Two-Step Activity-Based Protein Profiling with the Proteasome System as Model of Study.

Activity-based protein profiling (ABPP) is a method to highlight enzymatic activities in a biological sample, which uses chemical probes that react covalently with the catalytic nucleophile of the enzyme. To circumvent disadvantages associated with the presence of reporter tags on chemical probes, the probe is equipped with a ligation handle to which the reporter can be reacted at the desired time and place in the ABPP workflow. This chapter demonstrates the power of a triple bioorthogonal ligation strategy which addresses the three activities of the proteasome: the β5-subunit selective norbornene-tagged probe is reacted with fluorescent tetrazine, the β1-selective azide-functionalized probe was addressed with a biotinylated phosphine, followed by an alkyne-substituted pan-reactive probe to label the remaining β2 activity to which an azide-coupled fluorophore was ligated.

A Set of Activity-Based Probes to Visualize Human (Immuno)proteasome Activities.

Proteasomes are therapeutic targets for various cancers and autoimmune diseases. Constitutively expressed proteasomes have three active sites, β1c, β2c, and β5c. Lymphoid tissues also express the immunoproteasome subunits β1i, β2i, and β5i.

Activity-based profiling reveals reactivity of the murine thymoproteasome-specific subunit beta5t.

Epithelial cells of the thymus cortex express a unique proteasome particle involved in positive T cell selection. This thymoproteasome contains the recently discovered beta5t subunit that has an uncharted activity, if any. We synthesized fluorescent epoxomicin probes that were used in a chemical proteomics approach, entailing activity-based profiling, affinity purification, and LC-MS identification, to demonstrate that the beta5t subunit is catalytically active in the murine thymus.