Time-optimized protein NMR assignment with an integrative deep learning approach using AlphaFold and chemical shift prediction.
Piotr KlukowskiRoland RiekPeter GüntertPublished in: Science advances (2023)
Chemical shift assignment is vital for nuclear magnetic resonance (NMR)-based studies of protein structures, dynamics, and interactions, providing crucial atomic-level insight. However, obtaining chemical shift assignments is labor intensive and requires extensive measurement time. To address this limitation, we previously proposed ARTINA, a deep learning method for automatic assignment of two-dimensional (2D)-4D NMR spectra. Here, we present an integrative approach that combines ARTINA with AlphaFold and UCBShift, enabling chemical shift assignment with reduced experimental data, increased accuracy, and enhanced robustness for larger systems, as presented in a comprehensive study with more than 5000 automated assignment calculations on 89 proteins. We demonstrate that five 3D spectra yield more accurate assignments (92.59%) than pure ARTINA runs using all experimentally available NMR data (on average 10 3D spectra per protein, 91.37%), considerably reducing the required measurement time. We also showcase automated assignments of only 15 N-labeled samples, and report improved assignment accuracy in larger synthetic systems of up to 500 residues.
Keyphrases
- deep learning
- magnetic resonance
- high resolution
- machine learning
- density functional theory
- solid state
- artificial intelligence
- convolutional neural network
- protein protein
- big data
- electronic health record
- binding protein
- high throughput
- contrast enhanced
- magnetic resonance imaging
- small molecule
- mass spectrometry
- positron emission tomography
- data analysis
- case control