Coupling of Slack and NaV1.6 sensitizes Slack to quinidine blockade and guides anti-seizure strategy development

Tian Yuan; Yifan Wang; Yuchen Jin; Hui Yang; Shuai Xu; Heng Zhang; Qian Chen; Na Li; Xinyue Ma; Huifang Song; Chao Peng; Ze Geng; Jie Dong; Guifang Duan; Qi Sun; Yang Yang; Fan Yang; Zhuo Huang

doi:10.7554/eLife.87559.3

eLife assessment

The authors report that an interaction between the sodium-activated potassium channel Slack and Nav1.6 sensitizes Slack to inhibition by quinidine. This is an important finding because it contributes to our understanding of how the antiseizure drug quinidine affects epilepsy syndromes arising from mutations in the Slack-encoding gene KCNT1. The results are largely compelling and the work will likely spark interest in further examining the proposed channel-channel interaction in neuronal cell membranes.

https://doi.org/10.7554/eLife.87559.3.sa3

Significance of findings

important: Findings that have theoretical or practical implications beyond a single subfield

landmark
fundamental
important
valuable
useful

Strength of evidence

compelling: Evidence that features methods, data and analyses more rigorous than the current state-of-the-art

exceptional
compelling
convincing
solid
incomplete
inadequate

During the peer-review process the editor and reviewers write an eLife assessment that summarises the significance of the findings reported in the article (on a scale ranging from landmark to useful) and the strength of the evidence (on a scale ranging from exceptional to inadequate). Learn more about eLife assessments

Abstract

Quinidine has been used as an anticonvulsant to treat patients with KCNT1-related epilepsy by targeting gain-of-function KCNT1 pathogenic mutant variants. However, the detailed mechanism underlying quinidine’s blockade against KCNT1 (Slack) remains elusive. Here, we report a functional and physical coupling of the voltage-gated sodium channel Na_V1.6 and Slack. Na_V1.6 binds to and highly sensitizes Slack to quinidine blockade. Homozygous knockout of Na_V1.6 reduces the sensitivity of native sodium-activated potassium currents to quinidine blockade. Na_V1.6-mediated sensitization requires the involvement of Na_V1.6’s N-and C-termini binding to Slack’s C-terminus, and is enhanced by transient sodium influx through Na_V1.6. Moreover, disrupting the Slack-Na_V1.6 interaction by viral expression of Slack’s C-terminus can protect against SlackG269S-induced seizures in mice. These insights about a Slack-Na_V1.6 complex challenge the traditional view of “Slack as an isolated target” for anti-epileptic drug discovery efforts, and can guide the development of innovative therapeutic strategies for KCNT1-related epilepsy.

Graphical abstract

Introduction

The sodium-activated potassium (K_Na) channels Slack and Slick were first identified in guinea pig cardiomyocytes, and were subsequently found to be encoded by two genes of the Slo2 family^1,2. Slack channels encoded by the Slo2.2 (KCNT1) gene are gated by Na⁺, while Slick channels encoded by the Slo2.1 (KCNT2) gene are more sensitive to Cl^- than Na⁺. Slack channels are expressed at high levels in the central nervous system (CNS), especially the cortex and brainstem^3–5. Activation of Slack channels by intracellular sodium ions forms delayed outward currents in neurons, contributes to slow afterhyperpolarization (AHP) following repeated action potentials, and modulates the firing frequency of neurons^6,7.

Mutations in the KCNT1 gene have been implicated in a wide spectrum of epileptic disorders, including early-onset epilepsy (e.g., epilepsy of infancy with migrating focal seizures (EIMFS), non-EIMFS developmental and epileptic encephalopathies, and autosomal dominant or sporadic sleep-related hypermotor epilepsy (ADSHE))^8–11. Over 50 mutations related to seizure disorders have been identified, typically displaying a gain-of-function (GOF) phenotype in heterologous expression systems^11,12. The prescribed antiarrhythmic drug, quinidine, has emerged as a precision therapy for KCNT1-related epilepsy by blocking Slack mutant variants in vitro and conferring decreased seizure frequency and improved psychomotor development in clinical treatment^13–16. However, clinical quinidine therapy has shown limited success and contradictory therapeutic effects, probably due to poor blood–brain barrier penetration, dose-limiting off-target effects, phenotype-genotype associations, and rational therapeutic schedule^16–19.

Slack requires high intracellular free Na⁺ concentrations ([Na⁺]_in) for its activation in neurons (K_d of ∼66 mM)²⁰. However, previous investigations have shown that the [Na⁺]_in at resting states (∼10 mM) is much lower than the [Na⁺]_in needed for effective Slack activation (e.g., K_d value)^1,20,21. Therefore, native Slack channels need to localize with Na⁺ sources within a nanodomain to be activated and exert physiological function. Slack channels are known to be functionally coupled with sodium-permeable ion channels in neurons, such as voltage-gated sodium (Na_V) channels and AMPA receptors ^21,22. A question arises as to whether these known Na⁺ sources modulate Slack’s sensitivity to quinidine blockade.

Here, we found that Na_V1.6 sensitizes Slack to quinidine blockade. Slack and Na_V1.6 form a complex that functions in Na_V1.6-mediated transient sodium influx to sensitize Slack to quinidine blockade in HEK293 cells and in primary cortical neurons. The widespread expression of these channel proteins in cerebral cortex, hippocampus, and cerebellum supports that the Na_V1.6-Slack complex is essential for the function of a wide range of electrically excitable neurons, and moreover, that this complex can be viewed as a vulnerable target for drug development to treat KCNT1-related disorders.

Results

Na_V1.6 sensitizes Slack to quinidine blockade

Slack currents are activated by sodium entry through voltage-gated sodium (Na_V) channels and ionotropic glutamate receptors (e.g. AMPA receptors)^21–23. To investigate potential modulators of Slack’s sensitivity to quinidine blockade, we initially focused on the known Na⁺ sources of Slack. Working in HEK293 cells, we co-expressed Slack with AMPA receptor subunits (GluA1, GluA2, GluA3, or GluA4) or Na_V channel α subunits (Na_V1.1, Na_V1.2, Na_V1.3, or Na_V1.6), which are highly expressed in the central nervous system^24–27. The sensitivity of Slack to quinidine blockade was assessed based on the detected inhibitory effects of quinidine on delayed outward potassium currents^13,28. Interestingly, all neuronal Na_V channels significantly sensitized Slack to 30 μM quinidine blockade, whereas no effect was observed upon co-expression of Slack with GluA1, GluA2, GluA3, or GluA4 (Fig. S1).

When co-expressing Slack with Na_V1.6 in HEK293 cells, Na_V1.6 sensitized Slack to quinidine blockade by nearly 100-fold (IC₅₀ = 85.13 μM for Slack expressed alone and an IC₅₀ = 0.87 μM for Slack upon co-expression with Na_V1.6) (Fig.1A,B,D,F). Na_V1.6 also exhibited >10-fold selectivity in sensitizing Slack to quinidine blockade against Na_V1.1, Na_V1.2, and Na_V1.3 (Fig. 1C,F, and Supplementary Table 1). When we co-expressed the cardiac sodium channel Na_V1.5 with Slack, we observed only ∼3-fold sensitization of Slack to quinidine blockade (Fig.1E,F). These results together indicate that the apparent functional coupling between Slack and Na_V channels is Na_V-channel-subtype-specific, with Na_V1.6 being particularly impactful in Slack’s responsivity to quinidine blockade.

Na_V1.6 specifically sensitizes Slack to quinidine blockade.
(A) The voltage protocol and current traces from control (non-transfected) HEK293 cells. The arrows on the voltage protocol indicate the onset of inward sodium currents through Na_V channels and delayed outward potassium currents through Slack channels. The currents were evoked by applying 600-ms step pulses to voltages varying from -120 mV to +100 mV in 10 mV increments, with a holding potential of -90 mV and a stimulus frequency of 0.20 Hz. (B) Example current traces from HEK293 cells expressing Slack alone. The left traces show the family of control currents; the right traces show Slack currents remaining after application of 30 μΜ quinidine in the bath solution. (**C-E**) Example current traces from HEK293 cells co-expressing Slack with Na_V1.2 (C), Na_V1.6 (D), or Na_V1.5 (E) channels before and after application of 30 μΜ quinidine. (F) The concentration-response curves for blocking of Slack by quinidine at +100 mV upon expression of Slack alone (n = 6) and co-expression of Slack with Na_V1.1 (n = 7), Na_V1.2 (n = 10), Na_V1.3 (n = 13), Na_V1.5 (n = 9), or Na_V1.6 (n = 19). Please refer to Supplementary Table 1 for IC₅₀ values. (**G-H**) Delayed outward currents in primary cortical neurons from postnatal (P0-P1) homozygous Na_V1.6 knockout C3HeB/FeJ mice (Na_V1.6-KO) (H) and the wild-type littermate controls (WT) (G). Current traces were elicited by 600-ms step pulses to voltages varying from -120 mV to +100 mV in 20 mV increments, with a holding potential of -70 mV, and recorded with different bath solutions in the following order: Na⁺-based bath solution (I_Control), replacement of external Na⁺ with Li⁺ in equivalent concentration (I_Li), washout of quinidine by Na⁺-based bath solution (I_Wash), Na⁺-based bath solution with 3 μM quinidine (I_Quid), Li⁺-based bath solution with 3 μM quinidine (I_Li+Quid). The removal and subsequent replacement of extracellular Na⁺ revealed the I_KNa in neurons. (**I-J**), The sensitivity of native sodium-activated potassium currents (I_KNa) to 3 μM quinidine blockade in WT (I) and Na_V1.6-KO (J) neurons. I_KNa before application of quinidine was obtained from the subtraction of I_Control and I_Li. Maintained I_KNa after application of 3 μM quinidine was obtained from the subtraction of I_Quid and I_Li+Quid. (K) Summarized amplitudes of I_KNa before and after application of 3 μM quinidine in the bath solution in WT (black, n = 12) and Na_V1.6-KO (red, n = 10) primary cortical neurons. ****p < 0.0001, Two-way repeated measures ANOVA followed by Bonferroni’s post hoc test.

Slack and Slick are both K_Na channels (with 74% sequence identity) and adopt similar structures²⁹, and Slick is also blocked by quinidine³⁰. We next assessed whether Na_V1.6 sensitizes Slick to quinidine blockade and observed that, similar to Slack, co-expression of Slick and Na_V1.6 in HEK293 cells resulted in a sensitization of Slick to quinidine blockade (7-fold) (Fig. S2A,B). These results support that Na_V1.6 regulates both Slack and Slick and that Na_V1.6 can sensitize K_Na channels to quinidine blockade in vitro.

We also asked whether Na_V1.6 sensitizes native K_Na channels to quinidine blockade in neurons. We performed whole-cell patch-clamp recordings in primary cortical neurons from postnatal (P0-P1) homozygous Na_V1.6 knockout C3HeB/FeJ mice and the wild-type littermate controls. As Lithium is a much weaker activator of K_Na channels than sodium²⁹, K_Na currents (I_KNa) were isolated by replacing sodium ions with equivalent lithium ions in the bath solution (Fig. 1G,H) as previously described²². The amplitudes of I_KNa remained unaffected by the homozygous knockout of Na_V1.6 (Fig. S3A). Notably, 3 μM quinidine significantly inhibited native I_KNa (44%) in wild-type neurons (Fig. 1I,K) and this inhibitory effect was not limited to targeting the larger I_KNa (Fig. S3B). Conversely, the same concentration of quinidine had no significant effect on I_KNa in Na_V1.6-knockout (Na_V1.6-KO) neurons (Fig. 1J,K). These results support that Na_V1.6 is required for the observed high sensitivity of native K_Na channels to quinidine blockade.

Transient sodium influx through Na_V1.6 enhances Na_V1.6-mediated sensitization of Slack to quinidine blockade

We next investigated the biomolecular mechanism underlying Na_V1.6-mediated sensitization of Slack to quinidine blockade. Considering that Slack currents are activated by sodium influx^22,29, we initially assessed the effects of Na_V1.6-mediated sodium influx on sensitizing Slack to quinidine blockade. We used 100 nM tetrodotoxin (TTX) to block Na_V1.6-mediated sodium influx (Fig. S4A,B)³¹. In HEK293 cells expressing Slack alone, 100 nM TTX did not affect Slack currents; nor did it affect Slack’s sensitivity to quinidine blockade (IC₅₀ = 83.27 μM) (Fig. 2A,B and Fig. S4C,D). In contrast, upon co-expression of Slack and Na_V1.6 in HEK293 cells, bath-application of 100nM TTX significantly reduced the effects of Na_V1.6 in sensitizing Slack to quinidine blockade (IC₅₀ = 25.04 μM) (Fig. 2A,B). These findings support that sodium influx through Na_V1.6 contributes to Na_V1.6-mediated sensitization of Slack to quinidine blockade.

Blocking transient sodium influx through Na_V1.6 reduces Na_V1.6-mediated sensitization of Slack to quinidine blockade.
(A) Example current traces from HEK293 cells expressing Slack alone (top) and co-expressing Slack with Na_V1.6 (bottom), with 100nM TTX in the bath solution. The left traces show the family of control currents; the right traces show Slack currents remaining after application of quinidine. The presented concentrations of quinidine were chosen to be near the IC₅₀ values. (B) The concentration-response curves for blocking of Slack by quinidine at +100 mV upon expression of Slack alone (n = 3) and co-expression of Slack with Na_V1.6 (n = 7), with 100 nM TTX in the bath solution. (C) Top, example current traces recorded from a HEK293 cell co-expressing Slack with Na_V1.6 and evoked from a 100-ms prepulse (pre) of -90 mV, with the same voltage protocol as in Fig. 1D. Bottom, example current traces recorded from the same cell but evoked from a 100-ms prepulse of -40 mV, before and after application of quinidine. (D) I-V curves of Slack upon co-expression with Na_V1.6. The currents were evoked from a prepulse of -90 mV (black) or -40 mV (blue). (E) The concentration-response curves for blocking of Slack by quinidine at +100 mV with a prepulse of -90 mV (black, n = 19) or -40 mV (blue, n = 5). (F) Top, example current traces recorded from a HEK293 cell co-expressing Slack and Na_V1.6 without riluzole in the bath solution. Bottom, example current traces recorded from the same cell with 20 µM riluzole in the bath solution, before and after application of quinidine. (G) I-V curves of Slack upon co-expression with Na_V1.6 before (black) and after (red) application of 20 µM riluzole into bath solution.The concentration-response curves for blocking of Slack by quinidine upon co-expression of Slack with Na_V1.6, without (n = 19) or with (n = 6) 20 µM riluzole in the bath solution. (**I-J**) The sensitivity of Na_V channel subtypes to quinidine blockade upon expression of Na_V alone in HEK293 cells. Example current traces (I) were evoked by a 50-ms step depolarization to 0 mV from a holding potential of -90 mV. The Concentration-response curves for blocking of Na_V channel subtypes by quinidine (J) were shown on the right panel (n = 5 for Na_V1.1, n = 3 for Na_V1.2, n = 6 for Na_V1.3, n = 6 for Na_V1.5, and n = 4 for Na_V1.6).

