De novo design of protein interactions with learned surface fingerprints

Gainza, Pablo; Wehrle, Sarah; Hall-Beauvais, Alexandra Van; Marchand, Anthony; Scheck, Andreas; Harteveld, Zander; Buckley, Stephen M.; Ni, Dongchun; Tan, Shuguang; Sverrisson, Freyr; Goverde, Casper; Turelli, Priscilla; Raclot, Charlène; Teslenko, Alexandra; Pačesa, Martin; Rosset, Stéphane; Georgeon, Sandrine; Marsden, Jane; Petruzzella, Aaron S.; Liu, Kefang; Xu, Zepeng; Chai, Yan; Han, Pu; Gao, Lidong; Oricchio, Elisa; Fierz, Beat; Trono, Didier; Stahlberg, Henning; Bronstein, Michael M.; Correia, Bruno E.

doi:10.1038/s41586-023-05993-x

Cited by 87 publications

(50 citation statements)

References 77 publications

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“…They introduced MaSIF (molecular surface interaction fingerprinting), a conceptual framework utilizing geometric deep-learning techniques to capture crucial fingerprints relevant to specific biomolecular interactions, including protein pocket–ligand interactions and protein–protein interaction. Two years later, the same framework was used to design novel protein interactions …”

Section: Computational Methods To Predict Protein–protein Interaction...mentioning

confidence: 99%

Computational Approaches to Predict Protein–Protein Interactions in Crowded Cellular Environments

Grassmann,

Miotto,

Desantis

et al. 2024

Chem. Rev.

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Investigating protein–protein interactions is crucial for understanding cellular biological processes because proteins often function within molecular complexes rather than in isolation. While experimental and computational methods have provided valuable insights into these interactions, they often overlook a critical factor: the crowded cellular environment. This environment significantly impacts protein behavior, including structural stability, diffusion, and ultimately the nature of binding. In this review, we discuss theoretical and computational approaches that allow the modeling of biological systems to guide and complement experiments and can thus significantly advance the investigation, and possibly the predictions, of protein–protein interactions in the crowded environment of cell cytoplasm. We explore topics such as statistical mechanics for lattice simulations, hydrodynamic interactions, diffusion processes in high-viscosity environments, and several methods based on molecular dynamics simulations. By synergistically leveraging methods from biophysics and computational biology, we review the state of the art of computational methods to study the impact of molecular crowding on protein–protein interactions and discuss its potential revolutionizing effects on the characterization of the human interactome.

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Section: Computational Methods To Predict Protein–protein Interaction...mentioning

confidence: 99%

Computational Approaches to Predict Protein–Protein Interactions in Crowded Cellular Environments

Grassmann,

Miotto,

Desantis

et al. 2024

Chem. Rev.

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“…While a first approach for designing protein cages used genetic fusion 4,29 , subsequent work (beginning with King et al 2012) has increasingly relied on the computational design of de novo non-covalent interfaces between protein subunits. A critical factor therefore in successful material design is the specification of a geometrically precise interface that is accessible and cooperative with the surrounding energy landscape 30 . The interface must encode sufficient information to drive the emergence of quaternary structure 31 , while not corrupting the energetics governing tertiary structure 32 .…”

Section: Introductionmentioning

confidence: 99%

A Suite of Designed Protein Cages Using Machine Learning Algorithms and Protein Fragment-Based Protocols

Meador,

Castells-Graells,

Aguirre

et al. 2023

Preprint

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Designed protein cages and related materials provide unique opportunities for applications in biotechnology and medicine, while methods for their creation remain challenging and unpredictable. In the present study, we apply new computational approaches to design a suite of new tetrahedrally symmetric, self-assembling protein cages. For the generation of docked poses, we emphasize a protein fragment-based approach, while forde novointerface design, a comparison of computational protocols highlights the power and increased experimental success achieved using the machine learning program ProteinMPNN. In relating information from docking and design, we observe that agreement between fragment-based sequence preferences and ProteinMPNN sequence inference correlates with experimental success. Additional insights for designing polar interactions are highlighted by experimentally testing larger and more polar interfaces. In all, using X-ray crystallography and cryo-EM, we report five structures for seven protein cages, with atomic resolution in the best case reaching 2.0 Å. We also report structures of two incompletely assembled protein cages, providing unique insights into one type of assembly failure. The new set of designed cages and their structures add substantially to the body of available protein nanoparticles, and to methodologies for their creation.

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“…14,15 As an alternative to small molecule-based approaches, peptidebased ligands possess large protein-protein interaction surfaces, making them suitable for targeting any POI. Coupled with the rapid development of structural biology techniques that provide detailed protein-protein structural information, 16,17 mature directedevolution technologies such as phage and yeast display, [18][19][20] and emerging computational approaches for rapid discovery of synthetic binding peptides, 6,[21][22][23] peptide-based ligands are ideal for extending the scope of PROTACs to "undruggable" proteins. 24,25 Several Peptide-based Proteolysis Targeting Chimeras (PepTACs) targeting oncoproteins and transcription factors make use of a cationic cell-penetrating peptides 26,27 , cyclic peptides, 28,29 or peptide stapling [30][31][32][33] to facilitate cellular uptake.…”

mentioning

confidence: 99%

Nanoparticle-mediated delivery of peptide-based degraders enables targeted protein degradation

Ghosal,

Robertus,

Wang

et al. 2024

Preprint

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The development of small molecule-based degraders against intracellular protein targets is a rapidly growing field that is hindered by the limited availability of high-quality small molecule ligands that bind to the target of interest. Despite the feasibility of designing peptide ligands against any protein target, peptide-based degraders still face significant obstacles such as, limited serum stability and poor cellular internalization. To overcome these obstacles, we repurposed lipid nanoparticle (LNP) formulations to facilitate the delivery of Peptide-based proteolysis TArgeting Chimeras (PepTACs). Our investigations reveal robust intracellular transport of PepTAC-LNPs across various clinically relevant human cell lines. Our studies also underscore the critical nature of the linker and hydrophobic E3 binding ligand for efficient LNP packaging and transport. We demonstrate the clinical utility of this strategy by engineering PepTACs targeting two critical transcription factors, β-catenin and CREPT (cell-cycle-related and expression-elevated protein in tumor), involved in the Wnt-signalling pathway. The PepTACs induced target-specific protein degradation and led to a significant reduction in Wnt-driven gene expression and cancer cell proliferation. Mouse biodistribution studies revealed robust accumulation of PepTAC-LNPs in the spleen and liver, among other organs, and PepTACs designed against β-catenin and formulated in LNPs showed a reduction in β-catenin levels in the liver. Our findings demonstrate that LNPs can be formulated to encapsulate PepTACs, thus enabling robust delivery and potent intracellular protein degradation.

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De novo design of protein interactions with learned surface fingerprints

Cited by 87 publications

References 77 publications

Computational Approaches to Predict Protein–Protein Interactions in Crowded Cellular Environments

Computational Approaches to Predict Protein–Protein Interactions in Crowded Cellular Environments

A Suite of Designed Protein Cages Using Machine Learning Algorithms and Protein Fragment-Based Protocols

Nanoparticle-mediated delivery of peptide-based degraders enables targeted protein degradation

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