Neurogranin Unlocks the L-type Ca²⁺ Channel and Directs Calmodulin Delivery

Neurogranin (Ng) is enriched in the postsynaptic density, with mounting evidence of its importance to neural pathophysiology. Ng has long been recognized as a dedicated calmodulin (CaM)- binding/buffering protein. This study demonstrates that Ng, through its CaM-binding IQ domain, directly binds the distal C-terminus (DCT) of the L-type Ca ²⁺ (CaV1) channel, as a de novo mechanism regulating excitation-transcription coupling. The Ng/DCT interaction attenuates autonomous C- terminus-mediated inhibition and promotes specific CaM delivery to CaV1, cooperatively enhancing channel gating (activation and inactivation), Ca ²⁺ influx and downstream neuronal signaling. Phosphorylation of Ng leads to the dissociation of the CaM C-lobe, while transiently forming the linkage with the CaM N-lobe. In contrast to neurodegenerative disease-related Ng mutants, WT Ng, within the above transient complex, enables the “targeted CaM transfer” to the proximal C-terminus of CaV1. Collective evidence from electrophysiology, binding assays, structural modeling and Ca ²⁺ imaging supports a paradigm of dynamic intra- and inter-molecular interactions/facilitations underlying Ng and CaV1, both of which are representative CaM-binding proteins. This work proposes a mechanistic scheme potentially applicable to a broad scope of CaM-related physiology.