Structural basis for UFM1 transfer from UBA5 to UFC1.

Ufmylation is a post-translational modification essential for regulating key cellular processes. A three-enzyme cascade involving E1, E2 and E3 is required for UFM1 attachment to target proteins. How UBA5 (E1) and UFC1 (E2) cooperatively activate and transfer UFM1 is still unclear. Here, we present the crystal structure of UFC1 bound to the C-terminus of UBA5, revealing how UBA5 interacts with UFC1 via a short linear sequence, not observed in other E1-E2 complexes. We find that UBA5 has a region outside the adenylation domain that is dispensable for UFC1 binding but critical for UFM1 transfer. This region moves next to UFC1's active site Cys and compensates for a missing loop in UFC1, which exists in other E2s and is needed for the transfer. Overall, our findings advance the understanding of UFM1's conjugation machinery and may serve as a basis for the development of ufmylation inhibitors.

Crystal structures of an E1-E2-ubiquitin thioester mimetic reveal molecular mechanisms of transthioesterification.

E1 enzymes function as gatekeepers of ubiquitin (Ub) signaling by catalyzing activation and transfer of Ub to tens of cognate E2 conjugating enzymes in a process called E1-E2 transthioesterification. The molecular mechanisms of transthioesterification and the overall architecture of the E1-E2-Ub complex during catalysis are unknown. Here, we determine the structure of a covalently trapped E1-E2-ubiquitin thioester mimetic. Two distinct architectures of the complex are observed, one in which the Ub thioester (Ub(t)) contacts E1 in an open conformation and another in which Ub(t) instead contacts E2 in a drastically different, closed conformation. Altogether our structural and biochemical data suggest that these two conformational states represent snapshots of the E1-E2-Ub complex pre- and post-thioester transfer, and are consistent with a model in which catalysis is enhanced by a Ub(t)-mediated affinity switch that drives the reaction forward by promoting productive complex formation or product release depending on the conformational state.

Measuring APC/C-Dependent Ubiquitylation In Vitro.

The anaphase-promoting complex/cyclosome (APC/C) is a 1.2 MDa ubiquitin ligase complex with important functions in both proliferating and post-mitotic differentiated cells. In proliferating cells, APC/C controls cell cycle progression by targeting inhibitors of chromosome segregation and mitotic exit for degradation by the 26S proteasome. To understand how APC/C recruits and ubiquitylates its substrate proteins and how these processes are controlled, it is essential to analyze APC/C activity in vitro. In the past, such experiments have been limited by the fact that large quantities of purified APC/C were difficult to obtain and that mutated versions of the APC/C could not be easily generated. In this chapter we review recent advances in generating and purifying recombinant forms of the human APC/C and its co-activators, using methods that are scalable and compatible with mutagenesis. We also describe a method that allows the quantitative analysis of APC/C activity using fluorescently labeled substrate proteins.

Expression, purification, and crystal structure of N-terminal domains of human ubiquitin-activating enzyme (E1).

Ubiquitin-activating enzyme (E1) is a key regulator in protein ubiquitination, which lies on the upstream of the ubiquitin-related pathways and determines the activation of the downstream enzyme cascade. Thus far, no structural information about the human ubiquitin-activating enzyme has been reported. We expressed and purified the N-terminal domains of human E1 and determined their crystal structures, which contain inactive adenylation domain (IAD) and the first catalytic cysteine half-domain (FCCH). This study presents the crystal structure of human E1 fragment for the first time. The main structure of both IAD and FCCH superimposed well with their corresponding domains in yeast Uba1, but their relative positions vary significantly. This work provides new structural insights in understanding the mechanisms of ubiquitin activation in humans.

Electrophilic adduction of ubiquitin activating enzyme E1 by N,N-diethyldithiocarbamate inhibits ubiquitin activation and is accompanied by striatal injury in the rat.

