metadata
license: apache-2.0
Struct2Seq-GNN
Model Description
Struct2Seq-GNN is a lightweight, 6-layer Graph Neural Network designed for inverse protein folding (structure-to-sequence prediction). By mapping the 3D spatial coordinates of protein backbones to their corresponding amino acid sequences, this model serves as a foundational tool for computational protein engineering and structural bioinformatics workflows.
Intended Uses & Limitations
- Primary Use: Computational protein design, generating plausible sequences for novel or heavily modified protein backbones.
- Limitations: This is a lightweight architecture built as an independent research project. While it achieves high native sequence recovery, it is not intended for out-of-the-box production of clinical therapeutics without further validation and optimization.
Training Data & Procedure
- Dataset: Trained on biological protein assemblies from the PDB, clustered at a 30% sequence identity cutoff to prevent data leakage.
- Data Augmentation: During training, 0.1 Å standard deviation Gaussian noise was applied to all input atomic coordinates. This critical augmentation prevents the model from "reading out" the native sequence from over-refined crystal artifacts, forcing it to learn the underlying biophysics of the fold.
- Hardware: Trained efficiently over ~65 epochs on a 4-GPU HPC cluster.
Evaluation Metrics
The model demonstrates strong generalization and robust learning of physical constraints:
- Global Sequence Recovery: ~33% validation accuracy across all residues. (Achieving >30% sequence identity strongly suggests the generated sequences will reliably adopt the target 3D fold).
- Convergence: Validation loss plateaued smoothly at ~2.236.
- (Optional: Add your 5.0 Å binding pocket recovery metric here once you calculate it!)