portion of Rpn11 enabled recruitment of missing module 2 subunits. In vitro, module 1 was reconstituted stepwise, initiated by Rpn11–Rpn8 heterodimerization. Upon recruitment of Rpn6, the module 1 intermediate was competent to lock into base-CP and reconstitute an incomplete 26S proteasome. Thus, base-CP can serve as a platform for gradual incorporation of lid, along a proteasome assembly pathway. Identification of proteasome intermediates and reconstitution of minimal functional units should clarify aspects of the inner workings of this machine and how multiple catalytic processes are synchronized within the 26S proteasome holoenzymes.

Defective proteasome 19S regulatory particles (RPs) were identified in rpn11f–m1, a proteasomal mutant with mitochondrial phenotypes. The Rpn11 subunit initiates assembly of a five-subunit lid module competent to integrate into pre-assembled base-20S core particle (CP), with subsequent recruitment of remaining lid subunits.

Preparing to read the ubiquitin code: a middle-out strategy for characterization of all lysine-linked diubiquitins

Multiple studies demonstrate that ubiquitination of proteins codes for regulation of cell differentiation, apoptosis, endocytosis and many other cellular functions. There is great interest in and considerable effort being given to defining the relationships between the structures of polyubiquitin modifications and the fates of the modified proteins. Does each ubiquitin modification achieve a specific effect, much like phosphorylation, or is ubiquitin like glycosylation, where there is heterogeneity and redundancy in the signal? The sensitive analytical tools needed to address such questions readily are not yet mature. To lay the foundation for mass spectrometry (MS)-based studies of the ubiquitin code, we have assembled seven isomeric diubiquitins with all-native sequences and isopeptide linkages. Using these compounds as standards enables the development and testing of a new MS-based strategy tailored specifically to characterize the number and sites of isopeptide linkages in polyubiquitin chains. Here, we report the use of Asp-selective acid cleavage, separation by reverse phase high-performance liquid chromatography and characterization by tandem MS to distinguish and characterize all seven isomeric lysine-linked ubiquitin dimers.

Dissecting ubiquitin signaling with linkage-defined and protease resistant ubiquitin chains

Ubiquitylation is a complex posttranslational protein modification and deregulation of this pathway has been associated with different human disorders. Ubiquitylation comes in different flavors: Besides mono-ubiquitylation, ubiquitin chains of various topologies are formed on substrate proteins. The fate of ubiquitylated proteins is determined by the linkage-type of the attached ubiquitin chains, however, the underlying mechanism is poorly characterized. Herein, we describe a new method based on codon expansion and click-chemistry-based polymerization to generate linkage-defined ubiquitin chains that are resistant to ubiquitin-specific proteases and adopt native-like functions. The potential of these artificial chains for analyzing ubiquitin signaling is demonstrated by linkage-specific effects on cell-cycle progression.

Chemical protein polyubiquitination reveals the role of a noncanonical polyubiquitin chain in DNA damage tolerance

Polyubiquitination of proteins regulates a variety of cellular processes, including protein degradation, NF-κB pathway activation, apoptosis, and DNA damage tolerance. Methods for generating polyubiquitinated protein with defined ubiquitin chain linkage and length are needed for an in-depth molecular understanding of protein polyubiquitination. However, enzymatic protein polyubiquitination usually generates polyubiquitinated proteins with mixed chain lengths in a low yield. We report herein a new chemical approach for protein polyubiquitination with a defined ubiquitin chain length and linkage under a mild condition that preserves the native fold of the target protein. In DNA damage tolerance, K63-polyubiquitinated proliferating cell nuclear antigen (PCNA) plays an important yet unclear role in regulating the selection of the error-free over error-prone lesion bypass pathways. Using the chemically polyubiquitinated PCNA, we revealed a mechanism of the K63 polyubiquitin chain on PCNA in promoting the error-free lesion bypass by suppressing the DNA translesion synthesis (TLS).

