Litcius/Paper detail

Massive experimental quantification allows interpretable deep learning of protein aggregation

Michael Thompson, Mariano Martín, Trinidad Sanmartín Olmo, Chandana Rajesh, Peter K. Koo, Benedetta Bolognesi, Ben Lehner

2025Science Advances32 citationsDOIOpen Access PDF

Abstract

Protein aggregation is a pathological hallmark of more than 50 human diseases and a major problem for biotechnology. Methods have been proposed to predict aggregation from sequence, but these have been trained and evaluated on small and biased experimental datasets. Here we directly address this data shortage by experimentally quantifying the aggregation of >100,000 protein sequences. This unprecedented dataset reveals the limited performance of existing computational methods and allows us to train CANYA, a convolution-attention hybrid neural network that accurately predicts aggregation from sequence. We adapt genomic neural network interpretability analyses to reveal CANYA's decision-making process and learned grammar. Our results illustrate the power of massive experimental analysis of random sequence-spaces and provide an interpretable and robust neural network model to predict aggregation.

Topics & Concepts

Computer scienceDeep learningComputational biologyProtein aggregationArtificial intelligenceBiological systemChemistryBiologyBiochemistryProtein Structure and DynamicsCell Image Analysis TechniquesBioinformatics and Genomic Networks