Harnessing AlphaFold3 to elucidate BBSome structure and protein partners.

Abstract

The BBSome, an eight-protein complex implicated in Bardet-Biedl syndrome (BBS), plays a crucial role in various cellular processes including ciliary function. Although important aspects of its structural organization and protein interactions have been elucidated, additional questions remain regarding how these features relate to cargo recognition and complex dynamics. Using AlphaFold3, we generated a structural model closely matching recent cryo-EM data (α-carbon root means square deviation: 1.203 Å). Interface residue analysis of the model identified BBSome proteins BBS1 and BBS9 as central interaction hubs (most interface residues between two proteins), with BBS2 and BBS7 showing the most polar contacts. The common BBS1^M390R pathogenic mutation, known to cause BBS, was predicted to destabilize the complex. BBS4 was also found to interact stably with pericentriolar material 1, suggesting a role in centriolar satellite localization. AlphaFold3-mediated analysis of BBSome interactions with G protein-coupled receptors (GPCRs) led to the identification of contact hotspots on BBS1, BBS4, and BBS5. These predictions were supported by immunoprecipitation and peptide competition assays. The modeling also suggested plausible interfaces between specific BBS proteins and metabolic signaling proteins, including melanocortin receptor accessory protein 2 (MRAP2) [an melanocortin-4 receptor (MC4R) chaperonin], the leptin receptor, and the insulin receptor. These predicted interfaces align with previously reported biochemical associations between BBS proteins and these receptors, supporting the idea that the BBSome regulates trafficking and signaling in metabolic pathways. Together, these findings provide new insights into BBSome structure and receptor interactions, offering a predictive framework to explore its role in ciliary trafficking and human disease.NEW & NOTEWORTHY This study combines AI modeling and experimental validation to define key structural features and receptor interactions of the BBSome complex. The analysis identifies BBS1 and BBS9 as central hubs, reveals how the BBS1^M390R mutation destabilizes the complex, and uncovers novel contacts with various receptors including those involved in metabolic regulation. These findings provide a predictive framework linking BBSome structure to ciliary signaling and metabolic regulation in Bardet-Biedl syndrome.