E2 Partner Tunes the Ubiquitylation Specificity of Arkadia E3 Ubiquitin Ligase.

Arkadia (RNF111) is a positive regulator of the TGF-ß signaling that mediates the proteasome-dependent degradation of negative factors of the pathway. It is classified as an E3 ubiquitin ligase and a SUMO-targeted ubiquitin ligase (STUBL), implicated in various pathological conditions including cancer and fibrosis. The enzymatic (ligase) activity of Arkadia is located at its C-terminus and involves the RING domain. Notably, E3 ligases require E2 enzymes to perform ubiquitylation. However, little is known about the cooperation of Arkadia with various E2 enzymes and the type of ubiquitylation that they mediate. In the present work, we study the interaction of Arkadia with the E2 partners UbcH5B and UbcH13, as well as UbcH7. Through NMR spectroscopy, we found that the E2-Arkadia interaction surface is similar in all pairs examined. Nonetheless, the requirements and factors that determine an enzymatically active E2-Arkadia complex differ in each case. Furthermore, we revealed that the cooperation of Arkadia with different E2s results in either monoubiquitylation or polyubiquitin chain formation via K63, K48, or K11 linkages, which can determine the fate of the substrate and lead to distinct biological outcomes.

1H, 13C, 15N backbone resonance assignment of apo and ADP-ribose bound forms of the macro domain of Hepatitis E virus through solution NMR spectroscopy.

The genome of Hepatitis E virus (HEV) is 7.2 kilobases long and has three open reading frames. The largest one is ORF1, encoding a non-structural protein involved in the replication process, and whose processing is ill-defined. The ORF1 protein is a multi-modular protein which includes a macro domain (MD). MDs are evolutionarily conserved structures throughout all kingdoms of life. MDs participate in the recognition and removal of ADP-ribosylation, and specifically viral MDs have been identified as erasers of ADP-ribose moieties interpreting them as important players at escaping the early stages of host-immune response. A detailed structural analysis of the apo and bound to ADP-ribose state of the native HEV MD would provide the structural information to understand how HEV MD is implicated in virus-host interplay and how it interacts with its intracellular partner during viral replication. In the present study we present the high yield expression of the native macro domain of HEV and its analysis by solution NMR spectroscopy. The HEV MD is folded in solution and we present a nearly complete backbone and sidechains assignment for apo and bound states. In addition, a secondary structure prediction by TALOS + analysis was performed. The results indicated that HEV MD has a α/ß/α topology very similar to that of most viral macro domains.

Unveiling the Essential Role of Arkadia's Non-RING Elements in the Ubiquitination Process.

Arkadia is a positive regulator of the TGFß-SMAD2/3 pathway, acting through its C-terminal RING-H2 domain and targeting for degradation of its negative regulators. Here we explore the role of regions outside the RING domain (non-RING elements) of Arkadia on the E2-E3 interaction. The contribution of the non-RING elements was addressed using Arkadia RING 68 aa and Arkadia 119 aa polypeptides. The highly conserved NRGA (asparagine-arginine-glycine-alanine) and TIER (threonine-isoleucine-glutamine-arginine) motifs within the 119 aa Arkadia polypeptide, have been shown to be required for pSMAD2/3 substrate recognition and ubiquitination in vivo. However, the role of the NRGA and TIER motifs in the enzymatic activity of Arkadia has not been addressed. Here, nuclear magnetic resonance interaction studies with the E2 enzyme, UBCH5B, C85S UBCH5B-Ub oxyester hydrolysis, and auto-ubiquitination assays were used to address the role of the non-RING elements in E2-E3 interaction and in the enzymatic activity of the RING. The results support that the non-RING elements including the NRGA and TIER motifs are required for E2-E3 recognition and interaction and for efficient auto-ubiquitination. Furthermore, while Arkadia isoform-2 and its close homologue Arkadia 2C are known to interact with free ubiquitin, the results here showed that Arkadia isoform-1 does not interact with free ubiquitin.

Impact of a Single Nucleotide Polymorphism on the 3D Protein Structure and Ubiquitination Activity of E3 Ubiquitin Ligase Arkadia.

Single nucleotide polymorphisms (SNPs) are genetic variations which can play a vital role in the study of human health. SNP studies are often used to identify point mutations that are associated with diseases. Arkadia (RNF111) is an E3 ubiquitin ligase that enhances transforming growth factor-beta (TGF-ß) signaling by targeting negative regulators for degradation. Dysregulation of the TGF-ß pathway is implicated in cancer because it exhibits tumor suppressive activity in normal cells while in tumor cells it promotes invasiveness and metastasis. Τhe SNP CGT > TGT generated an amino-acid (aa) substitution of Arginine 957 to Cysteine on the enzymatic RING domain of Arkadia. This was more prevalent in a tumor than in a normal tissue sample of a patient with colorectal cancer. This prompted us to investigate the effect of this mutation in the structure and activity of Arkadia RING. We used nuclear magnetic resonance (NMR) to analyze at an atomic-level the structural and dynamic properties of the R957C Arkadia RING domain, while ubiquitination and luciferase assays provided information about its enzymatic functionality. Our study showed that the R957C mutation changed the electrostatic properties of the RING domain however, without significant effects on the structure of its core region. However, the functional studies revealed that the R957C Arkadia exhibits significantly increased enzymatic activity supporting literature data that Arkadia within tumor cells promotes aggressive and metastatic behavior.

