Epistatic Net allows the sparse spectral regularization of deep neural networks for inferring fitness functions

Aghazadeh, Amirali; Nisonoff, Hunter; Ocal, Orhan; Brookes, David H.; Huang, Yijie; Koyluoglu, O. Ozan; Listgarten, Jennifer; Ramchandran, Kannan

Epistatic Net allows the sparse spectral regularization of deep neural networks for inferring fitness functions

Amirali Aghazadeh, Hunter Nisonoff, Orhan Ocal, David H. Brookes, Yijie Huang, O. Ozan Koyluoglu, Jennifer Listgarten and Kannan Ramchandran ()
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Amirali Aghazadeh: Department of Electrical Engineering and Computer Sciences
Hunter Nisonoff: Center for Computational Biology
Orhan Ocal: Department of Electrical Engineering and Computer Sciences
David H. Brookes: University of California
Yijie Huang: Department of Electrical Engineering and Computer Sciences
O. Ozan Koyluoglu: Department of Electrical Engineering and Computer Sciences
Jennifer Listgarten: Department of Electrical Engineering and Computer Sciences
Kannan Ramchandran: Department of Electrical Engineering and Computer Sciences

Nature Communications, 2021, vol. 12, issue 1, 1-10

Abstract: Abstract Despite recent advances in high-throughput combinatorial mutagenesis assays, the number of labeled sequences available to predict molecular functions has remained small for the vastness of the sequence space combined with the ruggedness of many fitness functions. While deep neural networks (DNNs) can capture high-order epistatic interactions among the mutational sites, they tend to overfit to the small number of labeled sequences available for training. Here, we developed Epistatic Net (EN), a method for spectral regularization of DNNs that exploits evidence that epistatic interactions in many fitness functions are sparse. We built a scalable extension of EN, usable for larger sequences, which enables spectral regularization using fast sparse recovery algorithms informed by coding theory. Results on several biological landscapes show that EN consistently improves the prediction accuracy of DNNs and enables them to outperform competing models which assume other priors. EN estimates the higher-order epistatic interactions of DNNs trained on massive sequence spaces-a computational problem that otherwise takes years to solve.

Date: 2021
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DOI: 10.1038/s41467-021-25371-3

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