Synthesis Of Ubiquitin Chains Research Articles

STING induces HOIP-mediated synthesis of M1 ubiquitin chains to stimulate NFκB signaling.

STING activation by cyclic dinucleotides in mammals induces IRF3- and NFκB -mediated gene expression, and the lipidation of LC3B at Golgi-related membranes. While mechanisms of the IRF3 response are well understood, the mechanisms of NFκB activation mediated by STING remain unclear. We report that STING activation induces linear/M1-linked ubiquitin chain (M1-Ub) formation and recruitment of the LUBAC E3 ligase, HOIP, to LC3B-associated Golgi membranes where ubiquitin is also localized. Loss of HOIP prevents formation of M1-Ub ubiquitin chains and reduces STING-induced NFκB and IRF3-mediated signaling in human monocytic THP1 cells and mouse bone marrow derived macrophages, without affecting STING activation. STING-induced LC3B lipidation is not required for M1-Ub chain formation or the immune-related gene expression, however the recently reported function of STING to neutralize the pH of the Golgi may be involved. Thus, LUBAC synthesis of M1 ubiquitin chains mediates STING-induced innate immune signaling.

Cyclophilin J limits linear ubiquitin signaling and controls colorectal cancer progression

Exorbitant sustained inflammation is closely linked to inflammation-associated disorders, including cancer. The initiation of gastrointestinal cancers such as colorectal cancer (CRC) is frequently accelerated by uncontrollable chronic inflammation which is triggered by excessive activation of nuclear factor kappa-B (NF-κB) signaling. Linear ubiquitin chains play an important role in activating canonical NF-κB pathway. The only known E3 complex, linear ubiquitin assembly complex (LUBAC) is responsible for the synthesis of linear ubiquitin chains, thus leading to the activation of NF-κB axis and promoting the development of inflammation and inflammation-associated cancers. We report here cyclophilin J (CYPJ) is a negative regulator of the LUBAC. The N-terminus of CYPJ binds to the second Npl4-like zinc finger (NZF2) domain of HOIP and the ubiquitin-like (UBL) domain of SHARPIN to disrupt the interaction between HOIP and SHARPIN and thus restrains linear ubiquitin chain synthesis and NF-κB activation. Cypj-deficient mice are highly susceptible to dextran sulfate sodium (DSS)-induced colitis and DSS plus azoxymethane (AOM)-induced colon cancer. Moreover, CYPJ expression is induced by hypoxia. Patients with high expression of both CYPJ and hypoxia-inducible factor-1α (HIF-1α) have longer overall survival and progression-free survival. These results implicate CYPJ as an unexpected robust attenuator of inflammation-driven tumorigenesis that exerts its effects by controlling linear ubiquitin chain synthesis in NF-κB signal pathway.

Structural Dynamics of E6AP E3 Ligase HECT Domain and Involvement of a Flexible Hinge Loop in the Ubiquitin Chain Synthesis Mechanism.

Ubiquitin (Ub) ligases E3 are important factors in selecting target proteins for ubiquitination and determining the type of polyubiquitin chains on the target proteins. In the HECT (homologous to E6AP C-terminus)-type E3 ligases, the HECT domain is composed of an N-lobe and a C-lobe that are connected by a flexible hinge loop. The large conformational rearrangement of the HECT domain via the flexible hinge loop is essential for the HECT-type E3-mediated Ub transfer from E2 to a target protein. However, detailed insights into the structural dynamics of the HECT domain remain unclear. Here, we provide the first direct demonstration of the structural dynamics of the HECT domain using high-speed atomic force microscopy at the nanoscale. We also found that the flexibility of the hinge loop has a great impact not only on its structural dynamics but also on the formation mechanism of free Ub chains.

