SubsidieMeestersPeptide-based Supramolecular Co-assembly Design: Multiscale Machine Learning Modeling Approach
Develop a multiscale Graph Neural Network framework to predict peptide co-assembly, enhancing material design and understanding of supramolecular systems.
Projectdetails
Introduction
Supramolecular self-assembly is a fundamental process abundantly utilized by nature and emerging functional materials technologies ranging from drug delivery to soft semiconductor devices. Recently, an increased focus has been placed on the multicomponent peptide co-assembly as they often display unique emergent properties that can dramatically expand the functional utility of peptide-based materials.
Challenges
Still, the full potential is hindered by the combinatorial complexity of peptide-based materials and our inability to predict the co-assembled structures and, therefore, properties and functionality. Machine Learning models built on top of Molecular Dynamics simulations are ideally suited to decipher the co-assembly behavior.
Limitations of Existing Models
However, the existing molecular models either suffer from severe approximations disabling them to give accurate predictions or are computationally too expensive to traverse the material space.
Proposed Solution
Addressing this trade-off, I aim to develop a computational framework for fast and accurate peptide co-assembly prediction using as a key strategy a multiscale construction of Graph Neural Network-based models that can predict the peptide co-assembly.
Objectives
This innovative approach will enable me to reach the following objectives:
- Obtain unprecedented molecular insight into the peptide co-assembly process inaccessible to experiments.
- Uncover novel candidate materials.
- Provide rational design rules for multicomponent peptide-based supramolecular materials.
Broader Impact
In a broader context, increased insight into cooperative behavior will bring us closer to understanding and ultimately synthetically replicating the exceptional functionality of living systems. Meanwhile, the methodological advancements of data-driven molecular modeling will be of paramount importance in other areas of biomaterial engineering and beyond.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.474.182 |
| Totale projectbegroting | € 1.474.182 |
Tijdlijn
| Startdatum | 1-4-2023 |
| Einddatum | 31-3-2028 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- TECHNISCHE UNIVERSITAET MUENCHENpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
Physical and molecular underpinnings of the multifunctionality of bacterial peptide assembliesThis project aims to uncover the self-assembly mechanisms of phenol soluble modulins in Staphylococcus aureus to understand their multifunctionality and develop novel therapeutics against infections. | ERC Starting... | € 1.500.000 | 2025 | Details |
Decoding the Mechanisms Underlying Metal-Organic Frameworks Self-AssemblyMAGNIFY aims to develop a multi-scale computational methodology to decode MOF self-assembly mechanisms, enabling efficient synthesis and rational design of new materials. | ERC Starting... | € 1.340.375 | 2022 | Details |
Mechanisms of co-translational assembly of multi-protein complexesThis project aims to uncover the mechanisms of co-translational protein complex assembly using advanced techniques to enhance understanding of protein biogenesis and its implications for health and disease. | ERC Synergy ... | € 9.458.525 | 2023 | Details |
BiFoldome: Homo- and Hetero-typic Interactions in Assembled FoldomesBiFOLDOME aims to understand co-assembly in amyloids through innovative NMR techniques, enhancing insights into self-assembly and potential applications in disease-related protein manipulation. | ERC Starting... | € 1.496.823 | 2022 | Details |
Supramolecular & Covalent Bonds for Engineering Spatiotemporal Complexity in Hydrogel BiomaterialsThe project aims to develop tough, spatiotemporally responsive hydrogels by combining dynamic supramolecular assemblies with covalent bonds for innovative biomaterial applications. | ERC Consolid... | € 2.000.000 | 2024 | Details |
Physical and molecular underpinnings of the multifunctionality of bacterial peptide assemblies
This project aims to uncover the self-assembly mechanisms of phenol soluble modulins in Staphylococcus aureus to understand their multifunctionality and develop novel therapeutics against infections.
Decoding the Mechanisms Underlying Metal-Organic Frameworks Self-Assembly
MAGNIFY aims to develop a multi-scale computational methodology to decode MOF self-assembly mechanisms, enabling efficient synthesis and rational design of new materials.
Mechanisms of co-translational assembly of multi-protein complexes
This project aims to uncover the mechanisms of co-translational protein complex assembly using advanced techniques to enhance understanding of protein biogenesis and its implications for health and disease.
BiFoldome: Homo- and Hetero-typic Interactions in Assembled Foldomes
BiFOLDOME aims to understand co-assembly in amyloids through innovative NMR techniques, enhancing insights into self-assembly and potential applications in disease-related protein manipulation.
Supramolecular & Covalent Bonds for Engineering Spatiotemporal Complexity in Hydrogel Biomaterials
The project aims to develop tough, spatiotemporally responsive hydrogels by combining dynamic supramolecular assemblies with covalent bonds for innovative biomaterial applications.