Abstract
Natural systems use weak interactions and avidity effects to give biological systems high specificity and signal-to-noise ratios. Here we describe design principles for engineering fusion proteins that target therapeutic fusion proteins to membrane-bound signaling receptors by first binding to designer-chosen co-receptors on the same cell surface. The key design elements are separate protein modules, one that has no signaling activity and binds to a cell surface receptor with high affinity and a second that binds to a receptor with low or moderate affinity and carries out a desired signaling or inhibitory activity. These principles are inspired by natural cytokines such as CNTF, IL-2, and IL-4 that bind strongly to nonsignaling receptors and then signal through low-affinity receptors. Such designs take advantage of the fact that when a protein is anchored to a cell membrane, its local concentration is extremely high with respect to those of other membrane proteins, so a second-step, low-affinity binding event is favored. Protein engineers have used these principles to design treatments for cancer, anemia, hypoxia, and HIV infection.