A photoconversion model for full spectral programming and multiplexing of optogenetic systems

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Abstract: Optogenetics combines externally applied light signals and genetically engineered photoreceptors to control cellular processes with unmatched precision. Here, we develop a mathematical model of wavelength‐ and intensity‐dependent photoconversion, signaling, and output gene expression for our two previously engineered light‐sensing Escherichia coli two‐component systems. To parameterize the model, we develop a simple set of spectral and dynamical calibration experiments using our recent open‐source “Light Plate Apparatus” device. In principle, the parameterized model should predict the gene expression response to any time‐varying signal from any mixture of light sources with known spectra. We validate this capability experimentally using a suite of challenging light sources and signals very different from those used during the parameterization process. Furthermore, we use the model to compensate for significant spectral cross‐reactivity inherent to the two sensors in order to develop a new method for programming two simultaneous and independent gene expression signals within the same cell. Our optogenetic multiplexing method will enable powerful new interrogations of how metabolic, signaling, and decision‐making pathways integrate multiple input signals.

Location
Deutsche Nationalbibliothek Frankfurt am Main
Extent
Online-Ressource
Language
Englisch

Bibliographic citation
A photoconversion model for full spectral programming and multiplexing of optogenetic systems ; volume:13 ; number:4 ; year:2017 ; extent:13
Molecular systems biology ; 13, Heft 4 (2017) (gesamt 13)

Creator
Olson, Evan J.
Tzouanas, Constantine N.
Tabor, Jeffrey J.

DOI
10.15252/msb.20167456
URN
urn:nbn:de:101:1-2022100508251683793378
Rights
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
Last update
15.08.2025, 7:31 AM CEST

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Associated

  • Olson, Evan J.
  • Tzouanas, Constantine N.
  • Tabor, Jeffrey J.

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