A hallmark of living systems is their ability to respond and adapt to many types of exogenous and endogenous cues. At the core of this capability lie the evolved mechanisms of cellular signaling which perform the relay of biochemical signals throughout the cell. Much of this core signaling functionality in living systems is afforded by the ability of proteins to change their chemical and structural “status”, by populating distinct states in conformational landscapes, undergoing post-translational modifications that alter these populations, and dynamically interacting with other cellular partners. Despite the remarkable advances we have witnessed in computational protein design, it remains an outstanding challenge to rationally design many of these aspects that are at the core of biological function. Here, we set out to design a minimal signaling network triggered by phosphorylation, which relies on de novo components that sample low-populated conformational states to control a designed protein interaction. In these designed components we implemented principles of signal amplification, conformational heterogeneity and molecular recognition which are ubiquitously used by nature to sustain biological function in cells. The designed proteins were biochemically and structurally characterized and ultimately are functional in cell-based systems where they regulate the transcription of reporter proteins in a phosphorylation-dependent manner. Overall, this work lays the foundation for designing synthetic signaling cascades using de novo protein components, which could be important to enhance our understanding of natural systems and for relevant applications in synthetic biology.