It is known that Na_V1.6-mediated sodium influx involves a transient inward flux that reaches a peak before subsequently decaying to the baseline within a few milliseconds; this is termed a transient sodium current (I_NaT)³². A small fraction of Na_V1.6 currents are known to persist after the rapid decay of I_NaT, and these are termed persistent sodium currents (I_NaP)³³. We isolated I_NaT and I_NaP to explore their potential contributions in sensitizing Slack to quinidine blockade. We selectively inactivated I_NaT using a depolarized prepulse of -40 mV (Fig. S5A) and selectively blocked I_NaP by bath-application of 20 μM riluzole, which is a relatively specific I_NaP blocker that is known to stabilize inactivated-state Na_V channels and delay recovery from inactivation^34,35. Our findings ultimately confirmed that the 20 μM riluzole selectively blocked I_NaP compared to I_NaT in HEK293 cells co-expressing Slack and Na_V1.6 (Fig. S5B) and that 20 μM riluzole had no effect on Slack currents when expressed alone (Fig. S5C,D).

Consistent with previous investigations^21,22, inactivating I_NaT reduced whole-cell Slack currents by 20%, and blocking I_NaP reduced Slack currents by 40% at +100 mV (Fig. 2C,D,F,G), supporting that Na_V1.6-mediated sodium influx activates Slack. Interestingly, inactivating I_NaT resulted in a > 20-fold decrease in Slack’s sensitization to quinidine blockade (IC₅₀ = 22.26 μM) (Fig. 2C,E). In contrast, blocking I_NaP had no effect on Slack’s sensitization to quinidine blockade (IC₅₀ = 1.60 μM) (Fig. 2F,H). These findings indicate that Na_V1.6 sensitizes Slack to quinidine blockade via I_NaT but not I_NaP.

Given that Slack current amplitudes are sensitive to sodium influx, and considering that quinidine is a sodium channel blocker, we examined whether Na_V1.6 has higher sensitivity to quinidine blockade than other Na_V channel subtypes, which could plausibly explain the observed increased strength of sensitization. We used whole-cell patch-clamping to assess the sensitivity of Na_V1.1, Na_V1.2, Na_V1.3, Na_V1.5, and Na_V1.6 to quinidine blockade. These sodium channels exhibited similar levels of quinidine sensitivity (IC₅₀ values in the range of 35.61-129.84 μM) (Fig. 2I,J and Supplementary Table 2), all of which were at least 40-fold lower than the Na_V1.6-mediated sensitization of Slack to quinidine blockade (Fig. 1F). Additionally, co-expressing Slack with Na_V1.1, Na_V1.2, Na_V1.3, Na_V1.5, or Na_V1.6 in HEK293 cells did not change the sensitivity of these Na_V channel subtypes to quinidine blockade (Fig. S6 and Supplementary Table 2). Thus, differential quinidine affinity for specific Na_V channel subtypes cannot explain the large observed Na_V1.6-mediated sensitization of Slack to quinidine blockade. Moreover, it is clear that Na_V1.6-mediated sensitization of Slack to quinidine blockade is directly mediated by I_NaT, rather than through some secondary effects related to Na_V1.6’s higher sensitivity to quinidine blockade.

Slack physically interacts with Na_V1.6

We found that the specific voltage-gated sodium channel blocker TTX did not completely abolish the effects of Na_V1.6 on sensitizing Slack to quinidine blockade (Fig. 2B), so it appears that a sodium-influx-independent mechanism is involved in the observed Na_V1.6-mediated sensitization of Slack to quinidine blockade. We therefore investigated a potential physical interaction between Slack and Na_V1.6. We initially assessed the cellular distribution of Na_V1.2, Na_V1.6, and Slack in the hippocampus and the neocortex of mouse. Consistent with previous studies^36,37, Na_V1.2 and Na_V1.6 were localized to the axonal initial segment (AIS) of neurons, evident as the co-localization of Na_V and AnkG, a sodium channel-associated protein known to accumulate at the AIS (Fig. 3A). Slack channels were also localized to the AIS of these neurons (Fig. 3A), indicating that Slack channels are located in close proximity to Na_V1.6 channels, and supporting their possible interaction. Moreover, Na_V1.6 was co-immunoprecipitated with Slack in homogenates from mouse cortical and hippocampal tissues and from HEK293T cells co-transfected with Slack and Na_V1.6 (Fig. 3B,C), supporting that Slack and Na_V1.6 form protein complexes in mouse brains.

To assess the interaction between Slack and Na_V1.6 inside living cells, we performed a FRET assay in transfected HEK293T cells³⁸. Briefly, we genetically fused mTFP1 and mVenus to the C-terminal regions of Slack and Na_V1.6, respectively (Fig. 3D). Upon imaging the emission spectra cells co-expressing Na_V1.6-mVenus and Slack-mTFP1 (measured at the plasma membrane region) (Fig. 3E), we detected positive FRET signals, indicating a Slack-Na_V1.6 interaction (Fig. 3F,H). The plasma membrane regions from HEK293T cells co-transfected with Na_V1.6 and Slack showed FRET efficiency values much larger than a negative control (in which standalone mVenus and mTFP1 proteins were co-expressed) (Fig. 3G,H), indicating that Slack channels reside in close spatial proximity (less than 10 nm) to Na_V1.6 channels in living cells.

We next characterized the consequences of the Slack-Na_V1.6 interaction in HEK293 cells using whole-cell recordings. Slack increased the rate of recovery from fast inactivation of Na_V1.6 (Fig. S7E), with no significant effects on the steady-state activation, steady-state fast inactivation, or ramp currents (Fig. S7C,D,F and Supplementary Table 3). Additionally, we found that Na_V1.6 had no significant effects on the activation rate or the current-voltage (I-V) relationship of Slack currents (Fig. S7A,B). These results indicate that the physical interaction between Slack and Na_V1.6 produces functional consequences. Taken together, these findings support functional and physical coupling of Slack and Na_V1.6.

Na_V1.6’s N- and C-termini bind to Slack’s C-terminus and sensitize Slack to quinidine blockade

To explore whether the physical interaction between Slack and Na_V1.6 is required for sodium-influx-mediated sensitization of Slack to quinidine blockade, we performed inside-out patch-clamp recordings on HEK293 cells transfected with Slack alone or co-transfected with Slack and Na_V1.6. Note that in these experiments the intracellular sodium concentration ([Na⁺]_in) was raised to 140 mM (a concentration at which most Slack channels can be activated²⁰), seeking to mimic the increased intracellular sodium concentration upon sodium influx. When expressing Slack alone, increasing the sodium concentration did not sensitize Slack to quinidine blockade (IC₅₀ = 120.42 μM) (Fig. 4a). However, upon co-expression of Na_V1.6 and Slack, Na_V1.6 significantly sensitized Slack to quinidine blockade (IC₅₀ = 2.91 μM) (Fig. 4A). These results support that physical interaction between Slack and Na_V1.6 is a prerequisite for sodium-influx-mediated sensitization of Slack to quinidine blockade.

Na_V1.6’s N- and C-termini interacting with Slack is a prerequisite for Na_V1.6-mediated sensitization of Slack to quinidine blockade.
(A) The sensitivity of Slack to quinidine blockade upon expression of Slack alone (n = 3) and co-expression of Slack with Na_V1.6 (n = 3) from excised inside-out patches. The pipette solution contained (in mM) 130 KCl, 1 EDTA, 10 HEPES and 2 MgCl₂ (pH 7.3); the bath solution contained (in mM) 140 NaCl, 1 EDTA, 10 HEPES and 2 MgCl₂ (pH 7.4). The membrane voltage was held at 0 mV and stepped to voltages varying from −100 mV to 0 mV in 10 mV increments. Example current traces were shown on the left panel. The concentration-response curves for blocking of Slack by quinidine were shown on the right panel. (B) Domain architecture of the human Na_V channel pore-forming α subunit. (C) Calculated IC₅₀ values at +100 mV of quinidine on Slack upon co-expression with indicated cytoplasmic fragments from Na_V channels. For Na_V1.6, cytoplasmic fragments used include N-terminus (Na_V1.6-N, residues 1-132), inter domain linkers (Domain I-II linker, residues 409-753; Domain II-III linker, residues 977-1199; Domain III-IV linker, residues 1461-1523), and C-terminus (Na_V1.6-C, residues 1766-1980). For Na_V1.5, cytoplasmic fragments used include N-terminus (Na_V1.5-N, residues 1-131) and C-terminus (Na_V1.5-C, residues 1772-2016). (D) Co-IP of Slack and terminal domains of Na_V1.6 in cell lysates from HEK293T cells co-expressing 3×Flag-tagged Slack (Slack-3×Flag) and 3×HA-tagged termini of Na_V1.6 (3×HA-Na_V1.6-N or 3×HA-Na_V1.6-C). The 3×Flag tag was fused to the C-terminal region of Slack and the 3×HA tag was fused to the N-terminal region of Na_V1.6’s fragments. (E) The sensitivity of Slack to quinidine blockade upon co-expression of Slack with GFP (n = 12) or N- and C-termini of Na_V1.6 (n = 11), from whole-cell recordings. (F) The sensitivity of Slack to quinidine blockade upon co-expression of Slack with N- and C-termini of Na_V1.6, from excised inside-out recordings (n = 10, using the same protocols as in Fig. 4A). Example current traces before and after application of quinidine were shown on the left panel. The concentration-response curves were shown on the right panel. (G) A schematic diagram of the Na_V1.5-1.6 chimeric channels (Na_V1.5/6^NC and Na_V1.5/6^N) used in this study. (H) Example current traces recorded from HEK293 cells co-expressing Slack and Na_V1.5-1.6 chimeras before and after application of the indicated concentration of quinidine. (I) The concentration-response curves for blocking of Slack by quinidine upon co-expression of Slack with Na_V1.5 (n = 9), Na_V1.6 (n = 19), Na_V1.5/6^NC (n = 9), or Na_V1.5/6^N (n = 9).

To investigate which interacting domains mediate Na_V1.6’s sensitization of Slack to quinidine blockade, we focused on Na_V1.6’s cytoplasmic fragments, including its N-terminus, inter domain linkers, and C-terminus (Fig. 4B). Whole-cell recordings from HEK293 cells co-expressing Slack with these Na_V1.6 fragments revealed that the N-terminus and C-terminus of Na_V1.6 significantly enhanced the sensitivity of Slack to quinidine blockade (IC₅₀ = 31.59 μM for Slack upon co-expression with Na_V1.6’s N-terminus and IC₅₀ = 43.70 μM for Slack upon co-expression with Na_V1.6’s C-terminus); note that the inter domain linkers had no effect (Fig. 4C).

Subsequent co-immunoprecipitation and glutathione S-transferase (GST) pull down assays of HEK293T cell lysates experimentally confirmed that Na_V1.6’s N-and C-termini each interact with Slack (Fig. 4D and Fig. S8). Additionally, whole-cell recordings using an [Na⁺]_in of 5 mM again showed that Na_V1.6’s N-terminus and Na_V1.6’s C-terminus sensitize Slack to quinidine blockade (IC₅₀ = 27.87 μM) (Fig. 4E). And inside-out recordings using an [Na⁺]_in of 140 mM showed that co-expression of Slack, Na_V1.6’s N-terminus, and Na_V1.6’s C-terminus resulted in obvious sensitization of Slack to quinidine blockade, with an IC₅₀ of 2.57 μM (Fig. 4F)—thus fully mimicking the aforementioned effects of full-length Na_V1.6 (IC₅₀ = 2.91 μM) (Fig. 4A). These findings support that the binding of Na_V1.6’s N- and C-termini to Slack is required for Na_V1.6’s sensitization of Slack to quinidine blockade.

Recalling that Na_V1.5 had the least pronounced effect in sensitizing Slack to quinidine blockade among all examined Na_V channels (IC₅₀ = 29.46 μM) (Fig. 1F and Supplementary Table 1), we initially compared the sodium currents of Na_V channel subtypes co-expressed with Slack. The results revealed no significant differences in activation time constants (Fig. S9A). It’s worth noting that Na_V1.5 exhibited significantly larger current amplitudes than Na_V1.6 (Fig. S9B). Subsequently, we constructed Na_V1.5-1.6 chimeras to test the roles of Na_V1.6’s N- and C-termini in sensitizing Slack to quinidine blockade. The replacement of both the N-terminus [residues 1-131] and C-terminus [residues 1772-2016] of Na_V1.5 with Na_V1.6’s N-terminus [residues 1-132] and C-terminus [residues 1766-1980] (namely Na_V1.5/6^NC) fully mimicked effects of Na_V1.6 in sensitizing Slack to quinidine blockade (IC₅₀ = 1.13 μM) (Fig. 4G-I). We also found that replacement of Na_V1.5’s N-terminus [residues 1-131] with Na_V1.6’s N-terminus [residues 1-132] (namely Na_V1.5/6^N) fully mimicked the effects of Na_V1.6 (IC₅₀ = 1.18 μM) (Fig. 4G-I).

Notably, despite both Na_V1.5 and Na_V1.5/6^N exhibited much larger current amplitudes compared to Na_V1.6 (Fig. S9B), only Na_V1.5/6^N replicated the effect of Na_V1.6 in sensitizing Slack to quinidine blockade (Fig. 4H-I). These results suggest that the observed differences between Na_V1.5 and Na_V1.6 in sensitizing Slack are unlikely to be attributed to Na_V1.6’s smaller sodium current amplitudes but involve Na_V1.6’s N-terminus. Consistently, Na_V1.5’s C-terminus sensitized Slack to quinidine blockade (IC₅₀ = 37.59 μM), whereas Na_V1.5’s N-terminus had no effect on Slack sensitization (Fig. 4C). These findings support that Na_V1.6’s N-terminus is essential for sensitizing Slack to quinidine blockade.