1H, 13C, 15N backbone and side-chain resonance assignment of the native form of UbcH7 (UBE2L3) through solution NMR spectroscopy.

Ubiquitination is a post-translational modification that regulates a plethora of processes in cells. Ubiquitination requires three type of enzyme: E1 ubiquitin (Ub) activating enzymes, E2 Ub conjugating enzymes and E3 ubiquitin ligases. The E2 enzymes perform a variety of functions, as Ub chain initiation, elongation and regulation of the topology and the process of chain formation. The E2 enzymes family is mainly characterized by a highly conserved ubiquitin conjugating domain (UBC), which comprises the binding region for the activated Ub, E1 and E3 enzymes. The E2 enzyme UbcH7 (UBE2L3) is a known interacting partner for different types of E3 Ub ligases such as HECT, RING and RBR. A structural analysis of the apo form of the native UbcH7 will provide the structural information to understand how this E2 enzyme is implicated in a wide range of diseases and how it interacts with its partners. In the present study we present the high yield expression of the native UbcH7 E2 enzyme and its preliminary analysis via solution NMR spectroscopy. The E2 enzyme is folded in solution and nearly a complete backbone assignment was achieved. Additionally, TALOS+ analysis was performed and the results indicated that UbcH7 adopts a αßßßßααα topology which is similar to that of the majority of E2 enzymes.

Conformational plasticity of the VEEV macro domain is important for binding of ADP-ribose.

Venezuelan equine encephalitis virus (VEEV) is a new world alphavirus which can be involved in several central nervous system disorders such as encephalitis and meningitis. The VEEV genome codes for 4 non-structural proteins (nsP), of which nsP3 contains a Macro domain. Macro domains (MD) can be found as stand-alone proteins or embedded within larger proteins in viruses, bacteria and eukaryotes. Their most common feature is the binding of ADP-ribose (ADPr), while several macro domains act as ribosylation writers, erasers or readers. Alphavirus MD erase ribosylation but their precise contribution in viral replication is still under investigation. NMR-driven titration experiments of ADPr in solution with the VEEV macro domain (in apo- and complex state) show that it adopts a suitable conformation for ADPr binding. Specific experiments indicate that the flexibility of the loops ß5-α3 and α3-ß6 is critical for formation of the complex and assists a wrapping mechanism for ADPr binding. Furthermore, along with this sequence of events, the VEEV MD undergoes a conformational exchange process between the apo state and a low-populated "dark" conformational state.

Lead Identification Through the Synergistic Action of Biomolecular NMR and In Silico Methodologies.

The combination of virtual screening with biomolecular NMR can be a powerful approach in the first steps toward drug discovery. Here, we describe how computational methodologies to screen large databases readily available for testing small molecules, in synergy with NMR techniques focused on protein-ligand interactions, can be used in the early lead compound identification process against a protein drug target.

A Residue Specific Insight into the Arkadia E3 Ubiquitin Ligase Activity and Conformational Plasticity.

Arkadia (Rnf111) is an E3 ubiquitin ligase that plays a central role in the amplification of transforming growth factor beta (TGF-ß) signaling responses by targeting for degradation the negative regulators of the pathway, Smad6 and Smad7, and the nuclear co-repressors Ski and Skil (SnoN). Arkadia's function in vivo depends on the really interesting new gene (RING)-H2 interaction with the E2 enzyme UbcH5b in order to ligate ubiquitin chains on its substrates. A conserved tryptophan (W972) in the C-terminal α-helix is widely accepted as essential for E2 recruitment and interaction and thus also for E3 enzymatic activity. The present NMR-driven study provides an atomic-level investigation of the structural and dynamical properties of two W972 Arkadia RING mutants, attempting to illuminate for the first time the differences between a functional and a nonfunctional mutant W972A and W972R, respectively. A TGF-ß-responsive promoter driving luciferase was used to assay for Arkadia function in vivo. These experiments showed that the Arkadia W972A mutant has the same activity as wild-type (WT) Arkadia in enhancing TGF-ß signaling responses, while W972R does not. Only minor structural differences exist between the W972A RING domain and WT-RING. In contrast, the W972R mutant hardly interacts with E2. The loss of function correlates with structural changes in the C-terminal α-helix and an increase in the distance between the Zn(II) ions. Our data show that the position occupied by W972 within WT Arkadia is critical for the function of RING and that it depends on the nature of the residue at this position.