Ixazomib inhibits myeloma cell proliferation by targeting UBE2K

PurposeIxazomib is a selective, effective, and reversible inhibitor of 20S proteasome and is approved for the treatment of multiple myeloma. Ubiquitin-conjugating enzyme E2 (UBE2K) is involved in the synthesis of K48-linked ubiquitin chains and is the target of certain drugs used for the treatment of tumors. The purpose of this study was to investigate the relationship between ixazomib and UBE2K in myeloma cells. MethodsWe used CCK-8 and Annexin V-FITC/propidium iodide kit to detect the effects of ixazomib on survival and apoptosis of RPMI-8226 and U-266 myeloma cell lines. Quantitative polymerase chain reaction and western blot were used to detect the change in gene and protein expression levels of myeloma cells treated with ixazomib. Furthermore, the regulatory effects of ixazomib on UBE2K and its downstream targets were investigated following the overexpression of UBE2K. ResultsIn myeloma cells, ixazomib decreased cell survival and increased apoptosis in a dose-dependent manner. Ixazomib significantly increased the expression of HIST1H2BD, MNAT1, NEK3, and TARS2, while decreasing the expression of HSPA1B and UBE2K. In addition, ixazomib inhibited the proliferation of myeloma cells, blocked cell cycle, induced cell apoptosis, and increased the production of reactive oxygen species by inhibiting UBE2K expression. Lastly, ixazomib regulates mitosis- and apoptosis-related genes by lowering UBE2K expression. ConclusionIn summary, ixazomib leads to impaired proliferation of myeloma cells by targeting UBE2K.

Enzymatic Logic of Ubiquitin Chain Assembly.

Protein ubiquitination impacts virtually every biochemical pathway in eukaryotic cells. The fate of a ubiquitinated protein is largely dictated by the type of ubiquitin modification with which it is decorated, including a large variety of polymeric chains. As a result, there have been intense efforts over the last two decades to dissect the molecular details underlying the synthesis of ubiquitin chains by ubiquitin-conjugating (E2) enzymes and ubiquitin ligases (E3s). In this review, we highlight these advances. We discuss the evidence in support of the alternative models of transferring one ubiquitin at a time to a growing substrate-linked chain (sequential addition model) versus transferring a pre-assembled ubiquitin chain (en bloc model) to a substrate. Against this backdrop, we outline emerging principles of chain assembly: multisite interactions, distinct mechanisms of chain initiation and elongation, optimal positioning of ubiquitin molecules that are ultimately conjugated to each other, and substrate-assisted catalysis. Understanding the enzymatic logic of ubiquitin chain assembly has important biomedical implications, as the misregulation of many E2s and E3s and associated perturbations in ubiquitin chain formation contribute to human disease. The resurgent interest in bifunctional small molecules targeting pathogenic proteins to specific E3s for polyubiquitination and subsequent degradation provides an additional incentive to define the mechanisms responsible for efficient and specific chain synthesis and harness them for therapeutic benefit.

Crystal structure of the Ube2K/E2-25K and K48-linked di-ubiquitin complex provides structural insight into the mechanism of K48-specific ubiquitin chain synthesis

Ubiquitin-conjugating enzymes (E2) form thioester bonds with ubiquitin (Ub), which are subsequently transferred to target proteins for cellular progress. Ube2K/E2-25K (a class II E2 enzyme) contains a C-terminal ubiquitin-associated (UBA) domain that has been suggested to control ubiquitin recognition, dimerization, or poly-ubiquitin chain formation. Ube2K is a special E2 because it synthesizes K48-linked poly-ubiquitin chains without E3 ubiquitin ligase. We found that a novel interaction between the acceptor di-Ub (Ub2) and the auxiliary Ube2K promotes the discharging reaction and production of tri-Ub (Ub3), probably by guiding and positioning the K48 (in the distal Ub) of the acceptor Ub2 in the active site. We also determined the crystal structure of Ube2K-Ub2 at 2.47 Å resolution. Based on our structural and biochemical data, we proposed a structural model of Ub3 synthesis by Ube2K without E3.

E6AP/UBE3A catalyzes encephalomyocarditis virus 3C protease polyubiquitylation and promotes its concentration reduction in virus-infected cells

The encephalomyocarditis virus (EMCV) 3C protease (3Cpro) is one of a small number of viral proteins whose concentration is known to be regulated by the cellular ubiquitin-proteasome system. Here we report that the ubiquitin-conjugating enzyme UbcH7/UBE2L3 and the ubiquitin-protein ligase E6AP/UBE3A are components of a previously unknown EMCV 3Cpro-polyubiquitylating pathway. Following the identification of UbcH7/UBE2L3 as a participant in 3Cpro ubiquitylation, we purified a UbcH7-dependent 3Cpro-ubiquitylating activity from mouse cells, which we identified as E6AP. In vitro reconstitution assays demonstrated that E6AP catalyzes the synthesis of 3Cpro-attached Lys48-linked ubiquitin chains, known to be recognized by the 26S proteasome. We found that the 3Cpro accumulates to higher levels in EMCV-infected E6AP knockdown cells than in control cells, indicating a role for E6AP in in vivo 3Cpro concentration regulation. We also discovered that ARIH1 functions with UbcH7 to catalyze EMCV 3Cpro monoubiquitylation, but this activity does not influence the in vivo 3Cpro concentration.

