Difference between revisions of "Team:Heidelberg/Software"
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Artificial intelligence for Genetic Evolution Mimicking| | Artificial intelligence for Genetic Evolution Mimicking| | ||
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{{Heidelberg/abstract|https://static.igem.org/mediawiki/2017/b/ba/T--Heidelberg--2017_AiGEM_GA.jpg| | {{Heidelberg/abstract|https://static.igem.org/mediawiki/2017/b/ba/T--Heidelberg--2017_AiGEM_GA.jpg| | ||
| − | To simplify the generation desired functionalities <i>de novo</i> and enable evolutionary leaps, we created AiGEM, our Artificial Intelligence for Genetic Evolution Mimicking software suite. The heart of our software is DeeProtein, a deep neuronal network trained on ~10 million protein sequences and able to infer sequence-function relationships from raw sequence data with high accuracy. By interfacing DeeProtein with our genetic algorithm GAIA, we – for the first time - established a fully closed, <i>in silico</i> evolution cycle driven by an intelligent network. We used AiGEM to successfully modulate the catalytic efficiency of beta-lactamases, thereby even producing variants which highly outperform the wild type enzyme. To demonstrate AiGEM’s ability for generating functionality de novo, we created a novel, highly efficient beta-galactosidase purely by <i>in silico</i> evolution of a \(\beta\)-glucuronidase parental sequence. Finally, as part of our integrated human practices project, we implemented SafetyNet, a DeeProtein-based web application safeguarding directed evolution experiments. | + | {{#tag:html| |
| − | }} | + | To simplify the generation desired functionalities <i>de novo</i> and enable evolutionary leaps, we created AiGEM, our Artificial Intelligence for Genetic Evolution Mimicking software suite. The heart of our software is DeeProtein, a deep neuronal network trained on ~10 million protein sequences and able to infer sequence-function relationships from raw sequence data with high accuracy. By interfacing DeeProtein with our genetic algorithm GAIA, we – for the first time - established a fully closed, <i>in silico</i> evolution cycle driven by an intelligent network. We used AiGEM to successfully modulate the catalytic efficiency of \(\beta\)-lactamases, thereby even producing variants which highly outperform the wild type enzyme. To demonstrate AiGEM’s ability for generating functionality de novo, we created a novel, highly efficient \(\beta\)-galactosidase purely by <i>in silico</i> evolution of a \(\beta\) -glucuronidase parental sequence. Finally, as part of our integrated human practices project, we implemented SafetyNet, a DeeProtein-based web application safeguarding directed evolution experiments. |
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Revision as of 19:37, 1 November 2017
AiGEM
Artificial intelligence for Genetic Evolution Mimicking
