Mechanical stress is a ubiquitous stimulus sensed by membrane proteins, but rarely by synthetic molecules. Inspired by mechano-sensitive ion channels found in cell membranes, tension-responsive transmembrane multiblock amphiphiles were developed. In membranes, a single-transmembrane amphiphile responds to both expanding and contracting tensions to weaken and strengthen the stacking of membrane-spanning units, respectively, and ion transportation is triggered by expanding tension to form a supramolecular channel, while little transportation is observed under a tensionless condition. In contrast, a three-transmembrane amphiphile showed little spectroscopic response to tensions, likely due to weaker stacking of membrane-spanning units than in the single-transmembrane amphiphile. Nevertheless, the three-transmembrane amphiphile shows ion transportation by forming a unimolecular channel even under a tensionless condition, and the ion-transporting activity decreased with expanding tension. Interestingly, the estimated operating force of these synthetic systems was comparable to that of the mechano-sensitive proteins. This study opens the door toward new mechano-sensitive molecular devices.