Practical Chemical Synthesis of Atypical Ubiquitin Chains by Using an Isopeptide‐Linked Ub Isomer

AbstractChemical ubiquitination is an effective approach for accessing structurally defined, atypical ubiquitin (Ub) chains that are difficult to prepare by other techniques. Herein, we describe a strategy that uses a readily accessible premade isopeptide‐linked 76‐mer (isoUb), which has an N‐terminal Cys and a C‐terminal hydrazide, as the key building block to assemble atypical Ub chains in a modular fashion. This method avoids the use of auxiliary‐modified Lys and instead employs the canonical and therefore more robust Cys‐based native chemical ligation technique. The efficiency and capacity of this isoUb‐based strategy is exemplified by the cost‐effective synthesis of several linkage‐ and length‐defined atypical Ub chains, including K27‐linked tetra‐Ub and K11/K48‐branched tri‐, tetra‐, penta‐, and hexa‐Ubs.

Practical Chemical Synthesis of Atypical Ubiquitin Chains by Using an Isopeptide-Linked Ub Isomer.

Chemical ubiquitination is an effective approach for accessing structurally defined, atypical ubiquitin (Ub) chains that are difficult to prepare by other techniques. Herein, we describe a strategy that uses a readily accessible premade isopeptide-linked 76-mer (isoUb), which has an N-terminal Cys and a C-terminal hydrazide, as the key building block to assemble atypical Ub chains in a modular fashion. This method avoids the use of auxiliary-modified Lys and instead employs the canonical and therefore more robust Cys-based native chemical ligation technique. The efficiency and capacity of this isoUb-based strategy is exemplified by the cost-effective synthesis of several linkage- and length-defined atypical Ub chains, including K27-linked tetra-Ub and K11/K48-branched tri-, tetra-, penta-, and hexa-Ubs.

Mechanism of ubiquitin chain synthesis employed by a HECT domain ubiquitin ligase

Homologous to E6AP C-terminal (HECT) ubiquitin (Ub) ligases (E3s) are a large class of enzymes that bind to their substrates and catalyze ubiquitination through the formation of a Ub thioester intermediate. The mechanisms by which these E3s assemble polyubiquitin chains on their substrates remain poorly defined. We report here that the Nedd4 family HECT E3, WWP1, assembles substrate-linked Ub chains containing Lys-63, Lys-48, and Lys-11 linkages (Lys-63 > Lys-48 > Lys-11). Our results demonstrate that WWP1 catalyzes the formation of Ub chains through a sequential addition mechanism, in which Ub monomers are transferred in a successive fashion to the substrate, and that ubiquitination by WWP1 requires the presence of a low-affinity, noncovalent Ub-binding site within the HECT domain. Unexpectedly, we find that the formation of Ub chains by WWP1 occurs in two distinct phases. In the first phase, chains are synthesized in a unidirectional manner and are linked exclusively through Lys-63 of Ub. In the second phase, chains are elongated in a multidirectional fashion characterized by the formation of mixed Ub linkages and branched structures. Our results provide new insight into the mechanism of Ub chain formation employed by Nedd4 family HECT E3s and suggest a framework for understanding how this family of E3s generates Ub signals that function in proteasome-independent and proteasome-dependent pathways.

SCFFbl12 Increases p21Waf1/Cip1 Expression Level through Atypical Ubiquitin Chain Synthesis.

The cyclin-dependent kinase (CDK) inhibitor p21 is an unstructured protein regulated by multiple turnover pathways. p21 abundance is tightly regulated, and its defect causes tumor development. However, the mechanisms that underlie the control of p21 level are not fully understood. Here, we report a novel mechanism by which a component of the SCF ubiquitin ligase, Fbl12, augments p21 via the formation of atypical ubiquitin chains. We found that Fbl12 binds and ubiquitinates p21. Unexpectedly, Fbl12 increases the expression level of p21 by enhancing the mixed-type ubiquitination, including not only K48- but also K63-linked ubiquitin chains, followed by promotion of binding between p21 and CDK2. We also found that proteasome activator PA28γ attenuates p21 ubiquitination by interacting with Fbl12. In addition, UV irradiation induces a dissociation of p21 from Fbl12 and decreases K63-linked ubiquitination, leading to p21 degradation. These data suggest that Fbl12 is a key factor that maintains adequate intracellular concentration of p21 under normal conditions. Our finding may provide a novel possibility that p21's fate is governed by diverse ubiquitin chains.