Nonenzymatic rubylation and ubiquitination of proteins for structural and functional studies

Uncovering the mechanisms that allow conjugates of ubiquitin (Ub) and/or Ub-like (UBL) proteins such as Rub1 to serve as distinct molecular signals requires the ability to make them with native connectivity and defined length and linkage composition. A novel, effective, and affordable strategy for controlled chemical assembly of fully natural UBL-Ub, Ub-UBL, and UBL-UBL conjugates from recombinant monomers is presented. Rubylation of Ub and Rub1 and ubiquitination of Rub1 was achieved without E2/E3 enzymes. New residue-specific information was obtained on the interdomain contacts in naturally-occurring K48-linked Rub1-Ub and Ub-Rub1, and K29-linked Rub1-Ub heterodimers, and their recognition by a K48-linkage-specific Ub receptor. The disassembly of these heterodimers by major deubiquitinating enzymes was examined and it was discovered that some deubiquitinases also possess derubylase activity. This unexpected result suggests possible crosstalk between Ub and Rub1/Nedd8 signaling pathways.

Expanding and reprogramming the genetic code of cells and animals

Genetic code expansion and reprogramming enable the site-specific incorporation of diverse designer amino acids into proteins produced in cells and animals. Recent advances are enhancing the efficiency of unnatural amino acid incorporation by creating and evolving orthogonal ribosomes and manipulating the genome. Increasing the number of distinct amino acids that can be site-specifically encoded has been facilitated by the evolution of orthogonal quadruplet decoding ribosomes and the discovery of mutually orthogonal synthetase/tRNA pairs. Rapid progress in moving genetic code expansion from bacteria to eukaryotic cells and animals (C. elegans and D. melanogaster) and the incorporation of useful unnatural amino acids has been aided by the development and application of the pyrrolysyl-transfer RNA (tRNA) synthetase/tRNA pair for unnatural amino acid incorporation. Combining chemoselective reactions with encoded amino acids has facilitated the installation of posttranslational modifications, as well as rapid derivatization with diverse fluorophores for imaging.

Unique structural, dynamical, and functional properties of k11-linked polyubiquitin chains

K11-linked polyubiquitin chains play important signaling and regulatory roles in both degradative and nonproteolytic pathways in eukaryotes. To understand the structural basis of how these chains are recognized and distinguished from other polyubiquitins, we determined solution structures of K11-linked diubiquitin (K11-Ub2) in the absence and presence of salt. These structures reveal that K11-Ub2 adopts conformations distinct from those of K48-linked or K63-linked chains. Importantly, our solution NMR and SANS data are inconsistent with published crystal structures of K11-Ub2. We found that increasing salt concentration compacts K11-Ub2 and strengthens interactions between the two Ub units. Binding studies indicate that K11-Ub2 interacts with ubiquitin-receptor proteins from both proteasomal and nonproteasomal pathways but with intermediate affinity and different binding modes than either K48-linked or K63-linked diubiquitin. Our data support the hypothesis that polyubiquitin chains of different linkages possess unique conformational and dynamical properties, allowing them to be recognized differently by downstream receptor proteins.

Chemical methods for protein ubiquitination

In eukaryotic cells, many proteins undergo extensive post-translational modifications (PTMs) such as methylation, acetylation, phosphorylation, glycosylation, and ubiquitination. Among these, ubiquitination is a particularly interesting PTM from both structural and functional viewpoints. In ubiquitination, the C-terminal carboxyl group of the small ubiquitin protein is attached to the ε-amine of a lysine residue of a substrate protein through an isopeptide bond. Ubiquitination has been shown to be involved in the regulation of many cellular processes including protein degradation and gene expression. And dysfunction of these processes is implicated in many human diseases. Despite many years of intensive research, a large number of protein ubquitination events remain poorly characterized. The challenge lies with the tremendous difficulties in isolating homogeneously modified proteins from biological samples for structural and functional studies. Enzymatic ubiquitination in vitro often has limited practical value due to the large number of substrate-specific E3 ligases and the difficulties in identifying or isolating these enzymes. Chemical approaches to the preparation of ubiquitinated proteins provide a powerful solution, and the development of such approaches has been the subject of intense research by many research laboratories. This review summarizes the methodological developments of protein chemical ubiquitination in recent years.

