TY - JOUR
T1 - Synchrony and pattern formation of coupled genetic oscillators on a chip of artificial cells
AU - Tayar, Alexandra M.
AU - Karzbrun, Eyal
AU - Noireaux, Vincent
AU - Bar-Ziv, Roy H.
N1 - Author contributions: A.M.T., E.K., V.N., and R.H.B.-Z. designed research; A.M.T. performed research; A.M.T. and R.H.B.-Z. analyzed data; and A.M.T., E.K., V.N., and R.H.B.-Z. wrote the paper.
PY - 2017/10/31
Y1 - 2017/10/31
N2 - Understanding how biochemical networks lead to large-scale non equilibrium self-organization and pattern formation in life is a major challenge, with important implications for the design of programmable synthetic systems. Here, we assembled cell-free genetic oscillators in a spatially distributed system of on-chip DNA compartments as artificial cells, and measured reaction-diffusion dynamics at the single cell level up to the multicell scale. Using a cell-free gene network we programmed molecular interactions that control the frequency of oscillations, population variability, and dynamical stability. We observed frequency entrainment, synchronized oscillatory reactions and pattern formation in space, as manifestation of collective behavior. The transition to synchrony occurs as the local coupling between compartments strengthens. Spatiotemporal oscillations are induced either by a concentration gradient of a diffusible signal, or by spontaneous symmetry breaking close to a transition from oscillatory to nonoscillatory dynamics. This work offers design principles for programmable biochemical reactions with potential applications to autonomous sensing, distributed computing, and biomedical diagnostics.
AB - Understanding how biochemical networks lead to large-scale non equilibrium self-organization and pattern formation in life is a major challenge, with important implications for the design of programmable synthetic systems. Here, we assembled cell-free genetic oscillators in a spatially distributed system of on-chip DNA compartments as artificial cells, and measured reaction-diffusion dynamics at the single cell level up to the multicell scale. Using a cell-free gene network we programmed molecular interactions that control the frequency of oscillations, population variability, and dynamical stability. We observed frequency entrainment, synchronized oscillatory reactions and pattern formation in space, as manifestation of collective behavior. The transition to synchrony occurs as the local coupling between compartments strengthens. Spatiotemporal oscillations are induced either by a concentration gradient of a diffusible signal, or by spontaneous symmetry breaking close to a transition from oscillatory to nonoscillatory dynamics. This work offers design principles for programmable biochemical reactions with potential applications to autonomous sensing, distributed computing, and biomedical diagnostics.
U2 - https://doi.org/10.1073/pnas.1710620114
DO - https://doi.org/10.1073/pnas.1710620114
M3 - مقالة
SN - 0027-8424
VL - 114
SP - 11609
EP - 11614
JO - Proceedings Of The National Academy Of Sciences Of The United States Of America-Physical Sciences
JF - Proceedings Of The National Academy Of Sciences Of The United States Of America-Physical Sciences
IS - 44
ER -