Abstract
Cells sense various environmental cues and process intracellular signals to decide their migration direction in many physiological and pathological processes. Although several signaling molecules have been identified in these directed migrations, it still remains elusive how cells decipher multiple cues, specifically chemical and fluidic cues. Here, we investigated the cellular signal processing machinery by reverse-engineering directed cell migration under integrated chemical and fluidic cues. We exposed controlled chemical and fluidic cues to cells using a microfluidic platform and analyzed the extracellular coupling of the cues with respect to the cellular detection limit. Then, the cell’s migratory behavior was reverse-engineered to build the cell’s intrinsic signal processing system as a logic gate. Our primary finding is that the cellular signal processing machinery functions as a ternary logic gate to decipher integrated chemical and fluidic cues. The proposed framework of the ternary logic gate suggests a systematic approach to understand how cells decode multiple cues to make decisions in migration.
Competing Interest Statement
The authors have declared no competing interest.