Having demonstrated that Na_V1.6 sensitizes Slack via Na_V1.6’s cytoplasmic N- and C-termini, we investigated which domains of Slack interact with Na_V1.6 and focused on Slack’s cytoplasmic fragments, including Slack’s N-terminus and C-terminus (Fig. 5A). In HEK293 cells co-expressing Na_V and Slack, Na_V-mediated sensitization of Slack to quinidine blockade was significantly attenuated upon the additional expression of Slack’s C-terminus, but not of Slack’s N-terminus (Fig. 5B,C), suggesting that Slack’s C-terminus can disrupt the Slack-Na_V1.6 interaction by competing with Slack for binding to Na_V1.6. Consistently, Slack’s C-terminus co-immunoprecipitated with Na_V1.6’s N- and C-termini in HEK293T cell lysates (Fig. 5D). Together, these results support that Slack’s C-terminus physically interacts with Na_V1.6 and that this interaction is required for Na_V1.6’s sensitization of Slack to quinidine blockade.

Slack’s C-terminus is required for Na_V1.6-mediated sensitization of Slack to quinidine blockade.
(A) Domain architecture of the human Slack channel subunit. Slack’s N-terminus (Slack-N, residues 1-116) and C-terminus (Slack-C, residues 345-1235) were shown in the blue boxes. (B) The concentration-response curves for blocking of Slack by quinidine upon additional expression of Slack’s N- or C-terminus in HEK293T cells co-expressing Slack and Na_V1.5/6^NC. (C) The concentration-response curves for blocking Slack by quinidine upon additional expression of Slack’s C-terminus in HEK293 cells co-expressing Slack and Na_V1.6. (D) Co-IP of Myc-tagged Slack’s C-terminus (Slack-C-Myc) with 3×HA-tagged Na_V1.6’s termini (3×HA-Na_V1.6-N or 3×HA-Na_V1.6-C) in HEK293T cell lysates. The 3×HA tag was fused to the N-terminal region of Na_V1.6’s fragments, and the Myc tag was fused to the C-terminal region of Slack’s fragment.

Na_V1.6 binds to and sensitizes epilepsy-related Slack mutant variants to quinidine blockade

Over 50 mutations in KCNT1 (Slack) have been identified and related to seizure disorders¹¹. Having established that Na_V1.6 can sensitize wild-type Slack to quinidine blockade, we next investigated whether Na_V1.6 also sensitizes epilepsy-related Slack mutant variants to quinidine blockade. We chose 3 Slack pathogenic mutant variants (K629N, R950Q, and K985N) initially detected in patients with KCNT1-related epilepsy^15,39,40. Considering that these 3 mutations are located in Slack’s C-terminus, and recalling that Slack’s C-terminus interacts with Na_V1.6 (Fig. 5D), we first used co-immunoprecipitation assays and successfully confirmed that each of these Slack mutant variants interacts with Na_V1.6 in HEK293T cell lysates (Fig. 6A).

Na_V1.6 sensitizes epilepsy-related Slack mutant variants to quinidine blockade.
(A) Co-IP of 3×Flag-tagged Slack or its mutations (Slack-3×Flag) with 3×HA-tagged Na_V1.6 (Na_V1.6-3×HA) in HEK293T cell lysates. The tags were all fused to the C-terminal region of wild-type or mutant ion channels. (**B-D**) The sensitivity of Slack mutant variants (Slack^K629N [B], Slack^R950Q [C], and Slack^K985N [D]) to quinidine blockade upon expression of Slack mutant variants alone and co-expression of Slack mutant variants with Na_V1.6. Left, example current traces recorded from HEK293 cells expressing Slack mutant variants alone and co-expressing Slack mutant variants with Na_V1.6, before and after application of the indicated concentrations of quinidine. Right, the concentration-response curves for blocking of Slack mutant variants by quinidine upon expression of Slack mutant variants alone (n = 8 for Slack^K629N, n = 7 for Slack^R950Q, and n = 5 for Slack^K985N) and co-expression of Slack mutant variants with Na_V1.6 (n = 8 for Slack^K629N upon co-expression with Na_V1.6, n = 5 for Slack^R950Q upon co-expression with Na_V1.6, and n = 7 for Slack^K985N upon co-expression with Na_V1.6). Please refer to Supplementary Table 4 for IC₅₀ values.

Subsequently, whole-cell recordings revealed that the examined Slack mutant variants exhibited no discernible impact on the amplitudes of Na_V1.6 currents (Fig. S10A), while pharmacologically blocking Na_V1.6 currents using bath-application of 100 nM TTX significantly reduced the amplitudes of Slack mutant variant (Slack^R950Q) currents (Fig. S10B), suggesting a Na⁺-mediated functional coupling between Slack mutant variant and Na_V1.6 currents. Notably, Na_V1.6 significantly sensitized all of the examined Slack mutant variants to quinidine blockade, with IC₅₀ values ranging from 0.26 to 2.41 μM (Fig. 6B-D and Supplementary Table 4). These results support that Na_V1.6 interacts with examined Slack mutant variants and sensitizes them to quinidine blockade. It is plausible that the Slack-Na_V1.6 interaction contributes to the therapeutical role of quinidine in the treatment of KCNT1-related epilepsy.

Viral expression of Slack’s C-terminus prevents Slack^G269S-induced seizures

Having established that blocking Na_V1.6-mediated sodium influx significantly reduced Slack current amplitudes (Fig. 2D,G and Fig. S10B), we found that the heterozygous knockout of Na_V1.6 significantly reduced the afterhyperpolarization amplitude in murine hippocampal neurons (Fig. S11), together indicating that Na_V1.6 activates native Slack through providing Na⁺. We therefore assumed that disruption of the Slack-Na_V1.6 interaction should reduce the amount of Na⁺ in the close vicinity of epilepsy-related Slack mutant variants and thereby counter the increased current amplitudes of these Slack mutant variants. Pursuing this, we disrupted the Slack-Na_V interaction by overexpressing Slack’s C-terminus (to compete with Slack) and measured whole-cell current densities. In HEK293 cells co-expressing epilepsy-related Slack mutant variants (G288S, R398Q)^41,42 and Na_V1.5/6^NC, expression of Slack’s C-terminus significantly reduced whole-cell current densities of Slack^G269S and Slack^R398Q (Fig. 7A,B), supporting that disrupting the Slack-Na_V1.6 interaction can indeed reduce current amplitudes of Slack mutant variants, which may protect against seizures induced by Slack mutant variants.

We next induced an in vivo epilepsy model by introducing a Slack G269S variant into C57BL/6N mice using adeno-associated virus (AAV) injection to mimic the human Slack mutation G288S⁴¹. Specifically, we delivered stereotactic injections of AAV9 containing expression cassettes for Slack^G269S (or GFP negative controls) into the hippocampal CA1 region of 3-week-old C57BL/6N mice (Fig. 7C,D). At 3-5 week intervals after AAV injection, we quantified the seizure susceptibility of mice upon the induction of a classic kainic acid (KA) model of temporal lobe epilepsy^43,44. In this model, seizures with stage IV or higher (as defined by a modified Racine, Pinal, and Rovner scale⁴⁵) are induced in rodents by intraperitoneal administration of 28 mg/kg KA.

We assessed a time course of KA-induced seizure stages at 10-min intervals and found that viral expression of Slack^G269S resulted in faster seizure progression in mice compared to control GFP expression (Fig. 7E). We calculated the total seizure score per mouse to assess seizure severity⁴⁶. Slack^G269S-expressing mice showed significantly higher seizure severity than GFP-expressing mice (Fig. 7F). The percentage of mice with stage VI∼IX seizures also increased, from 9.1% in GFP-expressing control mice to 58.3% in the Slack^G269S-expressing mice (Fig. 7G). These results support that viral expression of Slack^G269S significantly increases seizure susceptibility in mice.

To evaluate the potential therapeutic effects of disrupting the Slack-Na_V1.6 interaction, we delivered two AAV9s (one for Slack^G269S and one for Slack’s C-terminus [residues 326-1238]) into the CA1 region of mice (Fig. 7D). Viral expression of Slack’s C-terminus in Slack^G269S-expressing mice significantly decreased seizure progression, seizure severity, and the percentage of mice experiencing stage VI∼IX seizures (Fig. 7E-G). These results support that viral expression of Slack’s C-terminus can prevent Slack^G269S-induced seizures in mice, thus showcasing that using Slack’s C-terminus to disrupt the Slack-Na_V1.6 interaction is a promising therapeutic intervention to treat KCNT1-related epilepsy.

Discussion

We here found that Na_V1.6’s N- and C-termini bind to Slack’s C-terminus and sensitize Slack to quinidine blockade via Na_V1.6-mediated transient sodium currents. These results suggest that the pharmacological blocking effects of a channel blocker are not exclusively mediated by the channel per.se., but modulated by channel’s interacting proteins. Moreover, we show that viral expression of Slack’s C-terminus can rescue the increased seizure susceptibility and confer protection against Slack^G269S-induced seizures in mice.

At resting membrane potential, the intracellular sodium concentration ([Na⁺]_in) in neurons (equal to ∼10 mM) is too low to effectively activate Slack (K_d of 66 mM)^1,20. Slack is functionally coupled to sodium influx, which is known to be mediated by ion channels and receptors, including Na_V, AMPARs, and NMDARs^21–23,47. Such Na⁺ sources can provide both the membrane depolarization and the Na⁺ entry known to be required for Slack activation, enabling Slack to contribute both to action potential repolarization during neuronal high-frequency firing^7,48 and to regulating excitatory postsynaptic potential (EPSP) at post-synaptic neurons²³. Our results support that Slack and Na_V1.6 form a channel complex, while also implying that Na_V1.6-mediated sodium influx increases the Na⁺ concentration in the close vicinity of Slack to activate Slack. As a low threshold Na_V channel subtype, Na_V1.6 has been reported to dominate the initiation and propagation of action potentials in axon initial segments (AIS) in excitatory neurons^36,49–51. The activation of Slack by Na_V1.6 at AIS has multiple impacts, including ensuring the timing of the fast-activated component of Slack currents, regulating the action potential amplitude, and apparently contributing to intrinsic neuronal excitability²⁹. The use of HEK cells and cultured primary cortical neurons in this study may not fully capture the complexity of native Slack-Na_V1.6 interaction. Future studies employing more intact systems, such as in vivo models, could provide a more comprehensive understanding of the physiological relevance of the native Slack-Na_V1.6 interaction.

An interesting question arises from our observation that Slack’s sensitivity to quinidine blockade is enhanced by I_NaT but not I_NaP: what can explain the distinct I_NaT and I_NaP contributions? We speculate that with physical modulation by Na_V1.6, I_NaT may elicit a specific open conformation of Slack that brings its quinidine binding pocket into a high affinity state, which could lead to a substantial increase in Slack’s sensitivity to quinidine blockade. The possibility of this hypothetical open conformation is supported by previous reports of the presence of subconductance states detected in single-channel recordings of Xenopus oocytes expressing Slack channels⁵², which implies that there are multiple open conformations of Slack. Although only one open conformation of Slack has been observed in cryo-EM, the gap between maximum conformational open probability (∼1.0) and maximum functional open probability (∼0.7) implies a subclass within this class of open channels⁵³. Additionally, it’s worth noting that blocking of I_NaP by application of riluzole has its limitation on selectivity. Riluzole has been reported to bind to Slack channels with low affinity⁵⁴. Therefore, the dual binding of riluzole to both Slack and Na_V1.6 may stabilize or inhibit the Slack-Na_V1.6 interaction, consequently influencing the sensitization of Slack to quinidine blockade.

As previously mentioned, gain-of-function Slack mutant variants have been linked to a broad spectrum of epileptic disorders that are accompanied by intellectual disabilities and both psychomotor and developmental defects^18,55. Given that many patients are refractory or non-responsive to conventional anticonvulsants^12,55,56, and considering the limited success of quinidine in clinical treatment of KCNT1-related epilepsy, inhibitors targeting Slack are needed urgently¹⁸. Several small-molecule inhibitors against Slack have been reported, providing informative starting points for drug development efforts with KCNT1-related epilepsy^28,57,58. However, our discovery of the Slack-Na_V1.6 complex challenges the traditional view that Slack acts as an isolated target in KCNT1-related epilepsy¹⁸. Indeed, our study supports that co-expression of Slack and Na_V1.6 in heterologous cell models should be performed when analyzing clinically relevant Slack mutations and when screening anti-epileptic drugs for use in treating KCNT1-related disorders.

Genotype-phenotype analysis has shown that ADSHE-related mutations are clustered in the regulator of conductance of K⁺ (RCK2) domain; while EIMFS-related mutations do not show a particular pattern of distribution¹¹. All functionally tested Slack mutant variants show gain-of-function phenotypes, with increased Slack currents ^9,11,18. Further, the epilepsy-related Slack mutant variants confer their gain-of-function phenotypes through two molecular mechanisms: increasing maximal channel open probability (P_max) or increasing sodium sensitivity (K_d) of Slack⁵⁹. Both P_max and K_d are highly sensitive to [Na⁺]_in; these are respectively analogous to the efficacy and potency of [Na⁺]_in on Slack currents⁵⁹. Notably, several Slack mutant variants show gain-of-function phenotypes only at high [Na⁺]_in (e.g. 80 mM)⁵⁹. These results indicate that the gain-of-function phenotype of epilepsy-related Slack mutant variants is aggravated by high [Na⁺]_in. Our discovery of functional coupling between Na_V1.6 and Slack presents a plausible basis for how Na_V1.6-mediated sodium influx can increase [Na⁺]_in and thus apparently aggravate the gain-of-function phenotype of Slack mutant variants. Therefore, it makes sense that disruption of the Slack-Na_V1.6 interaction by overexpressing Slack’s C-terminus reduces the current amplitudes of gain-of-function Slack mutant variants (Fig. 7A,B). Our successful demonstration that viral expression of Slack’s C-terminus prevents epilepsy-related Slack^G269S-induced seizures in mice (Fig. 7E-G) warrants further translational evaluation for developing therapeutic interventions to treat KCNT1-related epilepsy.

Methods

Animals

C57BL/6 mice were purchased from Charles River Laboratories. Na_V1.6 knockout C3HeB/FeJ mice were generous gifts from Professor Yousheng Shu at Fudan University. All animals were housed on a 12-hour light/dark cycle with ad libitum access to food and water. All procedures related to animal care and treatment were approved by the Peking University Institutional Animal Care and Use Committee and met the guidelines of the National Institute of Health Guide for the Care and Use of Laboratory Animals. Each effort was made to minimize animal suffering and the number of animals used. The experiments were blind to viral treatment condition during behavioral testing.

