Biosystems Design by Machine Learning

Biosystems such as enzymes, pathways, and whole cells have been increasingly explored for biotechnological applications. However, the intricate connectivity and resulting complexity of biosystems poses a major hurdle in designing biosystems with desirable features. As -omics and other high throughpu...

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Veröffentlicht in:	ACS synthetic biology 2020-07, Vol.9 (7), p.1514-1533
Hauptverfasser:	Volk, Michael Jeffrey, Lourentzou, Ismini, Mishra, Shekhar, Vo, Lam Tung, Zhai, Chengxiang, Zhao, Huimin
Format:	Artikel
Sprache:	eng
Schlagworte:	BASIC BIOLOGICAL SCIENCES Biosystems design Machine learning Metabolic engineering Synthetic biology
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creator	Volk, Michael Jeffrey Lourentzou, Ismini Mishra, Shekhar Vo, Lam Tung Zhai, Chengxiang Zhao, Huimin
description	Biosystems such as enzymes, pathways, and whole cells have been increasingly explored for biotechnological applications. However, the intricate connectivity and resulting complexity of biosystems poses a major hurdle in designing biosystems with desirable features. As -omics and other high throughput technologies have been rapidly developed, the promise of applying machine learning (ML) techniques in biosystems design has started to become a reality. ML models enable the identification of patterns within complicated biological data across multiple scales of analysis and can augment biosystems design applications by predicting new candidates for optimized performance. ML is being used at every stage of biosystems design to help find nonobvious engineering solutions with fewer design iterations. In this review, we first describe commonly used models and modeling paradigms within ML. We then discuss some applications of these models that have already shown success in biotechnological applications. Moreover, we discuss successful applications at all scales of biosystems design, including nucleic acids, genetic circuits, proteins, pathways, genomes, and bioprocesses. Finally, we discuss some limitations of these methods and potential solutions as well as prospects of the combination of ML and biosystems design.
doi_str_mv	10.1021/acssynbio.0c00129
format	Article
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subjects	BASIC BIOLOGICAL SCIENCES Biosystems design Machine learning Metabolic engineering Synthetic biology
title	Biosystems Design by Machine Learning
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