The molecular basis of lysine 48 ubiquitin chain synthesis by Ube2K.

The post-translational modification of proteins by ubiquitin is central to the regulation of eukaryotic cells. Substrate-bound ubiquitin chains linked by lysine 11 and 48 target proteins to the proteasome for degradation and determine protein abundance in cells, while other ubiquitin chain linkages regulate protein interactions. The specificity of chain-linkage type is usually determined by ubiquitin-conjugating enzymes (E2s). The degradative E2, Ube2K, preferentially catalyses formation of Lys48-linked chains, but like most E2s, the molecular basis for chain formation is not well understood. Here we report the crystal structure of a Ube2K~ubiquitin conjugate and demonstrate that even though it is monomeric, Ube2K can synthesize Lys48-linked ubiquitin chains. Using site-directed mutagenesis and modelling, our studies reveal a molecular understanding of the catalytic complex and identify key features required for synthesis of degradative Lys48-linked chains. The position of the acceptor ubiquitin described here is likely conserved in other E2s that catalyse Lys48-linked ubiquitin chain synthesis.

Structural basis for the RING-catalyzed synthesis of K63-linked ubiquitin chains.

The RING E3 ligase catalysed formation of lysine 63 linked ubiquitin chains by the Ube2V2–Ubc13 E2 complex is required for many important biological processes. Here we report the structure of the RING domain dimer of rat RNF4 in complex with a human Ubc13~Ub conjugate and Ube2V2. The structure has captured Ube2V2 bound to the acceptor (priming) ubiquitin with Lys63 in a position that could lead to attack on the linkage between the donor (second) ubiquitin and Ubc13 that is held in the active “folded back” conformation by the RING domain of RNF4. The interfaces identified in the structure were verified by in vitro ubiquitination assays of site directed mutants. This represents the first view of the synthesis of Lys63 linked ubiquitin chains in which both substrate ubiquitin and ubiquitin-loaded E2 are juxtaposed to allow E3 ligase mediated catalysis.

Defining roles of PARKIN and ubiquitin phosphorylation by PINK1 in mitochondrial quality control using a ubiquitin replacement strategy

The PTEN-induced putative kinase protein 1 (PINK1) and ubiquitin (UB) ligase PARKIN direct damaged mitochondria for mitophagy. PINK1 promotes PARKIN recruitment to the mitochondrial outer membrane (MOM) for ubiquitylation of MOM proteins with canonical and noncanonical UB chains. PINK1 phosphorylates both Ser65 (S65) in the UB-like domain of PARKIN and the conserved Ser in UB itself, but the temporal sequence and relative importance of these events during PARKIN activation and mitochondria quality control remain poorly understood. Using "UB(S65A)-replacement," we find that PARKIN phosphorylation and activation, and ubiquitylation of Lys residues on a cohort of MOM proteins, occur similarly irrespective of the ability of the UB-replacement to be phosphorylated on S65. In contrast, polyubiquitin (poly-UB) chain synthesis, PARKIN retention on the MOM, and mitophagy are reduced in UB(S65A)-replacement cells. Analogous experiments examining roles of individual UB chain linkage types revealed the importance of K6 and K63 chain linkages in mitophagy, but phosphorylation of K63 chains by PINK1 did not enhance binding to candidate mitophagy receptors optineurin (OPTN), sequestosome-1 (p62), and nuclear dot protein 52 (NDP52) in vitro. Parallel reaction monitoring proteomics of total mitochondria revealed the absence of p-S65-UB when PARKIN cannot build UB chains, and <0.16% of the monomeric UB pool underwent S65 phosphorylation upon mitochondrial damage. Combining p-S65-UB and p-S65-PARKIN in vitro showed accelerated transfer of nonphosphorylated UB to PARKIN itself, its substrate mitochondrial Rho GTPase (MIRO), and UB. Our data further define a feed-forward mitochondrial ubiquitylation pathway involving PARKIN activation upon phosphorylation, UB chain synthesis on the MOM, UB chain phosphorylation, and further PARKIN recruitment and enzymatic amplification via binding to phosphorylated UB chains.