Antibodies and Reagents

Commercial antibodies used were: anti-AnkG (Santa Cruz), anti-Slack (NeuroMab), anti-Na_V1.2 (Alomone), anti-Na_V1.6 (Alomone), anti-HA (Abbkine), anti-Flag (Abbkine), anti-β-Actin (Biodragon), HRP Goat Anti-Mouse IgG LCS (Abbkine), HRP Mouse Anti-Rabbit IgG LCS (Abbkine), Alexa Fluor 488-AffinityPure Fab Fragment Donkey anti-rabbit IgG (Jackson), Alexa Fluor 594 Donkey anti-mouse IgG (Yeason). GPCR Extraction Reagent was from Pierce, NP40 lysis buffer was from Beyotime, protease inhibitor mixture cocktail was from Roche Applied Science, rabbit IgG and mouse IgG was from Santa Cruz, and Protein G Dynabeads were from Invitrogen. Tetrodotoxin was from Absin Bioscience. Quinidine was from Macklin, and riluzole was from Meilunbio. All other reagents were purchased from Sigma-Aldrich.

Molecular cloning

The ion channels used are: Slack-B (Ref Seq: NM_020822.3), Slick (Ref Seq: NM_198503.5), Na_V1.1 (Ref Seq: NM_001165963.4), Na_V1.2 (Ref Seq: NM_001040142.2), Na_V1.3 (Ref Seq: NM_006922.4), Na_V1.5 (Ref Seq: NM_198056.3), Na_V1.6 (Ref Seq: NM_014191.4), GluA1 (Ref Seq: XM_032913972.1), GluA2 (Ref Seq: NM_017261.2), GluA3 (Ref Seq: NM_007325.5), and GluA4 (Ref Seq: NM_000829.4). Human Slack-B and Na_V1.6 were subcloned into the modified pcDNA3.1(+) vector using Gibson assembly. All mutations and chimeras of ion channels were also constructed using Gibson assembly. For GST pull down assay, the segments of Slack and Na_V1.6 were subcloned into pCDNA3.1(+) and pGEX-4T-1 vector, respectively. For FRET experiments, mVenus-tag was fused to the C-terminus of Na_V1.6 sequence, and mTFP1-tag was also fused to the C-terminus of Slack sequence.

Immunoprecipitation

The brain tissues or HEK293T cells co-expressing full-length or fragments of Slack and Na_V1.6 were homogenized and lysed in GPCR Extraction Reagent (Pierce) with cocktail for 30 min at 4 °C. The homogenate was centrifuged for 20 min at 16 000 g and 4 °C to remove cell debris and then supernatant was incubated with 5 μg Slack antibody (NeuroMab) or Na_v1.6 antibody (Alomone) for 12 h at 4 °C with constant rotation. 40 μl of protein G Dynabeads (Invitrogen) was then added and the incubation was continued until the next day. Beads were then washed three times with NP40 lysis. Between washes, the beads were collected by DynaMag. The remaining proteins were eluted from the beads by re-suspending the beads in 1×SDS-PAGE loading buffer and incubating for 30 min at 37 °C. The resultant materials from immunoprecipitation or lysates were then subjected to western blot analysis. And the co-immunoprecipitation assays for Slack and Na_V1.6 were repeated three times independently.

Western blot analysis

Proteins suspended in 1×SDS-PAGE loading buffer were denatured for 30 min at 37 °C. Then proteins were loaded on 6% or 8% sodium dodecyl sulphate–polyacrylamide gel electrophoresis and transferred onto nitrocellulose filter membrane (PALL). Non-specific binding sites were blocked with Tris-buffered saline-Tween (0.02 M Tris, 0.137 M NaCl and 0.1% Tween 20) containing 5% non-fat dried milk. Subsequently, proteins of interest were probed with primary antibodies for overnight at 4 °C. After incubation with a secondary antibody, immunoreactive bands were visualized using HRP Substrate Peroxide Solution (Millipore) according to the manufacturer’s recommendation.

GST pull down assay

Plasmids encoding GST-fused Na_V1.6 segments were transformed into BL21(DE3). After expressing recombinant proteins induced by overnight application of isopropyl-1-thio-β-D-galactopyranoside (IPTG) (0.1mM) at 25℃, the bacteria were collected, lysed and incubated with GSH beads using BeaverBeads GSH kit (Beaver) according to the manufacturer’s instruction.

Plasmids encoding KCNT1 channel or HA-tagged KCNT1 segments were transfected into HEK293T cells using lipofectamine 2000 (Introvigen). 40 h after transfection, cells were lysed in NP40 lysis buffer with inhibitor cocktail, and then centrifugated at 4 ℃, 15000 g for 20 min. The supernatants were incubated with protein-bound beads. The protein-bound beads were washed by washing buffer (50 mM Tris-HCl pH = 7.4, 120 mM NaCl, 2 mM EGTA, 2 mM DTT, 0.1% triton X-100, and 0.2% Tween-20) for 5 min 3 times and then denatured with 1×SDS-PAGE loading buffer and incubating for 30 min at 37 °C. The resultant materials were subjected to western blot analysis.

Cell culture

The human embryonic kidney cells (HEK293 and HEK293T) were maintained in Dulbecco’s Modified Eagle Medium (DMEM, Gibco) supplemented with 15% Fetal Bovine Serum (FBS, PAN-Biotech) at 37°C and 5% CO₂. Primary cortical neurons were prepared from either sex of postnatal (P0-P1) homozygous Na_V1.6 knockout C3HeB/FeJ mice and the wild-type littermate controls. After the mice were decapitated, the cortices were removed and separated from the meninges and surrounding tissue. Tissues were digested in 2 mg/mL Papain (Aladdin) containing 2 μg/mL DNase I (Psaitong) for 30 min followed by centrifugation and resuspension. Subsequently, the cells were plated on poly-D-lysine (0.05 mg/mL) pre-coated glass coverslips in plating medium (DMEM containing 15% FBS), at a density of 4×10⁵ cells/ml, and cultivated at 37°C and 5% CO₂ in a humidified incubator. 5 h after plating, the medium was replaced with Neurobasal Plus medium (Invitrogen) containing 2% v/v B-27 supplement (Invitrogen), 2 mM Glutamax (Invitrogen), 50 U/mL penicillin and streptomycin (Life Technologies). The primary neurons were grown 6-10 days before electrophysiological recordings with half of the media replaced every three days.

Voltage-clamp recordings

The plasmids expressing full-length or fragments of Slack and Na_V channels (excluding full-length Na_V1.6) were co-transfected into HEK293 cells using lipofectamine 2000 (Introvigen). To co-express Slack with Na_V1.6, the plasmid expressing Slack was transfected into a stable HEK293 cell line expressing Na_V1.6. 18-36 h after transfection, voltage-clamp recordings were obtained using a HEKA EPC-10 patch-clamp amplifier (HEKA Electronic) and PatchMaster software (HEKA Electronic). For all whole-cell patch clamp experiments in HEK cells except for data presented in Fig. S7D, the extracellular recording solution contained (in mM): 140 NaCl, 3 KCl, 1 CaCl₂, 1 MgCl2, 10 glucose, 10 HEPES, 1 Tetraethylammonium chloride (310 mOsm/L, pH 7.30 with NaOH). The recording pipette intracellular solution (5 mM Na) contained (in mM): 100 K-gluconate, 30 KCl, 15 Choline-Cl, 5 NaCl, 10 glucose,5 EGTA, 10 HEPES (300 mOsm/L, pH 7.30 with KOH). For data presented in Fig. S7D, the extracellular recording solution remains the same as above, the pipette intracellular solution contained (in mM): 140 CsF, 10 NaCl, 5 EGTA, 10 HEPES (pH 7.30 with NaOH), indicating that the unusual right shifts (15∼20 mV) in voltage dependence of Na_V1.6 were induced by components in pipette solution, not recording system errors. For primary cortical neurons, intracellular solution (0 mM Na) was used to prevent the activation of sodium-activated potassium channels by basal intracellular sodium ions. NaCl in the intracellular solution was replaced with choline chloride in an equimolar concentration. For inside out patch-clamps, the bath solution contained (in mM): 140 NaCl, 1 EDTA, 10 HEPES and 2 MgCl₂ (310 mOsm/L, pH 7.30 with NaOH). Pipette solution contained (in mM): 130 KCl, 1 EDTA, 10 HEPES and 2 MgCl₂ (300 mOsm/L, pH 7.30 with KOH). The pipettes were fabricated by a DMZ Universal Electrode puller (Zeitz Instruments) using borosilicate glass, with a resistance of 1.5-3.5 MΩ for whole-cell patch clamp recordings and 8.0-10.0 MΩ for inside-out patch clamp recordings.

All experiments were performed at room temperature. The cells were exposed to the bath solution with quinidine for about one minute before applying voltage protocols. The concentration-response curves were fitted to four-parameter Hill equation:

where Y is the value of I_Quinidine/I_Control, Top is the maximum response, Bottom is the minimum response, X is the lg of concentration, IC₅₀ is the drug concentration producing the half-maximum response, and H is the Hill coefficient. Significance of fitted IC₅₀ values compared to control was analyzed using extra sum-of-squares F test.

For data presented in Fig. S7, cells were excluded from analysis if series resistance > 5 MΩ and series resistance compensation was set to 70%∼90%.

The time constants (τ) of activation were fitted with a single exponential equation:

where I is the current amplitude, t is time, offset represents the asymptote of the fit, and A represents the amplitude for the activation or inactivation.

Steady-state fast inactivation (I-V) and conductance-voltage (G-V) relationships were fitting with Boltzmann equations:

where I is the peak current, G is conductance, V_m is the stimulus potential, V_1/2 is the midpoint voltage, E_Na is the equilibrium potential, and k is the slope factor. Significance of fitted V_1/2 compared to control was analyzed using extra sum-of-squares F test.

Recovery from fast inactivation data were fitted with a single exponential equation:

Where I is the peak current of test pulse, I_max is the peak current of first pulse, A is the proportional coefficient, t is the delay time between the two pulses, and τ is the time constant of recovery from fast inactivation.

The activation time constants of Na_V channels were fitted with a single exponential equation:

Where I is the current amplitude, A and B are the partition coefficients, t is the time, and τ is the time constant of activation.

Acute slice preparation and current-clamp recordings

Horizontal slices containing hippocampus were obtained from 6-8 weeks old heterozygous Na_V1.6 knockout (Scn8a^+/-) C3HeB/FeJ mice and the wild-type littermate controls. In brief, animals were anesthetized and perfused intracardially with ice-cold modified “cutting solution” containing (in mM): 110 choline chloride, 2.5 KCl, 0.5 CaCl₂, 7 MgCl₂, 25 NaHCO₃, 1.25 NaH₂PO₄, 10 glucose; bubbled continuously with 95%O₂/5%CO₂ to maintain PH at 7.2. The brain was then removed and submerged in ice-cold “cutting solution”. Next, the brain was cut into 300 μm slices with a vibratome (WPI). Slices were incubated in oxygenated (95% O₂ and 5% CO₂) “recording solution” containing (in mM): 125 NaCl, 2.5 KCl, 2 CaCl₂, 2 MgCl₂, 25 NaHCO₃, 1.25 NaH₂PO₄, 10 glucose (315 mOsm/L, PH 7.4, 37°C) for 30 min, and stored at room temperature.

Slices were subsequently transferred to a submerged chamber containing “recording solution” maintained at 34-36 °C. Whole-cell recordings were obtained from hippocampal CA1 neurons under a ×60 water-immersion objective of an Olympus BX51WI microscope (Olympus). Pipettes had resistances of 5-8 MΩ. For current-clamp recordings, the external solution (unless otherwise noted) was supplemented with 0.05 mM (2R)-amino-5-phosphonovaleric acid (APV), 0.01 mM 6-cyano-7-nitro-quinoxaline-2,3-dione, 0.01 mM bicuculline and 0.001 mM CGP 55845, and internal pipette solution containing (in mM): 118 KMeSO₄, 15 KCl, 10 HEPES, 2 MgCl₂, 0.2 EGTA, and 4 Na₂ATP, 0.3 Tris-GTP, 14 Tris-phosphocreatinin (pH 7.3 with KOH).

In our whole-cell current-clamp recordings with an Axon 700B amplifier (Molecular Devices), we initially applied a 100 ms, 20 pA test pulse to the recording neurons right after breaking into the whole-cell configuration. A fast-rising component and a slow-rising component of voltage response were clearly visible. Then we zoomed into the fast-rising component of the voltage responses and turned up the pipette capacitance neutralization slowly to shorten the rise time of the fast-rising component until the oscillations of voltage responses appeared. Subsequently, we decreased the capacitance compensation just until the oscillations disappeared. For bridge balance of current-clamp recordings, we increased the value of bridge balance slowly until the fast component of the voltage response disappeared, and the slow-rising component appeared to rise directly from the baseline. Series resistance and pipette capacitance were compensated using the bridge balance and pipette capacitance neutralization options in the Multiclamp 700B command software (Molecular Devices). The bridge balance value was between 20 and 30 MΩ and the pipette capacitance neutralization value was between 3 and 5 pF. For in vitro experiments, the cells were selected by criteria based on hippocampal CA1 cell morphology and electrophysiological properties in the slices. Electrophysiological recordings were made using a Multiclamp 700B amplifier (Molecular Devices). Recordings were filtered at 10 kHz and sampled at 50 kHz. Data were acquired and analyzed using pClamp10.0 (Molecular Devices). Series resistance was in the order of 10–30 MΩ and was approximately 60–80% compensated. Recordings were discarded if the series resistance increased by more than 20% during the time course of the recordings.

Fluorescence Imaging and FRET Quantification

The spectroscopic imaging was built upon a Nikon TE2000-U microscope. The excitation light was generated by an Ar laser. The fluorescent protein mVenus fused to Na_V1.6 and mTFP1 fused to Slack were excited by laser line at 500 and 400-440 nm, respectively. The duration of light exposure was controlled by a computer-driven mechanical shutter (Uniblitz). A spectrograph (Acton SpectraPro 2150i) was used in conjunction with a charge coupled device (CCD) camera (Roper Cascade 128B). In this recording mode two filter cubes (Chroma) were used to collect spectroscopic images from each cell (excitation, dichroic): cube I, D436/20, 455dclp; cube II, HQ500/20, Q515lp. No emission filter was used in these cubes. Under the experimental conditions, auto fluorescence from untransfected cells was negligible. Fluorescence imaging and analysis were done using the MetaMorph software (Universal Imaging). User-designed macros were used for automatic collection of the bright field cell image, the fluorescence cell image, and the spectroscopic image. Emission spectra were collected from the plasma membrane of the cell by positioning the spectrograph slit across a cell and recording the fluorescence intensity at the position corresponding to the membrane region (Fig. 2e, dotted lines in red); the same slit position applied to both the spectrum taken with the mTFP1 excitation and the spectrum taken with the mVenus excitation. Using this approach, the spectral and positional information are well preserved, thus allowing reliable quantification of FRET efficiency specifically from the cell membrane. Spectra were corrected for background light, which was estimated from the blank region of the same image.

