Directed evolution of a genetic circuit

Creators: Yokobayashi, Yohei; Weiss, Ron; Arnold, Frances H.

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Abstract

The construction of artificial networks of transcriptional control elements in living cells represents a new frontier for biological engineering. However, biological circuit engineers will have to confront their inability to predict the precise behavior of even the most simple synthetic networks, a serious shortcoming and challenge for the design and construction of more sophisticated genetic circuitry in the future. We propose a combined rational and evolutionary design strategy for constructing genetic regulatory circuits, an approach that allows the engineer to fine-tune the biochemical parameters of the networks experimentally in vivo. By applying directed evolution to genes comprising a simple genetic circuit, we demonstrate that a nonfunctional circuit containing improperly matched components can evolve rapidly into a functional one. In the process, we generated a library of genetic devices with a range of behaviors that can be used to construct more complex circuits.

Additional Information

© 2002 by The National Academy of Sciences. From the Cover. Edited by Charles R. Cantor, Sequenom, Inc., San Diego, CA, and approved October 21, 2002 (received for review September 3, 2002) This paper was submitted directly (Track II) to the PNAS office. This research was supported by National Science Foundation, Biological Information Technology and Storage (BITS) Grant EIA-0130613 and Maxygen Corporation. Y.Y. is supported by a Japan Society for the Promotion of Science Postdoctoral Fellowship for Research Abroad.

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