Litcius/Paper detail

Deep learning for optimization of protein expression

Evangelos-Marios Nikolados, Diego A. Oyarzún

2023Current Opinion in Biotechnology23 citationsDOIOpen Access PDF

Abstract

Advances in high-throughput DNA synthesis and sequencing have fuelled the use of massively parallel reporter assays for strain characterization. These experiments produce large datasets that map DNA sequences to protein expression levels, and have sparked increased interest in data-driven methods for sequence-to-expression modeling. Here, we highlight progress in deep learning models of protein expression and their potential for optimizing strains engineered to produce recombinant proteins. We discuss recent works that built highly accurate models as well as the challenges that hinder wider adoption by end users. There is a need to better align this technology with the requirements and capabilities encountered in strain engineering, particularly the cost of data acquisition and the need for interpretable models that generalize beyond the training data. Overcoming these barriers will help to incentivize academic and industrial laboratories to tap into a new era of data-centric strain engineering.

Topics & Concepts

Protein expressionComputer scienceDeep learningSynthetic biologyMassively parallelExpression (computer science)DNA sequencingComputational biologyThroughputArtificial intelligenceData scienceMachine learningDNABiologyGeneTelecommunicationsGeneticsParallel computingProgramming languageWirelessRNA and protein synthesis mechanismsViral Infectious Diseases and Gene Expression in InsectsBacterial Genetics and Biotechnology
Deep learning for optimization of protein expression | Litcius