FRET data was quantified in two ways. First, the FRET ratio was calculated from the increase in mVenus emission due to energy transfer as described in the previous study.⁶⁰ Briefly, mTFP1 emission was separated from mVenus emission by fitting of standard spectra acquired from cells expressiring only mVenus or mTFP1. The fraction of mVenus-tagged molecules that are associated with mTFP1-tagged molecules, Ab, is calculated as

where K_D is the dissociation constant and [Dfree] is the concentration of free donor molecules. Note that

Regression analysis was used to estimate Ab in individual cells. From each cell, the FRET ratio_exp was experimentally determined. The predicted Ab value was then computed by adjusting two parameters, FRET Ratio_max and apparent K_D. Ab was in turn used to give a predicted FRET ratiopredicted. By minimizing the squared errors (FRET ratio_exp – FRET ratio_predicted)², K_D was determined.

Second, apparent FRET efficiency was also calculated from the enhancement of mVenus fluorescence emission due to energy transfer^60–63 using a method as previously described.⁶⁴ Briefly, Ratio A₀ and Ratio A were measured to calculate FRET efficiency. Ratio A₀ represents the ratio between tetramethylrhodamine maleimide emission intensities (in the absence of fluorescein maleimide) upon excitation at the donor and acceptor excitation wavelengths^63–65, and was calculated in the present study at the mVenus peak emission wavelength. A particular advantage of quantifying Ratio A₀ for FRET measurement is that changes in fluorescence intensity caused by many experimental factors can be cancelled out by the ratiometric measurement. A similar ratio, termed Ratio A, was determined in the presence of mTFP1 in the same way as Ratio A₀. If FRET occurred, the Ratio A value should be higher than Ratio A₀; the difference between Ratio A and Ratio A₀ was directly proportional to the FRET efficiency by the factor of extinction coefficient ratio of mTFP1 and mVenus.^63–65

Immunostaining

After deep anesthesia with sodium pentobarbital, mice were sacrificed by perfusion with 0.5% paraformaldehyde and 0.5% sucrose (wt/vol) in 0.1 M phosphate buffer (pH 7.4). The brain was removed and post-fixed in the same fixative for 2 h, and subsequently immersed in 30% sucrose in 0.1 M phosphate buffer for 48 h. Cryostat coronal sections (20 μm) were obtained using a freezing microtome (Leica). The sections were rinsed in 0.01 M phosphate-buffered saline (PBS, pH 7.4), permeabilized in 0.5% Triton X-100 in PBS for 30 min, and incubated in a blocking solution (5% BSA, 0.1% Triton X-100 in PBS, vol/vol) at 20–25 °C for 2 h, followed by overnight incubation at 4 °C with primary antibody to AnkG (1:100, Santa Cruz, sc-31778), Slack (1:100, NeuroMab, 73-051), Na_V1.2 (1:200, Alomone, ASC-002), Na_V1.6 (1:200, Alomone, ASC-006), Flag (1:500, Abbkine, ABT2010), and HA (1:500, Abbkine, ABT2040) in blocking solution. After a complete wash in PBS, the sections were incubated in Alexa 488-conjugated doney anti-rabbit IgG and Alexa 594 donkey anti-mouse IgG in blocking solution at 20–25 °C for 2 h. The sections were subsequently washed and rinsed in Dapi solution. Images were taken in the linear range of the photomultiplier with a laser scanning confocal microscope (ZEISS LSM 510 META NLO).

Adeno-associated virus construction and injection

The adeno-associated viruses (AAVs) and the negative GFP control were from Shanghai GeneChem. Co., Ltd. The full-length Slack_G269S sequence (1-1238aa) was ligated into modified CV232 (CAG-MCS-HA-Poly A) adeno-associated viral vector. The Slack’s C-terminus sequence (326-1238aa) and the negative control were ligated into GV634 (CAG-MCS-3×Flag-T2A-EGFP-SV40-Poly A) adeno-associated viral vector. The viruses (>10¹¹ TU/ml) were used in the present study.

For dorsal CA1 viral injection, C57BL/6J mice aged 3 weeks were anesthetized with isoflurane and placed in a stereotaxic apparatus (RWD Life Science Co., Ltd.). Using a 5 μL micro syringe (Hamilton) with a 30 gauge needle (RWD Life Science Co., Ltd.), 600 nL of the viruses was delivered at 10 nL/min by a micro-syringe pump (RWD Life Science Co., Ltd.) at the following site in each of the bilateral CA1 regions, using the stereotaxic coordinates: 2.5 mm (anterior-posterior) from bregma, 2 mm (medio-lateral), ± 1.5 mm (dorsal-ventral)⁶⁶. The syringe was left in place for 5 min after each injection and withdrawn slowly. The exposed skin was closed by surgical sutures and returned to home cage for recovery. All the experiments were conducted after at least 3 weeks of recovery. All the mice were sacrificed after experiments to confirm the injection sites and the viral trans-infection effects by checking EGFP under a fluorescence microscope (ZEISS LSM 510 META NLO).

Kainic acid-induced status epilepticus

KA (Sigma-Aldrich) was intraperitoneally administered to produce seizures with stage IV or higher. The dose of kainic acid used was 28 mg/kg for mice (6–8 weeks)^67,68. To assess epilepsy susceptibility, seizures were rated using a modified Racine, Pinal, and Rovner scale^45,69: (1) Facial movements; (2) head nodding; (3) forelimb clonus; (4) dorsal extension (rearing); (5) Loss of balance and falling; (6) Repeated rearing and failing; (7) Violent jumping and running; (8) Stage 7 with periods of tonus; (9) Dead. Seizures was terminated 2 h after onset with the use of sodium pentobarbital (30 mg/kg; Sigma-Aldrich).

Statistical analysis

For in vitro experiments, the cells were evenly suspended and then randomly distributed in each well tested. For in vivo experiments, the animals were distributed into various treatment groups randomly. Statistical analyses were performed using GraphPad Prism 9 (GraphPad Software) and SPSS 26.0 software (SPSS Inc.). Before statistical analysis, variation within each group of data and the assumptions of the tests were checked. Comparisons between two independent groups were made using unpaired Student’s two-tailed t test. Comparisons among nonlinear fitted values were made using extra sum-of-squares F test. Comparisons among three or more groups were made using one- or two-way analysis of variance followed by Bonferroni’s post hoc test. No statistical methods were used to predetermine sample sizes but our sample sizes are similar to those reported previously in the field^37,70. All experiments and analysis of data were performed in a blinded manner by investigators who were unaware of the genotype or manipulation. * p < 0.05, ** p < 0.01, *** p < 0.001, **** p < 0.0001. All data are presented as mean ± SEM.

Author contributions

T.Y., Y.J., and H.Y. performed and analyzed voltage-clamp recordings. Y.W. performed and analyzed Western blotting, immunoprecipitation. S.X., C.P., and G.D. performed and analyzed pull down assay. Q.C. performed the immunostaining. H.Z. and F.Y. performed and analyzed the FRET imaging. H.S., N.L., and X.M. performed and analyzed the current clamp recordings. T.Y., H.Y., Z.G., and J.D. performed the molecular cloning. Z.H., T.Y., and Y.W. designed the experiments. Z.H., T.Y., and Y.J. wrote the manuscript. Z.H., F.Y., Y.Y., and Q.S. reviewed the manuscript.

Acknowledgements

This work was supported by Chinese National Programs for Brain Science and Brain-like intelligence technology No.2021ZD0202102 to Z.H.; National Natural Science Foundation of China Grant (Nos. 31871083 and 81371432 to Z.H.; Nos. 32000674 to G.D.). We also thank Professor Yousheng Shu at Fudan University for providing the Na_V1.6-knockout mice.

