RESUMEN
The ability to chemically introduce lipid modifications to specific intracellular protein targets would enable the conditional control of protein localization and activity in living cells. We recently developed a chemical-genetic approach in which an engineered SNAP-tag fusion protein can be rapidly relocated and anchored from the cytoplasm to the plasma membrane (PM) upon post-translational covalent lipopeptide conjugation in cells. However, the first-generation system achieved only low to moderate protein anchoring (recruiting) efficiencies and lacked wide applicability. Herein, we describe the rational design of an improved system for intracellular synthetic lipidation-induced PM anchoring of SNAP-tag fusion proteins. In the new system, the SNAPf protein engineered to contain an N-terminal hexalysine (K6) sequence and a C-terminal 10-amino acid deletion, termed K6-SNAPΔ, is fused to a protein of interest. In addition, a SNAP-tag substrate containing a metabolic-resistant myristoyl-DCys lipopeptidomimetic, called mDcBCP, is used as a cell-permeable chemical probe for intracellular SNAP-tag lipidation. The use of this combination allows significantly improved conditional PM anchoring of SNAP-tag fusion proteins. This second-generation system was applied to activate various signaling proteins, including Tiam1, cRaf, PI3K, and Sos, upon synthetic lipidation-induced PM anchoring/recruitment, offering a new and useful research tool in chemical biology and synthetic biology.