The targeting of non-fibrillar polyQ via distinct VCP-proteasome coupling

The aggregation of proteins containing expanded poly-glutamine (polyQ) repeat sequences is a cytopathological hallmark of several dominantly inherited neurodegenerative diseases (ND), including Huntington’s disease (HD). Previously, we observed that long polyQ repeats form a fibrillar core, surrounded by amorphous and soluble intermediates, which compared to the fibrils, are more readily taken up by autophagosomes ¹ . In this study, we investigated how the alternative major degradation pathway in cultured cells, ubiquitin proteasome system (UPS), interacts with the different pools of polyQ.

We observed that the AAA+ ATPase, valosin-containing protein VCP/p97, in collaboration with proteasomes, plays a crucial role in degrading non-fibrillar polyQ. As both VCP and proteasomes were recruited to the polyQ intermediates peripheral to the fibrils, we imaged these regions by in situ cryo-ET for subtomogram averaging. VCP predominantly adopts an ATP-bound state, often in an active processing conformation with resolved NPLOC4-like cofactor density. The region was also enriched with the 26S proteasome (26S), 20S proteasome core (20S), and 19S regulatory particles (19S). Distance analysis of the macromolecules revealed a striking proximity between VCP and the 20S in situ. This is likely mediated by VCP’s C-terminal hydrophobic-tyrosine-X (HbYX) motif, which binds the 20S via hydrophobic interactions, as confirmed by cryo-EM single-particle analysis (SPA) and in vitro assays. Our study highlights a distinct VCP-20S coupling mechanism, where VCP functionally overlaps with the 19S complex in substrate unfolding, facilitating the degradation of polyQ intermediates by the 20S catalytic core.