Pka/Cip4 Signaling Regulates Cip4 Relocation In Activated Natural Killer Cells

Natural killer (NK) cells are cytotoxic lymphocytes of the innate immune system that eliminate virus-infected and transformed cells through the formation of a specialized immune synapse. Effective target cell killing requires coordinated plasma membrane remodeling and dynamic reorganization of the actin and microtubule cytoskeletons, enabling centrosome polarization and directed secretion of lytic granules. The scaffold protein CIP4 has emerged as an important regulator of cytoskeletal coordination in NK cells, yet how its subcellular localization is controlled during NK cell activation is unknown. CIP4 contains a unique protein kinase A (PKA) phosphorylation site (threonine 225, T225) within its F-BAR domain, a domain that mediates interactions with microtubules and the plasma membrane. We hypothesized that localized PKA signaling controls CIP4 redistribution during immune synapse assembly. To test this hypothesis, we analyzed CIP4 localization and phosphorylation in NK cells engaged with sensitive target cells using biochemical and imaging approaches. We show that NK-target cell interaction enhances PKA activity and promotes phosphorylation of CIP4, coinciding with its delocalization from microtubules and accumulation at the immune synapse. Importantly, this relocalization process requires the PKA-anchoring protein AKAP350, which positions PKA and CIP4 within the same protein complex, thereby facilitating CIP4 phosphorylation. Consistently, pharmacological inhibition of PKA prevented CIP4 delocalization from microtubules and reduced its accumulation at the immune synapse. The non-phosphorylatable CIP4 mutant T225A displayed increased association with microtubules compared with a phosphomimetic mutant, identifying phosphorylation at T225 as a key determinant of CIP4 spatial regulation. Together, these findings identify a signaling mechanism that links compartmentalized PKA activity to the spatial control of CIP4 during immune synapse formation, providing new insight into the molecular mechanisms governing immune synapse maturation.