Voltage-gated Na+ (Nav) channels are a primary molecular determinant of the action potential (AP). Despite the canonical role of the pore-forming α subunit in conferring this function, protein–protein interactions (PPI) between the Nav channel α subunit and its auxiliary proteins are necessary to reconstitute the full physiological activity of the channel and to fine-tune neuronal excitability. In the brain, the Nav channel isoforms 1.2 (Nav1.2) and 1.6 (Nav1.6) are enriched, and their activities are differentially regulated by the Nav channel auxiliary protein fibroblast growth factor 14 (FGF14). Despite the known regulation of neuronal Nav channel activity by FGF14, less is known about cellular signaling molecules that might modulate these regulatory effects of FGF14. To that end, and building upon our previous investigations suggesting that neuronal Nav channel activity is regulated by a kinase network involving GSK3, AKT, and Wee1, we interrogate in our current investigation how pharmacological inhibition of Wee1 kinase, a serine/threonine and tyrosine kinase that is a crucial component of the G2-M cell cycle checkpoint, affects the Nav1.2 and Nav1.6 channel macromolecular complexes. Our results show that the highly selective inhibitor of Wee1 kinase, called Wee1 inhibitor II, modulates FGF14:Nav1.2 complex assembly, but does not significantly affect FGF14:Nav1.6 complex assembly. These results are functionally recapitulated, as Wee1 inhibitor II entirely alters FGF14-mediated regulation of the Nav1.2 channel, but displays no effects on the Nav1.6 channel. At the molecular level, these effects of Wee1 inhibitor II on FGF14:Nav1.2 complex assembly and FGF14-mediated regulation of Nav1.2-mediated Na+ currents are shown to be dependent upon the presence of Y158 of FGF14, a residue known to be a prominent site for phosphorylation-mediated regulation of the protein. Overall, our data suggest that pharmacological inhibition of Wee1 confers selective modulatory effects on Nav1.2 channel activity, which has important implications for unraveling cellular signaling pathways that fine-tune neuronal excitability.
Voltage-gated Na+ (Nav) channels are the primary molecular determinant of the action potential. Among the nine isoforms of the Nav channel α subunit that have been described (Nav1.1-Nav1.9), Nav1.1, Nav1.2, and Nav1.6 are the primary isoforms expressed in the central nervous system (CNS). Crucially, these three CNS Nav channel isoforms display differential expression across neuronal cell types and diverge with respect to their subcellular distributions. Considering these differences in terms of their localization, the CNS Nav channel isoforms could represent promising targets for the development of targeted neuromodulators. However, current therapeutics that target Nav channels lack selectivity, which results in deleterious side effects due to modulation of off-target Nav channel isoforms. Among the structural components of the Nav channel α subunit that could be pharmacologically targeted to achieve isoform selectivity, the C-terminal domains (CTD) of Nav channels represent promising candidates on account of displaying appreciable amino acid sequence divergence that enables functionally unique protein–protein interactions (PPIs) with Nav channel auxiliary proteins. In medium spiny neurons (MSNs) of the nucleus accumbens (NAc), a critical brain region of the mesocorticolimbic circuit, the PPI between the CTD of the Nav1.6 channel and its auxiliary protein fibroblast growth factor 14 (FGF14) is central to the generation of electrical outputs, underscoring its potential value as a site for targeted neuromodulation. Focusing on this PPI, we previously developed a peptidomimetic derived from residues of FGF14 that have an interaction site on the CTD of the Nav1.6 channel. In this work, we show that whereas the compound displays dose-dependent effects on the activity of Nav1.6 channels in heterologous cells, the compound does not affect Nav1.1 or Nav1.2 channels at comparable concentrations. In addition, we show that the compound correspondingly modulates the action potential discharge and the transient Na+ of MSNs of the NAc. Overall, these results demonstrate that pharmacologically targeting the FGF14 interaction site on the CTD of the Nav1.6 channel is a strategy to achieve isoform-selective modulation, and, more broadly, that sites on the CTDs of Nav channels interacted with by auxiliary proteins could represent candidates for the development of targeted therapeutics.
Targeting the Nav1.6:GSK3β Protein:Protein Interaction Complex to Mitigate Hippocampal Hyperexcitability in Early‐Stage Alzheimer’s Disease
BackgroundNav1.6 is the most densely expressed sodium channel isoform in the adult brain and is a primary determinant of action potential initiation and propagation due to its subcellular localization at the axon initial segment (AIS). Importantly, it has been shown that the firing frequency and Na+ currents of Nav 1.6 channels in hippocampal neurons are specifically increased by Aβ exposure in a concentration‐dependent manner. Nav1.6 is regulated through its interactions with key auxiliary proteins, notably Glycogen Synthase Kinase 3‐β (GSK3β), which has increased expression in the hippocampus of AD patients as well as peripheral circulating lymphocytes in both MCI and AD patients. We have shown that GSK3β regulates Nav1.6 channel activity through phosphorylation of and direct binding to the Nav1.6’s intracellular C‐terminal domain (CTD). Furthermore, genetic silencing of GSK3Ββ significantly decreased both Na+ currents and intrinsic firing compared to controls specifically through Nav1.6, while GSK3Ββ over‐expression or pharmacological disinhibition produced opposing phenotypes. Multiple lines of evidence indicate that hippocampal hyperactivity is present in patients with MCI and early‐stage AD and it is observed that reduction of hippocampal hyperactivity in MCI patients improves cognition and memory performance. We hypothesize that small‐molecule modulation of the Nav1.6:GSK3β PPI interface can counteract hippocampal hyperexcitability and could be used to treat early phases of AD, preventing the onset of cognitive decline.MethodHEK293 cells co‐transfected with WT or mutant Nav1.6 and GSK3β were utilized to interrogate the Nav1.6:GSK3β PPI and screen a series of 50 validated hit compounds using split‐luciferase complementation (LCA). Whole‐cell patch‐clamp electrophysiology was performed in heterologous cells and acute slice preparations to validate GSK3β‐mediated regulation of Nav1.6 activity and evaluate lead compound efficacy.ResultMutagenesis screening revealed putative interaction sites of the Nav1.6:GSK3β PPI. Counter‐screening of 50 validated hits revealed 5 compounds that inhibit Nav1.6:GSK3β complex assembly at low micromolar concentrations (Figure 1). Compound 5671063, identified from the counter‐screen, exhibits functional modulation of Nav1.6 activity in heterologous cells (Figure 2).ConclusionThe Nav1.6:GSK3β complex is a critical mediator of neuronal activity and represents a novel target for treatment of pathological hippocampal hyperexcitability associated with cognitive decline.
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