Data availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

References

1.
1. Kameyama M
2. Kakei M
3. Sato R
4. Shibasaki T
5. Matsuda H
6. Irisawa H.
1984Intracellular Na+ activates a K+ channel in mammalian cardiac cellsNature. 309:354–6https://doi.org/10.1038/309354a0
2.
1. Yuan A
2. Santi CM
3. Wei A
4. et al.
2003The sodium-activated potassium channel is encoded by a member of the Slo gene familyNeuron 37:765–773
3.
1. Joiner WJ
2. Tang MD
3. Wang LY
4. et al.
1998Formation of intermediate-conductance calcium-activated potassium channels by interaction of Slack and Slo subunitsNat Neurosci 1:462–9https://doi.org/10.1038/2176
4.
1. Rizzi S
2. Knaus HG
3. Schwarzer C.
2016Differential distribution of the sodium-activated potassium channels slick and slack in mouse brainJ Comp Neurol. 524:2093–116https://doi.org/10.1002/cne.23934
5.
1. Bhattacharjee A
2. Gan L
3. Kaczmarek LK.
2002Localization of the Slack potassium channel in the rat central nervous systemJ Comp Neurol. 454:241–54https://doi.org/10.1002/cne.10439
6.
1. Yang B
2. Desai R
3. Kaczmarek LK.
2007Slack and Slick K(Na) channels regulate the accuracy of timing of auditory neuronsJ Neurosci. 27:2617–27https://doi.org/10.1523/JNEUROSCI.5308-06.2007
7.
1. Wallen P
2. Robertson B
3. Cangiano L
4. et al.
2007Sodium-dependent potassium channels of a Slack-like subtype contribute to the slow afterhyperpolarization in lamprey spinal neuronsJ Physiol. 585:75–90https://doi.org/10.1113/jphysiol.2007.138156
8.
1. Heron SE
2. Smith KR
3. Bahlo M
4. et al.
2012Missense mutations in the sodium-gated potassium channel gene KCNT1 cause severe autosomal dominant nocturnal frontal lobe epilepsyNat Genet 44:1188–90https://doi.org/10.1038/ng.2440
9.
1. Barcia G
2. Fleming MR
3. Deligniere A
4. et al.
2012De novo gain-of-function KCNT1 channel mutations cause malignant migrating partial seizures of infancyNature genetics 44:1255–1259
10.
1. Kingwell K.
2012Mutations in potassium channel KCNT1—a novel driver of epilepsy pathogenesisNature Reviews Neurology 8:658–658
11.
1. Bonardi CM
2. Heyne HO
3. Fiannacca M
4. et al.
2021KCNT1-related epilepsies and epileptic encephalopathies: phenotypic and mutational spectrumBrain. 144:3635–3650https://doi.org/10.1093/brain/awab219
12.
1. McTague A
2. Nair U
3. Malhotra S
4. et al.
2018Clinical and molecular characterization of KCNT1-related severe early-onset epilepsyNeurology. 90:e55–e66https://doi.org/10.1212/WNL.0000000000004762
13.
1. Milligan CJ
2. Li M
3. Gazina EV
4. et al.
2014KCNT1 gain of function in 2 epilepsy phenotypes is reversed by quinidineAnnals of neurology 75:581–590
14.
1. Bearden D
2. Strong A
3. Ehnot J
4. DiGiovine M
5. Dlugos D
6. Goldberg EM.
2014Targeted treatment of migrating partial seizures of infancy with quinidineAnn Neurol 76:457–61https://doi.org/10.1002/ana.24229
15.
1. Mikati MA
2. Jiang YH
3. Carboni M
4. et al.
2015Quinidine in the treatment of KCNT1-positive epilepsiesAnn Neurol 78:995–9https://doi.org/10.1002/ana.24520
16.
1. Numis AL
2. Nair U
3. Datta AN
4. et al.
2018Lack of response to quinidine in KCNT 1-related neonatal epilepsyEpilepsia 59:1889–1898
17.
1. Liu R
2. Sun L
3. Wang Y
4. Wang Q
5. Wu J.
2022New use for an old drug: quinidine in KCNT1-related epilepsy therapyNeurol Sci. Nov https://doi.org/10.1007/s10072-022-06521-x
18.
1. Cole BA
2. Clapcote SJ
3. Muench SP
4. Lippiat JD.
2021Targeting KNa1.1 channels in KCNT1-associated epilepsyTrends Pharmacol Sci 42:700–713https://doi.org/10.1016/j.tips.2021.05.003
19.
1. Xu D
2. Chen S
3. Yang J
4. Wang X
5. Fang Z
6. Li M.
2022Precision therapy with quinidine of KCNT1-related epileptic disorders: A systematic reviewBr J Clin Pharmacol 88:5096–5112https://doi.org/10.1111/bcp.15479
20.
1. Zhang Z
2. Rosenhouse-Dantsker A
3. Tang QY
4. Noskov S
5. Logothetis DE.
2010The RCK2 domain uses a coordination site present in Kir channels to confer sodium sensitivity to Slo2.2 channelsJ Neurosci. 30:7554–62https://doi.org/10.1523/JNEUROSCI.0525-10.2010
21.
1. Budelli G
2. Hage TA
3. Wei A
4. et al.
2009Na+-activated K+ channels express a large delayed outward current in neurons during normal physiologyNat Neurosci 12:745–50https://doi.org/10.1038/nn.2313
22.
1. Hage TA
2. Salkoff L.
2012Sodium-activated potassium channels are functionally coupled to persistent sodium currentsJ Neurosci. Feb 32:2714–21https://doi.org/10.1523/JNEUROSCI.5088-11.2012
23.
1. Nanou E
2. Kyriakatos A
3. Bhattacharjee A
4. Kaczmarek LK
5. Paratcha G
6. El Manira A.
2008Na+-mediated coupling between AMPA receptors and KNa channels shapes synaptic transmissionProceedings of the National Academy of Sciences 105:20941–20946
24.
1. Goldin AL.
2001Resurgence of sodium channel researchAnnu Rev Physiol 63:871–94https://doi.org/10.1146/annurev.physiol.63.1.871
25.
1. Trimmer JS
2. Rhodes KJ.
2004Localization of voltage-gated ion channels in mammalian brainAnnu Rev Physiol 66:477–519https://doi.org/10.1146/annurev.physiol.66.032102.113328
26.
1. Lai HC
2. Jan LY.
2006The distribution and targeting of neuronal voltage-gated ion channelsNat Rev Neurosci 7:548–62https://doi.org/10.1038/nrn1938
27.
1. Pickard L
2. Noel J
3. Henley JM
4. Collingridge GL
5. Molnar E.
2000Developmental changes in synaptic AMPA and NMDA receptor distribution and AMPA receptor subunit composition in living hippocampal neuronsJ Neurosci. 20:7922–31
28.
1. Cole BA
2. Johnson RM
3. Dejakaisaya H
4. et al.
2020Structure-Based Identification and Characterization of Inhibitors of the Epilepsy-Associated KNa1.1 (KCNT1) Potassium ChanneliScience. 23https://doi.org/10.1016/j.isci.2020.101100
29.
1. Slack Kaczmarek LK.
2013Slick and Sodium-Activated Potassium ChannelsISRN Neurosci https://doi.org/10.1155/2013/354262
30.
1. Bhattacharjee A
2. Joiner WJ
3. Wu M
4. Yang Y
5. Sigworth FJ
6. Kaczmarek LK.
2003Slick (Slo2.1), a rapidly-gating sodium-activated potassium channel inhibited by ATPJ Neurosci. 23:11681–91
31.
1. Rosker C
2. Lohberger B
3. Hofer D
4. Steinecker B
5. Quasthoff S
6. Schreibmayer W.
2007The TTX metabolite 4, 9-anhydro-TTX is a highly specific blocker of the Nav1. 6 voltage-dependent sodium channelAmerican Journal of Physiology-Cell Physiology 293:C783–C789
32.
1. Rush AM
2. Dib-Hajj SD
3. Waxman SG.
2005Electrophysiological properties of two axonal sodium channels, Nav1.2 and Nav1.6, expressed in mouse spinal sensory neuronesJ Physiol 564:803–15https://doi.org/10.1113/jphysiol.2005.083089
33.
1. Chatelier A
2. Zhao J
3. Bois P
4. Chahine M.
2010Biophysical characterisation of the persistent sodium current of the Nav1.6 neuronal sodium channel: a single-channel analysisPflugers Arch 460:77–86https://doi.org/10.1007/s00424-010-0801-9
34.
1. Urbani A
2. Belluzzi O.
2000Riluzole inhibits the persistent sodium current in mammalian CNS neuronsEur J Neurosci 12:3567–74https://doi.org/10.1046/j.1460-9568.2000.00242.x
35.
1. Lukacs P
2. Foldi MC
3. Valanszki L
4. et al.
2018Non-blocking modulation contributes to sodium channel inhibition by a covalently attached photoreactive riluzole analogSci Rep. 8https://doi.org/10.1038/s41598-018-26444-y
36.
1. Hu W
2. Tian C
3. Li T
4. Yang M
5. Hou H
6. Shu Y.
2009Distinct contributions of Na(v)1.6 and Na(v)1.2 in action potential initiation and backpropagationNat Neurosci 12:996–1002https://doi.org/10.1038/nn.2359
37.
1. Liu Y
2. Lai S
3. Ma W
4. et al.
2017CDYL suppresses epileptogenesis in mice through repression of axonal Nav1.6 sodium channel expressionNat Commun. 8https://doi.org/10.1038/s41467-017-00368-z
38.
1. Takanishi CL
2. Bykova EA
3. Cheng W
4. Zheng J.
2006GFP-based FRET analysis in live cellsBrain Res 1091:132–9https://doi.org/10.1016/j.brainres.2006.01.119
39.
1. Dilena R
2. DiFrancesco JC
3. Soldovieri MV
4. et al.
2018Early Treatment with Quinidine in 2 Patients with Epilepsy of Infancy with Migrating Focal Seizures (EIMFS) Due to Gain-of-Function KCNT1 Mutations: Functional Studies, Clinical Responses, and Critical Issues for Personalized TherapyNeurotherapeutics 15:1112–1126https://doi.org/10.1007/s13311-018-0657-9
40.
1. Abdelnour E
2. Gallentine W
3. McDonald M
4. Sachdev M
5. Jiang Y-H
6. Mikati MA.
2018Does age affect response to quinidine in patients with KCNT1 mutations? Report of three new cases and review of the literatureSeizure 55:1–3
41.
1. Rizzo F
2. Ambrosino P
3. Guacci A
4. et al.
2016Characterization of two de novoKCNT1 mutations in children with malignant migrating partial seizures in infancyMol Cell Neurosci 72:54–63https://doi.org/10.1016/j.mcn.2016.01.004
42.
1. Barcia G
2. Chemaly N
3. Kuchenbuch M
4. et al.
2019Epilepsy with migrating focal seizures: KCNT1 mutation hotspots and phenotype variabilityNeurol Genet 5https://doi.org/10.1212/NXG.0000000000000363
43.
1. Nadler JV.
1981Kainic acid as a tool for the study of temporal lobe epilepsyLife sciences 29:2031–2042
44.
1. Levesque M
2. Avoli M.
2013The kainic acid model of temporal lobe epilepsyNeurosci Biobehav R 37:2887–2899https://doi.org/10.1016/j.neubiorev.2013.10.011
45.
1. Pinel JP
2. Rovner LI.
1978Electrode placement and kindling-induced experimental epilepsyExp Neurol. 58:335–46https://doi.org/10.1016/0014-4886(78)90145-0
46.
1. Kim EC
2. Zhang J
3. Tang AY
4. et al.
2021Spontaneous seizure and memory loss in mice expressing an epileptic encephalopathy variant in the calmodulin-binding domain of Kv7.2Proc Natl Acad Sci U S A. 118https://doi.org/10.1073/pnas.2021265118
47.
1. Ehinger R
2. Kuret A
3. Matt L
4. et al.
2021Slack K(+) channels attenuate NMDA-induced excitotoxic brain damage and neuronal cell deathFASEB J 35https://doi.org/10.1096/fj.202002308RR
48.
1. Markham MR
2. Kaczmarek LK
3. Zakon HH.
2013A sodium-activated potassium channel supports high-frequency firing and reduces energetic costs during rapid modulations of action potential amplitudeJ Neurophysiol 109:1713–23https://doi.org/10.1152/jn.00875.2012
49.
1. Kole MH
2. Ilschner SU
3. Kampa BM
4. Williams SR
5. Ruben PC
6. Stuart GJ.
2008Action potential generation requires a high sodium channel density in the axon initial segmentNat Neurosci 11:178–86https://doi.org/10.1038/nn2040
50.
1. Lazarov E
2. Dannemeyer M
3. Feulner B
4. et al.
2018An axon initial segment is required for temporal precision in action potential encoding by neuronal populationsScience advances 4
51.
1. Katz E
2. Stoler O
3. Scheller A
4. et al.
2018Role of sodium channel subtype in action potential generation by neocortical pyramidal neuronsProc Natl Acad Sci U S A. 115:E7184–E7192https://doi.org/10.1073/pnas.1720493115
52.
1. Brown MR
2. Kronengold J
3. Gazula VR
4. et al.
2008Amino-termini isoforms of the Slack K+ channel, regulated by alternative promoters, differentially modulate rhythmic firing and adaptationJ Physiol. 586:5161–79https://doi.org/10.1113/jphysiol.2008.160861
53.
1. Hite RK
2. MacKinnon R.
2017Structural Titration of Slo2.2, a Na(+)-Dependent K(+) ChannelCell. Jan 168:390–399https://doi.org/10.1016/j.cell.2016.12.030
54.
1. Biton B
2. Sethuramanujam S
3. Picchione KE
4. et al.
2012The antipsychotic drug loxapine is an opener of the sodium-activated potassium channel slack (Slo2.2)J Pharmacol Exp Ther 340:706–15https://doi.org/10.1124/jpet.111.184622
55.
1. Gertler T
2. Bearden D
3. Bhattacharjee A
4. Carvill G.
5. Adam MP
6. Ardinger HH
7. Pagon RA
8. et al
1993KCNT1-Related EpilepsyGeneReviews((R))
56.
1. Fitzgerald MP
2. Fiannacca M
3. Smith DM
4. et al.
2019Treatment Responsiveness in KCNT1-Related EpilepsyNeurotherapeutics 16:848–857https://doi.org/10.1007/s13311-019-00739-y
57.
1. Griffin AM
2. Kahlig KM
3. Hatch RJ
4. et al.
2021Discovery of the First Orally Available, Selective KNa1.1 Inhibitor: In Vitro and In Vivo Activity of an Oxadiazole SeriesACS Med Chem Lett 12:593–602https://doi.org/10.1021/acsmedchemlett.0c00675
58.
1. Spitznagel BD
2. Mishra NM
3. Qunies AM
4. et al.
2020VU0606170, a Selective Slack Channels InhibitorDecreases Calcium Oscillations in Cultured Cortical Neurons. ACS Chem Neurosci. 11:3658–3671https://doi.org/10.1021/acschemneuro.0c00583
59.
1. Tang QY
2. Zhang FF
3. Xu J
4. et al.
2016Epilepsy-Related Slack Channel Mutants Lead to Channel Over-Activity by Two Different MechanismsCell Rep. 14:129–139https://doi.org/10.1016/j.celrep.2015.12.019
60.
1. Qiu S
2. Hua YL
3. Yang F
4. Chen YZ
5. Luo JH.
2005Subunit assembly of N-methyl-d-aspartate receptors analyzed by fluorescence resonance energy transferJ Biol Chem. 280:24923–30https://doi.org/10.1074/jbc.M413915200
61.
1. Cheng W
2. Yang F
3. Takanishi CL
4. Zheng J.
2007Thermosensitive TRPV channel subunits coassemble into heteromeric channels with intermediate conductance and gating propertiesJournal of General Physiology 129:191–207
62.
1. Zou L
2. Peng Q
3. Wang P
4. Zhou B.
2017Progress in Research and Application of HIV-1 TAT-Derived Cell-Penetrating PeptideJ Membr Biol 250:115–122https://doi.org/10.1007/s00232-016-9940-z
63.
1. Zheng J
2. Trudeau MC
3. Zagotta WN.
2002Rod cyclic nucleotide-gated channels have a stoichiometry of three CNGA1 subunits and one CNGB1 subunitNeuron 36:891–896
64.
1. Yang F
2. Cui Y
3. Wang K
4. Zheng J.
2010Thermosensitive TRP channel pore turret is part of the temperature activation pathwayProceedings of the National Academy of Sciences 107:7083–7088
65.
1. Erickson MG
2. Alseikhan BA
3. Peterson BZ
4. Yue DT.
2001Preassociation of calmodulin with voltage-gated Ca2+ channels revealed by FRET in single living cellsNeuron 31:973–985
66.
1. Chai AP
2. Chen XF
3. Xu XS
4. et al.
2021A Temporal Activity of CA1 Neurons Underlying Short-Term Memory for Social Recognition Altered in PTEN Mouse Models of Autism Spectrum DisorderFront Cell Neurosci 15https://doi.org/10.3389/fncel.2021.699315
67.
1. Huang Z
2. Walker MC
3. Shah MM.
2009Loss of dendritic HCN1 subunits enhances cortical excitability and epileptogenesisJ Neurosci. 29:10979–88https://doi.org/10.1523/JNEUROSCI.1531-09.2009
68.
1. He X-P
2. Kotloski R
3. Nef S
4. Luikart BW
5. Parada LF
6. McNamara JO.
2004Conditional deletion of TrkB but not BDNF prevents epileptogenesis in the kindling modelNeuron 43:31–42
69.
1. Racine RJ.
1972Modification of seizure activity by electrical stimulationII. Motor seizure. Electroencephalogr Clin Neurophysiol 32:281–94https://doi.org/10.1016/0013-4694(72)90177-0
70.
1. Huang Z
2. Lujan R
3. Martinez-Hernandez J
4. Lewis AS
5. Chetkovich DM
6. Shah MM.
2012TRIP8b-independent trafficking and plasticity of adult cortical presynaptic HCN1 channelsJ Neurosci. 32:14835–48https://doi.org/10.1523/JNEUROSCI.1544-12.2012

Article and author information

Author information

Tian Yuan
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
- These authors contribute equally to this work
Yifan Wang
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
- These authors contribute equally to this work
Yuchen Jin
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
- These authors contribute equally to this work
Hui Yang
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
- These authors contribute equally to this work
Shuai Xu
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Heng Zhang
NHC and CAMS Key Laboratory of Medical Neurobiology, MOE Frontier Science Center for Brain Research and Brain-Machine Integration, School of Brain Science and Brain Medicine, Zhejiang University, Hangzhou, ,, 310058, China
Qian Chen
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Na Li
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Xinyue Ma
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Huifang Song
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Chao Peng
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Ze Geng
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Jie Dong
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Guifang Duan
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Qi Sun
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China
Yang Yang
Department of Medicinal Chemistry and Molecular Pharmacology, College of Pharmacy, Purdue University, ,, IN 47907, USA
ORCID iD: 0000-0001-6417-3654
Fan Yang
Department of Biophysics, Kidney Disease Center of the First Affiliated Hospital, Zhejiang University School of Medicine, Hangzhou, ,, 310058, China, NHC and CAMS Key Laboratory of Medical Neurobiology, MOE Frontier Science Center for Brain Research and Brain-Machine Integration, School of Brain Science and Brain Medicine, Zhejiang University, Hangzhou, ,, 310058, China
Zhuo Huang
State Key Laboratory of Natural and Biomimetic Drugs, Department of Molecular and Cellular Pharmacology, School of Pharmaceutical Sciences, Peking University Health Science Center, Beijing, 100191, China, IDG/McGovern Institute for Brain Research, Peking University, Beijing, 100871, China
ORCID iD: 0000-0001-9198-4778
- Correspondence: huangz@hsc.pku.edu.cn (Z.H.)

Version history

Sent for peer review: March 16, 2023
Preprint posted: March 18, 2023
Reviewed Preprint version 1: May 31, 2023
Reviewed Preprint version 2: October 11, 2023
Reviewed Preprint version 3: January 11, 2024
Version of Record published: January 30, 2024
Version of Record updated: February 9, 2024

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

Revised: This Reviewed Preprint has been revised by the authors in response to the previous round of peer review; the eLife assessment and the public reviews have been updated where necessary by the editors and peer reviewers.

Reviewing Editor
Stephan Pless
University of Copenhagen, Copenhagen, Denmark
Senior Editor
Kenton Swartz
National Institute of Neurological Disorders and Stroke, Bethesda, United States of America

Reviewer #1 (Public Review):

Despite numerous studies on quinidine therapies for epilepsies associated with GOF mutant variants of Slack, there is no consensus on its utility due to contradictory results. In this study Yuan et al. investigated the role of different sodium selective ion channels on the sensitization of Slack to quinidine block. The study employed electrophysiological approaches, FRET studies, genetically modified proteins and biochemistry to demonstrate that Nav1.6 N- and C-tail interacts with Slack's C-terminus and significantly increases Slack sensitivity to quinidine blockade in vitro and in vivo. This finding inspired the authors to investigate whether they could rescue Slack GOF mutant variants by simply disrupting the interaction between Slack and Nav1.6. They find that the isolated C-terminus of Slack can reduce the current amplitude of Slack GOF mutant variants co-expressed with Nav1.6 in HEK cells and prevent Slack induced seizures in mouse models of epilepsy. This study adds to the growing list of channels that are modulated by protein-protein interactions, and is of great value for future therapeutic strategies.

https://doi.org/10.7554/eLife.87559.3.sa2

Reviewer #2 (Public Review):

This is a very interesting paper about the coupling of Slack and Nav1.6 and the insight this brings to the effects of quinidine to treat some epilepsy syndromes.

