Monitoring HECT Ubiquitination Activity In Vitro.

In vitro ubiquitination tools have been employed to mechanistically study the ubiquitin enzymatic cascade. Here, we describe an assay capable to monitor ubiquitin conjugation in real time using the Time-Resolved Fluorescence Resonance Energy Transfer (TR-FRET) system. The assay requires purified E1 and E2 enzymes, the HECT E3 ligase of choice and two fluorophore-labeled ubiquitins. This single step technique represents an excellent tool to study the enzymatic activity during chain elongation, to compare ligase activity in the presence or absence of the substrate, and to set-up high-throughput screenings for enzymatic activity modulators (i.e., activators or inhibitors).

BioE3 identifies specific substrates of ubiquitin E3 ligases.

Hundreds of E3 ligases play a critical role in recognizing specific substrates for modification by ubiquitin (Ub). Separating genuine targets of E3s from E3-interactors remains a challenge. We present BioE3, a powerful approach for matching substrates to Ub E3 ligases of interest. Using BirA-E3 ligase fusions and bioUb, site-specific biotinylation of Ub-modified substrates of particular E3s facilitates proteomic identification. We show that BioE3 identifies both known and new targets of two RING-type E3 ligases: RNF4 (DNA damage response, PML bodies), and MIB1 (endocytosis, autophagy, centrosome dynamics). Versatile BioE3 identifies targets of an organelle-specific E3 (MARCH5) and a relatively uncharacterized E3 (RNF214). Furthermore, BioE3 works with NEDD4, a HECT-type E3, identifying new targets linked to vesicular trafficking. BioE3 detects altered specificity in response to chemicals, opening avenues for targeted protein degradation, and may be applicable for other Ub-likes (UbLs, e.g., SUMO) and E3 types. BioE3 applications shed light on cellular regulation by the complex UbL network.