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A Formalized Design Process for Bacterial Consortia That Perform Logic Computing

Author

Listed:
  • Weiyue Ji
  • Handuo Shi
  • Haoqian Zhang
  • Rui Sun
  • Jingyi Xi
  • Dingqiao Wen
  • Jingchen Feng
  • Yiwei Chen
  • Xiao Qin
  • Yanrong Ma
  • Wenhan Luo
  • Linna Deng
  • Hanchi Lin
  • Ruofan Yu
  • Qi Ouyang

Abstract

The concept of microbial consortia is of great attractiveness in synthetic biology. Despite of all its benefits, however, there are still problems remaining for large-scaled multicellular gene circuits, for example, how to reliably design and distribute the circuits in microbial consortia with limited number of well-behaved genetic modules and wiring quorum-sensing molecules. To manage such problem, here we propose a formalized design process: (i) determine the basic logic units (AND, OR and NOT gates) based on mathematical and biological considerations; (ii) establish rules to search and distribute simplest logic design; (iii) assemble assigned basic logic units in each logic operating cell; and (iv) fine-tune the circuiting interface between logic operators. We in silico analyzed gene circuits with inputs ranging from two to four, comparing our method with the pre-existing ones. Results showed that this formalized design process is more feasible concerning numbers of cells required. Furthermore, as a proof of principle, an Escherichia coli consortium that performs XOR function, a typical complex computing operation, was designed. The construction and characterization of logic operators is independent of “wiring” and provides predictive information for fine-tuning. This formalized design process provides guidance for the design of microbial consortia that perform distributed biological computation.

Suggested Citation

  • Weiyue Ji & Handuo Shi & Haoqian Zhang & Rui Sun & Jingyi Xi & Dingqiao Wen & Jingchen Feng & Yiwei Chen & Xiao Qin & Yanrong Ma & Wenhan Luo & Linna Deng & Hanchi Lin & Ruofan Yu & Qi Ouyang, 2013. "A Formalized Design Process for Bacterial Consortia That Perform Logic Computing," PLOS ONE, Public Library of Science, vol. 8(2), pages 1-9, February.
    • Handle: RePEc:plo:pone00:0057482
    DOI: 10.1371/journal.pone.0057482
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    References listed on IDEAS

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