Slack is a sodium-activated potassium channel that is important to hyperpolarization of neurons after an action potential. Slack is encoded by KNCT1 which has mutations in some epilepsy syndromes. These types of epilepsy are treated with quinidine but this is an atypical antiseizure drug, not used for other types of epilepsy. For sufficient sodium to activate Slack, Slack needs to be close to a channel that allows robust sodium entry, like Nav channels or AMPA receptors. but more mechanistic information is not available. Of particular interest to the authors is what allows quinidine to be effective in reducing Slack.

In the manuscript, the authors show that Nav, not AMPA receptors, are responsible for Slack's sensitization to quinidine blockade, at least in cultured neurons (HeK293, primary cortical neurons). Most of the paper focuses on the evidence that Nav1.6 promotes Slack sensitivity to quinidine.

https://doi.org/10.7554/eLife.87559.3.sa1

Reviewer #3 (Public Review):

Yuan et al., set out to examine the role of functional and structural interaction between Slack and NaVs on the Slack sensitivity to quinidine. Through pharmacological and genetic means they identify NaV1.6 as the privileged NaV isoform in sensitizing Slack to quinidine. Through biochemical assays, they then determine that the C-terminus of Slack physically interacts with the N- and C-termini of NaV1.6. Using the information gleaned from the in vitro experiments the authors then show that virally-mediated transduction of Slack's C-terminus lessens the extent of SlackG269S-induced seizures. These data uncover a previously unrecognized interaction between a sodium and a potassium channel, which contributes to the latter's sensitivity to quinidine.

https://doi.org/10.7554/eLife.87559.3.sa0

Author Response

The following is the authors’ response to the previous reviews.

We appreciate the constructive comments made by the editor and the reviewers. We have corrected errors and provided additional experimental data and analysis to address the latest criticisms raised by the reviewers and provided point-by-point response to the reviewers as below.

Reviewer #1 (Recommendations For The Authors):

I do acknowledge the work the authors put into this manuscript and I can accept the fact that the authors decided on a minimum of additional experiments. However, I would recommend the authors to be more concise by adding more information in the method and result sections about how they performed their experiments such as which Nav and AMPAR DNA constructs they used, the age of the mice, how long time they exposed the patches to quinidine, information on how many times they repeated their pull downs etc.

Answer: We thank the reviewer’s comments. we have incorporated the suggested modifications into our revised manuscript. Specifically, we have included detailed information on the NaV and AMPAR constructs in the Methods section. The age of the homozygous NaV1.6 knockout mice and the wild-type littermate controls is postnatal (P0-P1) (see in Results and Methods section). Prior to the application of step pulses, cells were subjected to the bath solution containing quinidine for approximately one minute (see in Methods section). Additionally, the co-immunoprecipitation assays for Slack and NaV1.6 were repeated three times (see in Methods section).

Minor detail in line 263: "...KCNT1 (Slack) have been identified to related to seizure..." I guess this should have been "...KCNT1 (Slack) have been identified and related to seizure..."?

Answer: We thank the reviewer for raising this point. We have corrected it in the revised manuscript.

Also, and again minor detail, I had a comment about the color coding in Fig 4 and by mistake, I added 4B, but I meant the use of colors in the entire figure, and mainly the use of colors in 4C, G and I.

Answer: We apologize for the confusion. We have changed the color coding of Figure 4 in the revised manuscript.

Reviewer #2 (Recommendations For The Authors):

While the paper is improved, several concerns do not seem to have been addressed. Some may have been missed because there is no response at all, but others may have been unclear because the response does not address the concern, but a related issue. Details are below.

Answer: We thank the reviewer for the criticisms. We have made changes of our manuscript to address the concerns.

Original issue:

Remove the term in vivo.

Answer: We thank the reviewer for raising this point. In our experiments, although we did not conduct experiments directly in living organisms, our results demonstrated the coimmunoprecipitation of NaV1.6 with Slack in homogenates from mouse cortical and hippocampal tissues (Fig. 3C). This result may support that the interaction between Slack and NaV1.6 occurs in vivo.

New comment from reviewer:

The argument to use the term in vivo is not well supported by what the authors have said. Just because tissues are used from an animal does not mean experiments were conducted in vivo. As the authors say, they did not conduct experiments in living organisms. Therefore the term in vivo should be avoided. This is a minor point.

Answer: We thank the reviewer for pointing this out. We have removed the term “in vivo” in the revised manuscript.

Original:

Figure 1C Why does Nav1.2 have a small inward current before the large inward current in the inset?

Answer: We apologize for the confusion. We would like to clarify that the small inward current can be attributed to the current of membrane capacitance (slow capacitance or C-slow). The larger inward current is mediated by NaV1.2.

New comment:

This is not well argued. Please note why the authors know the current is due to capacitance. Also, how do they know the larger current is due to NaV1.2? Please add that to the paper so readers know too.

Answer: We thank the reviewer’s comment. To provide a clearer representation of NaV1.2mediated currents in Fig. 1C, we have replaced the original example trace with a new one in which only one inward current is observed.

Original:

The slope of the rising phase of the larger sodium current seems greater than Nav1.6 or Nav1.5. Was this examined?

Answer: Additionally, we did not compare the slope of the rising phase of NaV subtypes sodium currents but primarily focused on the current amplitudes.

New comment:

This is not a strong answer. There seems to be an effect that the authors do not mention and evidently did not quantify that argues against their conclusion, which weakens the presentation.

Answer: We thank the reviewer’s comment. To assess the slope of the rising phase of NaV subtype currents, we compared the activation time constants of NaV1.2, NaV1.5, and NaV1.6 peak currents in HEK293 cells co-expressing NaV channel subtypes with Slack. The results have shown no significant differences (Author response image 1). We have included this analysis (see Fig. S9A) and the corresponding fitting equation (see in Methods section) in the revised manuscript.

Author response image 1.

The activation time constants of peak sodium currents in HEK293 cells co-expressing NaV1.2 (n=6), NaV1.5 (n=5), and NaV1.6 (n=5) with Slack, respectively. ns, p > 0.05, one-way ANOVA followed by Bonferroni’s post hoc test.

Original:

2D-E For Nav1.5 the sodium current is very large compared to Nav1.6. Is it possible the greater effect of quinidine for Nav1.6 is due to the lesser sodium current of Nav1.6?

Answer: We thank the reviewer for raising this point. We would like to clarify that our results indicate that transient sodium currents contribute to the sensitization of Slack to quinidine blockade (Fig. 2C,E). Therefore, it is unlikely that the greater effect observed for NaV1.6 in sensitizing Slack is due to its lower sodium currents.

New comment:

I am not sure the question I was asking was clear. How can the authors discount the possibility that quinidine is more effective on NaV1.6 because the NaV1.6 current is relatively weak?

Answer: We thank the reviewer for raising this point. We have examined the sodium current amplitudes of NaV1.5, NaV1.5/1.6 chimeras, and NaV1.6 upon co-expression of NaV with Slack. Our analysis revealed that there are no significant differences between NaV1.5 and NaV1.5/6N, with both exhibiting much larger current amplitudes compared to NaV1.6 (Author response image 2), but only NaV1.5/6N replicates the effect of NaV1.6 in sensitizing Slack to quinidine blockade (Fig. 4H-I), suggesting the observed differences between NaV1.5 and NaV1.6 in sensitizing Slack are unlikely to be attributed to NaV1.6's lower sodium currents but may instead involve NaV1.6's Nterminus-induced physical interaction. We have included this analysis in the revised manuscript (see Fig. S9B).

Author response image 2.

Comparison of peak sodium current amplitudes of NaV1.5 (n=9), NaV1.5/6NC (n=13), NaV1.5/6N (n=10), and NaV1.6 (n=8) upon co-expressed with Slack in HEK293 cells. ns, p > 0.05, * p < 0.05, ** p < 0.01, *** p < 0.001, **** p < 0.0001; one-way ANOVA followed by Bonferroni’s post hoc test.

Original:

The differences between WT and KO in G -H are hard to appreciate. Could quantification be shown? The text uses words like "block" but this is not clear from the figure. It seems that the replacement of Na+ with Li+ did not block the outward current or effect of quinidine.

Answer: We apologize for the confusion. We would like to clarify the methods used in this experiment. The lithium ion (Li+) is a much weaker activator of sodium-activated potassium channel Slack than sodium ion (Na+)1,2.

Zhang Z, Rosenhouse-Dantsker A, Tang QY, Noskov S, Logothetis DE. The RCK2 domain uses a coordination site present in Kir channels to confer sodium sensitivity to Slo2.2 channels. J Neurosci. Jun 2 2010;30(22):7554-62. doi:10.1523/JNEUROSCI.0525-10.2010
Kaczmarek LK. Slack, Slick and Sodium-Activated Potassium Channels. ISRN Neurosci. Apr 18 2013;2013(2013)doi:10.1155/2013/354262 Therefore, we replaced Na+ with Li+ in the bath solution to measure the current amplitudes of sodium-activated potassium currents (IKNa)3.
Budelli G, Hage TA, Wei A, et al. Na+-activated K+ channels express a large delayed outward current in neurons during normal physiology. Nat Neurosci. Jun 2009;12(6):745-50. doi:10.1038/nn.2313

The following equation was used for quantification:

Furthermore, the remaining IKNa after application of 3 μM quinidine in the bath solution was measured as the following:

The quantification results were presented in Fig. 1K. The term "block" used in the text referred to the inhibitory effect of quinidine on IKNa.

New comment:

The fact remains that the term "block" is too strong for an effect that is incomplete. Also, the authors should add to the paper that Li+ is a weaker activator, so the reader knows some of the caveats to the approach.

Answer: We thank the reviewer for raising this point. We have added related citations and replaced the term “block” with “inhibit” in the revised manuscript.

Original:

In K, for the WT, why is the effect of quinidine only striking for the largest currents?

Answer: We thank the reviewer for raising this point. After conducting an analysis, we found no correlation between the inhibitory effect of quinidine and the amplitudes of baseline IKNa in WT neurons (p = 0.6294) (Author response image 3). Therefore, the effect of quinidine is not solely limited to targeting the larger currents.

Author response image 3.

The correlation between the inhibitory effect of quinidine and the amplitudes of baseline IKNa in WT neurons (data from manuscript Fig. 1K). r = 0.1555, p=0.6294, Pearson correlation analysis.

New comment:

Please add this to the paper and the figure as Supplemental.

Answer: We thank the reviewer for raising this point. We have added this figure as Fig.S3B in the revised manuscript.

Original:

Figure 2 A. The argument could be better made if the same concentration of quinidine were used for Slack and Slack + Nav1.6. It is recognized a greater sensitivity to quinidine is to be shown but as presented the figure is a bit confusing."

Answer: We apologize for the confusion. We would like to clarify that the presented concentrations of quinidine were chosen to be near the IC50 values for Slack and Slack+NaV1.6.

New comment:

Please add this to the paper.

Answer: We thank the reviewer for raising this point. We have added the clarification about the presented concentrations in the revised manuscript.

Original:

2C. Can the authors add the effect of quinidine to the condition where the prepulse potential was 90?"

Answer: We apologize for the confusion. We would like to clarify that the condition of prepulse potential at -90 mV is the same as the condition in Fig. 1. We only changed one experiment condition where the prepulse potential was changed to -40 mV from -90 mV.

New comment:

There was no confusion. The authors should consider adding the condition where the prepulse potential was -90.

Answer: We thank the reviewer for raising this point. We have added the clarification about the voltage condition in the revised manuscript (see in Fig. 2A caption).

Original:

2A. Clarify these 6 panels."

Answer: We thank the reviewer for raising this point. We have clarified the captions of Fig. 3A in the revised manuscript.

New comment: Clarification is needed. What is the blue? DAPI? What area of hippocamps? Please label cell layers. What area of cortex? Please label layers.

Answer: We thank the reviewer for raising this point. We have included the clarification in the Figure caption.

Original:

Figure 7. The images need more clarity. They are very hard to see. Text is also hard to see."

Answer: We apologize for the lack of clarity in the images and text. we would like to provide a concise summary of the key findings shown in this figure.

Figure 7 illustrates an innovative intervention for treating SlackG269S-induced seizures in mice by disrupting the Slack-NaV1.6 interaction. Our results showed that blocking NaV1.6-mediated sodium influx significantly reduced Slack current amplitudes (Fig. 2D,G), suggesting that the Slack-NaV1.6 interaction contributes to the current amplitudes of epilepsy-related Slack mutant variants, aggravating the gain-of-function phenotype. Additionally, Slack’s C-terminus is involved in the Slack-NaV1.6 interaction (Fig. 5D). We assumed that overexpressing Slack’s C-terminus can disrupt the Slack-NaV1.6 interaction (compete with Slack) and thereby encounter the current amplitudes of epilepsy-related Slack mutant variants.

In HEK293 cells, overexpression of Slack’s C-terminus indeed significantly reduced the current amplitudes of epilepsy-related SlackG288S and SlackR398Q upon co-expression with NaV1.5/6NC (Fig. 7A,B). Subsequently, we evaluated this intervention in an in vivo epilepsy model by introducing the Slack G269S variant into C57BL/6N mice using AAV injection, mimicking the human Slack mutation G288S that we previously identified (Fig. 7C-G).

New comment:

The images do not appear to have changed. Consider moving labels above the images so they can be distinguished better. Please label cell layers. Consider adding arrows to the point in the figure the authors want the reader to notice. The study design and timeline are unclear. What is (1) + (3), (2), etc.?

Answer: We thank the reviewer for pointing this out. We have modified Figure 7 in the revised manuscript and included the cell layer information in the Figure caption.

Original:

It is not clear how data were obtained because injection of kainic acid does not lead to a convulsive seizure every 10 min for several hours, which is what appears to be shown. Individual seizures are just at the beginning and then they merge at the start of status epilepticus. After the onset of status epilepticus the animals twitch, have varied movements, sometime rear and fall, but there is not a return to normal behavior. Therefore one can not call them individual seizures. In some strains of mice, however, individual convulsive seizures do occur (even if the EEG shows status epilepticus is occurring) but there are rarely more than 5 over several hours and the graph has many more. Please explain."

