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Complex signal processing in synthetic gene circuits using cooperative regulatory assemblies.

Caleb J BashorNikit PatelSandeep ChoubeyAli BeyzaviJané KondevJames J CollinsAhmad S Khalil
Published in: Science (New York, N.Y.) (2019)
Eukaryotic genes are regulated by multivalent transcription factor complexes. Through cooperative self-assembly, these complexes perform nonlinear regulatory operations involved in cellular decision-making and signal processing. In this study, we apply this design principle to synthetic networks, testing whether engineered cooperative assemblies can program nonlinear gene circuit behavior in yeast. Using a model-guided approach, we show that specifying the strength and number of assembly subunits enables predictive tuning between linear and nonlinear regulatory responses for single- and multi-input circuits. We demonstrate that assemblies can be adjusted to control circuit dynamics. We harness this capability to engineer circuits that perform dynamic filtering, enabling frequency-dependent decoding in cell populations. Programmable cooperative assembly provides a versatile way to tune the nonlinearity of network connections, markedly expanding the engineerable behaviors available to synthetic circuits.
Keyphrases
  • transcription factor
  • genome wide identification
  • genome wide
  • decision making
  • dna binding
  • copy number
  • single cell
  • genome wide analysis
  • dna methylation
  • gene expression
  • genetic diversity