Deubiquitinating enzyme specificity for ubiquitin chain topology profiled by di-ubiquitin activity probes

Posttranslational modification with ubiquitin (Ub) controls many cellular processes, and aberrant ubiquitination can contribute to cancer, immunopathology, and neurodegeneration. The versatility arises from the ability of Ub to form polymer chains with eight distinct linkages via lysine side chains and the N terminus. In this study, we engineered Di-Ub probes mimicking all eight different poly-Ub linkages and profiled the deubiquitinating enzyme (DUB) selectivity for recognizing Di-Ub moieties in cellular extracts. Mass spectrometric profiling revealed that most DUBs examined have broad selectivity, whereas a subset displays a clear preference for recognizing noncanonical over K48/K63 Ub linkages. Our results expand knowledge of Ub processing enzyme functions in cellular contexts that currently depends largely on using recombinant enzymes and substrates.

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Synthesis of Di-ubiquitin-based active site probes representing all eight linkages

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Mass spectrometric profiling of DUB-Ub linkage preference in whole cell extracts

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Activity-based Di-Ub probe screen for DUB specificity toward poly-Ub linkages

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DUBs detected with a preference for noncanonical linkages over K48/K63-linked Ub

Synthetic polyubiquitinated α-Synuclein reveals important insights into the roles of the ubiquitin chain in regulating its pathophysiology

Ubiquitination regulates, via different modes of modifications, a variety of biological processes, and aberrations in the process have been implicated in the pathogenesis of several neurodegenerative diseases. However, our ability to dissect the pathophysiological relevance of the ubiquitination code has been hampered due to the lack of methods that allow site-specific introduction of ubiquitin (Ub) chains to a specific substrate. Here, we describe chemical and semisynthetic strategies for site-specific incorporation of K48-linked di- or tetra-Ub chains onto the side chain of Lys12 of α-Synuclein (α-Syn). These advances provided unique opportunities to elucidate the role of ubiquitination and Ub chain length in regulating α-Syn stability, aggregation, phosphorylation, and clearance. In addition, we investigated the cross-talk between phosphorylation and ubiquitination, the two most common α-Syn pathological modifications identified within Lewy bodies and Parkinson disease. Our results suggest that α-Syn functions under complex regulatory mechanisms involving cross-talk among different posttranslational modifications.

Modifying the vicinity of the isopeptide bond to reveal differential behavior of ubiquitin chains with interacting proteins: organic chemistry applied to synthetic proteins

In every direction: Chemical protein synthesis allows the construction of 14 di-ubiquitin analogues modified in the vicinity of the isopeptide bond to examine their behavior with deubiquitinases and ubiquitin binding domains. The results set the ground for the generation of unique probes for studying the interactions of these chains with various ubiquitin-interacting proteins.

Nonenzymatic assembly of branched polyubiquitin chains for structural and biochemical studies

Polymeric chains of a small protein ubiquitin are involved in regulation of nearly all vital processes in eukaryotic cells. Elucidating the signaling properties of polyubiquitin requires the ability to make these chains in vitro. In recent years, chemical and chemical-biology tools have been developed that produce fully natural isopeptide-linked polyUb chains with no need for linkage-specific ubiquitin-conjugating enzymes. These methods produced unbranched chains (in which no more than one lysine per ubiquitin is conjugated to another ubiquitin). Here we report a nonenzymatic method for the assembly of fully natural isopeptide-linked branched polyubiquitin chains. This method is based on the use of mutually orthogonal removable protecting groups (e.g., Boc- and Alloc-) on lysines combined with an Ag-catalyzed condensation reaction between a C-terminal thioester on one ubiquitin and a specific ε-amine on another ubiquitin, and involves genetic incorporation of more than one Lys(Boc) at the desired linkage positions in the ubiquitin sequence. We demonstrate our method by making a fully natural branched tri-ubiquitin containing isopeptide linkages via Lys11 and Lys33, and a (15)N-enriched proximal ubiquitin, which enabled monomer-specific structural and dynamical studies by NMR. Furthermore, we assayed disassembly of branched and unbranched tri-ubiquitins as well as control di-ubiquitins by the yeast proteasome-associated deubiquitinase Ubp6. Our results show that Ubp6 can recognize and disassemble a branched polyubiquitin, wherein cleavage preferences for individual linkages are retained. Our spectroscopic and functional data suggest that, at least for the chains studied here, the isopeptide linkages are effectively independent of each other. Together with our method for nonenzymatic assembly of unbranched polyubiquitin, these developments now provide tools for making fully natural polyubiquitin chains of essentially any type of linkage and length.

