Impaired AIS plasticity in ankyrin-G mutant mice alters cortical excitability and behavior.
Min Li, Bingqing Zhao, Zhimin Lu, Liu Zhe, Yue Han, Yating Chen, Huichao Wang, Yu Wang, Chunsheng Wu, Mingjie Zhang, Keyu Chen, Rui Yang
Abstract
Open AccessThe developing brain undergoes neuroplasticity driven by learning, experience, and memory formation. The axon initial segment (AIS) is a specialized membrane domain within the proximal axon that initiates action potential. Studies have demonstrated that the AIS exhibits plasticity by altering its length and/or localization to adjust the excitability in response to neural stimuli. However, how AIS plasticity may affect brain function is unclear. The 480-kDa giant ankyrin-G protein (gAnkG) is the master organizer of AISs and nodes of Ranvier. Previously, we reported that a neurodevelopmental disorder-linked variant (Thr1861Met) in the neuron-specific domain of gAnkG causes the formation of diffused AISs in cultured ankyrin-G null neurons. Here, we generated a knock-in mouse harboring this mutation. The knock-in mice displayed impairments in motor coordination and social interaction. Neurons from these knock-in mice formed elongated AISs with no significant reduction in the accumulation of key AIS components-including ankyrin-G, β4-spectrin, voltage-gated sodium channels, and neurofascin. Crucially, unlike wild-type AISs, which shorten in response to stimulation by high K+ or chemogenetics (designer receptors exclusively activated by designer drugs), the elongated AISs in mutant neurons failed to undergo such shortening, indicating a deficit in AIS plasticity. Neurons in the primary motor cortex and anterior cingulate cortex of knock-in mice exhibited AISs of normal length at early stage but failed to undergo the developmental shortening observed in wild-type neurons; by postnatal day 60, this resulted in elongated AISs and increased neuronal excitability in these regions. Thus, the gAnkG protein mutation impairs activity-dependent AIS plasticity, leading to abnormal neuronal excitability and behavioral deficits.