Axon initial segment dysfunction in a mouse model of genetic epilepsy with febrile seizures plus
Verena C. Wimmer, … , Heinz Beck, Steven Petrou
Verena C. Wimmer, … , Heinz Beck, Steven Petrou
Published July 12, 2010
Citation Information: J Clin Invest. 2010;120(8):2661-2671. https://doi.org/10.1172/JCI42219.
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Research Article Neuroscience

Axon initial segment dysfunction in a mouse model of genetic epilepsy with febrile seizures plus

Abstract

Febrile seizures are a common childhood seizure disorder and a defining feature of genetic epilepsy with febrile seizures plus (GEFS+), a syndrome frequently associated with Na+ channel mutations. Here, we describe the creation of a knockin mouse heterozygous for the C121W mutation of the β1 Na+ channel accessory subunit seen in patients with GEFS+. Heterozygous mice with increased core temperature displayed behavioral arrest and were more susceptible to thermal challenge than wild-type mice. Wild-type β1 was most concentrated in the membrane of axon initial segments (AIS) of pyramidal neurons, while the β1(C121W) mutant subunit was excluded from AIS membranes. In addition, AIS function, an indicator of neuronal excitability, was substantially enhanced in hippocampal pyramidal neurons of the heterozygous mouse specifically at higher temperatures. Computational modeling predicted that this enhanced excitability was caused by hyperpolarized voltage activation of AIS Na+ channels. This heat-sensitive increased neuronal excitability presumably contributed to the heightened thermal seizure susceptibility and epileptiform discharges seen in patients and mice with β1(C121W) subunits. We therefore conclude that Na+ channel β1 subunits modulate AIS excitability and that epilepsy can arise if this modulation is impaired.

Authors

Verena C. Wimmer, Christopher A. Reid, Suzanne Mitchell, Kay L. Richards, Byron B. Scaf, Bryan T. Leaw, Elisa L. Hill, Michel Royeck, Marie-Therese Horstmann, Brett A. Cromer, Philip J. Davies, Ruwei Xu, Holger Lerche, Samuel F. Berkovic, Heinz Beck, Steven Petrou

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Figure 6

Altered AIS AP initiation in CW mice.

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Altered AIS AP initiation in CW mice. Black line/bars: CC, n = 13 neuron...
Black line/bars: CC, n = 13 neurons from 8 mice; red line/bars: CW, n = 13 neurons from 6 mice. (A) Averaged AP waveforms showing increased amplitude in CW cells (CC, 85.28 ± 0.2914 mV; CW, 97.52 ± 0.1081 mV; amplitude only analyzed for drive currents > 120 pA; CC, n = 97 APs; CW, n = 118; Mann-Whitney U test, P < 0.0001). (B) Time-aligned second derivative of AP waveform (d2V/dt2). (C) Magnification of boxed area in B; second derivative peaks illustrating significantly increased acceleration and increased peak-to-peak time in CW neurons (error bars represent SEM). (D) Comparison of phase plot of AP waveforms (dVdt/ dt) from CC and CW neurons. (E) Increased voltage acceleration in CW AIS (CC, n = 118 APs; CW, n = 139; Mann-Whitney U test, *P < 0.0001). (F) Increased delay between AIS and somatic peaks (CC, n = 103 APs; CW, n = 124; Mann-Whitney U test; *P < 0.0001). (G) Comparison of temperature sensitivity of AIS kinetics. Red solid (CW) and black (CC) lines are recordings made at 34°C as shown in D. Blue traces are recordings from the same genotypes but made at 22°C recording temperature (CW, light blue; CC, dark blue; CC, n = 71 APs from 8 cells; CW, n = 57 APs from 6 cells; P = 0.91, Student’s t test). Time bar: 0.5 ms or 0.1 ms (C); Vm bar: 20 mV; d2/V/dt2 bar: 1000 mV/s–2.