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An automated platform for accelerating and focusing adaptive laboratory evolution.

Peter Ruppen1, Maximilian Ole Bahls1, Michael Sebastian Gerlt2

  • 1Department of Biosystems Science and Engineering, ETH Zürich, Basel, Switzerland.

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Summary

This study presents an automated microfluidic platform that accelerates bacterial transformation via electroporation. This innovation streamlines adaptive laboratory evolution (ALE) for engineering novel microbial phenotypes.

Keywords:
AutomationE. coliElectroporationGenome editingMedium exchangeMicrofluidicsTransformation

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Area of Science:

  • Microbiology
  • Synthetic Biology
  • Biotechnology

Background:

  • Adaptive laboratory evolution (ALE) is vital for developing microorganisms with desired traits under selective pressure.
  • ALE is often slow due to mutagenesis rates and the labor-intensive nature of genetic engineering.
  • Existing genome editing methods are cumbersome and conflict with the continuous ALE process.

Purpose of the Study:

  • To develop an automated microfluidic platform to accelerate bacterial transformation.
  • To integrate transformation with ALE for efficient engineering of microbial phenotypes.
  • To demonstrate the platform's utility in a riboflavin prototrophy engineering experiment.

Main Methods:

  • Development of a fully integrated microfluidic platform for automated bacterial electroporation.
  • Application of oligonucleotide-directed mutagenesis within the microfluidic system.
  • Integration of the platform with an adaptive laboratory evolution experiment in Escherichia coli.

Main Results:

  • The microfluidic platform automates and significantly accelerates bacterial transformation.
  • The system streamlines the engineering process, making it less labor-intensive.
  • Demonstrated successful acceleration of engineering riboflavin prototrophy in E. coli.

Conclusions:

  • Automated microfluidic electroporation platforms can overcome limitations in ALE.
  • This technology facilitates rapid engineering of complex microbial traits.
  • The platform offers a push-button solution for accelerating microbial evolution and engineering.