Gp78 elongates of polyubiquitin chains from the distal end through the cooperation of its G2BR and CUE domains.

The modification of proteins with polyubiquitin chains alters their stability, localization and activity, thus regulating various aspects of cellular functions in eukaryotic cells. The ER quality control protein E3 gp78 catalyzes Lys48-linked polyubiquitin-chain- assembly on the Ube2g2 active site and is capable of transferring preassembled ubiquitin chains to its substrates. However, the underlying mechanism of polyubiquitin- chain-assembly remains elusive. Here, we demonstrate that the active site-linked ubiquitin chain is extended from the distal end by the cooperative actions of the G2BR and CUE domains of gp78. The G2BR domain is involved in ubiquitin chain synthesis by binding to the donor Ube2g2~Ub and promoting ubiquitin transfer from the E2 in cis. The CUE domain shows preferential binding to the ubiquitin chain compared to monoubiquitin and helps to position the distal ubiquitin in the correct orientation to attack the Ube2g2~Ub thioester bond. Our studies reveal that two interactions, one between the donor Ube2g2~Ub and the gp78 G2BR domain and another between the Ube2g2-linked ubiquitin chain and the gp78 CUE domain, cooperatively drive polyubiquitin-chain-assembly on the Ube2g2 active site.

Insights into the anaphase-promoting complex: a molecular machine that regulates mitosis.

The anaphase-promoting complex/cyclosome (APC/C) is a large multimeric complex that functions as a RING domain E3 ubiquitin ligase to regulate ordered transitions through the cell cycle. It does so by controlling the ubiquitin-mediated proteolysis of cell cycle proteins, notably cyclins and securins, whose degradation triggers sister chromatid disjunction and mitotic exit. Regulation of APC/C activity and modulation of its substrate specificity are subject to intricate cell cycle checkpoints and control mechanisms involving the switching of substrate-specifying cofactors, association of regulatory protein complexes and post-translational modifications. This review discusses the recent progress towards understanding the overall architecture of the APC/C, the molecular basis for degron recognition and ubiquitin chain synthesis, and how these activities are regulated.

Ubiquitin-dependent regulation of immune and inflammatory signaling pathways

Modification of proteins with ubiquitin is a key mechanism for the regulation of a wide range of cellular functions. The outcome of the modification is determined by the way ubiquitin molecules are linked to each other. Linear (M1-linked) ubiquitin chains play an important role in the regulation of immune and inflammatory signaling pathways and contribute to the activation of NF-κB. They are synthesized by the E3 ubiquitin ligase LUBAC (linear ubiquitin chain assembly complex) that is composed of at least three subunits named HOIL-1L, HOIP and SHARPIN. LUBAC belongs to the RBR (RING-inbetween-RING) family of E3 ligases that combine the properties of RING and HECT ligases and act as RING/HECT hybrids. Indeed, we have recently shown that linear ubiquitin chain synthesis proceeds via ubiquitin thioester intermediate formed by the HOIP subunit before subsequent transfer onto the target. I will present a combination of structural and biochemical data that provide a molecular explanation how this unusual E3 ligase complex promotes the synthesis of linear ubiquitin chains with high specificity, regardless of the E2 conjugating enzyme it works with.

Ubiquitin Binding by a CUE Domain Regulates Ubiquitin Chain Formation by ERAD E3 Ligases

Ubiquitin-binding domains (UBDs) differentially recognize ubiquitin (ub) modifications. Some of them specifically bind mono-ub, as has been shown for the CUE domain. Interestingly, so far no significant ubiquitin binding has been observed for the CUE domain of yeast Cue1p. Cue1p is receptor and activator of the ubiquitin-conjugating enzyme Ubc7p. It integrates Ubc7p into endoplasmic reticulum (ER) membrane-bound ubiquitin ligase complexes, and thus, it is crucial for ER-associated protein degradation (ERAD). Here we show that the CUE domain of Cue1p binds ubiquitin chains, which is pivotal for the efficient formation of K48-linked polyubiquitin chains in vitro. Mutations that abolish ubiquitin binding by Cue1p affect the turnover of ERAD substrates in vivo. Our data strongly imply that the CUE domain facilitates substrate ubiquitylation by stabilizing growing ubiquitin chains at the ERAD ubiquitin ligases. Hence, we demonstrate an unexpected function of a UBD in the regulation of ubiquitin chain synthesis.

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.

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.