Non-enzymatic synthesis of ubiquitin chains: where chemistry makes a difference

Ubiquitination is a highly important posttranslational modification in eukaryotic cells where a target protein is conjugated to ubiquitin or a chain of ubiquitins via an isopeptide bond to trigger various cellular events such as proteasomal degradation. Rigorous investigations of the ubiquitin signal at the molecular level require homogeneous samples of ubiquitin chains in their free form or as anchored to a protein substrate in adequate quantities. The complexity of ubiquitin chains in terms of linkage types (owing to presence of seven Lys in ubiquitin) makes them difficult to prepare via enzymatic methods. Even more challenging is the attachment of these chains to a protein target at a selected site. This dearth is being filled by the recent developments of novel chemical tools that offer atomic level control over the synthesis for structural and functional studies. These emerging chemical approaches are discussed in this mini-review with focus on the preparation of ubiquitin chains to aid the ongoing efforts in understanding their role in the ubiquitin signal.

Nonenzymatic polymerization of ubiquitin: single-step synthesis and isolation of discrete ubiquitin oligomers

Linked: a method based on thiol-ene chemistry enables the synthesis and purification of ubiquitin oligomers with ≥4 units. This approach, which employs free-radical polymerization, can be applied towards the synthesis of homogeneous Lys6-linked ubiquitin oligomers currently inaccessible by enzymatic methods. By using these chains, one can study their roles in the ubiquitin proteasome system and the DNA damage response pathway.

Polymerization behavior of a bifunctional ubiquitin monomer as a function of the nucleophile site and folding conditions

Biopolymers with repeating modules composed of either folded peptides or tertiary protein domains are considered some of the basic biomaterials that nature has evolved to optimize for energy efficient synthesis and unique functions. Such biomaterials continue to inspire scientists to mimic their exceptional properties and the ways that nature adopts to prepare them. Ubiquitin chains represent another example of nature's approach to use a protein-repeating module to prepare functionally important biopolymers. In the current work, we utilize a novel synthetic strategy to prepare bifunctional ubiquitin monomers having a C-terminal thioester and a nucleophilic 1,2-aminothiol at a desired position to examine their polymerization products under different conditions. Our study reveals that such analogues, when subjected to polymerization conditions under different folding states, afford distinct patterns of polymerization products where both the dynamic and the tertiary structures of the chains play important roles in such processes. Moreover, we also show that the presence of a specific ubiquitin-binding domain, which binds specifically to some of these chains, could interfere selectively with the polymerization outcome. Our study represents the first example of examining the polymerization of designed and synthetic repeating modules based on tertiary protein domains and affords early lessons in the design and synthesis of biomaterial. In regards to the ubiquitin system, our study may have implications on the ease of synthesis of ubiquitin chains with varying lengths and types for structural and functional analyses. Importantly, such an approach could also assist in understanding the enzymatic machinery and the factors controlling the assembly of these chains with a desired length.

