The importance of hydrogen bonding has prompted us to investigate systems in which the strengths of hydrogen bonds can be modulated at will by external stimuli. Three-component systems consisting of a hydrogen-bonding site (electron donor), a bridge, and a reaction center (electron acceptor) have been designed to achieve this goal of hydrogen-bonding modulation. When the reaction center was protonated, a signal was sent out to the other end of the three-component molecule via intramolecular charge transfer (ICT) and thus affected the binding ability of the binding site. It has been found that the constituents of the bridge greatly influence the efficiency of remote signal communication between the reaction and binding centers. In the current theoretical study, we focused on the carbon-based conjugated bridges and studied the effects of bridge structure and substituents on signal transduction. It was found that the quinoidal bridges or bridges with cyano substitutions near the reaction center were more effective than the parent unsubstituted transoid (CH=CH)3 bridge. For bridges such as (CR1=CR2)n or (CR1=CR1-CR2=CR2)n, signal reduction due to longer bridge lengths could be minimized if R2 are substituted with electron-withdrawing substituents such as F and CN. Finally, the (C(CN)=C(CN))n bridges are signal amplifying, i.e., longer bridge lengths cause stronger binding change at the binding site.