TY - JOUR
T1 - Towards a structurally resolved human protein interaction network
AU - Burke, David F
AU - Bryant, Patrick
AU - Barrio-Hernandez, Inigo
AU - Memon, Danish
AU - Pozzati, Gabriele
AU - Shenoy, Aditi
AU - Zhu, Wensi
AU - Dunham, Alistair S
AU - Albanese, Pascal
AU - Keller, Andrew
AU - Scheltema, Richard A
AU - Bruce, James E
AU - Leitner, Alexander
AU - Kundrotas, Petras
AU - Beltrao, Pedro
AU - Elofsson, Arne
N1 - Publisher Copyright:
© 2023, The Author(s).
PY - 2023/2
Y1 - 2023/2
N2 - Cellular functions are governed by molecular machines that assemble through protein-protein interactions. Their atomic details are critical to studying their molecular mechanisms. However, fewer than 5% of hundreds of thousands of human protein interactions have been structurally characterized. Here we test the potential and limitations of recent progress in deep-learning methods using AlphaFold2 to predict structures for 65,484 human protein interactions. We show that experiments can orthogonally confirm higher-confidence models. We identify 3,137 high-confidence models, of which 1,371 have no homology to a known structure. We identify interface residues harboring disease mutations, suggesting potential mechanisms for pathogenic variants. Groups of interface phosphorylation sites show patterns of co-regulation across conditions, suggestive of coordinated tuning of multiple protein interactions as signaling responses. Finally, we provide examples of how the predicted binary complexes can be used to build larger assemblies helping to expand our understanding of human cell biology.
AB - Cellular functions are governed by molecular machines that assemble through protein-protein interactions. Their atomic details are critical to studying their molecular mechanisms. However, fewer than 5% of hundreds of thousands of human protein interactions have been structurally characterized. Here we test the potential and limitations of recent progress in deep-learning methods using AlphaFold2 to predict structures for 65,484 human protein interactions. We show that experiments can orthogonally confirm higher-confidence models. We identify 3,137 high-confidence models, of which 1,371 have no homology to a known structure. We identify interface residues harboring disease mutations, suggesting potential mechanisms for pathogenic variants. Groups of interface phosphorylation sites show patterns of co-regulation across conditions, suggestive of coordinated tuning of multiple protein interactions as signaling responses. Finally, we provide examples of how the predicted binary complexes can be used to build larger assemblies helping to expand our understanding of human cell biology.
KW - Computational Biology/methods
KW - Humans
KW - Mutation
KW - Protein Interaction Maps
KW - Signal Transduction
UR - http://www.scopus.com/inward/record.url?scp=85146676554&partnerID=8YFLogxK
U2 - 10.1038/s41594-022-00910-8
DO - 10.1038/s41594-022-00910-8
M3 - Article
C2 - 36690744
SN - 1545-9993
VL - 30
SP - 216
EP - 225
JO - Nature Structural and Molecular Biology
JF - Nature Structural and Molecular Biology
IS - 2
ER -