Abstract
Biological organisms use their sensory systems to detect changes in their environment. The ability of sensory systems to adapt to static inputs allows wide dynamic range as well as sensitivity to input changes including fold-change detection, a response that depends only on fold changes in input, and not on absolute changes. This input scale invariance underlies an important strategy for search that depends solely on the spatial profile of the input. Synthetic efforts to reproduce the architecture and response of cellular circuits provide an important step to foster understanding at the molecular level. We report the bottom-up assembly of biochemical systems that show exact adaptation and fold-change detection. Using a malachite green aptamer as the output, a synthetic transcriptional circuit with the connectivity of an incoherent feed-forward loop motif exhibits pulse generation and exact adaptation. A simple mathematical model was used to assess the amplitude and duration of pulse response as well as the parameter regimes required for fold-change detection. Upon parameter tuning, this synthetic circuit exhibits fold-change detection for four successive rounds of two-fold input changes. The experimental realization of fold-change detection circuit highlights the programmability of transcriptional switches and the ability to obtain predictive dynamical systems in a cell-free environment for technological applications.
Highlights
Biological organisms use their sensory systems to respond to changes in their environment
One of the common features found in many sensory systems is exact adaptation in which the output upon change of input to a new constant level gradually returns to a steady level independent of the input [1,2]
Using the synthetic transcriptional switch as the regulatory motif and the aptamer for the chromophore Malachite Green (MG) as the output signal, we construct an incoherent feed-forward loop (IFFL) motif (Figure 1B). (Preliminary design and analysis of IFFL circuit was reported in [30].) We designed two transcriptional switches that share common input domains such that they are both activated by a single DNA activator A, serving the role of input u
Summary
Biological organisms use their sensory systems to respond to changes in their environment. Fold-change detection can be generated by IFFL within a certain range of parameters, for example, when the intermediate species is a strong repressor of output [15]; this awaits experimental demonstration [16]. Synthetic circuits that demonstrate hallmarks of fold-change detection through IFFL motif provide evidence that this design is sufficient for foldchange detection with biochemically realizable parameters. This helps illustrate that such design may exist in natural biological networks as proposed from previous mathematical analysis and further it could form the basis of exquisite sensing capabilities with biotechnological applications
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