Intracellular signaling nodes can sample multiple inputs and induce different cellular outputs. High combinatorial between their numerous potential conformational intermediaries having distinct enzymatic activities and/or repertoire of partners makes it challenging to determine their dynamic coding molecularly. We have combined protein engineering with optogenetic to investigate coding functions of specific intermediaries of the kinase Src, a representative example of versatile signaling node. Optogenetic is used to generate local flux of specific Src intermediaries, as Src dimers, into adhesion sites. Modulations of this molecular flux are sufficient to code different Src signaling pathways and Src-dependent cellular outputs implicated in migration or invasion. This response selectivity is based on the ability for each flux of Src conformational intermediary to generate distinct Src signaling waves in protein-protein interaction networks revealed by time-resolved analysis of phosphotyrosine-proteome. Thus, the pleiotropy of a signaling node is molecularly coded by modulation of its local fluxes of specific conformational intermediaries.