Harnessing AlphaFold3 to Elucidate BBSome Structure and Protein Partners

Deng-Fu Guo; Younes Rouabhi; Mallory Tollefson; Kai Vorhies; Kamal Rahmouni

doi:10.1152/ajpcell.00804.2025

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Harnessing AlphaFold3 to Elucidate BBSome Structure and Protein Partners

Journal article

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Harnessing AlphaFold3 to Elucidate BBSome Structure and Protein Partners

Deng-Fu Guo, Younes Rouabhi, Mallory Tollefson, Kai Vorhies and Kamal Rahmouni

American Journal of Physiology: Cell Physiology

03/31/2026

DOI: 10.1152/ajpcell.00804.2025

PMID: 41915029

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Abstract

The BBSome, an eight-protein complex implicated in Bardet-Biedl syndrome (BBS), plays a crucial role in 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 (Cα RMSD: 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 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 MRAP2 (an 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.

AlphaFold3

structural modeling

GPCR trafficking

ciliopathies

BBSome

protein-protein interactions

Details

Title: Subtitle: Harnessing AlphaFold3 to Elucidate BBSome Structure and Protein Partners
Creators: Deng-Fu Guo - University of Iowa
Younes Rouabhi - University of Iowa
Mallory Tollefson - University of Iowa
Kai Vorhies - University of Iowa
Kamal Rahmouni - University of Iowa
Resource Type: Journal article
Publication Details: American Journal of Physiology: Cell Physiology
DOI: 10.1152/ajpcell.00804.2025
PMID: 41915029
NLM abbreviation: Am J Physiol Cell Physiol
ISSN: 0363-6143
eISSN: 1522-1563
Publisher: American Physiological Society
Grant note: R01 HL162773 and R01 HL172944 / HHS | National Institutes of Health (NIH) T32 DK11275 / HHS | National Institutes of Health (NIH) University of Iowa Fraternal Order of Eagles Diabetes Research Center I01 BX004249 and IK6 BX006040 / U.S. Department of Veterans Affairs (VA)
Language: English
Electronic publication date: 03/31/2026
Academic Unit: Iowa Neuroscience Institute; Fraternal Order of Eagles Diabetes Research Center; Neuroscience and Pharmacology; Biochemistry and Molecular Biology; Internal Medicine
Record Identifier: 9985148851102771

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