Abstract
A DNA reaction circuit consisting of components E/Q(1), E(1)/T(1), F/Q(1), and F(1)/T(1) in which each includes the antimesenchymal epithelial transition (Met) receptor aptamer sequence is anchored within MCF-7 cells to emulate the natural signaling network on the live cell membrane. Subjecting the membrane-integrated circuit to an auxiliary fuel strand, in the presence of a nicking enzyme, results in the dynamic reconfiguration of the circuit into a constitutional dynamic network, CDN, in which the pre-engineered duplex interactions between the constituents lead to allosterically stabilized Met-dimer complexes. The concomitant nickase-induced separation of the CDN leads to the parent reaction circuit, and to the transient formation and depletion of the Met-dimer complex. By labeling the components comprising the reaction circuits with fluorophores, the dynamic transient reconfiguration of the CDN and the accompanying Met-dimer formation and separation within the cell membranes are characterized by temporal confocal fluorescence microscopy imaging. Moreover, the transient formation of the Met-dimer in the MCF-7 cell membrane induces intracellular signaling and activation of the Akt/FAK phosphorylation pathway. This is reflected by the network-guided control over the transient migration/motility functions of the MCF-7 cells.