High-Resolution Snapshots of Proteasome Inhibitors in Action Revise Inhibition Paradigms and Inspire Next-Generation Inhibitor Design.

New high-resolution crystal structures reported by Schrader and colleagues refine our understanding of how peptide epoxyketone anticancer drugs inactivate their target: the human proteasome. These findings provide important clues for the design of next-generation proteasome inhibitor drugs.

Proteasome inhibitors with pyrazole scaffolds from structure-based virtual screening.

We performed a virtual screen of ∼340 000 small molecules against the active site of proteasomes followed by in vitro assays and subsequent optimization, yielding a proteasome inhibitor with pyrazole scaffold. The pyrazole-scaffold compound displayed excellent metabolic stability and was highly effective in suppressing solid tumor growth in vivo. Furthermore, the effectiveness of this compound was not negatively impacted by resistance to bortezomib or carfilzomib.

A FRET-based approach for identification of proteasome catalytic subunit composition.

Mammalian cells have two main types of proteasomes, the constitutive proteasome and the immunoproteasome, each containing a distinct set of three catalytic subunits. Recently, additional proteasome subtypes containing a non-standard mixture of catalytic subunits have gained increasing attention, especially due to their presence in cancer settings. However, practical methods for identifying proteasome subtypes have been lacking.

Activity-based imaging probes of the proteasome.

Over the years, the proteasome has been extensively investigated due to its crucial roles in many important signaling pathways and its implications in diseases. Two proteasome inhibitors--bortezomib and carfilzomib--have received FDA approval for the treatment of multiple myeloma, thereby validating the proteasome as a chemotherapeutic target. As a result, further research efforts have been focused on dissecting the complex biology of the proteasome to gain the insight required for developing next-generation proteasome inhibitors.

Revisiting the role of the immunoproteasome in the activation of the canonical NF-κB pathway.

The discovery of NF-κB signaling pathways has greatly enhanced our understanding of inflammatory and immune responses. In the canonical NF-κB pathway, the proteasomal degradation of IκBα, an inhibitory protein of NF-κB, is widely accepted to be a key regulatory step. However, contradictory findings have been reported as to whether the immunoproteasome plays an obligatory role in the degradation of IκBα and activation of the canonical NF-κB pathway.

PROTAC-induced proteolytic targeting.

Small-molecule modulators of protein activity are increasingly being utilized as tools to examine the functional roles of proteins. Operating at the post-translational level, these molecules provide enhanced temporal and spatial control and mitigate the potential for compensatory responses in comparison with classical genetic approaches. Proteolysis targeting chimeric molecules, or PROTACs, are small molecules that inhibit the function of their target proteins by targeting them for degradation by the ubiquitin proteasome system.

A bright approach to the immunoproteasome: development of LMP2/β1i-specific imaging probes.

While the constitutive, 26S proteasome plays an important role in regulating many important cellular processes, a variant form known as the immunoproteasome is thought to primarily function in adaptive immune responses. However, recent studies indicate an association of immunoproteasomes with many physiological disorders such as cancer, neurodegenerative, and inflammatory diseases. Despite this, the detailed functions of the immunoproteasome remain poorly understood.