Answer: We apologize for the confusion. Regarding the data acquisition in relation to kainic acid injection, we initiated the timing following intraperitoneal injection of kainic acid and recorded the seizure scores of per mouse at ten-minute intervals, following the methodology described in previous studies4.

Huang Z, Walker MC, Shah MM. Loss of dendritic HCN1 subunits enhances cortical excitability and epileptogenesis. J Neurosci. Sep 2 2009;29(35):10979-88. doi:10.1523/JNEUROSCI.1531-09.2009

The seizure scores were determined using a modified Racine, Pinal, and Rovner scale5,6: (1) Facial movements; (2) head nodding; (3) forelimb clonus; (4) dorsal extension (rearing); (5) Loss of balance and falling; (6) Repeated rearing and failing; (7) Violent jumping and running; (8) Stage 7 with periods of tonus; (9) Dead.

Pinel JP, Rovner LI. Electrode placement and kindling-induced experimental epilepsy. Exp Neurol. Jan 15 1978;58(2):335-46. doi:10.1016/0014-4886(78)90145-0
Racine RJ. Modification of seizure activity by electrical stimulation. II. Motor seizure. Electroencephalogr Clin Neurophysiol. Mar 1972;32(3):281-94. doi:10.1016/00134694(72)90177-0

New comment:

This was clear. Perhaps my question was not clear. The question is how one can count individual seizures if animals have continuous seizures. It seems like the authors did not consider or observe status epilepticus but individual seizures. If that is true the data are hard to believe because too many seizures were counted. Animals do not have nearly this many seizures after kainic acid.

Answer: We appreciate the reviewer’s clarification. Our methodology involved assessing the maximum seizure scale during 10-minute intervals per mouse as previously described7, rather than counting individual seizures. For instance, a mouse exhibited the loss of balance and falling multiple times within 30-40 minute interval, we recorded the seizure scale as 5 for that time interval.

Kim EC, Zhang J, Tang AY, et al. Spontaneous seizure and memory loss in mice expressing an epileptic encephalopathy variant in the calmodulin-binding domain of Kv7.2. Proc Natl Acad Sci U S A. Dec 21 2021;118(51)doi:10.1073/pnas.2021265118

Reviewer #3 (Recommendations For The Authors):

While the authors have improved the manuscript, several outstanding issues still need to be addressed. Some may have been missed because there is no response at all, but others may have been unclear.

Answer: We thank the reviewer for the criticisms. We have added additional experimental data and analysis to address the concerns.

Original issue from Public Review:

Immunolabeling of the hippocampus CA1 suggests sodium channels as well as Slack colocalization with AnkG (Fig 3A). Proximity ligation assay for NaV1.6 and Slack or a super-resolution microscopy approach would be needed to increase confidence in the presented colocalization results. Furthermore, coimmunoprecipitation studies on the membrane fraction would bolster the functional relevance of NaV1.6-Slack interaction on the cell surface.

Answer: We thank the reviewer for good suggestions. We acknowledge that employing proximity ligation assay and high-resolution techniques would significantly enhance our understanding of the localization of the Slack-NaV1.6 coupling.

At present, the technical capabilities available in our laboratory and institution do not support highresolution testing. However, we are enthusiastic about exploring potential collaborations to address these questions in the future. Furthermore, we fully recognize the importance of conducting coimmunoprecipitation (Co-IP) assays from membrane fractions. While we have already completed Co-IP assays for total protein and quantified the FRET efficiency values between Slack and NaV1.6 in the membrane region, the Co-IP assays on membrane fractions will be conducted in our future investigations.

New comment from reviewer: so far, the authors have not demonstrated that Nav1.6 and Slack interact on the cell surface.

Answer: We thank the reviewer for pointing this out. We acknowledgement that our data did not directly demonstrate interaction between NaV1.6 and Slack on the cell surface and we have removed related terminology in the revised manuscript. Notably, our patch-clamp experiments in Fig. 2D,G and Fig. S10B showed a Na+-mediated membrane current coupling of Slack and NaV1.6. Additionally, the FRET efficiency values between Slack and NaV1.6 were quantified in the membrane region. These findings suggest that membrane-near Slack interacts with NaV1.6.

Although hippocampal slices from Scn8a+/- were used for studies in Fig. S8, it is not clear whether Scn8a-/- or Scn8a+/- tissue was used in other studies (Fig 1J & 1K). It will be important to clarify whether genetic manipulation of NaV1.6 expression (Fig. 1K) has an impact on sodiumactivated potassium current, level of surface Slack expression, or that of NaV1.6 near Slack.

Answer: We thank the reviewer for pointing this out. In Fig. 1G,J,K, primary cortical neurons from homozygous NaV1.6 knockout (Scn8a-/-) mice were used. We will clarify this information in the revised manuscript. In terms of the effects of genetic manipulation of NaV1.6 expression on IKNa and surface Slack expression, we compared the amplitudes of IKNa measured from homozygous NaV1.6 knockout (NaV1.6-KO) neurons and wild-type (WT) neurons. The results showed that homozygous knockout of NaV1.6 does not alter the amplitudes of IKNa (Author response image 4). The level of surface Slack expression will be tested further.

Author response image 4.

The amplitudes of IKNa in WT and NaV1.6-KO neurons (data from manuscript Fig. 1K). ns, p > 0.05, unpaired two-tailed Student’s t test.

New comment from reviewer: The current version of the manuscrip>t does not contain these pertinent details and needs to be updated to include the information pertaining homozygous NaV1.6 knockouts. What age were these homozygous NaV1.6 knockout mice? These details need to be clearly stated in the manuscript.

Answer: We thank the reviewer for pointing this out. We have included this analysis in the revised manuscript (see Fig. S3A). The age of homozygous NaV1.6 knockout mice are P0-P1 and we have added this detail in the revised manuscript.

Did the epilepsy-related Slack mutations have an impact on NaV1.6-mediated sodium current?

Answer: We thank the reviewer’s question. We examined the amplitudes of NaV1.6 sodium current upon expression alone or co-expression of NaV1.6 with epilepsy-related Slack mutations (K629N, R950Q, K985N). The results showed that the tested epilepsy-related Slack mutations do not alter the amplitudes of NaV1.6 sodium current (Author response image 5).

Author response image 5.

The amplitudes of NaV1.6 sodium currents upon co-expression of NaV1.6 with epilepsy-related Slack mutant variants (SlackK629N, SlackR950Q, and SlackK985N). ns, p>0.05, oneway ANOVA followed by Bonferroni’s post hoc test.

New comment from reviewer: Figure with the functional effect of co-expression of NaV1.6 with epilepsy-related Slack mutations should be included in the revised manuscript

Answer: We thank the reviewer for pointing this out. We have included this analysis in the revised manuscript (see Fig. S10A).

Original issue from Recommendations For The Authors:

A reference to homozygous knockout is made in the abstract; however, only heterozygous mice are mentioned in the methods section. The genotype of the mice needs to be made clear in the manuscript. Furthermore, at what age were these mice used in the study. Since homozygous knockout of NaV1.6 is lethal at a very young age (<4 wks), it would be important to clarify that point as well.

Answer: We thank the reviewer for pointing this out. In the revised manuscript, we have included information about the source of the primary cortical neurons used in our study. These neurons were obtained from postnatal homozygous NaV1.6 knockout C3HeB/FeJ mice and their wild-type littermate controls.

New comment from reviewer: The answer that postnatal homozygous NaV1.6 knockout C3HeB/FeJ mice were used is insufficient. What age were these mice? This needs to be clearly stated in the manuscript.

Answer: We thank the reviewer for pointing this out. The postnatal homozygous NaV1.6 knockout C3HeB/FeJ mice and their wild-type littermate controls are in P0-P1. We have included this information in the revised manuscript.

How long were the cells exposed to quinidine before the functional measurement were performed?

Answer: We thank the reviewer for pointing this out. The cells were exposed to the bath solution with quinidine for about one minute before applying step pulses.

New comment from reviewer: This needs to be clearly stated in the manuscript.

Answer: We thank the reviewer for pointing this out. We have included this information in the revised manuscript (see in Methods section).

In Fig. 6B-D, it is not clear to what extent co-expression of Slack mutants and NaV1.6 increases sodium-activated potassium current.

Answer: We thank the reviewer for pointing this out. We notice that the current amplitudes of Slack mutants exhibit a considerable degree of variation, ranging from less than 1 nA to over 20 nA (n =58). To accurately measure the effects of NaV1.6 on increasing current amplitudes of Slack mutants, we plan to apply tetrodotoxin in the bath solution to block NaV1.6 sodium currents upon coexpression of Slack mutants with NaV1.6.

New comment from reviewer: Were these experiments with TTX completed? If so, they should be added to the revised manuscript.

Answer: We thank the reviewer for pointing this out. We compared the current amplitudes of epilepsy-related Slack mutant (SlackR950Q) before and after bath-application of 100 nM TTX upon co-expression with NaV1.6 in HEK293 cells. The results showed that bath-application of TTX significantly reduced the current amplitudes of SlackR950Q at +100 mV by nearly 40% (Author response image 6), suggesting NaV1.6 contributes to the current amplitudes of SlackR950Q. We have included this data in the revised manuscript (see Fig. S10B).

Author response image 6.

The current amplitudes of SlackR950Q before and after bath-application of 100 nM TTX upon co-expression with NaV1.6 in HEK293 cells (n=5). ***p < 0.001, Two-way repeated measures ANOVA followed by Bonferroni’s post hoc test.

Additionally, we have corrected some errors in the methods and figure captions section:

Line 513, bath solution “5 glucose” should be “10 glucose.”
Figure 3A caption, the description “hippocampus CA1 (left) and neocortex (right)” was flipped and we have corrected it.

References

Zhang Z, Rosenhouse-Dantsker A, Tang QY, Noskov S, Logothetis DE. The RCK2 domain uses a coordination site present in Kir channels to confer sodium sensitivity to Slo2.2 channels. J Neurosci. Jun 2 2010;30(22):7554-62. doi:10.1523/JNEUROSCI.0525-10.2010
Kaczmarek LK. Slack, Slick and Sodium-Activated Potassium Channels. ISRN Neurosci. Apr 18 2013;2013(2013)doi:10.1155/2013/354262
Budelli G, Hage TA, Wei A, et al. Na+-activated K+ channels express a large delayed outward current in neurons during normal physiology. Nat Neurosci. Jun 2009;12(6):745-50. doi:10.1038/nn.2313
Huang Z, Walker MC, Shah MM. Loss of dendritic HCN1 subunits enhances cortical excitability and epileptogenesis. J Neurosci. Sep 2 2009;29(35):10979-88. doi:10.1523/JNEUROSCI.1531-09.2009
Pinel JP, Rovner LI. Electrode placement and kindling-induced experimental epilepsy. Exp Neurol. Jan 15 1978;58(2):335-46. doi:10.1016/0014-4886(78)90145-0
Racine RJ. Modification of seizure activity by electrical stimulation. II. Motor seizure. Electroencephalogr Clin Neurophysiol. Mar 1972;32(3):281-94. doi:10.1016/0013-4694(72)90177-0
Kim EC, Zhang J, Tang AY, et al. Spontaneous seizure and memory loss in mice expressing an epileptic encephalopathy variant in the calmodulin-binding domain of Kv7.2. Proc Natl Acad Sci U S A. Dec 21 2021;118(51)doi:10.1073/pnas.2021265118

https://doi.org/10.7554/eLife.87559.3.sa4

Significance of findings

Strength of evidence

Abstract

Graphical abstract

Introduction

Results

NaV1.6 sensitizes Slack to quinidine blockade

NaV1.6 specifically sensitizes Slack to quinidine blockade.

Transient sodium influx through NaV1.6 enhances NaV1.6-mediated sensitization of Slack to quinidine blockade

Blocking transient sodium influx through NaV1.6 reduces NaV1.6-mediated sensitization of Slack to quinidine blockade.

Slack physically interacts with NaV1.6

Slack physically interacts with NaV1.6.

NaV1.6’s N- and C-termini bind to Slack’s C-terminus and sensitize Slack to quinidine blockade

NaV1.6’s N- and C-termini interacting with Slack is a prerequisite for NaV1.6-mediated sensitization of Slack to quinidine blockade.

Slack’s C-terminus is required for NaV1.6-mediated sensitization of Slack to quinidine blockade.

NaV1.6 binds to and sensitizes epilepsy-related Slack mutant variants to quinidine blockade

NaV1.6 sensitizes epilepsy-related Slack mutant variants to quinidine blockade.

Viral expression of Slack’s C-terminus prevents SlackG269S-induced seizures

Viral expression of Slack’s C-terminus prevents SlackG269S-induced seizures.

Discussion

Methods

Animals

Antibodies and Reagents

Molecular cloning

Immunoprecipitation

Western blot analysis

GST pull down assay

Cell culture

Voltage-clamp recordings

Acute slice preparation and current-clamp recordings

Fluorescence Imaging and FRET Quantification

Immunostaining

Adeno-associated virus construction and injection

Kainic acid-induced status epilepticus

Statistical analysis

Author contributions

Acknowledgements

Data availability

References

Article and author information

Author information

Tian Yuan#

Yifan Wang#

Yuchen Jin#

Hui Yang#

Shuai Xu

Heng Zhang

Qian Chen

Na Li

Xinyue Ma

Huifang Song

Chao Peng

Ze Geng

Jie Dong

Guifang Duan

Qi Sun

Yang Yang

Fan Yang

Zhuo Huang

Version history

Copyright

Peer review process

Editors

Na_V1.6 sensitizes Slack to quinidine blockade

Na_V1.6 specifically sensitizes Slack to quinidine blockade.

Transient sodium influx through Na_V1.6 enhances Na_V1.6-mediated sensitization of Slack to quinidine blockade

Blocking transient sodium influx through Na_V1.6 reduces Na_V1.6-mediated sensitization of Slack to quinidine blockade.

Slack physically interacts with Na_V1.6

Slack physically interacts with Na_V1.6.

Na_V1.6’s N- and C-termini bind to Slack’s C-terminus and sensitize Slack to quinidine blockade

Na_V1.6’s N- and C-termini interacting with Slack is a prerequisite for Na_V1.6-mediated sensitization of Slack to quinidine blockade.

Slack’s C-terminus is required for Na_V1.6-mediated sensitization of Slack to quinidine blockade.

Na_V1.6 binds to and sensitizes epilepsy-related Slack mutant variants to quinidine blockade

Na_V1.6 sensitizes epilepsy-related Slack mutant variants to quinidine blockade.

Viral expression of Slack’s C-terminus prevents Slack^G269S-induced seizures

Viral expression of Slack’s C-terminus prevents Slack^G269S-induced seizures.

Tian Yuan

Yifan Wang

Yuchen Jin

Hui Yang