Previous studies have shown ubiquitin activating enzyme E1 to be sensitive to adduction through both Michael addition and SN(2) chemistry in vitro. E1 presents a biologically important putative protein target for adduction due to its role in initiating ubiquitin based protein processing and the involvement of impaired ubiquitin protein processing in two types of familial Parkinson's disease. We tested whether E1 is susceptible to xenobiotic-mediated electrophilic adduction in vivo and explored the potential contribution of E1 adduction to neurodegenerative events in an animal model. N,N-Diethyldithiocarbamate (DEDC) was administered to rats using a protocol that produces covalent cysteine modifications in vivo, and brain E1 protein adducts were characterized and mapped using shotgun LC-MS/MS. E1 activity, global and specific protein expression, and protein carbonyls were used to characterize cellular responses and injury in whole brain and dorsal striatal samples. The data demonstrate that DEDC treatment produced S-(ethylaminocarbonyl) adducts on Cys234 and Cys179 residues of E1 and decreased the levels of activated E1 and total ubiquitinated proteins. Proteomic analysis of whole brain samples identified expression changes for proteins involved in myelin structure, antioxidant response, and catechol metabolism, systems often disrupted in neurodegenerative disease. Our studies also delineated localized injury within the striatum as indicated by decreased levels of tyrosine hydroxylase, elevated protein carbonyl content, increased antioxidant enzyme and α-synuclein expression, and enhanced phosphorylation of tau and tyrosine hydroxylase. These data are consistent with E1 having similar susceptibility to adduction in vivo as previously reported in vitro and support further investigation into environmental agent adduction of E1 as a potential contributing factor to neurodegenerative disease. Additionally, this study supports the predictive value of in vitro screens for identifying sensitive protein targets that can be used to guide subsequent in vivo experiments.

High-yield expression in Escherichia coli and purification of mouse ubiquitin-activating enzyme E1.

Research in the ubiquitin field requires large amounts of ubiquitin-activating enzyme (E1) for in vitro ubiquitination assays. Typically, the mammalian enzyme is either isolated from natural sources or produced recombinantly using baculovirus/insect cell protein expression systems. Escherichia coli is seldom used to produce mammalian E1 probably due to the instability and insolubility of this high-molecular mass protein. In this report, we show that 5-10 mg of histidine-tagged mouse E1 can be easily obtained from a 1 l E. coli culture. A low temperature during the protein induction step was found to be critical to obtain an active enzyme.

Expression, purification and characterization of human ubiquitin-activating enzyme, UBE1.

UBE1 plays an important role in the first step of ubiquitin-proteasome pathway to activate ubiquitin. Both the structure and biochemical property research of human UBE1 protein, and the activity analysis of those enzymes which are related with ubiquitination pathway, are based on high purity of UBE1 protein. To obtain human UBE1 protein, the full length of human UBE1 was expressed in E. coli and purified by Ni-NTA superflow sepharose and strep-tactin sepharose which based on UB-UBE1 high-energy thioester bonded intermediate complex. It was demonstrated that purified UBE1 could activate and conjugate UB to ubiquitin-conjugating enzyme E2s. The purified large amount of UBE1 could be used for in vitro studies of ubiquitin pathway and structural studies.

Proteomic identification of novel proteins associated with Lewy bodies.

The manifestation of Lewy bodies (LB) in the brain is a hallmark of Parkinson's disease. Here, we present a comprehensive analysis of protein elements in Lewy bodies by comparative mass spectrometry. Cortical LB inclusions were enriched by sucrose gradient centrifugation from postmortem brains, and a negative control sample was prepared from specimen without LB pathology. Whereas approximately 550 proteins were identified in the LB-enriched sample by mass spectrometry, quantitative comparison with the control sample revealed that approximately 40 proteins were co-enriched with alpha-synuclein, the major component in Lewy bodies. As expected, the list of proteins included previously reported constituents, such as those involved in protein folding, membrane trafficking and oxidative stress. More interestingly, we discovered in the LB-enriched sample several kinases (MAPKK1/MEK1, protein kinase C, and doublecortin-like kinase), a novel deubiquitinating enzyme (otubain 1), and numerous ubiquitin ligases (KPC and SCF). The proteomic studies provide enzyme candidates to investigate the regulation of alpha-synuclein and/or other LB proteins, which may contribute to the formation of Lewy bodies and the toxicity of alpha-synuclein in the related neurodegenerative disorders.

Purification of E1 and E1-like enzymes.

Ubiquitin-activating enzyme is the archetype for a family of enzymes catalyzing the ATP-coupled activation of ubiquitin and other class 1 ubiquitin-like proteins required for their subsequent conjugation to cellular targets. The general physical and mechanistic features of the E1 family appear well conserved. Formation of an obligatory E1-ubiquitin thiol ester intermediate forms the basis of a one-step covalent purification of the enzyme on ubiquitin-linked affinity columns that has been adapted for the isolation of E1 paralogs. We describe the facile purification of active E1 from outdated human red blood cells in yields (2-4 nmol/U of blood) that make this an attractive alternative to expression of the proteolytically labile recombinant protein. In addition, two stoichiometric activity assays are described that rely on formation of the E1 125I-ubiquitin thiol ester and ubiquitin [2,8-3H]adenylate intermediates.