Structural insights into the conformation and oligomerization of E2~ubiquitin conjugates

Post-translational modification of proteins by ubiquitin (Ub) regulates a host of cellular processes, including protein quality control, DNA repair, endocytosis, and cellular signaling. In the ubiquitination cascade, a thioester-linked conjugate between the C-terminus of Ub and the active site cysteine of a ubiquitin-conjugating enzyme (E2) is formed. The E2~Ub conjugate interacts with a ubiquitin ligase (E3) to transfer Ub to a lysine residue on a target protein. The flexibly linked E2~Ub conjugates have been shown to form a range of structures in solution. In addition, select E2~Ub conjugates oligomerize through a noncovalent "backside" interaction between Ub and E2 components of different conjugates. Additional studies are needed to bridge the gap between the dynamic monomeric conjugates, E2~Ub oligomers, and the mechanisms of ubiquitination. We present a new 2.35 Å crystal structure of an oligomeric UbcH5c~Ub conjugate. The conjugate forms a staggered linear oligomer that differs substantially from the "infinite spiral" helical arrangement of the only previously reported structure of an oligomeric conjugate. Our structure also differs in intraconjugate conformation from other structurally characterized conjugates. Despite these differences, we find that the backside interaction mode is conserved in different conjugate oligomers and is independent of intraconjugate relative E2-Ub orientations. We delineate a common intraconjugate E2-binding surface on Ub. In addition, we demonstrate that an E3 CHIP (carboxyl terminus of Hsp70 interacting protein) interacts directly with UbcH5c~Ub oligomers, not only with conjugate monomers. These results provide insights into the conformational diversity of E2~Ub conjugates and conjugate oligomers, and into their compatibility and interactions with E3s, which have important consequences for the ubiquitination process.

Targeting deubiquitinases enabled by chemical synthesis of proteins

Ubiquitination/ubiquitylation is involved in a wide range of cellular processes in eukaryotes, such as protein degradation and DNA repair. Ubiquitination is a reversible post-translational modification, with the removal of the ubiquitin (Ub) protein being catalyzed by a family of enzymes known as deubiquitinases (DUBs). Approximately 100 DUBs are encoded in the human genome and are involved in a variety of regulatory processes, such as cell-cycle progression, tissue development, and differentiation. DUBs were, moreover, found to be associated with several diseases and as such are emerging as potential therapeutic targets. Several directions have been pursued in the search for lead anti-DUB compounds. However, none of these strategies have delivered inhibitors reaching advanced clinical stages due to several challenges in the discovery process, such as the absence of a highly sensitive and practically available high-throughput screening assay. In this study, we report on the design and preparation of a FRET-based assay for DUBs based on the application of our recent chemical method for the synthesis of Ub bioconjugates. In the assay, the ubiquitinated peptide was specifically labeled with a pair of FRET labels and used to screen a library comprising 1000 compounds against UCH-L3. Such analysis identified a novel and potent inhibitor able to inhibit this DUB in time-dependent manner with k(inact) = 0.065 min(-1) and K(i) = 0.8 μM. Our assay, which was also found suitable for the UCH-L1 enzyme, should assist in the ongoing efforts targeting the various components of the ubiquitin system and studying the role of DUBs in health and disease.

Unraveling the complexity of ubiquitin signaling

Protein ubiquitination, the covalent attachment of ubiquitin to target proteins, has emerged as one of the most prevalent posttranslational modifications (PTMs), regulating nearly every cellular pathway. The diversity of signaling associated with this particular PTM stems from the myriad ways in which a target protein can be modified by ubiquitin, e.g., monoubiquitin, multi-monoubiquitin, and polyubiquitin linkages. In this Review, we focus on developments in both enzymatic and chemical methods that engender ubiquitin with new chemical and physical properties. Moreover, we highlight how these methods have enabled studies directed toward (i) characterizing enzymes responsible for reversing the ubiquitin modification, (ii) understanding the influence of ubiquitin on protein function and crosstalk with other PTMs, and (iii) uncovering the impact of polyubiquitin chain linkage and length on downstream signaling events.

Structure and recognition of polyubiquitin chains of different lengths and linkage

The polyubiquitin signal is post-translationally attached to a large number of proteins, often directing formation of macromolecular complexes resulting in the translocation, assembly or degradation of the attached protein. Recent structural and functional studies reveal general mechanisms by which different architectures and length of the signal are distinguished.